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\n \n\n \n \n \n \n \n \n Non‐native hosts of an invasive seaweed holobiont have more stable microbial communities compared to native hosts in response to thermal stress.\n \n \n \n \n\n\n \n Bonthond, G., Neu, A., Bayer, T., Krueger‐Hadfield, S. A., Künzel, S., & Weinberger, F.\n\n\n \n\n\n\n Ecology and Evolution, 13(1). January 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Non‐native$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n \n \n 2 downloads\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{bonthond_nonnative_2023,\n\ttitle = {Non‐native hosts of an invasive seaweed holobiont have more stable microbial communities compared to native hosts in response to thermal stress},\n\tvolume = {13},\n\tissn = {2045-7758, 2045-7758},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1002/ece3.9753},\n\tdoi = {10.1002/ece3.9753},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2023-01-27},\n\tjournal = {Ecology and Evolution},\n\tauthor = {Bonthond, Guido and Neu, Anna‐Katrin and Bayer, Till and Krueger‐Hadfield, Stacy A. and Künzel, Sven and Weinberger, Florian},\n\tmonth = jan,\n\tyear = {2023},\n}\n\n

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\n \n\n \n \n \n \n \n \n Photodegradation of a bacterial pigment and resulting hydrogen peroxide release enable coral settlement.\n \n \n \n \n\n\n \n Petersen, L., Kellermann, M. Y., Fiegel, L. J., Nietzer, S., Bickmeyer, U., Abele, D., & Schupp, P. J.\n\n\n \n\n\n\n Scientific Reports, 13(1): 3562. March 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Photodegradation$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{petersen_photodegradation_2023,\n\ttitle = {Photodegradation of a bacterial pigment and resulting hydrogen peroxide release enable coral settlement},\n\tvolume = {13},\n\tissn = {2045-2322},\n\turl = {https://www.nature.com/articles/s41598-023-30470-w},\n\tdoi = {10.1038/s41598-023-30470-w},\n\tabstract = {Abstract \n             \n              The global degradation of coral reefs is steadily increasing with ongoing climate change. Yet coral larvae settlement, a key mechanism of coral population rejuvenation and recovery, is largely understudied. Here, we show how the lipophilic, settlement-inducing bacterial pigment cycloprodigiosin (CYPRO) is actively harvested and subsequently enriched along the ectoderm of larvae of the scleractinian coral \n              Leptastrea purpura \n              . A light-dependent reaction transforms the CYPRO molecules through photolytic decomposition and provides a constant supply of hydrogen peroxide (H \n              2 \n              O \n              2 \n              ), leading to attachment on the substrate and metamorphosis into a coral recruit. Micromolar concentrations of H \n              2 \n              O \n              2 \n              in seawater also resulted in rapid metamorphosis, but without prior larval attachment. We propose that the morphogen CYPRO is responsible for initiating attachment while simultaneously acting as a molecular generator for the comprehensive metamorphosis of pelagic larvae. Ultimately, our approach opens a novel mechanistic dimension to the study of chemical signaling in coral settlement and provides unprecedented insights into the role of infochemicals in cross-kingdom interactions.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2023-03-28},\n\tjournal = {Scientific Reports},\n\tauthor = {Petersen, Lars-Erik and Kellermann, Matthias Y. and Fiegel, Laura J. and Nietzer, Samuel and Bickmeyer, Ulf and Abele, Doris and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2023},\n\tpages = {3562},\n}\n\n

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\n \n\n \n \n \n \n \n \n Detailed visualization of settlement and early development in Leptastrea purpurea reveals distinct bio-optical features.\n \n \n \n \n\n\n \n Fiegel, L. J., Kellermann, M. Y., Nietzer, S., Petersen, L., Smykala, M., Bickmeyer, U., & Schupp, P. J.\n\n\n \n\n\n\n Frontiers in Marine Science, 10: 984656. March 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Detailed$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{fiegel_detailed_2023,\n\ttitle = {Detailed visualization of settlement and early development in {Leptastrea} purpurea reveals distinct bio-optical features},\n\tvolume = {10},\n\tissn = {2296-7745},\n\turl = {https://www.frontiersin.org/articles/10.3389/fmars.2023.984656/full},\n\tdoi = {10.3389/fmars.2023.984656},\n\tabstract = {Sexually produced juvenile scleractinian corals play a key role in the adaptation process of coral reefs, as they are considered to possess an innate plasticity and thus can adjust to changing environmental parameters within a certain range. In this study we investigated in detail the early life stages of the brooding species \n              Leptastrea purpurea \n              to identify, categorize and visualize the critical steps of the complex transformation process from a swimming coral larva to a sessile coral recruit and later to a coral colony. For that, we performed settlement experiments using previously known cues: cycloprodigiosin (CYPRO) and crustose coralline algae (CCA) as well as novel cues: crude extracts of \n              Pseudoalteromonas espejiana \n              and \n              P. piscicida \n              to identify a general, cue-independent settlement pathway. We monitored the development of \n              L. purpurea \n              over 12 months using bright field and fluorescence microscopy. Also we identified the fluorescence signals of \n              L. purpurea \n              with confocal microscopy at four crucial development steps: (A) swimming larva, (B) metamorphosing larva, (C) coral recruit and (D) adult coral. Our methodological approach allowed us to observe an ontogenetic shift of fluorescence signals which provokes the hypothesis that certain fluorescence patterns might be connected to distinct sequential functions in the early life cycle of scleractinian corals. Our observations showed great similarities to the early development of other brooding and spawning corals, making \n              L. purpurea \n              a prospective candidate to be used as a model organism for coral research. Furthermore, our in-depth picture series provides a robust monitoring reference for coral nurseries or field applications and demonstrates the potential of fluorescence as an indicator to instantly determine the growth stage of a developing coral recruit.},\n\turldate = {2023-03-28},\n\tjournal = {Frontiers in Marine Science},\n\tauthor = {Fiegel, Laura J. and Kellermann, Matthias Y. and Nietzer, Samuel and Petersen, Lars-Erik and Smykala, Mike and Bickmeyer, Ulf and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2023},\n\tpages = {984656},\n}\n\n

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\n \n\n \n \n \n \n \n \n The Rhodoexplorer platform for red algal genomics and whole genome assemblies for several Gracilaria species.\n \n \n \n \n\n\n \n Lipinska, A. P., Krueger-Hadfield, S. A., Godfroy, O., Dittami, S., Ayres-Ostrock, L., Bonthond, G., Brillet-Guéguen, L., Coelho, S., Corre, E., Cossard, G., Destombe, C., Epperlein, P., Faugeron, S., Ficko-Blean, E., Beltrán, J., Lavaut, E., Bars, A. L., Marchi, F., Mauger, S., Michel, G., Potin, P., Scornet, D., Sotka, E. E., Weinberger, F., Cabral De Oliveira, M., Guillemin, M., Plastino, E. M., & Valero, M.\n\n\n \n\n\n\n March 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"The$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@misc{lipinska_rhodoexplorer_2023,\n\ttype = {preprint},\n\ttitle = {The {Rhodoexplorer} platform for red algal genomics and whole genome assemblies for several {Gracilaria} species},\n\turl = {http://biorxiv.org/lookup/doi/10.1101/2023.03.20.533491},\n\tabstract = {ABSTRACT \n           \n            Macroalgal (seaweed) genomic resources are generally lacking as compared to other eukaryotic taxa, and this is particularly true in the red algae (Rhodophyta). Understanding red algal genomes is critical to understanding eukaryotic evolution given that red algal genes are spread across eukaryotic lineages from secondary endosymbiosis and red algae diverged early in the Archaeplastids. The Gracilariales are highly diverse and widely distributed order whose species can serve as ecosystem engineers in intertidal habitats, including several notorious introduced species. The genus \n            Gracilaria \n            is cultivated worldwide, in part for its production of agar and other bioactive compounds with downstream pharmaceutical and industrial applications. This genus is also emerging as a model for algal evolutionary ecology. Here, we report new whole genome assemblies for two species ( \n            G. chilensis \n            and \n            G. gracilis \n            ), a draft genome assembly of \n            G. caudata \n            , and genome annotation of the previously published \n            G. vermiculophylla \n            genome. To facilitate accessibility and comparative analysis, we integrated these data in a newly created web-based portal dedicated to red algal genomics ( \n            https://rhodoexplorer.sb-roscoff.fr \n            ). These genomes will provide a resource for understanding algal biology and, more broadly, eukaryotic evolution.},\n\tlanguage = {en},\n\turldate = {2023-03-28},\n\tpublisher = {Genomics},\n\tauthor = {Lipinska, Agnieszka P. and Krueger-Hadfield, Stacy A. and Godfroy, Olivier and Dittami, Simon and Ayres-Ostrock, Lígia and Bonthond, Guido and Brillet-Guéguen, Loraine and Coelho, Susana and Corre, Erwan and Cossard, Guillaume and Destombe, Christophe and Epperlein, Paul and Faugeron, Sylvain and Ficko-Blean, Elizabeth and Beltrán, Jessica and Lavaut, Emma and Bars, Arthur Le and Marchi, Fabiana and Mauger, Stéphane and Michel, Gurvan and Potin, Philippe and Scornet, Delphine and Sotka, Erik E. and Weinberger, Florian and Cabral De Oliveira, Mariana and Guillemin, Marie-Laure and Plastino, Estela M. and Valero, Myriam},\n\tmonth = mar,\n\tyear = {2023},\n\tdoi = {10.1101/2023.03.20.533491},\n}\n\n

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\n \n\n \n \n \n \n \n \n Bio-optical properties of cyanobacterium Nodularia spumigena.\n \n \n \n \n\n\n \n Garaba, S. P., Albinus, M., Bonthond, G., Flöder, S., Miranda, M. L. M., Rohde, S., Yong, J. Y. L., & Wollschläger, J.\n\n\n \n\n\n\n January 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Bio-optical$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n \n \n 1 download\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@misc{garaba_bio-optical_2023,\n\ttype = {preprint},\n\ttitle = {Bio-optical properties of cyanobacterium {Nodularia} spumigena},\n\turl = {https://essd.copernicus.org/preprints/essd-2023-23/},\n\tabstract = {Abstract. In the last century an increasing number of extreme weather events have been experienced across the globe. These events have also been linked to changes in water quality especially due to heavy rains, flooding, or droughts. In terms of blue economic activities, one major threat are harmful algal bloom events that tend to be widespread and can last up to several days. We present and discuss advanced measurements of a bloom involving the cyanobacterium Nodularia spumigena conducted by hyperspectral optical technologies through experiments-of-opportunity. Absorption coefficients, absorbance and fluorescence were measured in the laboratory and these are available via (https://doi.org/10.4121/21610995.v1 (Wollschläger et al., 2022), https://doi.org/10.4121/21822051.v1 (Miranda et al., 2023) and https://doi.org/10.4121/21904632.v1 (Miranda and Garaba, 2023). Data used to derive the above-water reflectance is available via https://doi.org/10.4121/21814977.v1 (Garaba, 2023) and https://doi.org/10.4121/21814773.v1 (Garaba and Albinus, 2023). Additionally, hyperspectral fluorescence measurements of the dissolved compounds in the water were done. The hyperspectral measurements were conducted over a wide spectrum (200–2500 nm). Identification of the cyanobacterium was completed by visual analyses under a microscope. Diagnostic optical features were determined using robust statistical techniques. Water clarity was inferred from Secchi disk measurements https://doi.org/10.1594/PANGAEA.951239 (Garaba and Albinus, 2022). Full sequences were obtained of the 16S rRNA and rbcL genes revealing a very strong match to Nodularia spumigena, data available via GenBank https://www.ncbi.nlm.nih.gov/nuccore/OP918142/ (Garaba and Bonthond, 2022b) and https://www.ncbi.nlm.nih.gov/nuccore/OP925098 (Garaba and Bonthond, 2022a). The chlorophyll-a and phycocyanin levels determined are in open-access https://doi.org/10.4121/21792665.v1 (Rohde et al., 2023). Our experiments-of-opportunity echo the importance of sustainable, simplified, coordinated and continuous water quality monitoring as a way to thrive for the targets 2 set in the United Nations Sustainable Goals (e.g., Goals 6, 11, 12 and 14) or European Union Framework Directives (e.g. Water, Marine Strategy).},\n\turldate = {2023-02-15},\n\tpublisher = {ESSD – Ocean/Biological oceanography},\n\tauthor = {Garaba, Shungudzemwoyo P. and Albinus, Michelle and Bonthond, Guido and Flöder, Sabine and Miranda, Mario L. M. and Rohde, Sven and Yong, Joanne Y. L. and Wollschläger, Jochen},\n\tmonth = jan,\n\tyear = {2023},\n\tdoi = {10.5194/essd-2023-23},\n}\n\n

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\n Abstract. In the last century an increasing number of extreme weather events have been experienced across the globe. These events have also been linked to changes in water quality especially due to heavy rains, flooding, or droughts. In terms of blue economic activities, one major threat are harmful algal bloom events that tend to be widespread and can last up to several days. We present and discuss advanced measurements of a bloom involving the cyanobacterium Nodularia spumigena conducted by hyperspectral optical technologies through experiments-of-opportunity. Absorption coefficients, absorbance and fluorescence were measured in the laboratory and these are available via (https://doi.org/10.4121/21610995.v1 (Wollschläger et al., 2022), https://doi.org/10.4121/21822051.v1 (Miranda et al., 2023) and https://doi.org/10.4121/21904632.v1 (Miranda and Garaba, 2023). Data used to derive the above-water reflectance is available via https://doi.org/10.4121/21814977.v1 (Garaba, 2023) and https://doi.org/10.4121/21814773.v1 (Garaba and Albinus, 2023). Additionally, hyperspectral fluorescence measurements of the dissolved compounds in the water were done. The hyperspectral measurements were conducted over a wide spectrum (200–2500 nm). Identification of the cyanobacterium was completed by visual analyses under a microscope. Diagnostic optical features were determined using robust statistical techniques. Water clarity was inferred from Secchi disk measurements https://doi.org/10.1594/PANGAEA.951239 (Garaba and Albinus, 2022). Full sequences were obtained of the 16S rRNA and rbcL genes revealing a very strong match to Nodularia spumigena, data available via GenBank https://www.ncbi.nlm.nih.gov/nuccore/OP918142/ (Garaba and Bonthond, 2022b) and https://www.ncbi.nlm.nih.gov/nuccore/OP925098 (Garaba and Bonthond, 2022a). The chlorophyll-a and phycocyanin levels determined are in open-access https://doi.org/10.4121/21792665.v1 (Rohde et al., 2023). Our experiments-of-opportunity echo the importance of sustainable, simplified, coordinated and continuous water quality monitoring as a way to thrive for the targets 2 set in the United Nations Sustainable Goals (e.g., Goals 6, 11, 12 and 14) or European Union Framework Directives (e.g. Water, Marine Strategy).\n

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\n \n\n \n \n \n \n \n \n Ecotoxicological Effects of Four Commonly Used Organic Solvents on the Scleractinian Coral Montipora digitata.\n \n \n \n \n\n\n \n Di Mauro, V., Kamyab, E., Kellermann, M. Y., Moeller, M., Nietzer, S., Luetjens, L. H., Pawlowski, S., Petersen-Thiery, M., & Schupp, P. J.\n\n\n \n\n\n\n Toxics, 11(4): 367. April 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Ecotoxicological$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n\n

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@article{di_mauro_ecotoxicological_2023,\n\ttitle = {Ecotoxicological {Effects} of {Four} {Commonly} {Used} {Organic} {Solvents} on the {Scleractinian} {Coral} {Montipora} digitata},\n\tvolume = {11},\n\tcopyright = {http://creativecommons.org/licenses/by/3.0/},\n\tissn = {2305-6304},\n\turl = {https://www.mdpi.com/2305-6304/11/4/367},\n\tdoi = {10.3390/toxics11040367},\n\tabstract = {Organic solvents are often used in aquatic toxicity tests to facilitate the testing of hydrophobic or poorly water-soluble substances such as ultraviolet (UV) filters, pesticides, or polycyclic aromatic hydrocarbons (PAHs). Knowledge of intrinsic effects (i.e., measured as standardized and non-standardized endpoints) of such carrier solvents in non-standardized organisms (i.e., corals), is critical to regulatory processes. Therefore, we exposed the reef-building coral Montipora digitata to the most commonly used carrier solvents ethanol, methanol, dimethyl sulfoxide, and dimethylformamide in the range of 10–100 µL L−1 for 16 days. The effects on mortality, photobiological, morphological, and oxidative stress markers were evaluated. In our study, all solvents resulted in significant morphological and/or oxidative stress responses, but not in mortality. Moreover, ethanol led to a rapid increase in turbidity, thus questioning its suitability as a carrier solvent in aquatic studies in general. Based on our observations, we could rank the solvent effects as follows: dimethylformamide {\\textless} dimethyl sulfoxide ≈ methanol ≤ ethanol, with dimethylformamide showing the least and ethanol the most pronounced effects. We conclude that the use of solvents in toxicity studies with corals, particularly by examining non-standardized (e.g., morphological, physiological) endpoints, should be taken with caution and requires further elaboration.},\n\tlanguage = {en},\n\tnumber = {4},\n\turldate = {2023-04-13},\n\tjournal = {Toxics},\n\tauthor = {Di Mauro, Valentina and Kamyab, Elham and Kellermann, Matthias Y. and Moeller, Mareen and Nietzer, Samuel and Luetjens, Laura H. and Pawlowski, Sascha and Petersen-Thiery, Mechtild and Schupp, Peter J.},\n\tmonth = apr,\n\tyear = {2023},\n\tkeywords = {\\textit{Montipora digitata}, UV-filter, biomarker, dimethyl sulfoxide, dimethylformamide, ecotoxicology, ethanol, methanol, sunscreen, toxicity},\n\tpages = {367},\n}\n\n

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\n \n\n \n \n \n \n \n \n Body-Plan Reorganization in a Sponge Correlates with Microbiome Change.\n \n \n \n \n\n\n \n Vargas, S., Leiva, L., Eitel, M., Curdt, F., Rohde, S., Arnold, C., Nickel, M., Schupp, P., Orsi, W. D, Adamska, M., & Wörheide, G.\n\n\n \n\n\n\n Molecular Biology and Evolution, 40(6): msad138. June 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Body-Plan$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{vargas_body-plan_2023,\n\ttitle = {Body-{Plan} {Reorganization} in a {Sponge} {Correlates} with {Microbiome} {Change}},\n\tvolume = {40},\n\tissn = {0737-4038, 1537-1719},\n\turl = {https://academic.oup.com/mbe/article/doi/10.1093/molbev/msad138/7191912},\n\tdoi = {10.1093/molbev/msad138},\n\tabstract = {Abstract \n            Mounting evidence suggests that animals and their associated bacteria interact via intricate molecular mechanisms, and it is hypothesized that disturbances to the microbiome influence animal development. Here, we show that the loss of a key photosymbiont (i.e., bleaching) upon shading correlates with a stark body-plan reorganization in the common aquarium cyanosponge Lendenfeldia chondrodes. The morphological changes observed in shaded sponges include the development of a thread-like morphology that contrasts with the flattened, foliose morphology of control specimens. The microanatomy of shaded sponges markedly differed from that of control sponges, with shaded specimens lacking a well-developed cortex and choanosome. Also, the palisade of polyvacuolar gland-like cells typical in control specimens was absent in shaded sponges. The morphological changes observed in shaded specimens are coupled with broad transcriptomic changes and include the modulation of signaling pathways involved in animal morphogenesis and immune response, such as the Wnt, transforming growth factor β (TGF-β), and TLR–ILR pathways. This study provides a genetic, physiological, and morphological assessment of the effect of microbiome changes on sponge postembryonic development and homeostasis. The correlated response of the sponge host to the collapse of the population of symbiotic cyanobacteria provides evidence for a coupling between the sponge transcriptomic state and the state of its microbiome. This coupling suggests that the ability of animals to interact with their microbiomes and respond to microbiome perturbations has deep evolutionary origins in this group.},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2024-01-11},\n\tjournal = {Molecular Biology and Evolution},\n\tauthor = {Vargas, Sergio and Leiva, Laura and Eitel, Michael and Curdt, Franziska and Rohde, Sven and Arnold, Christopher and Nickel, Michael and Schupp, Peter and Orsi, William D and Adamska, Maja and Wörheide, Gert},\n\teditor = {Crandall, Keith},\n\tmonth = jun,\n\tyear = {2023},\n\tpages = {msad138},\n}\n\n

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\n \n\n \n \n \n \n \n \n Mass mortality event of the giant barrel sponge Xestospongia sp.: population dynamics and size distribution in Koh Phangan, Gulf of Thailand.\n \n \n \n \n\n\n \n Mueller, J. S., Grammel, P., Bill, N., Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n PeerJ, 11: e16561. December 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Mass$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{mueller_mass_2023,\n\ttitle = {Mass mortality event of the giant barrel sponge \\textit{{Xestospongia}} sp.: population dynamics and size distribution in {Koh} {Phangan}, {Gulf} of {Thailand}},\n\tvolume = {11},\n\tissn = {2167-8359},\n\tshorttitle = {Mass mortality event of the giant barrel sponge \\textit{{Xestospongia}} sp.},\n\turl = {https://peerj.com/articles/16561},\n\tdoi = {10.7717/peerj.16561},\n\tabstract = {Marine sponges are prominent organisms of the benthic coral reef fauna, providing important ecosystem services. While there have been increasing reports that sponges are becoming one of the dominant benthic organisms in some locations and ecoregions ( \n              e.g \n              . Caribbean), they can be impacted by changing environmental conditions. This study presents the first documentation of a mass mortality event of the barrel sponge \n              Xestospongia \n              sp. in the lower Gulf of Thailand and its consequences on population dynamics and size distribution. Two anthropogenic impacted reefs (Haad Khom and Mae Haad) of the island Koh Phangan and two anthropogenic non-impacted reefs of the islands Koh Yippon and Hin Yippon within the Mu Ko Ang Thong Marine National Park were surveyed in the years 2015 and 2016. The results showed a strong shift in population densities at Koh Phangan. Fatal “bleaching” ending up in mass mortality was observed for these reefs in 2015. \n              Xestospongia \n              sp. abundance decreased from 2015 to 2016 by 80.6\\% at Haad Khom and by 98.4\\% at Mae Haad. Sponges of all sizes were affected, and mortality occurred regardless of the survey depth (4 and 6 m). However, \n              Xestospongia \n              population densities in the Marine Park were at a constant level during the surveys. The abundances in 2015 were 65\\% higher at the Marine Park than at Koh Phangan and 92\\% higher in 2016. The most likely causes of the mass mortality event was a local harmful algal bloom event, pathogens, undetected local higher water temperatures, or a combination of these factors, whereas sea surface temperature analyses showed no marine heatwave during the observed mass mortality event in 2015. Considering the ecological importance of sponges such as \n              Xestospongia \n              sp., long-term monitoring of reefs and their environmental parameters should be implemented to prevent such mass die-offs.},\n\tlanguage = {en},\n\turldate = {2024-01-11},\n\tjournal = {PeerJ},\n\tauthor = {Mueller, Jasmin S. and Grammel, Paul-Jannis and Bill, Nicolas and Rohde, Sven and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2023},\n\tpages = {e16561},\n}\n\n

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\n \n\n \n \n \n \n \n \n Expanded sampling of New Zealand glass sponges (Porifera: Hexactinellida) provides new insights into biodiversity, chemodiversity, and phylogeny of the class.\n \n \n \n \n\n\n \n Dohrmann, M., Reiswig, H. M., Kelly, M., Mills, S., Schätzle, S., Reverter, M., Niesse, N., Rohde, S., Schupp, P., & Wörheide, G.\n\n\n \n\n\n\n PeerJ, 11: e15017. April 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Expanded$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{dohrmann_expanded_2023,\n\ttitle = {Expanded sampling of {New} {Zealand} glass sponges ({Porifera}: {Hexactinellida}) provides new insights into biodiversity, chemodiversity, and phylogeny of the class},\n\tvolume = {11},\n\tissn = {2167-8359},\n\tshorttitle = {Expanded sampling of {New} {Zealand} glass sponges ({Porifera}},\n\turl = {https://peerj.com/articles/15017},\n\tdoi = {10.7717/peerj.15017},\n\tabstract = {Glass sponges (Hexactinellida) constitute important parts of ecosystems on the deep-sea floor worldwide. However, they are still an understudied group in terms of their diversity and systematics. Here, we report on new specimens collected during RV \n              Sonne \n              expedition SO254 to the New Zealand region, which has recently emerged as a biodiversity hotspot for hexactinellids. Examination of the material revealed several species new to science or so far unknown from this area. While formal taxonomic descriptions of a fraction of these were published earlier, we here briefly report on the morphology of the remaining new species and use the collection to greatly expand the molecular phylogeny of the group as established with ribosomal DNA and cytochrome oxidase subunit I markers. In addition, we provide a chemical fingerprinting analysis on a subset of the specimens to investigate if the metabolome of glass sponges contains phylogenetic signal that could be used to supplement morphological and DNA-based approaches.},\n\tlanguage = {en},\n\turldate = {2024-01-11},\n\tjournal = {PeerJ},\n\tauthor = {Dohrmann, Martin and Reiswig, Henry M. and Kelly, Michelle and Mills, Sadie and Schätzle, Simone and Reverter, Miriam and Niesse, Natascha and Rohde, Sven and Schupp, Peter and Wörheide, Gert},\n\tmonth = apr,\n\tyear = {2023},\n\tpages = {e15017},\n}\n\n

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\n \n\n \n \n \n \n \n \n Benthic microbial biogeographic trends in the North Sea are shaped by an interplay of environmental drivers and bottom trawling effort.\n \n \n \n \n\n\n \n Bonthond, G., Beermann, J., Gutow, L., Neumann, A., Barboza, F. R., Desiderato, A., Fofonova, V., Helber, S. B., Khodami, S., Kraan, C., Neumann, H., Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n ISME Communications, 3(1): 132. December 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Benthic$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{bonthond_benthic_2023,\n\ttitle = {Benthic microbial biogeographic trends in the {North} {Sea} are shaped by an interplay of environmental drivers and bottom trawling effort},\n\tvolume = {3},\n\tissn = {2730-6151},\n\turl = {https://www.nature.com/articles/s43705-023-00336-3},\n\tdoi = {10.1038/s43705-023-00336-3},\n\tabstract = {Abstract \n            Microbial composition and diversity in marine sediments are shaped by environmental, biological, and anthropogenic processes operating at different scales. However, our understanding of benthic microbial biogeography remains limited. Here, we used 16S rDNA amplicon sequencing to characterize benthic microbiota in the North Sea from the top centimeter of 339 sediment samples. We utilized spatially explicit statistical models, to disentangle the effects of the different predictors, including bottom trawling intensity, a prevalent industrial fishing practice which heavily impacts benthic ecosystems. Fitted models demonstrate how the geographic interplay of different environmental and anthropogenic drivers shapes the diversity, structure and potential metabolism of benthic microbial communities. Sediment properties were the primary determinants, with diversity increasing with sediment permeability but also with mud content, highlighting different underlying processes. Additionally, diversity and structure varied with total organic matter content, temperature, bottom shear stress and bottom trawling. Changes in diversity associated with bottom trawling intensity were accompanied by shifts in predicted energy metabolism. Specifically, with increasing trawling intensity, we observed a transition toward more aerobic heterotrophic and less denitrifying predicted metabolism. Our findings provide first insights into benthic microbial biogeographic patterns on a large spatial scale and illustrate how anthropogenic activity such as bottom trawling may influence the distribution and abundances of microbes and potential metabolism at macroecological scales.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2024-01-11},\n\tjournal = {ISME Communications},\n\tauthor = {Bonthond, Guido and Beermann, Jan and Gutow, Lars and Neumann, Andreas and Barboza, Francisco Rafael and Desiderato, Andrea and Fofonova, Vera and Helber, Stephanie B. and Khodami, Sahar and Kraan, Casper and Neumann, Hermann and Rohde, Sven and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2023},\n\tpages = {132},\n}\n\n

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\n \n\n \n \n \n \n \n \n Acute Toxicity Assays with Adult Coral Fragments: A Method for Standardization.\n \n \n \n \n\n\n \n Brefeld, D., Di Mauro, V., Kellermann, M. Y., Nietzer, S., Moeller, M., Lütjens, L. H., Pawlowski, S., Petersen-Thiery, M., & Schupp, P. J.\n\n\n \n\n\n\n Toxics, 12(1): 1. December 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Acute$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{brefeld_acute_2023,\n\ttitle = {Acute {Toxicity} {Assays} with {Adult} {Coral} {Fragments}: {A} {Method} for {Standardization}},\n\tvolume = {12},\n\tissn = {2305-6304},\n\tshorttitle = {Acute {Toxicity} {Assays} with {Adult} {Coral} {Fragments}},\n\turl = {https://www.mdpi.com/2305-6304/12/1/1},\n\tdoi = {10.3390/toxics12010001},\n\tabstract = {Coral reefs are globally declining due to various anthropogenic stressors. Amongst those, chemical pollutants, such as pesticides from agricultural runoff, sewage or an overabundance of personal care products in coastal waters due to intense tourism, may be considered as a local stressor for reef-building corals. The extent to which such chemicals exhibit toxic effects towards corals at environmentally relevant concentrations is currently controversially discussed and existing studies are often based on varying and sometimes deficient test methods. To address this uncertainty, we adapted available methods into a reliable and comprehensive acute coral toxicity test method for the reef-building coral Montipora digitata. The toxicities of the four substances benzophenone-3 (BP-3), Diuron (DCMU), copper (Cu2+ as CuCl2, positive control) and dimethylformamide (DMF, solvent) were assessed in a 96 h semi-static test design. Endpoints such as maximum quantum yield, bleaching, tissue loss and mortality were evaluated with respect to their suitability for regulatory purposes. Overall, the endpoints bleaching and mortality yielded sensitive and robust results for the four tested substances. As the test method follows the principles of internationally standardized testing methods (ISO, OECD), it can be considered suitable for further validation and standardization. Once validated, a standardized test method will help to obtain reproducible toxicity results useful for marine hazard and risk assessment and regulatory decision making.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2024-01-11},\n\tjournal = {Toxics},\n\tauthor = {Brefeld, David and Di Mauro, Valentina and Kellermann, Matthias Y. and Nietzer, Samuel and Moeller, Mareen and Lütjens, Laura H. and Pawlowski, Sascha and Petersen-Thiery, Mechtild and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2023},\n\tpages = {1},\n}\n\n

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\n \n\n \n \n \n \n \n \n Abundance, biomass and species richness of macrozoobenthos along an intertidal elevation gradient.\n \n \n \n \n\n\n \n Dewenter, J., Yong, J., Schupp, P. J., Lõhmus, K., Kröncke, I., Moorthi, S., Pieck, D., Kuczynski, L., & Rohde, S.\n\n\n \n\n\n\n Ecology and Evolution, 13(12): e10815. December 2023.\n \n\n\n\n
\n\n\n\n \n \n $\"Abundance,$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{dewenter_abundance_2023,\n\ttitle = {Abundance, biomass and species richness of macrozoobenthos along an intertidal elevation gradient},\n\tvolume = {13},\n\tissn = {2045-7758, 2045-7758},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1002/ece3.10815},\n\tdoi = {10.1002/ece3.10815},\n\tabstract = {Abstract \n             \n              Ecology aims to comprehend species distribution and its interaction with environmental factors, from global to local scales. While global environmental changes affect marine biodiversity, understanding the drivers at smaller scales remains crucial. Tidal flats can be found on most of the world's coastlines and are particularly vulnerable to anthropogenic disturbances. They are important transient ecosystems between terrestrial and marine ecosystems, and their biodiversity provides important ecosystem services. Owing to this unique, terrestrial–marine transition, strong environmental gradients of elevation, sediment composition and food availability prevail. Here, we investigated which regional and local environmental factors drive the spatio‐temporal dynamics of macrozoobenthos communities on back‐barrier tidal flats in the East Frisian Wadden Sea. On the regional level, we found that species composition changed significantly from west to east on the East Frisian islands and that total abundance and species richness decreased from west to east. On the local abiotic level, we found that macrozoobenthos biomass decreased with higher elevation towards the salt marsh and that the total abundance of organisms in the sediment significantly increased with increasing mud content, while biodiversity and biomass were not changing significantly. In contrast to expectations, increasing Chl \n              a \n              availability as a measure of primary productivity did not result in changes in abundance, biomass or biodiversity, but extremely high total organic carbon (TOC) content was associated with a decrease in biomass and biodiversity. In conclusion, we found regional and local relationships that are similar to those observed in previous studies on macrozoobenthos in the Wadden Sea. Macrozoobenthos biomass, abundance and biodiversity are interrelated in a complex way with the physical, abiotic and biotic processes in and above the sediment.},\n\tlanguage = {en},\n\tnumber = {12},\n\turldate = {2024-01-12},\n\tjournal = {Ecology and Evolution},\n\tauthor = {Dewenter, Jana and Yong, Joanne and Schupp, Peter J. and Lõhmus, Kertu and Kröncke, Ingrid and Moorthi, Stefanie and Pieck, Daniela and Kuczynski, Lucie and Rohde, Sven},\n\tmonth = dec,\n\tyear = {2023},\n\tpages = {e10815},\n}\n\n

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\n \n 2022\n \n \n (15)\n \n \n

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\n \n\n \n \n \n \n \n \n A roadmap to understanding diversity and function of coral reef-associated fungi.\n \n \n \n \n\n\n \n Roik, A., Reverter, M., & Pogoreutz, C.\n\n\n \n\n\n\n FEMS Microbiology Reviews, 46(6): fuac028. November 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"A$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n \n \n 1 download\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{roik_roadmap_2022,\n\ttitle = {A roadmap to understanding diversity and function of coral reef-associated fungi},\n\tvolume = {46},\n\tissn = {1574-6976},\n\turl = {https://academic.oup.com/femsre/article/doi/10.1093/femsre/fuac028/6615459},\n\tdoi = {10.1093/femsre/fuac028},\n\tabstract = {Abstract\n            Tropical coral reefs are hotspots of marine productivity, owing to the association of reef-building corals with endosymbiotic algae and metabolically diverse bacterial communities. However, the functional importance of fungi, well-known for their contribution to shaping terrestrial ecosystems and global nutrient cycles, remains underexplored on coral reefs. We here conceptualize how fungal functional traits may have facilitated the spread, diversification, and ecological adaptation of marine fungi on coral reefs. We propose that functions of reef-associated fungi may be diverse and go beyond their hitherto described roles of pathogens and bioeroders, including but not limited to reef-scale biogeochemical cycles and the structuring of coral-associated and environmental microbiomes via chemical mediation. Recent technological and conceptual advances will allow the elucidation of the physiological, ecological, and chemical contributions of understudied marine fungi to coral holobiont and reef ecosystem functioning and health and may help provide an outlook for reef management actions.},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2022-11-08},\n\tjournal = {FEMS Microbiology Reviews},\n\tauthor = {Roik, Anna and Reverter, Miriam and Pogoreutz, Claudia},\n\tmonth = nov,\n\tyear = {2022},\n\tpages = {fuac028},\n}\n

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\n \n\n \n \n \n \n \n \n Mercury contamination level is repeatable and predicted by wintering area in a long-distance migratory seabird.\n \n \n \n \n\n\n \n Bertram, J., Kürten, N., Bichet, C., Schupp, P. J., & Bouwhuis, S.\n\n\n \n\n\n\n Environmental Pollution, 313: 120107. November 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Mercury$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{bertram_mercury_2022,\n\ttitle = {Mercury contamination level is repeatable and predicted by wintering area in a long-distance migratory seabird},\n\tvolume = {313},\n\tissn = {02697491},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0269749122013215},\n\tdoi = {10.1016/j.envpol.2022.120107},\n\tlanguage = {en},\n\turldate = {2022-11-08},\n\tjournal = {Environmental Pollution},\n\tauthor = {Bertram, Justine and Kürten, Nathalie and Bichet, Coraline and Schupp, Peter J. and Bouwhuis, Sandra},\n\tmonth = nov,\n\tyear = {2022},\n\tpages = {120107},\n}\n\n

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\n \n\n \n \n \n \n \n \n Harnessing the microbiome to prevent global biodiversity loss.\n \n \n \n \n\n\n \n Peixoto, R. S., Voolstra, C. R., Sweet, M., Duarte, C. M., Carvalho, S., Villela, H., Lunshof, J. E., Gram, L., Woodhams, D. C., Walter, J., Roik, A., Hentschel, U., Thurber, R. V., Daisley, B., Ushijima, B., Daffonchio, D., Costa, R., Keller-Costa, T., Bowman, J. S., Rosado, A. S., Reid, G., Mason, C. E., Walke, J. B., Thomas, T., & Berg, G.\n\n\n \n\n\n\n Nature Microbiology, 7(11): 1726–1735. July 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Harnessing$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{peixoto_harnessing_2022,\n\ttitle = {Harnessing the microbiome to prevent global biodiversity loss},\n\tvolume = {7},\n\tissn = {2058-5276},\n\turl = {https://www.nature.com/articles/s41564-022-01173-1},\n\tdoi = {10.1038/s41564-022-01173-1},\n\tlanguage = {en},\n\tnumber = {11},\n\turldate = {2022-11-08},\n\tjournal = {Nature Microbiology},\n\tauthor = {Peixoto, Raquel S. and Voolstra, Christian R. and Sweet, Michael and Duarte, Carlos M. and Carvalho, Susana and Villela, Helena and Lunshof, Jeantine E. and Gram, Lone and Woodhams, Douglas C. and Walter, Jens and Roik, Anna and Hentschel, Ute and Thurber, Rebecca Vega and Daisley, Brendan and Ushijima, Blake and Daffonchio, Daniele and Costa, Rodrigo and Keller-Costa, Tina and Bowman, Jeff S. and Rosado, Alexandre S. and Reid, Gregor and Mason, Christopher E. and Walke, Jenifer B. and Thomas, Torsten and Berg, Gabriele},\n\tmonth = jul,\n\tyear = {2022},\n\tpages = {1726--1735},\n}\n\n

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\n \n\n \n \n \n \n \n \n Transformation of dissolved organic matter by two Indo-Pacific sponges.\n \n \n \n \n\n\n \n Hildebrand, T., Osterholz, H., Bunse, C., Grotheer, H., Dittmar, T., & Schupp, P. J.\n\n\n \n\n\n\n Limnology and Oceanography,lno.12214. September 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Transformation$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n \n \n 3 downloads\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{hildebrand_transformation_2022,\n\ttitle = {Transformation of dissolved organic matter by two {Indo}-{Pacific} sponges},\n\tissn = {0024-3590, 1939-5590},\n\tshorttitle = {Transformation of dissolved organic matter by two {Indo}-{Pacific} sponges},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1002/lno.12214},\n\tdoi = {10.1002/lno.12214},\n\tlanguage = {en},\n\turldate = {2022-11-08},\n\tjournal = {Limnology and Oceanography},\n\tauthor = {Hildebrand, Tabea and Osterholz, Helena and Bunse, Carina and Grotheer, Hendrik and Dittmar, Thorsten and Schupp, Peter J.},\n\tmonth = sep,\n\tyear = {2022},\n\tpages = {lno.12214},\n}\n\n

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\n \n\n \n \n \n \n \n \n Exploring the Antibiotic Production Potential of Heterotrophic Bacterial Communities Isolated from the Marine Sponges Crateromorpha meyeri, Pseudaxinella reticulata, Farrea similaris, and Caulophacus arcticus through Synergistic Metabolomic and Genomic Analyses.\n \n \n \n \n\n\n \n Tareen, S., Schupp, P. J., Iqbal, N., & Wink, J.\n\n\n \n\n\n\n Marine Drugs, 20(7): 463. July 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Exploring$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{tareen_exploring_2022,\n\ttitle = {Exploring the {Antibiotic} {Production} {Potential} of {Heterotrophic} {Bacterial} {Communities} {Isolated} from the {Marine} {Sponges} {Crateromorpha} meyeri, {Pseudaxinella} reticulata, {Farrea} similaris, and {Caulophacus} arcticus through {Synergistic} {Metabolomic} and {Genomic} {Analyses}},\n\tvolume = {20},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/20/7/463},\n\tdoi = {10.3390/md20070463},\n\tabstract = {The discovery of novel secondary metabolites is actively being pursued in new ecosystems. Sponge-associated bacteria have been in the limelight in recent years on account of their ability to produce bioactive compounds. In this study, heterotrophic bacteria associated with four sponge species were isolated, taxonomically identified, and subjected to screening for the production of bioactive entities against a panel of nine microorganisms, including Gram-positive and negative bacteria, as well as yeast and fungi. Of the 105 isolated strains, 66\\% were represented by Proteobacteria, 16\\% by Bacteriodetes, 7\\% by Actinobacteria, and 11\\% by Firmicutes. Bioactivity screening revealed that 40\\% of the total isolated strains showed antimicrobial activity against one or more of the target microorganisms tested. Further, active extracts from selective species were narrowed down by bioassay-guided fractionation and subsequently identified by HR-ESI-MS analyses to locate the active peaks. Presumably responsible compounds for the observed bioactivities were identified as pentadecenoic acid, oleic acid, and palmitoleic acid. One isolate, Qipengyuania pacifica NZ-96T, based on 16S rRNA novelty, was subjected to comparative metabolic reconstruction analysis with its closest phylogenetic neighbors, revealing 79 unique functional roles in the novel isolate. In addition, genome mining of Qipengyuania pacifica NZ-96T revealed three biosynthetic gene clusters responsible for the biosynthesis of terpene, beta lactone, lasso peptide, and hserlactone secondary metabolites. Our results demonstrate the ability to target the sponge microbiome as a potential source of novel microbial life with biotechnological potential.},\n\tlanguage = {en},\n\tnumber = {7},\n\turldate = {2022-11-08},\n\tjournal = {Marine Drugs},\n\tauthor = {Tareen, Sanaullah and Schupp, Peter J. and Iqbal, Naveed and Wink, Joachim},\n\tmonth = jul,\n\tyear = {2022},\n\tpages = {463},\n}\n\n

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\n \n\n \n \n \n \n \n \n Population genetics and demography of the coral-killing cyanobacteriosponge, Terpios hoshinota, in the Indo-West Pacific.\n \n \n \n \n\n\n \n Chow, S. W., Keshavmurthy, S., Reimer, J. D., de Voogd, N., Huang, H., Wang, J., Tang, S., Schupp, P. J., Tan, C. H., Liew, H., Soong, K., Subhan, B., Madduppa, H., & Chen, C. A.\n\n\n \n\n\n\n PeerJ, 10: e13451. May 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Population$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{chow_population_2022,\n\ttitle = {Population genetics and demography of the coral-killing cyanobacteriosponge, \\textit{{Terpios} hoshinota,} in the {Indo}-{West} {Pacific}},\n\tvolume = {10},\n\tissn = {2167-8359},\n\turl = {https://peerj.com/articles/13451},\n\tdoi = {10.7717/peerj.13451},\n\tabstract = {The first occurrence of the cyanobacteriosponge\n              Terpios hoshinota\n              was reported from coral reefs in Guam in 1973, but was only formally described in 1993. Since then, the invasive behavior of this encrusting, coral-killing sponge has been observed in many coral reefs in the West Pacific. From 2015, its occurrence has expanded westward to the Indian Ocean. Although many studies have investigated the morphology, ecology, and symbiotic cyanobacteria of this sponge, little is known of its population genetics and demography. In this study, a mitochondrial cytochrome oxidase I (COI) fragment and nuclear ribosomal internal transcribed spacer 2 (ITS2) were sequenced to reveal the genetic variation of\n              T. hoshinota\n              collected from 11 marine ecoregions throughout the Indo-West Pacific. Both of the statistical parsimony networks based on the COI and nuclear ITS2 were dominated by a common haplotype. Pairwise\n              F\n              ST\n              and Isolation-by-distance by Mantel test of ITS2 showed moderate gene flow existed among most populations in the marine ecoregions of West Pacific, Coral Triangle, and Eastern Indian Ocean, but with a restricted gene flow between these regions and Maldives in the Central Indian Ocean. Demographic analyses of most\n              T. hoshinota\n              populations were consistent with the mutation-drift equilibrium, except for the Sulawesi Sea and Maldives, which showed bottlenecks following recent expansion. Our results suggest that while long-range dispersal might explain the capability of\n              T. hoshinota\n              to spread in the IWP, stable population demography might account for the long-term persistence of\n              T. hoshinota\n              outbreaks on local reefs.},\n\tlanguage = {en},\n\turldate = {2022-11-08},\n\tjournal = {PeerJ},\n\tauthor = {Chow, Savanna Wenhua and Keshavmurthy, Shashank and Reimer, James Davis and de Voogd, Nicole and Huang, Hui and Wang, Jih-Terng and Tang, Sen-Lin and Schupp, Peter J. and Tan, Chun Hong and Liew, Hock-Chark and Soong, Keryea and Subhan, Beginer and Madduppa, Hawis and Chen, Chaolun Allen},\n\tmonth = may,\n\tyear = {2022},\n\tpages = {e13451},\n}\n\n

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\n \n\n \n \n \n \n \n \n Towards the Development of Standardized Bioassays for Corals: Acute Toxicity of the UV Filter Benzophenone-3 to Scleractinian Coral Larvae.\n \n \n \n \n\n\n \n Miller, I. B., Moeller, M., Kellermann, M. Y., Nietzer, S., Di Mauro, V., Kamyab, E., Pawlowski, S., Petersen-Thiery, M., & Schupp, P. J.\n\n\n \n\n\n\n Toxics, 10(5): 244. May 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Towards$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{miller_towards_2022,\n\ttitle = {Towards the {Development} of {Standardized} {Bioassays} for {Corals}: {Acute} {Toxicity} of the {UV} {Filter} {Benzophenone}-3 to {Scleractinian} {Coral} {Larvae}},\n\tvolume = {10},\n\tissn = {2305-6304},\n\tshorttitle = {Towards the {Development} of {Standardized} {Bioassays} for {Corals}},\n\turl = {https://www.mdpi.com/2305-6304/10/5/244},\n\tdoi = {10.3390/toxics10050244},\n\tabstract = {Coral reefs have been declining globally at a historically unprecedented rate. Ultraviolet (UV) filters used in sunscreens may contribute to this decline at local scales, which has already led to bans on various organic UV filters in some regions. However, the underlying studies for these bans demonstrated significant flaws in the experimental design due to a lack of validated and standardized testing methods for corals. This study aimed to investigate options for the development of a standard acute toxicity test for the larval stage of scleractinian corals. Planula larvae of two brooding (Leptastrea purpurea and Tubastraea faulkneri) and two spawning (Acropora digitifera and A. millepora) species were exposed to the organic UV filter benzophenone-3 (BP3) for 48 h under static conditions. We observed interspecific variations in toxicity, with A. digitifera being the most sensitive (LC50 = 0.75 µg L−1) and T. faulkneri the least sensitive (LC50 = 2951.24 µg L−1) species. Inhibition of settlement was found to be a useful endpoint leading to an EC50 of 1.84 µg L−1 in L. purpurea larvae. Although the analytical challenges of measuring lipophilic substances in small volume test setups remain, the here applied test design and selected endpoints are suitable for further validation and subsequent standardization.},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-09},\n\tjournal = {Toxics},\n\tauthor = {Miller, Ingo B. and Moeller, Mareen and Kellermann, Matthias Y. and Nietzer, Samuel and Di Mauro, Valentina and Kamyab, Elham and Pawlowski, Sascha and Petersen-Thiery, Mechtild and Schupp, Peter J.},\n\tmonth = may,\n\tyear = {2022},\n\tpages = {244},\n}\n\n

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\n \n\n \n \n \n \n \n \n Prevalence, complete genome, and metabolic potentials of a phylogenetically novel cyanobacterial symbiont in the coral‐killing sponge, Terpios hoshinota.\n \n \n \n \n\n\n \n Chen, Y., Chen, H., Yang, C., Shiu, J., Hoh, D. Z., Chiang, P., Chow, W. S., Chen, C. A., Shih, T., Lin, S., Yang, C., Reimer, J. D., Hirose, E., Iskandar, B. H., Huang, H., Schupp, P. J., Tan, C. H. J., Yamashiro, H., Liao, M., & Tang, S.\n\n\n \n\n\n\n Environmental Microbiology, 24(3): 1308–1325. March 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Prevalence,$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n \n \n 1 download\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{chen_prevalence_2022,\n\ttitle = {Prevalence, complete genome, and metabolic potentials of a phylogenetically novel cyanobacterial symbiont in the coral‐killing sponge, \\textit{{Terpios} hoshinota}},\n\tvolume = {24},\n\tissn = {1462-2912, 1462-2920},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1111/1462-2920.15824},\n\tdoi = {10.1111/1462-2920.15824},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-08},\n\tjournal = {Environmental Microbiology},\n\tauthor = {Chen, Yu‐Hsiang and Chen, Hsing‐Ju and Yang, Cheng‐Yu and Shiu, Jia‐Ho and Hoh, Daphne Z. and Chiang, Pei‐Wen and Chow, Wenhua Savanna and Chen, Chaolun Allen and Shih, Tin‐Han and Lin, Szu‐Hsien and Yang, Chi‐Ming and Reimer, James Davis and Hirose, Euichi and Iskandar, Budhi Hascaryo and Huang, Hui and Schupp, Peter J. and Tan, Chun Hong James and Yamashiro, Hideyuki and Liao, Ming‐Hui and Tang, Sen‐Lin},\n\tmonth = mar,\n\tyear = {2022},\n\tpages = {1308--1325},\n}\n\n

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\n \n\n \n \n \n \n \n \n Light Availability Affects the Symbiosis of Sponge Specific Cyanobacteria and the Common Blue Aquarium Sponge (Lendenfeldia chondrodes).\n \n \n \n \n\n\n \n Curdt, F., Schupp, P. J., & Rohde, S.\n\n\n \n\n\n\n Animals, 12(10): 1283. May 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Light$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{curdt_light_2022,\n\ttitle = {Light {Availability} {Affects} the {Symbiosis} of {Sponge} {Specific} {Cyanobacteria} and the {Common} {Blue} {Aquarium} {Sponge} ({Lendenfeldia} chondrodes)},\n\tvolume = {12},\n\tissn = {2076-2615},\n\turl = {https://www.mdpi.com/2076-2615/12/10/1283},\n\tdoi = {10.3390/ani12101283},\n\tabstract = {Bacterial symbionts in marine sponges play a decisive role in the biological and ecological functioning of their hosts. Although this topic has been the focus of numerous studies, data from experiments under controlled conditions are rare. To analyze the ongoing metabolic processes, we investigated the symbiosis of the sponge specific cyanobacterium Synechococcus spongiarum and its sponge host Lendenfeldia chondrodes under varying light conditions in a defined aquarium setting for 68 days. Sponge clonal pieces were kept at four different light intensities, ranging from no light to higher intensities that were assumed to trigger light stress. Growth as a measure of host performance and photosynthetic yield as a proxy of symbiont photosynthetic activity were measured throughout the experiment. The lack of light prevented sponge growth and induced the expulsion of all cyanobacteria and related pigments by the end of the experiment. Higher light conditions allowed rapid sponge growth and high cyanobacteria densities. In addition, photosynthetically active radiation above a certain level triggered an increase in cyanobacteria’s lutein levels, a UV absorbing protein, thus protecting itself and the host’s cells from UV radiation damage. Thus, L. chondrodes seems to benefit strongly from hosting the cyanbacterium S. spongiarum and the relationship should be considered obligatory mutualistic.},\n\tlanguage = {en},\n\tnumber = {10},\n\turldate = {2022-11-08},\n\tjournal = {Animals},\n\tauthor = {Curdt, Franziska and Schupp, Peter J. and Rohde, Sven},\n\tmonth = may,\n\tyear = {2022},\n\tpages = {1283},\n}\n\n

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\n \n\n \n \n \n \n \n \n Coral reef benthic community changes in the Anthropocene: Biogeographic heterogeneity, overlooked configurations, and methodology.\n \n \n \n \n\n\n \n Reverter, M., Helber, S. B., Rohde, S., Goeij, J. M., & Schupp, P. J.\n\n\n \n\n\n\n Global Change Biology, 28(6): 1956–1971. March 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Coral$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{reverter_coral_2022,\n\ttitle = {Coral reef benthic community changes in the {Anthropocene}: {Biogeographic} heterogeneity, overlooked configurations, and methodology},\n\tvolume = {28},\n\tissn = {1354-1013, 1365-2486},\n\tshorttitle = {Coral reef benthic community changes in the {Anthropocene}},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1111/gcb.16034},\n\tdoi = {10.1111/gcb.16034},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2022-11-08},\n\tjournal = {Global Change Biology},\n\tauthor = {Reverter, Miriam and Helber, Stephanie B. and Rohde, Sven and Goeij, Jasper M. and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2022},\n\tpages = {1956--1971},\n}\n\n

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\n \n\n \n \n \n \n \n \n Pacificimonas pallium sp. nov., an Isolated Bacterium from the Mantle of Pacific Oyster Crassostrea gigas in Germany, and Prediction of One-Carbon Metabolism.\n \n \n \n \n\n\n \n Pira, H., Risdian, C., Müsken, M., Schupp, P. J., & Wink, J.\n\n\n \n\n\n\n Diversity, 14(3): 181. February 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Pacificimonas$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{pira_pacificimonas_2022,\n\ttitle = {Pacificimonas pallium sp. nov., an {Isolated} {Bacterium} from the {Mantle} of {Pacific} {Oyster} {Crassostrea} gigas in {Germany}, and {Prediction} of {One}-{Carbon} {Metabolism}},\n\tvolume = {14},\n\tissn = {1424-2818},\n\turl = {https://www.mdpi.com/1424-2818/14/3/181},\n\tdoi = {10.3390/d14030181},\n\tabstract = {A yellow bacterium from marine agar, strain WHA3T, was isolated from the mantel of the Pacific oysters Crassostrea gigas in the Wilhelmshaven Sea in northern Germany. Based on the 16S rRNA gene sequence, strain WHA3T had a high similarity to Pacificimonas flava JLT2015T (95.80\\%) and 94.79\\% to Pacificimonas aurantium JLT2012T. Furthermore, the dDDH and ANI value analysis between WHA3T and other closest type strains were lower than 70\\% and 95\\%, respectively. The percentage of conserved proteins (POCP) and the average amino acid identity (AAI) value against Pacificimonas flava JLT2015T and Pacificimonas aurantium JLT2012T represented in the ranges of higher than 50\\% and 60\\%, respectively. Strain WHA3T contained ubiquinone-10 (Q-10) as the predominant quinone, and the major fatty acids were C16:1 ω7c and C18:1 ω7c. Granules of polyhydroxyalkanoates (PHAs) were absent. The main polar lipids were diphosphatidylglycerol, phosphatidylethanolamine, phosphatidylglycerol, several sphingoglycolipids, an unknown phospholipid, an unknown glycolipid, and an unknown polar lipid. The polyamines contained spermidine and spermine. The DNA G + C content of strain WHA3T was 61.69\\%. An analysis of the whole-genome sequence in the frame of genome mining strain WHA3T predicted the presence of genomes for one-carbon metabolism, TonB-dependent transporters, vitamin B12 transporter, iron siderophore receptor protein, and other genes, some of which play important roles against restricted nutrient sources. The extract of strain WHA3T moderately inhibited the growth of Candida albicans DSM 1665. The polyphasic taxonomic analysis results suggested that strain WHA3T could be separated from its closest type strains. Strain WHA3T represents a novel species in the genus Pacificimonas, for which we propose the name Pacificimonaspallium sp. nov., with the type strain WHA3T (= DSM 111825T = NCCB 100832T).},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-08},\n\tjournal = {Diversity},\n\tauthor = {Pira, Hani and Risdian, Chandra and Müsken, Mathias and Schupp, Peter J. and Wink, Joachim},\n\tmonth = feb,\n\tyear = {2022},\n\tpages = {181},\n}\n\n

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\n \n\n \n \n \n \n \n \n A comprehensive approach to assess marine macro litter pollution and its impacts on corals in the Bangka Strait, North Sulawesi, Indonesia.\n \n \n \n \n\n\n \n Mueller, J. S., Bill, N., Reinach, M. S., Lasut, M. T., Freund, H., & Schupp, P. J.\n\n\n \n\n\n\n Marine Pollution Bulletin, 175: 113369. February 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"A$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{mueller_comprehensive_2022,\n\ttitle = {A comprehensive approach to assess marine macro litter pollution and its impacts on corals in the {Bangka} {Strait}, {North} {Sulawesi}, {Indonesia}},\n\tvolume = {175},\n\tissn = {0025326X},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0025326X22000510},\n\tdoi = {10.1016/j.marpolbul.2022.113369},\n\tlanguage = {en},\n\turldate = {2022-11-08},\n\tjournal = {Marine Pollution Bulletin},\n\tauthor = {Mueller, Jasmin S. and Bill, Nicolas and Reinach, Marco S. and Lasut, Markus T. and Freund, Holger and Schupp, Peter J.},\n\tmonth = feb,\n\tyear = {2022},\n\tpages = {113369},\n}\n\n

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\n \n\n \n \n \n \n \n \n Characterization of an Insoluble and Soluble Form of Melanin Produced by Streptomyces cavourensis SV 21, a Sea Cucumber Associated Bacterium.\n \n \n \n \n\n\n \n Wibowo, J. T., Kellermann, M. Y., Petersen, L., Alfiansah, Y. R., Lattyak, C., & Schupp, P. J.\n\n\n \n\n\n\n Marine Drugs, 20(1): 54. January 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Characterization$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{wibowo_characterization_2022,\n\ttitle = {Characterization of an {Insoluble} and {Soluble} {Form} of {Melanin} {Produced} by {Streptomyces} cavourensis {SV} 21, a {Sea} {Cucumber} {Associated} {Bacterium}},\n\tvolume = {20},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/20/1/54},\n\tdoi = {10.3390/md20010054},\n\tabstract = {Melanin is a widely distributed and striking dark-colored pigment produced by countless living organisms. Although a wide range of bioactivities have been recognized, there are still major constraints in using melanin for biotechnological applications such as its fragmentary known chemical structure and its insolubility in inorganic and organic solvents. In this study, a bacterial culture of Streptomyces cavourensis SV 21 produced two distinct forms of melanin: (1) a particulate, insoluble form as well as (2) a rarely observed water-soluble form. The here presented novel, acid-free purification protocol of purified particulate melanin (PPM) and purified dissolved melanin (PDM) represents the basis for an in-depth comparison of their physicochemical and biological properties, which were compared to the traditional acid-based precipitation of melanin (AM) and to a synthetic melanin standard (SM). Our data show that the differences in solubility between PDM and PPM in aqueous solutions may be a result of different adjoining cation species, since the soluble PDM polymer is largely composed of Mg2+ ions and the insoluble PPM is dominated by Ca2+ ions. Furthermore, AM shared most properties with SM, which is likely attributed to a similar, acid-based production protocol. The here presented gentler approach of purifying melanin facilitates a new perspective of an intact form of soluble and insoluble melanin that is less chemical altered and thus closer to its original biological form.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Wibowo, Joko Tri and Kellermann, Matthias Y. and Petersen, Lars-Erik and Alfiansah, Yustian R. and Lattyak, Colleen and Schupp, Peter J.},\n\tmonth = jan,\n\tyear = {2022},\n\tpages = {54},\n}\n\n

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\n \n\n \n \n \n \n \n \n Fungal endophytes vary by species, tissue type, and life cycle stage in intertidal macroalgae.\n \n \n \n \n\n\n \n Bonthond, G., Barilo, A., Allen, R. J., Cunliffe, M., & Krueger‐Hadfield, S. A.\n\n\n \n\n\n\n Journal of Phycology, 58(2): 330–342. April 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Fungal$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{bonthond_fungal_2022,\n\ttitle = {Fungal endophytes vary by species, tissue type, and life cycle stage in intertidal macroalgae},\n\tvolume = {58},\n\tcopyright = {Creative Commons Attribution 4.0 International License (CC-BY)},\n\tissn = {0022-3646, 1529-8817},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1111/jpy.13237},\n\tdoi = {10.1111/jpy.13237},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Phycology},\n\tauthor = {Bonthond, Guido and Barilo, Anastasiia and Allen, Ro J. and Cunliffe, Michael and Krueger‐Hadfield, Stacy A.},\n\teditor = {Lane, C.},\n\tmonth = apr,\n\tyear = {2022},\n\tpages = {330--342},\n}\n\n

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\n \n\n \n \n \n \n \n \n Spatial and temporal patterns of microphytobenthos communities along the marine-terrestrial boundary in the German Wadden Sea.\n \n \n \n \n\n\n \n Yong, J., Moick, M., Dewenter, J., Hillebrand, H., Kröncke, I., Lõhmus, K., Pieck, D., Rohde, S., & Moorthi, S.\n\n\n \n\n\n\n Frontiers in Ecology and Evolution, 10: 956092. September 2022.\n \n\n\n\n
\n\n\n\n \n \n $\"Spatial$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{yong_spatial_2022,\n\ttitle = {Spatial and temporal patterns of microphytobenthos communities along the marine-terrestrial boundary in the {German} {Wadden} {Sea}},\n\tvolume = {10},\n\tissn = {2296-701X},\n\turl = {https://www.frontiersin.org/articles/10.3389/fevo.2022.956092/full},\n\tdoi = {10.3389/fevo.2022.956092},\n\tabstract = {Microphytobenthos (MPBs) are the main primary producers in shallow marine ecosystems, such as the Wadden Sea. We investigated the spatial and temporal dynamics of MPB communities across the marine-terrestrial boundary over three seasons (spring, summer, and fall) on three East Frisian Islands (Norderney, Spiekeroog, and Wangerooge) in the German Wadden Sea. Natural transects were compared with 12 experimental islands (salt marsh vegetated vs. initially bare islands) established on the tidal flats of Spiekeroog for studying dispersal-mediated community assembly. Sediment cores were taken along triplicate transects and on three elevation levels of the experimental islands, corresponding to the pioneer (pio) zone, the lower salt (LS) marsh, and the upper salt (US) marsh. On both the natural transects and the experimental islands, the highest MPB biomass was observed in the pio zone, where vegetation-driven sediment stabilization and high-mud content could have promoted MPB biomass in this marine-terrestrial transition zone. On the experimental islands, MPB biomass and diversity significantly decreased with elevation regardless of the season, indicating that the rarely submerged upper salt marsh level supported minimal MPB growth. The MPB biomass was also higher on initially vegetated than on bare islands, which was the most pronounced on the US level. On the tidal flat transects, the MPB biomass significantly increased with elevation up to the pio zone before decreasing again in the LS marsh. Temperature, sediment water content, and grain size significantly affected transect MPB biomass. MPB diversity, on the other hand, was not related to elevation but was rather determined by temperature, mean grain size, and mud content. Our study suggests that extending MPB studies into the “terrestrial” domain of salt marshes enhances our understanding of the microalgae–plant interaction in this important boundary zone.},\n\turldate = {2022-11-10},\n\tjournal = {Frontiers in Ecology and Evolution},\n\tauthor = {Yong, Joanne and Moick, Melissa and Dewenter, Jana and Hillebrand, Helmut and Kröncke, Ingrid and Lõhmus, Kertu and Pieck, Daniela and Rohde, Sven and Moorthi, Stefanie},\n\tmonth = sep,\n\tyear = {2022},\n\tpages = {956092},\n}\n\n

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\n \n 2021\n \n \n (15)\n \n \n

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\n \n\n \n \n \n \n \n \n Zooshikella harenae sp. nov., Isolated from Pacific Oyster Crassostrea gigas, and Establishment of Zooshikella ganghwensis subsp. marina subsp. nov. and Zooshikella ganghwensis subsp. ganghwensis subsp. nov.\n \n \n \n \n\n\n \n Pira, H., Risdian, C., Kämpfer, P., Müsken, M., Schupp, P. J., & Wink, J.\n\n\n \n\n\n\n Diversity, 13(12): 641. December 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Zooshikella$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{pira_zooshikella_2021,\n\ttitle = {Zooshikella harenae sp. nov., {Isolated} from {Pacific} {Oyster} {Crassostrea} gigas, and {Establishment} of {Zooshikella} ganghwensis subsp. marina subsp. nov. and {Zooshikella} ganghwensis subsp. ganghwensis subsp. nov.},\n\tvolume = {13},\n\tissn = {1424-2818},\n\turl = {https://www.mdpi.com/1424-2818/13/12/641},\n\tdoi = {10.3390/d13120641},\n\tabstract = {Here, we describe the polyphasic taxonomy of a novel isolated strain WH53T from the genus Zooshikella isolated from the sand sediment located between the lumen of the Crassostrea gigas From Germany. Phylogenetic analysis determined that the strain WH53T had a high similarity to Zooshikella ganghwensis JC2044T (99.57\\%) and Zooshikella marina LMG 28823T (99.36\\%). Strain WH53T contained ubiquinone-9 (Q-9) as the predominant menaquinone, and the major fatty acids were C16:0, C16:1ω7c, and C18:1ω7c. Diphosphatidylglycerol, phosphatidylglycerol, phosphatidylethanolamine, amino phospholipids, and unidentified phospholipids were identified as their polar lipid composition. The DNA G+C content and genome size of strain WH53T were 40.08 mol\\% and 5,914,969 bp, respectively. Digital DNA–DNA hybridisation (dDDH) for strain WH53T against Z. ganghwensis JC2044T and Z. marina LMG 28823T showed low relatedness values of 26.3\\% and 26.1\\%, respectively. The extract of strain WH53T exhibited antimicrobial property. Strain WH53T represents a novel species in the genus Zooshikella. We propose the name of Zooshikella harenae sp. nov., with the type strain WH53T (= DSM 111628T = NCCB 100808T). Furthermore, the dDDH, average nucleotide identity (ANI), percentage of conserved proteins (POCP), and amino acid identity (AAI) value between Z. marina LGM 28823T and Z. ganghwensis DSM 15267T were 79.9\\%, 97.84\\%, 76.08\\%, and 87.01\\%, respectively, suggesting that both of them should be reclassified as Z. ganghwensis subsp. marina subsp. nov. and Z. ganghwensis subsp. ganghwensis DSM 15267 subsp. nov.},\n\tlanguage = {en},\n\tnumber = {12},\n\turldate = {2022-11-09},\n\tjournal = {Diversity},\n\tauthor = {Pira, Hani and Risdian, Chandra and Kämpfer, Peter and Müsken, Mathias and Schupp, Peter J. and Wink, Joachim},\n\tmonth = dec,\n\tyear = {2021},\n\tpages = {641},\n}\n\n

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\n \n\n \n \n \n \n \n \n Rossellid glass sponges (Porifera, Hexactinellida) from New Zealand waters, with description of one new genus and six new species.\n \n \n \n \n\n\n \n Reiswig, H. M., Dohrmann, M., Kelly, M., Mills, S., Schupp, P. J., & Wörheide, G.\n\n\n \n\n\n\n ZooKeys, 1060: 33–84. September 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Rossellid$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{reiswig_rossellid_2021,\n\ttitle = {Rossellid glass sponges ({Porifera}, {Hexactinellida}) from {New} {Zealand} waters, with description of one new genus and six new species},\n\tvolume = {1060},\n\tissn = {1313-2970, 1313-2989},\n\turl = {https://zookeys.pensoft.net/article/63307/},\n\tdoi = {10.3897/zookeys.1060.63307},\n\tabstract = {New Zealand’s surrounding deep waters have become known as a diversity hotspot for glass sponges (Porifera: Hexactinellida) in recent years, and description and collection efforts are continuing. Here we report on eight rossellids (Hexasterophora: Lyssacinosida: Rossellidae) collected during the 2017 RV Sonne cruise SO254 by ROV Kiel 6000 as part of Project PoribacNewZ of the University of Oldenburg, Germany. The material includes six species new to science, two of which are assigned to a so far undescribed genus; we further re-describe two previously known species. The known extant rossellid diversity from the New Zealand region is thus almost doubled, from nine species in five genera to 17 species in eight genera. The specimens described here are only a small fraction of hexactinellids collected on cruise SO254. Unfortunately, the first author passed away while working on this collection, only being able to complete the nine descriptions reported here. The paper concludes with an obituary to him, the world-leading expert on glass sponge taxonomy who will be greatly missed.},\n\turldate = {2022-11-09},\n\tjournal = {ZooKeys},\n\tauthor = {Reiswig, Henry M. and Dohrmann, Martin and Kelly, Michelle and Mills, Sadie and Schupp, Peter J. and Wörheide, Gert},\n\tmonth = sep,\n\tyear = {2021},\n\tpages = {33--84},\n}\n\n

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\n \n\n \n \n \n \n \n \n Photosensitivity of the Bacterial Pigment Cycloprodigiosin Enables Settlement in Coral Larvae—Light as an Understudied Environmental Factor.\n \n \n \n \n\n\n \n Petersen, L., Kellermann, M. Y., Nietzer, S., & Schupp, P. J.\n\n\n \n\n\n\n Frontiers in Marine Science, 8: 749070. October 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Photosensitivity$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{petersen_photosensitivity_2021,\n\ttitle = {Photosensitivity of the {Bacterial} {Pigment} {Cycloprodigiosin} {Enables} {Settlement} in {Coral} {Larvae}—{Light} as an {Understudied} {Environmental} {Factor}},\n\tvolume = {8},\n\tissn = {2296-7745},\n\turl = {https://www.frontiersin.org/articles/10.3389/fmars.2021.749070/full},\n\tdoi = {10.3389/fmars.2021.749070},\n\tabstract = {The survival of coral reefs largely depends among other factors on the recruitment of a new generation of coral individuals that are more adapted to a rapidly changing climate and other anthropogenic stressors (e.g., pollution, sedimentation). Therefore, a better understanding of the coral settlement process, the molecules involved as well as crucial environmental drivers that control settlement success are needed. In this study, we identified a novel settlement inducer for the brooding scleractinian coral\n              Leptastrea purpurea\n              and highlight the importance of light for the settlement process. Crude extract of the red-pigmented bacterium\n              Pseudoalteromonas rubra\n              reliably triggered attachment and metamorphosis in\n              L. purpurea\n              larvae in less than 24 h. Prodigiosin (II) and the two derivatives, cycloprodigiosin (I) and 2-methyl-3-hexyl prodiginine (III) were isolated and structurally elucidated from the crude extract of\n              P. rubra.\n              We demonstrated that the photosensitive pigment cycloprodigiosin (I) was the responsible compound for attachment and metamorphosis in\n              L. purpurea\n              larvae. Under the tested light regimes (i.e., darkness, constant light and a dark-light alternation), cycloprodigiosin (I) triggered approximately 90\\% settlement at a concentration of 0.2 μg mL\n              –1\n              under a 12 h alternating dark-light cycle, mimicking the light-flooded coral reef environment. Our findings enable for the first time a mechanistic understanding of the light-dependent larva to polyp transformation by discovering the novel bacterial settlement cue cycloprodigiosin and its photosensitivity as a determining factor for coral settlement.},\n\turldate = {2022-11-09},\n\tjournal = {Frontiers in Marine Science},\n\tauthor = {Petersen, Lars-Erik and Kellermann, Matthias Y. and Nietzer, Samuel and Schupp, Peter J.},\n\tmonth = oct,\n\tyear = {2021},\n\tpages = {749070},\n}\n\n

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\n \n\n \n \n \n \n \n \n Ecological and Pharmacological Activities of Polybrominated Diphenyl Ethers (PBDEs) from the Indonesian Marine Sponge Lamellodysidea herbacea.\n \n \n \n \n\n\n \n Faisal, M. R., Kellermann, M. Y., Rohde, S., Putra, M. Y., Murniasih, T., Risdian, C., Mohr, K. I., Wink, J., Praditya, D. F., Steinmann, E., Köck, M., & Schupp, P. J.\n\n\n \n\n\n\n Marine Drugs, 19(11): 611. October 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Ecological$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{faisal_ecological_2021,\n\ttitle = {Ecological and {Pharmacological} {Activities} of {Polybrominated} {Diphenyl} {Ethers} ({PBDEs}) from the {Indonesian} {Marine} {Sponge} {Lamellodysidea} herbacea},\n\tvolume = {19},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/19/11/611},\n\tdoi = {10.3390/md19110611},\n\tabstract = {Two known Polybrominated Diphenyl Ethers (PBDEs), 3,4,5-tribromo-2-(2′,4′-dibromophenoxy)phenol (1d) and 3,4,5,6-tetrabromo-2-(2′,4′-dibromophenoxy)phenol (2b), were isolated from the Indonesian marine sponge Lamellodysidea herbacea. The structure was confirmed using 13C chemical shift average deviation and was compared to the predicted structures and recorded chemical shifts in previous studies. We found a wide range of bioactivities from the organic crude extract, such as (1) a strong deterrence against the generalist pufferfish Canthigaster solandri, (2) potent inhibition against environmental and human pathogenic bacterial and fungal strains, and (3) the inhibition of the Hepatitis C Virus (HCV). The addition of a bromine atom into the A-ring of compound 2b resulted in higher fish feeding deterrence compared to compound 1d. On the contrary, compound 2b showed only more potent inhibition against the Gram-negative bacteria Rhodotorula glutinis (MIC 2.1 μg/mL), while compound 1d showed more powerful inhibition against the other human pathogenic bacteria and fungi. The first report of a chemical defense by compounds 1d and 2b against fish feeding and environmental relevant bacteria, especially pathogenic bacteria, might be one reason for the widespread occurrence of the shallow water sponge Lamellodysidea herbacea in Indonesia and the Indo-Pacific.},\n\tlanguage = {en},\n\tnumber = {11},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Faisal, Muhammad R. and Kellermann, Matthias Y. and Rohde, Sven and Putra, Masteria Y. and Murniasih, Tutik and Risdian, Chandra and Mohr, Kathrin I. and Wink, Joachim and Praditya, Dimas F. and Steinmann, Eike and Köck, Matthias and Schupp, Peter J.},\n\tmonth = oct,\n\tyear = {2021},\n\tpages = {611},\n}\n\n

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\n \n\n \n \n \n \n \n \n A Soft Spot for Chemistry–Current Taxonomic and Evolutionary Implications of Sponge Secondary Metabolite Distribution.\n \n \n \n \n\n\n \n Galitz, A., Nakao, Y., Schupp, P. J., Wörheide, G., & Erpenbeck, D.\n\n\n \n\n\n\n Marine Drugs, 19(8): 448. August 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"A$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{galitz_soft_2021,\n\ttitle = {A {Soft} {Spot} for {Chemistry}–{Current} {Taxonomic} and {Evolutionary} {Implications} of {Sponge} {Secondary} {Metabolite} {Distribution}},\n\tvolume = {19},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/19/8/448},\n\tdoi = {10.3390/md19080448},\n\tabstract = {Marine sponges are the most prolific marine sources for discovery of novel bioactive compounds. Sponge secondary metabolites are sought-after for their potential in pharmaceutical applications, and in the past, they were also used as taxonomic markers alongside the difficult and homoplasy-prone sponge morphology for species delineation (chemotaxonomy). The understanding of phylogenetic distribution and distinctiveness of metabolites to sponge lineages is pivotal to reveal pathways and evolution of compound production in sponges. This benefits the discovery rate and yield of bioprospecting for novel marine natural products by identifying lineages with high potential of being new sources of valuable sponge compounds. In this review, we summarize the current biochemical data on sponges and compare the metabolite distribution against a sponge phylogeny. We assess compound specificity to lineages, potential convergences, and suitability as diagnostic phylogenetic markers. Our study finds compound distribution corroborating current (molecular) phylogenetic hypotheses, which include yet unaccepted polyphyly of several demosponge orders and families. Likewise, several compounds and compound groups display a high degree of lineage specificity, which suggests homologous biosynthetic pathways among their taxa, which identifies yet unstudied species of this lineage as promising bioprospecting targets.},\n\tlanguage = {en},\n\tnumber = {8},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Galitz, Adrian and Nakao, Yoichi and Schupp, Peter J. and Wörheide, Gert and Erpenbeck, Dirk},\n\tmonth = aug,\n\tyear = {2021},\n\tpages = {448},\n}\n\n

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\n \n\n \n \n \n \n \n \n Challenges in Current Coral Reef Protection – Possible Impacts of UV Filters Used in Sunscreens, a Critical Review.\n \n \n \n \n\n\n \n Moeller, M., Pawlowski, S., Petersen-Thiery, M., Miller, I. B., Nietzer, S., Heisel-Sure, Y., Kellermann, M. Y., & Schupp, P. J.\n\n\n \n\n\n\n Frontiers in Marine Science, 8: 665548. April 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Challenges$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{moeller_challenges_2021,\n\ttitle = {Challenges in {Current} {Coral} {Reef} {Protection} – {Possible} {Impacts} of {UV} {Filters} {Used} in {Sunscreens}, a {Critical} {Review}},\n\tvolume = {8},\n\tissn = {2296-7745},\n\turl = {https://www.frontiersin.org/articles/10.3389/fmars.2021.665548/full},\n\tdoi = {10.3389/fmars.2021.665548},\n\tabstract = {Coral reefs are highly endangered ecosystems. The identification and quantification of potential stress factors are essential to protect them. UV filters from sunscreens that are introduced to coral reef areas are considered as one of these stressors and their impact on corals needs to be further investigated. Even though UV filters are functionally similar, their structural features are very diverse. Their impact on limnic organisms have also been shown to be highly variable ranging from no or low to high toxicity. It is therefore to be expected that their effect on corals also differs significantly and that each compound has to be evaluated individually. The demand for conclusive benchmarks and guidelines from policy makers and the public over the past years shows the necessity for an objective literature review on the effects of various UV filters on scleractinian corals. Here, we review the present literature, summarize the data on the different UV filters and discuss the different approaches, advantages and limitations of the studies. However, the methods used in the latter studies vary greatly. They differ in many aspects such as species and life stage used, field and laboratory approaches, with exposure times ranging from hours to weeks. Some studies include analytics and measure the actual test concentration, others only provide nominal concentrations. The lack of standardized methods renders comparisons between studies futile. Additionally, most UV filters have only been investigated in a single or a few studies of different quality. Reliable thresholds are therefore impossible to draw on the basis of currently available studies. Nevertheless, certain UV filters repeatedly showed comparable toxicity in both freshwater and marine species tested. Yet, existing differences in results from coral tests emphasize the need for a standardized testing method comparable to those established for other aquatic organisms in order to allow for a more conclusive assessment. In this review, we describe what a scientifically sound testing proposal should include in order to obtain reliable and reproducible data, which ultimately should result in an internationally organized standardized ring test trial. Such standardized toxicity tests would enable validation of coral toxicity data related to UV filters, but also testing of other types of compounds that are known to be introduced and effect coral reefs, thus helping to identify significant stressors and enabling objective policy decisions.},\n\turldate = {2022-11-09},\n\tjournal = {Frontiers in Marine Science},\n\tauthor = {Moeller, Mareen and Pawlowski, Sascha and Petersen-Thiery, Mechtild and Miller, Ingo B. and Nietzer, Samuel and Heisel-Sure, Yannik and Kellermann, Matthias Y. and Schupp, Peter J.},\n\tmonth = apr,\n\tyear = {2021},\n\tpages = {665548},\n}\n\n

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\n Coral reefs are highly endangered ecosystems. The identification and quantification of potential stress factors are essential to protect them. UV filters from sunscreens that are introduced to coral reef areas are considered as one of these stressors and their impact on corals needs to be further investigated. Even though UV filters are functionally similar, their structural features are very diverse. Their impact on limnic organisms have also been shown to be highly variable ranging from no or low to high toxicity. It is therefore to be expected that their effect on corals also differs significantly and that each compound has to be evaluated individually. The demand for conclusive benchmarks and guidelines from policy makers and the public over the past years shows the necessity for an objective literature review on the effects of various UV filters on scleractinian corals. Here, we review the present literature, summarize the data on the different UV filters and discuss the different approaches, advantages and limitations of the studies. However, the methods used in the latter studies vary greatly. They differ in many aspects such as species and life stage used, field and laboratory approaches, with exposure times ranging from hours to weeks. Some studies include analytics and measure the actual test concentration, others only provide nominal concentrations. The lack of standardized methods renders comparisons between studies futile. Additionally, most UV filters have only been investigated in a single or a few studies of different quality. Reliable thresholds are therefore impossible to draw on the basis of currently available studies. Nevertheless, certain UV filters repeatedly showed comparable toxicity in both freshwater and marine species tested. Yet, existing differences in results from coral tests emphasize the need for a standardized testing method comparable to those established for other aquatic organisms in order to allow for a more conclusive assessment. In this review, we describe what a scientifically sound testing proposal should include in order to obtain reliable and reproducible data, which ultimately should result in an internationally organized standardized ring test trial. Such standardized toxicity tests would enable validation of coral toxicity data related to UV filters, but also testing of other types of compounds that are known to be introduced and effect coral reefs, thus helping to identify significant stressors and enabling objective policy decisions.\n

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\n \n\n \n \n \n \n \n \n Streptomyces bathyalis sp. nov., an actinobacterium isolated from the sponge in a deep sea.\n \n \n \n \n\n\n \n Risdian, C., Landwehr, W., Rohde, M., Schumann, P., Hahnke, R. L., Spröer, C., Bunk, B., Kämpfer, P., Schupp, P. J., & Wink, J.\n\n\n \n\n\n\n Antonie van Leeuwenhoek, 114(4): 425–435. April 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Streptomyces$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{risdian_streptomyces_2021,\n\ttitle = {Streptomyces bathyalis sp. nov., an actinobacterium isolated from the sponge in a deep sea},\n\tvolume = {114},\n\tissn = {0003-6072, 1572-9699},\n\turl = {http://link.springer.com/10.1007/s10482-021-01528-4},\n\tdoi = {10.1007/s10482-021-01528-4},\n\tabstract = {Abstract\n            \n              A novel actinobacterium, designated ASO4wet\n              T\n              , was isolated from the unidentified sponge (SO4) in the deep sea collected of the North Atlantic Ocean. Study of 16S rRNA gene sequences indicated that strain ASO4wet\n              T\n              is a member of the genus\n              Streptomyces\n              and showed the closest similarities to\n              Streptomyces karpasiensis\n              K413\n              T\n              (98.87 \\%),\n              Streptomyces glycovorans\n              YIM M 10366\n              T\n              (98.38 \\%), and\n              Streptomyces abyssalis\n              YIM M 10400\n              T\n              (97.53 \\%). Strain ASO4wet\n              T\n              contained MK-9(H8) as the predominant menaquinone and the major fatty acids are iso-C\n              16:0\n              , anteiso-C\n              15:0\n              , and iso-C\n              15:0\n              . Polyphasic taxonomy was carried out between strain ASO4wet\n              T\n              and its phylogenetically closely related\n              Streptomyces\n              strains, which further elucidated their relatedness and revealed that strain ASO4wet\n              T\n              could be distinguished from currently known\n              Streptomyces\n              species. Strain ASO4wet\n              T\n              clearly represents a novel species in genus\n              Streptomyces\n              . We propose the name\n              Streptomyces bathyalis\n              sp. nov., with the type strain ASO4wet\n              T\n              (= DSM 106605\n              T\n               = NCCB 100657\n              T\n              ). Analysis of the whole-genome sequence of\n              S. bathyalis\n              revealed that genome size is 7,377,472 bp with 6332 coding sequences.},\n\tlanguage = {en},\n\tnumber = {4},\n\turldate = {2022-11-09},\n\tjournal = {Antonie van Leeuwenhoek},\n\tauthor = {Risdian, Chandra and Landwehr, Wiebke and Rohde, Manfred and Schumann, Peter and Hahnke, Richard L. and Spröer, Cathrin and Bunk, Boyke and Kämpfer, Peter and Schupp, Peter J. and Wink, Joachim},\n\tmonth = apr,\n\tyear = {2021},\n\tpages = {425--435},\n}\n\n

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\n \n\n \n \n \n \n \n \n Towards enhancing coral heat tolerance: a “microbiome transplantation” treatment using inoculations of homogenized coral tissues.\n \n \n \n \n\n\n \n Doering, T., Wall, M., Putchim, L., Rattanawongwan, T., Schroeder, R., Hentschel, U., & Roik, A.\n\n\n \n\n\n\n Microbiome, 9(1): 102. December 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Towards$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n \n \n 1 download\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{doering_towards_2021,\n\ttitle = {Towards enhancing coral heat tolerance: a “microbiome transplantation” treatment using inoculations of homogenized coral tissues},\n\tvolume = {9},\n\tissn = {2049-2618},\n\tshorttitle = {Towards enhancing coral heat tolerance},\n\turl = {https://microbiomejournal.biomedcentral.com/articles/10.1186/s40168-021-01053-6},\n\tdoi = {10.1186/s40168-021-01053-6},\n\tabstract = {Abstract\n            \n              Background\n              \n                Microbiome manipulation could enhance heat tolerance and help corals survive the pressures of ocean warming. We conducted coral microbiome transplantation (CMT) experiments using the reef-building corals,\n                Pocillopora\n                and\n                Porites\n                , and investigated whether this technique can benefit coral heat resistance while modifying the bacterial microbiome. Initially, heat-tolerant donors were identified in the wild. We then used fresh homogenates made from coral donor tissues to inoculate conspecific, heat-susceptible recipients and documented their bleaching responses and microbiomes by 16S rRNA gene metabarcoding.\n              \n            \n            \n              Results\n              \n                Recipients of both coral species bleached at lower rates compared to the control group when exposed to short-term heat stress (34 °C). One hundred twelve (\n                Pocillopora\n                sp.) and sixteen (\n                Porites\n                sp.) donor-specific bacterial species were identified in the microbiomes of recipients indicating transmission of bacteria. The amplicon sequence variants of the majority of these transmitted bacteria belonged to known, putatively symbiotic bacterial taxa of corals and were linked to the observed beneficial effect on the coral stress response. Microbiome dynamics in our experiments support the notion that microbiome community evenness and dominance of one or few bacterial species, rather than host-species identity, were drivers for microbiome stability in a holobiont context.\n              \n            \n            \n              Conclusions\n              Our results suggest that coral recipients likely favor the uptake of putative bacterial symbionts, recommending to include these taxonomic groups in future coral probiotics screening efforts. Our study suggests a scenario where these donor-specific bacterial symbionts might have been more efficient in supporting the recipients to resist heat stress compared to the native symbionts present in the control group. These findings urgently call for further experimental investigation of the mechanisms of action underlying the beneficial effect of CMT and for field-based long-term studies testing the persistence of the effect.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-08},\n\tjournal = {Microbiome},\n\tauthor = {Doering, Talisa and Wall, Marlene and Putchim, Lalita and Rattanawongwan, Tipwimon and Schroeder, Roman and Hentschel, Ute and Roik, Anna},\n\tmonth = dec,\n\tyear = {2021},\n\tpages = {102},\n}\n\n

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\n Abstract Background Microbiome manipulation could enhance heat tolerance and help corals survive the pressures of ocean warming. We conducted coral microbiome transplantation (CMT) experiments using the reef-building corals, Pocillopora and Porites , and investigated whether this technique can benefit coral heat resistance while modifying the bacterial microbiome. Initially, heat-tolerant donors were identified in the wild. We then used fresh homogenates made from coral donor tissues to inoculate conspecific, heat-susceptible recipients and documented their bleaching responses and microbiomes by 16S rRNA gene metabarcoding. Results Recipients of both coral species bleached at lower rates compared to the control group when exposed to short-term heat stress (34 °C). One hundred twelve ( Pocillopora sp.) and sixteen ( Porites sp.) donor-specific bacterial species were identified in the microbiomes of recipients indicating transmission of bacteria. The amplicon sequence variants of the majority of these transmitted bacteria belonged to known, putatively symbiotic bacterial taxa of corals and were linked to the observed beneficial effect on the coral stress response. Microbiome dynamics in our experiments support the notion that microbiome community evenness and dominance of one or few bacterial species, rather than host-species identity, were drivers for microbiome stability in a holobiont context. Conclusions Our results suggest that coral recipients likely favor the uptake of putative bacterial symbionts, recommending to include these taxonomic groups in future coral probiotics screening efforts. Our study suggests a scenario where these donor-specific bacterial symbionts might have been more efficient in supporting the recipients to resist heat stress compared to the native symbionts present in the control group. These findings urgently call for further experimental investigation of the mechanisms of action underlying the beneficial effect of CMT and for field-based long-term studies testing the persistence of the effect.\n

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\n \n\n \n \n \n \n \n \n Anti-Infective and Antiviral Activity of Valinomycin and Its Analogues from a Sea Cucumber-Associated Bacterium, Streptomyces sp. SV 21.\n \n \n \n \n\n\n \n Wibowo, J. T., Kellermann, M. Y., Köck, M., Putra, M. Y., Murniasih, T., Mohr, K. I., Wink, J., Praditya, D. F., Steinmann, E., & Schupp, P. J.\n\n\n \n\n\n\n Marine Drugs, 19(2): 81. February 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Anti-Infective$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n \n \n 1 download\n \n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{wibowo_anti-infective_2021,\n\ttitle = {Anti-{Infective} and {Antiviral} {Activity} of {Valinomycin} and {Its} {Analogues} from a {Sea} {Cucumber}-{Associated} {Bacterium}, {Streptomyces} sp. {SV} 21},\n\tvolume = {19},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/19/2/81},\n\tdoi = {10.3390/md19020081},\n\tabstract = {The manuscript investigated the isolation, characterization and anti-infective potential of valinomycin (3), streptodepsipeptide P11A (2), streptodepsipeptide P11B (1), and one novel valinomycin analogue, streptodepsipeptide SV21 (4), which were all produced by the Gram-positive strain Streptomycescavourensis SV 21. Although the exact molecular weight and major molecular fragments were recently reported for compound 4, its structure elucidation was not based on compound isolation and spectroscopic techniques. We successfully isolated and elucidated the structure based on the MS2 fragmentation pathways as well as 1H and 13C NMR spectra and found that the previously reported structure of compound 4 differs from our analysis. Our findings showed the importance of isolation and structure elucidation of bacterial compounds in the era of fast omics technologies. The here performed anti-infective assays showed moderate to potent activity against fungi, multi drug resistant (MDR) bacteria and infectivity of the Hepatitis C Virus (HCV). While compounds 2, 3 and 4 revealed potent antiviral activity, the observed minor cytotoxicity needs further investigation. Furthermore, the here performed anti-infective assays disclosed that the symmetry of the valinomycin molecule is most important for its bioactivity, a fact that has not been reported so far.},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-08},\n\tjournal = {Marine Drugs},\n\tauthor = {Wibowo, Joko T. and Kellermann, Matthias Y. and Köck, Matthias and Putra, Masteria Y. and Murniasih, Tutik and Mohr, Kathrin I. and Wink, Joachim and Praditya, Dimas F. and Steinmann, Eike and Schupp, Peter J.},\n\tmonth = feb,\n\tyear = {2021},\n\tpages = {81},\n}\n\n

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\n \n\n \n \n \n \n \n \n Toxic effects of UV filters from sunscreens on coral reefs revisited: regulatory aspects for “reef safe” products.\n \n \n \n \n\n\n \n Miller, I. B., Pawlowski, S., Kellermann, M. Y., Petersen-Thiery, M., Moeller, M., Nietzer, S., & Schupp, P. J.\n\n\n \n\n\n\n Environmental Sciences Europe, 33(1): 74. December 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Toxic$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{miller_toxic_2021,\n\ttitle = {Toxic effects of {UV} filters from sunscreens on coral reefs revisited: regulatory aspects for “reef safe” products},\n\tvolume = {33},\n\tissn = {2190-4707, 2190-4715},\n\tshorttitle = {Toxic effects of {UV} filters from sunscreens on coral reefs revisited},\n\turl = {https://enveurope.springeropen.com/articles/10.1186/s12302-021-00515-w},\n\tdoi = {10.1186/s12302-021-00515-w},\n\tabstract = {Abstract\n            \n              Background\n              Tropical coral reefs have been recognized for their significant ecological and economical value. However, increasing anthropogenic disturbances have led to progressively declining coral reef ecosystems on a global scale. More recently, several studies implicated UV filters used in sunscreen products to negatively affect corals and possibly contribute to regional trends in coral decline. Following a public debate, bans were implemented on several organic UV filters and sunscreen products in different locations including Hawaii, the U.S. Virgin Islands and Palau. This included banning the widely used oxybenzone and octinoxate, while promoting the use of inorganic filters such as zinc oxide even although their toxicity towards aquatic organisms had been documented previously. The bans of organic UV filters were based on preliminary scientific studies that showed several weaknesses as there is to this point no standardized testing scheme for scleractinian corals. Despite the lack of sound scientific proof, the latter controversial bans have already resulted in the emergence of a new sunscreen market for products claimed to be ‘reef safe’ (or similar). Thus, a market analysis of ‘reef safe’ sunscreen products was conducted to assess relevant environmental safety aspects of approved UV filters, especially for coral reefs. Further, a scientifically sound decision-making process in a regulatory context is proposed.\n            \n            \n              Results\n              Our market analysis revealed that about 80\\% of surveyed sunscreens contained inorganic UV filters and that there is a variety of unregulated claims being used in the marketing of ‘reef safe’ products with ‘reef friendly’ being the most frequently used term. Predominantly, four organic UV filters are used in ‘reef safe’ sunscreens in the absence of the banned filters oxybenzone and octinoxate. Analysis of safe threshold concentrations for marine water retrieved from existing REACH registration dossiers could currently also safeguard corals.\n            \n            \n              Conclusion\n              There is a substantial discrepancy of treatments of organic versus inorganic UV filters in politics as well as in the ‘reef safe’ sunscreen market, which to this point is not scientifically justified. Thus, a risk-based approach with equal consideration of organic and inorganic UV filters is recommended for future regulatory measures as well as a clear definition and regulation of the ‘reef safe’ terminology.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Environmental Sciences Europe},\n\tauthor = {Miller, Ingo B. and Pawlowski, Sascha and Kellermann, Matthias Y. and Petersen-Thiery, Mechtild and Moeller, Mareen and Nietzer, Samuel and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2021},\n\tpages = {74},\n}\n\n

\n

\n\n\n

\n Abstract Background Tropical coral reefs have been recognized for their significant ecological and economical value. However, increasing anthropogenic disturbances have led to progressively declining coral reef ecosystems on a global scale. More recently, several studies implicated UV filters used in sunscreen products to negatively affect corals and possibly contribute to regional trends in coral decline. Following a public debate, bans were implemented on several organic UV filters and sunscreen products in different locations including Hawaii, the U.S. Virgin Islands and Palau. This included banning the widely used oxybenzone and octinoxate, while promoting the use of inorganic filters such as zinc oxide even although their toxicity towards aquatic organisms had been documented previously. The bans of organic UV filters were based on preliminary scientific studies that showed several weaknesses as there is to this point no standardized testing scheme for scleractinian corals. Despite the lack of sound scientific proof, the latter controversial bans have already resulted in the emergence of a new sunscreen market for products claimed to be ‘reef safe’ (or similar). Thus, a market analysis of ‘reef safe’ sunscreen products was conducted to assess relevant environmental safety aspects of approved UV filters, especially for coral reefs. Further, a scientifically sound decision-making process in a regulatory context is proposed. Results Our market analysis revealed that about 80% of surveyed sunscreens contained inorganic UV filters and that there is a variety of unregulated claims being used in the marketing of ‘reef safe’ products with ‘reef friendly’ being the most frequently used term. Predominantly, four organic UV filters are used in ‘reef safe’ sunscreens in the absence of the banned filters oxybenzone and octinoxate. Analysis of safe threshold concentrations for marine water retrieved from existing REACH registration dossiers could currently also safeguard corals. Conclusion There is a substantial discrepancy of treatments of organic versus inorganic UV filters in politics as well as in the ‘reef safe’ sunscreen market, which to this point is not scientifically justified. Thus, a risk-based approach with equal consideration of organic and inorganic UV filters is recommended for future regulatory measures as well as a clear definition and regulation of the ‘reef safe’ terminology.\n

\n\n\n

\n \n\n \n \n \n \n \n \n High taxonomic resolution surveys and trait-based analyses reveal multiple benthic regimes in North Sulawesi (Indonesia).\n \n \n \n \n\n\n \n Reverter, M., Jackson, M., Rohde, S., Moeller, M., Bara, R., Lasut, M. T., Segre Reinach, M., & Schupp, P. J.\n\n\n \n\n\n\n Scientific Reports, 11(1): 16554. December 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"High$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{reverter_high_2021,\n\ttitle = {High taxonomic resolution surveys and trait-based analyses reveal multiple benthic regimes in {North} {Sulawesi} ({Indonesia})},\n\tvolume = {11},\n\tissn = {2045-2322},\n\turl = {https://www.nature.com/articles/s41598-021-95905-8},\n\tdoi = {10.1038/s41598-021-95905-8},\n\tabstract = {Abstract\n            As coral reef communities change and reorganise in response to increasing disturbances, there is a growing need for understanding species regimes and their contribution to ecosystem processes. Using a case study on coral reefs at the epicentre of tropical marine biodiversity (North Sulawesi, Indonesia), we explored how application of different biodiversity approaches (i.e., use of major taxonomic categories, high taxonomic resolution categories and trait-based approaches) affects the detection of distinct fish and benthic communities. Our results show that using major categories fails to identify distinct coral reef regimes. We also show that monitoring of only scleractinian coral communities is insufficient to detect different benthic regimes, especially communities dominated by non-coral organisms, and that all types of benthic organisms need to be considered. We have implemented the use of a trait-based approach to study the functional diversity of whole coral reef benthic assemblages, which allowed us to detect five different community regimes, only one of which was dominated by scleractinian corals. Furthermore, by the parallel study of benthic and fish communities we provide new insights into key processes and functions that might dominate or be compromised in the different community regimes.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Scientific Reports},\n\tauthor = {Reverter, Miriam and Jackson, Matthew and Rohde, Sven and Moeller, Mareen and Bara, Robert and Lasut, Markus T. and Segre Reinach, Marco and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2021},\n\tpages = {16554},\n}\n\n

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\n \n\n \n \n \n \n \n \n Draft genome and description of Waterburya agarophytonicola gen. nov. sp. nov. (Pleurocapsales, Cyanobacteria): a seaweed symbiont.\n \n \n \n \n\n\n \n Bonthond, G., Shalygin, S., Bayer, T., & Weinberger, F.\n\n\n \n\n\n\n Antonie van Leeuwenhoek, 114(12): 2189–2203. December 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Draft$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{bonthond_draft_2021,\n\ttitle = {Draft genome and description of {Waterburya} agarophytonicola gen. nov. sp. nov. ({Pleurocapsales}, {Cyanobacteria}): a seaweed symbiont},\n\tvolume = {114},\n\tissn = {0003-6072, 1572-9699},\n\tshorttitle = {Draft genome and description of {Waterburya} agarophytonicola gen. nov. sp. nov. ({Pleurocapsales}, {Cyanobacteria})},\n\turl = {https://link.springer.com/10.1007/s10482-021-01672-x},\n\tdoi = {10.1007/s10482-021-01672-x},\n\tabstract = {Abstract\n            \n              This work introduces\n              Waterburya agarophytonicola\n              Bonthond and Shalygin gen. nov., sp. nov, a baeocyte producing cyanobacterium that was isolated from the rhodophyte\n              Agarophyton vermiculophyllum\n              (Ohmi) Gurgel et al., an invasive seaweed that has spread across the northern hemisphere. The new species genome reveals a diverse repertoire of chemotaxis and adhesion related genes, including genes coding for type IV pili assembly proteins and a high number of genes coding for filamentous hemagglutinin family (FHA) proteins. Among a genetic basis for the synthesis of siderophores, carotenoids and numerous vitamins,\n              W. agarophytonicola\n              is potentially capable of producing cobalamin (vitamin B\n              12\n              ), for which\n              A\n              .\n              vermiculophyllum\n              is an auxotroph. With a taxonomic description of the genus and species and a draft genome, this study provides as a basis for future research, to uncover the nature of this geographically independent association between seaweed and cyanobiont.},\n\tlanguage = {en},\n\tnumber = {12},\n\turldate = {2022-11-03},\n\tjournal = {Antonie van Leeuwenhoek},\n\tauthor = {Bonthond, Guido and Shalygin, Sergei and Bayer, Till and Weinberger, Florian},\n\tmonth = dec,\n\tyear = {2021},\n\tpages = {2189--2203},\n}\n\n

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\n \n\n \n \n \n \n \n \n Intraspecific diversity and genetic structure in the widespread macroalga Agarophyton vermiculophyllum.\n \n \n \n \n\n\n \n Krueger‐Hadfield, S. A., Byers, J. E., Bonthond, G., Terada, R., Weinberger, F., & Sotka, E. E.\n\n\n \n\n\n\n Journal of Phycology, 57(5): 1403–1410. October 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"Intraspecific$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{kruegerhadfield_intraspecific_2021,\n\ttitle = {Intraspecific diversity and genetic structure in the widespread macroalga \\textit{{Agarophyton} vermiculophyllum}},\n\tvolume = {57},\n\tissn = {0022-3646, 1529-8817},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1111/jpy.13195},\n\tdoi = {10.1111/jpy.13195},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-03},\n\tjournal = {Journal of Phycology},\n\tauthor = {Krueger‐Hadfield, Stacy A. and Byers, James E. and Bonthond, Guido and Terada, Ryuta and Weinberger, Florian and Sotka, Erik E.},\n\teditor = {Graham, Michael},\n\tmonth = oct,\n\tyear = {2021},\n\tpages = {1403--1410},\n}\n\n

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\n \n\n \n \n \n \n \n \n The role of host promiscuity in the invasion process of a seaweed holobiont.\n \n \n \n \n\n\n \n Bonthond, G., Bayer, T., Krueger-Hadfield, S. A., Stärck, N., Wang, G., Nakaoka, M., Künzel, S., & Weinberger, F.\n\n\n \n\n\n\n The ISME Journal, 15(6): 1668–1679. June 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"The$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{bonthond_role_2021,\n\ttitle = {The role of host promiscuity in the invasion process of a seaweed holobiont},\n\tvolume = {15},\n\tcopyright = {Creative Commons Attribution 4.0 International License (CC-BY)},\n\tissn = {1751-7362, 1751-7370},\n\turl = {http://www.nature.com/articles/s41396-020-00878-7},\n\tdoi = {10.1038/s41396-020-00878-7},\n\tabstract = {Invasive species are co-introduced with microbiota from their native range and also interact with microbiota found in the novel environment to which they are introduced. Host ﬂexibility toward microbiota, or host promiscuity, is an important trait underlying terrestrial plant invasions. To test whether host promiscuity may be important in macroalgal invasions, we experimentally simulated an invasion in a common garden setting, using the widespread invasive macroalga Agarophyton vermiculophyllum as a model invasive seaweed holobiont. After disturbing the microbiota of individuals from native and non-native populations with antibiotics, we monitored the microbial succession trajectories in the presence of a new source of microbes. Microbial communities were strongly impacted by the treatment and changed compositionally and in terms of diversity but recovered functionally by the end of the experiment in most respects. Beta-diversity in disturbed holobionts strongly decreased, indicating that different populations conﬁgure more similar –or more common– microbial communities when exposed to the same conditions. This decline in beta-diversity occurred not only more rapidly, but was also more pronounced in non-native populations, while individuals from native populations retained communities more similar to those observed in the ﬁeld. This study demonstrates that microbial communities of non-native A. vermiculophyllum are more ﬂexibly adjusted to the environment and suggests that an intraspeciﬁc increase in host promiscuity has promoted the invasion process of A. vermiculophyllum. This phenomenon may be important among invasive macroalgal holobionts in general.},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2022-11-09},\n\tjournal = {The ISME Journal},\n\tauthor = {Bonthond, Guido and Bayer, Till and Krueger-Hadfield, Stacy A. and Stärck, Nadja and Wang, Gaoge and Nakaoka, Masahiro and Künzel, Sven and Weinberger, Florian},\n\tmonth = jun,\n\tyear = {2021},\n\tpages = {1668--1679},\n}\n\n

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\n \n\n \n \n \n \n \n \n UV filters used in sunscreens—A lack in current coral protection?.\n \n \n \n \n\n\n \n Pawlowski, S., Moeller, M., Miller, I. B., Kellermann, M. Y., Schupp, P. J., & Petersen‐Thiery, M.\n\n\n \n\n\n\n Integrated Environmental Assessment and Management, 17(5): 926–939. September 2021.\n \n\n\n\n
\n\n\n\n \n \n $\"UV$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{pawlowski_uv_2021,\n\ttitle = {{UV} filters used in sunscreens—{A} lack in current coral protection?},\n\tvolume = {17},\n\tissn = {1551-3777, 1551-3793},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1002/ieam.4454},\n\tdoi = {10.1002/ieam.4454},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-09},\n\tjournal = {Integrated Environmental Assessment and Management},\n\tauthor = {Pawlowski, Sascha and Moeller, Mareen and Miller, Ingo B. and Kellermann, Matthias Y. and Schupp, Peter J. and Petersen‐Thiery, Mechtild},\n\tmonth = sep,\n\tyear = {2021},\n\tpages = {926--939},\n}\n\n

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\n \n 2020\n \n \n (7)\n \n \n

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\n \n\n \n \n \n \n \n \n Chemical Defense Mechanisms and Ecological Implications of Indo-Pacific Holothurians.\n \n \n \n \n\n\n \n Kamyab, E., Rohde, S., Kellermann, M. Y., & Schupp, P. J.\n\n\n \n\n\n\n Molecules, 25(20): 4808. October 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Chemical$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{kamyab_chemical_2020,\n\ttitle = {Chemical {Defense} {Mechanisms} and {Ecological} {Implications} of {Indo}-{Pacific} {Holothurians}},\n\tvolume = {25},\n\tissn = {1420-3049},\n\turl = {https://www.mdpi.com/1420-3049/25/20/4808},\n\tdoi = {10.3390/molecules25204808},\n\tabstract = {Sea cucumbers are slow-moving organisms that use morphological, but also a diverse combination of chemical defenses to improve their overall fitness and chances of survival. Since chemical defense compounds are also of great pharmaceutical interest, we pinpoint the importance of biological screenings that are a relatively fast, informative and inexpensive way to identify the most bioactive organisms prior to further costly and elaborate pharmacological screenings. In this study, we investigated the presence and absence of chemical defenses of 14 different sea cucumber species from three families (Holothuriidae, Stichopodidae and Synaptidae) against ecological factors such as predation and pathogenic attacks. We used the different sea cucumber crude extracts as well as purified fractions and pure saponin compounds in a portfolio of ecological activity tests including fish feeding assays, cytotoxicity tests and antimicrobial assays against environmental pathogenic and non-pathogenic bacteria. Furthermore, we quantified and correlated the concentrations of sea cucumber characteristic saponin compounds as effective chemical defensive compounds in all 14 crude extracts by using the vanillin–sulfuric acid test. The initial results revealed that among all tested sea cucumber species that were defended against at least one ecological threat (predation and/or bacterial attack), Bohadschiaargus, Stichopuscholoronotus and Holothuria fuscopunctata were the three most promising bioactive sea cucumber species. Therefore, following further fractionation and purification attempts, we also tested saponin-containing butanol fractions of the latter, as well as two purified saponin species from B. argus. We could demonstrate that both, the amount of saponin compounds and their structure likely play a significant role in the chemical defense strategy of the sea cucumbers. Our study concludes that the chemical and morphological defense mechanisms (and combinations thereof) differ among the ecological strategies of the investigated holothurian species in order to increase their general fitness and level of survival. Finally, our observations and experiments on the chemical ecology of marine organisms can not only lead to a better understanding of their ecology and environmental roles but also can help in the better selection of bioactive organisms/compounds for the discovery of novel, pharmacologically active secondary metabolites in the near future.},\n\tlanguage = {en},\n\tnumber = {20},\n\turldate = {2022-11-09},\n\tjournal = {Molecules},\n\tauthor = {Kamyab, Elham and Rohde, Sven and Kellermann, Matthias Y. and Schupp, Peter J.},\n\tmonth = oct,\n\tyear = {2020},\n\tpages = {4808},\n}\n\n

\n

\n\n\n

\n Sea cucumbers are slow-moving organisms that use morphological, but also a diverse combination of chemical defenses to improve their overall fitness and chances of survival. Since chemical defense compounds are also of great pharmaceutical interest, we pinpoint the importance of biological screenings that are a relatively fast, informative and inexpensive way to identify the most bioactive organisms prior to further costly and elaborate pharmacological screenings. In this study, we investigated the presence and absence of chemical defenses of 14 different sea cucumber species from three families (Holothuriidae, Stichopodidae and Synaptidae) against ecological factors such as predation and pathogenic attacks. We used the different sea cucumber crude extracts as well as purified fractions and pure saponin compounds in a portfolio of ecological activity tests including fish feeding assays, cytotoxicity tests and antimicrobial assays against environmental pathogenic and non-pathogenic bacteria. Furthermore, we quantified and correlated the concentrations of sea cucumber characteristic saponin compounds as effective chemical defensive compounds in all 14 crude extracts by using the vanillin–sulfuric acid test. The initial results revealed that among all tested sea cucumber species that were defended against at least one ecological threat (predation and/or bacterial attack), Bohadschiaargus, Stichopuscholoronotus and Holothuria fuscopunctata were the three most promising bioactive sea cucumber species. Therefore, following further fractionation and purification attempts, we also tested saponin-containing butanol fractions of the latter, as well as two purified saponin species from B. argus. We could demonstrate that both, the amount of saponin compounds and their structure likely play a significant role in the chemical defense strategy of the sea cucumbers. Our study concludes that the chemical and morphological defense mechanisms (and combinations thereof) differ among the ecological strategies of the investigated holothurian species in order to increase their general fitness and level of survival. Finally, our observations and experiments on the chemical ecology of marine organisms can not only lead to a better understanding of their ecology and environmental roles but also can help in the better selection of bioactive organisms/compounds for the discovery of novel, pharmacologically active secondary metabolites in the near future.\n

\n\n\n

\n \n\n \n \n \n \n \n \n Metabolomics and Marine Biotechnology: Coupling Metabolite Profiling and Organism Biology for the Discovery of New Compounds.\n \n \n \n \n\n\n \n Reverter, M., Rohde, S., Parchemin, C., Tapissier-Bontemps, N., & Schupp, P. J.\n\n\n \n\n\n\n Frontiers in Marine Science, 7: 613471. December 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Metabolomics$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{reverter_metabolomics_2020,\n\ttitle = {Metabolomics and {Marine} {Biotechnology}: {Coupling} {Metabolite} {Profiling} and {Organism} {Biology} for the {Discovery} of {New} {Compounds}},\n\tvolume = {7},\n\tissn = {2296-7745},\n\tshorttitle = {Metabolomics and {Marine} {Biotechnology}},\n\turl = {https://www.frontiersin.org/articles/10.3389/fmars.2020.613471/full},\n\tdoi = {10.3389/fmars.2020.613471},\n\tabstract = {The high diversity of marine natural products represents promising opportunities for drug discovery, an important area in marine biotechnology. Within this context, high-throughput techniques such as metabolomics are extremely useful in unveiling unexplored chemical diversity at much faster rates than classical bioassay-guided approaches. Metabolomics approaches enable studying large sets of metabolites, even if they are produced at low concentrations. Although, metabolite identification remains the main metabolomics bottleneck, bioinformatic tools such as molecular networks can lead to the annotation of unknown metabolites and discovery of new compounds. A metabolomic approach in drug discovery has two major advantages: it enables analyses of multiple samples, allowing fast dereplication of already known compounds and provides a unique opportunity to relate metabolite profiles to organisms’ biology. Understanding the ecological and biological factors behind a certain metabolite production can be extremely useful in enhancing compound yields, optimizing compound extraction or in selecting bioactive compounds. Metazoan-associated microbiota are often responsible for metabolite synthesis, however, classical approaches only allow studying metabolites produced from cultivatable microbiota, which often differ from the compounds produced within the host. Therefore, coupling holobiome metabolomics with microbiome analysis can bring new insights to the role of microbiota in compound production. The ultimate potential of metabolomics is its coupling with other “omics” (i.e., transcriptomics and metagenomics). Although, such approaches are still challenging, especially in non-model species where genomes have not been annotated, this innovative approach is extremely valuable in elucidating gene clusters associated with biosynthetic pathways and will certainly become increasingly important in marine drug discovery.},\n\turldate = {2022-11-09},\n\tjournal = {Frontiers in Marine Science},\n\tauthor = {Reverter, Miriam and Rohde, Sven and Parchemin, Christelle and Tapissier-Bontemps, Nathalie and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2020},\n\tpages = {613471},\n}\n\n

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\n \n\n \n \n \n \n \n \n Compositional and Quantitative Insights Into Bacterial and Archaeal Communities of South Pacific Deep-Sea Sponges (Demospongiae and Hexactinellida).\n \n \n \n \n\n\n \n Steinert, G., Busch, K., Bayer, K., Kodami, S., Arbizu, P. M., Kelly, M., Mills, S., Erpenbeck, D., Dohrmann, M., Wörheide, G., Hentschel, U., & Schupp, P. J.\n\n\n \n\n\n\n Frontiers in Microbiology, 11: 716. April 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Compositional$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{steinert_compositional_2020,\n\ttitle = {Compositional and {Quantitative} {Insights} {Into} {Bacterial} and {Archaeal} {Communities} of {South} {Pacific} {Deep}-{Sea} {Sponges} ({Demospongiae} and {Hexactinellida})},\n\tvolume = {11},\n\tissn = {1664-302X},\n\turl = {https://www.frontiersin.org/article/10.3389/fmicb.2020.00716/full},\n\tdoi = {10.3389/fmicb.2020.00716},\n\turldate = {2022-11-09},\n\tjournal = {Frontiers in Microbiology},\n\tauthor = {Steinert, Georg and Busch, Kathrin and Bayer, Kristina and Kodami, Sahar and Arbizu, Pedro Martinez and Kelly, Michelle and Mills, Sadie and Erpenbeck, Dirk and Dohrmann, Martin and Wörheide, Gert and Hentschel, Ute and Schupp, Peter J.},\n\tmonth = apr,\n\tyear = {2020},\n\tpages = {716},\n}\n\n

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\n \n\n \n \n \n \n \n \n Anti-Fouling Effects of Saponin-Containing Crude Extracts from Tropical Indo-Pacific Sea Cucumbers.\n \n \n \n \n\n\n \n Kamyab, E., Goebeler, N., Kellermann, M. Y., Rohde, S., Reverter, M., Striebel, M., & Schupp, P. J.\n\n\n \n\n\n\n Marine Drugs, 18(4): 181. March 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Anti-Fouling$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{kamyab_anti-fouling_2020,\n\ttitle = {Anti-{Fouling} {Effects} of {Saponin}-{Containing} {Crude} {Extracts} from {Tropical} {Indo}-{Pacific} {Sea} {Cucumbers}},\n\tvolume = {18},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/18/4/181},\n\tdoi = {10.3390/md18040181},\n\tabstract = {Sea cucumbers are bottom dwelling invertebrates, which are mostly found on subtropical and tropical sea grass beds, sandy reef flats, or reef slopes. Although constantly exposed to fouling communities in these habitats, many species are surprisingly free of invertebrate epibionts and microfouling algae such as diatoms. In our study, we investigated the anti-fouling (AF) activities of different crude extracts of tropical Indo-Pacific sea cucumber species against the fouling diatom Cylindrotheca closterium. Nine sea cucumber species from three genera (i.e., Holothuria, Bohadschia, Actinopyga) were selected and extracted to assess their AF activities. To verify whether the sea cucumber characteristic triterpene glycosides were responsible for the observed potent AF activities, we tested purified fractions enriched in saponins isolated from Bohadschia argus, representing one of the most active anti-fouling extracts. Saponins were quantified by vanillin-sulfuric acid colorimetric assays and identified by LC-MS and LC-MS/MS analyses. We were able to demonstrate that AF activities in sea cucumber extracts were species-specific, and growth inhibition as well as attachment of the diatom to surfaces is dependent on the saponin concentration (i.e., Actinopyga contained the highest quantities), as well as on the molecular composition and structure of the present saponins (i.e., Bivittoside D derivative was the most bioactive compound). In conclusion, the here performed AF assay represents a promising and fast method for selecting the most promising bioactive organism as well as for identifying novel compounds with potent AF activities for the discovery of potentially novel pharmacologically active natural products.},\n\tlanguage = {en},\n\tnumber = {4},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Kamyab, Elham and Goebeler, Norman and Kellermann, Matthias Y. and Rohde, Sven and Reverter, Miriam and Striebel, Maren and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2020},\n\tpages = {181},\n}\n\n

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\n \n\n \n \n \n \n \n \n Shading by marine litter impairs the health of the two Indo-Pacific scleractinian corals Porites rus and Pavona cactus.\n \n \n \n \n\n\n \n Mueller, J. S., & Schupp, P. J.\n\n\n \n\n\n\n Marine Pollution Bulletin, 158: 111429. September 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Shading$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{mueller_shading_2020,\n\ttitle = {Shading by marine litter impairs the health of the two {Indo}-{Pacific} scleractinian corals {Porites} rus and {Pavona} cactus},\n\tvolume = {158},\n\tissn = {0025326X},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0025326X20305476},\n\tdoi = {10.1016/j.marpolbul.2020.111429},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {Marine Pollution Bulletin},\n\tauthor = {Mueller, Jasmin S. and Schupp, Peter J.},\n\tmonth = sep,\n\tyear = {2020},\n\tpages = {111429},\n}\n\n

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\n \n\n \n \n \n \n \n \n Chemical Biodiversity and Bioactivities of Saponins in Echinodermata with an Emphasis on Sea Cucumbers (Holothuroidea).\n \n \n \n \n\n\n \n Kamyab, E., Kellermann, M. Y., Kunzmann, A., & Schupp, P. J.\n\n\n \n\n\n\n In Jungblut, S., Liebich, V., & Bode-Dalby, M., editor(s), YOUMARES 9 - The Oceans: Our Research, Our Future, pages 121–157. Springer International Publishing, Cham, 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Chemical$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@incollection{jungblut_chemical_2020,\n\taddress = {Cham},\n\ttitle = {Chemical {Biodiversity} and {Bioactivities} of {Saponins} in {Echinodermata} with an {Emphasis} on {Sea} {Cucumbers} ({Holothuroidea})},\n\tisbn = {978-3-030-20388-7 978-3-030-20389-4},\n\turl = {http://link.springer.com/10.1007/978-3-030-20389-4_7},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tbooktitle = {{YOUMARES} 9 - {The} {Oceans}: {Our} {Research}, {Our} {Future}},\n\tpublisher = {Springer International Publishing},\n\tauthor = {Kamyab, Elham and Kellermann, Matthias Y. and Kunzmann, Andreas and Schupp, Peter J.},\n\teditor = {Jungblut, Simon and Liebich, Viola and Bode-Dalby, Maya},\n\tyear = {2020},\n\tdoi = {10.1007/978-3-030-20389-4_7},\n\tpages = {121--157},\n}\n\n

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\n \n\n \n \n \n \n \n \n Secondary Metabolites of Marine Microbes: From Natural Products Chemistry to Chemical Ecology.\n \n \n \n \n\n\n \n Petersen, L., Kellermann, M. Y., & Schupp, P. J.\n\n\n \n\n\n\n In Jungblut, S., Liebich, V., & Bode-Dalby, M., editor(s), YOUMARES 9 - The Oceans: Our Research, Our Future, pages 159–180. Springer International Publishing, Cham, 2020.\n \n\n\n\n
\n\n\n\n \n \n $\"Secondary$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@incollection{jungblut_secondary_2020,\n\taddress = {Cham},\n\ttitle = {Secondary {Metabolites} of {Marine} {Microbes}: {From} {Natural} {Products} {Chemistry} to {Chemical} {Ecology}},\n\tisbn = {978-3-030-20388-7 978-3-030-20389-4},\n\tshorttitle = {Secondary {Metabolites} of {Marine} {Microbes}},\n\turl = {http://link.springer.com/10.1007/978-3-030-20389-4_8},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tbooktitle = {{YOUMARES} 9 - {The} {Oceans}: {Our} {Research}, {Our} {Future}},\n\tpublisher = {Springer International Publishing},\n\tauthor = {Petersen, Lars-Erik and Kellermann, Matthias Y. and Schupp, Peter J.},\n\teditor = {Jungblut, Simon and Liebich, Viola and Bode-Dalby, Maya},\n\tyear = {2020},\n\tdoi = {10.1007/978-3-030-20389-4_8},\n\tpages = {159--180},\n}\n\n

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\n \n 2019\n \n \n (9)\n \n \n

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\n \n\n \n \n \n \n \n \n Biotechnological Potential of Bacteria Isolated from the Sea Cucumber Holothuria leucospilota and Stichopus vastus from Lampung, Indonesia.\n \n \n \n \n\n\n \n Wibowo, J. T., Kellermann, M. Y., Versluis, D., Putra, M. Y., Murniasih, T., Mohr, K. I., Wink, J., Engelmann, M., Praditya, D. F., Steinmann, E., & Schupp, P. J.\n\n\n \n\n\n\n Marine Drugs, 17(11): 635. November 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Biotechnological$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{wibowo_biotechnological_2019,\n\ttitle = {Biotechnological {Potential} of {Bacteria} {Isolated} from the {Sea} {Cucumber} {Holothuria} leucospilota and {Stichopus} vastus from {Lampung}, {Indonesia}},\n\tvolume = {17},\n\tissn = {1660-3397},\n\turl = {https://www.mdpi.com/1660-3397/17/11/635},\n\tdoi = {10.3390/md17110635},\n\tabstract = {In order to minimize re-discovery of already known anti-infective compounds, we focused our screening approach on understudied, almost untapped marine environments including marine invertebrates and their associated bacteria. Therefore, two sea cucumber species, Holothuria leucospilota and Stichopus vastus, were collected from Lampung (Indonesia), and 127 bacterial strains were identified by partial 16S rRNA-gene sequencing analysis and compared with the NCBI database. In addition, the overall bacterial diversity from tissue samples of the sea cucumbers H. leucospilota and S. vastus was analyzed using the cultivation-independent Illumina MiSEQ analysis. Selected bacterial isolates were grown to high densities and the extracted biomass was tested against a selection of bacteria and fungi as well as the hepatitis C virus (HCV). Identification of putative bioactive bacterial-derived compounds were performed by analyzing the accurate mass of the precursor/parent ions (MS1) as well as product/daughter ions (MS2) using high resolution mass spectrometry (HRMS) analysis of all active fractions. With this attempt we were able to identify 23 putatively known and two previously unidentified precursor ions. Moreover, through 16S rRNA-gene sequencing we were able to identify putatively novel bacterial species from the phyla Actinobacteria, Proteobacteria and also Firmicutes. Our findings suggest that sea cucumbers like H. leucospilota and S. vastus are promising sources for the isolation of novel bacterial species that produce compounds with potentially high biotechnological potential.},\n\tlanguage = {en},\n\tnumber = {11},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Wibowo, Joko T. and Kellermann, Matthias Y. and Versluis, Dennis and Putra, Masteria Y. and Murniasih, Tutik and Mohr, Kathrin I. and Wink, Joachim and Engelmann, Michael and Praditya, Dimas F. and Steinmann, Eike and Schupp, Peter J.},\n\tmonth = nov,\n\tyear = {2019},\n\tpages = {635},\n}\n\n

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\n \n\n \n \n \n \n \n \n Prokaryotic Diversity and Community Patterns in Antarctic Continental Shelf Sponges.\n \n \n \n \n\n\n \n Steinert, G., Wemheuer, B., Janussen, D., Erpenbeck, D., Daniel, R., Simon, M., Brinkhoff, T., & Schupp, P. J.\n\n\n \n\n\n\n Frontiers in Marine Science, 6: 297. June 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Prokaryotic$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{steinert_prokaryotic_2019,\n\ttitle = {Prokaryotic {Diversity} and {Community} {Patterns} in {Antarctic} {Continental} {Shelf} {Sponges}},\n\tvolume = {6},\n\tissn = {2296-7745},\n\turl = {https://www.frontiersin.org/article/10.3389/fmars.2019.00297/full},\n\tdoi = {10.3389/fmars.2019.00297},\n\turldate = {2022-11-09},\n\tjournal = {Frontiers in Marine Science},\n\tauthor = {Steinert, Georg and Wemheuer, Bernd and Janussen, Dorte and Erpenbeck, Dirk and Daniel, Rolf and Simon, Meinhard and Brinkhoff, Thorsten and Schupp, Peter J.},\n\tmonth = jun,\n\tyear = {2019},\n\tpages = {297},\n}\n\n

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\n \n\n \n \n \n \n \n \n Express Method for Isolation of Ready-to-Use 3D Chitin Scaffolds from Aplysina archeri (Aplysineidae: Verongiida) Demosponge.\n \n \n \n \n\n\n \n Klinger, C., Żółtowska-Aksamitowska, S., Wysokowski, M., Tsurkan, M. V., Galli, R., Petrenko, I., Machałowski, T., Ereskovsky, A., Martinović, R., Muzychka, L., Smolii, O. B., Bechmann, N., Ivanenko, V., Schupp, P. J., Jesionowski, T., Giovine, M., Joseph, Y., Bornstein, S. R., Voronkina, A., & Ehrlich, H.\n\n\n \n\n\n\n Marine Drugs, 17(2): 131. February 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Express$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{klinger_express_2019,\n\ttitle = {Express {Method} for {Isolation} of {Ready}-to-{Use} {3D} {Chitin} {Scaffolds} from {Aplysina} archeri ({Aplysineidae}: {Verongiida}) {Demosponge}},\n\tvolume = {17},\n\tissn = {1660-3397},\n\tshorttitle = {Express {Method} for {Isolation} of {Ready}-to-{Use} {3D} {Chitin} {Scaffolds} from {Aplysina} archeri ({Aplysineidae}},\n\turl = {http://www.mdpi.com/1660-3397/17/2/131},\n\tdoi = {10.3390/md17020131},\n\tabstract = {Sponges are a valuable source of natural compounds and biomaterials for many biotechnological applications. Marine sponges belonging to the order Verongiida are known to contain both chitin and biologically active bromotyrosines. Aplysina archeri (Aplysineidae: Verongiida) is well known to contain bromotyrosines with relevant bioactivity against human and animal diseases. The aim of this study was to develop an express method for the production of naturally prefabricated 3D chitin and bromotyrosine-containing extracts simultaneously. This new method is based on microwave irradiation (MWI) together with stepwise treatment using 1\\% sodium hydroxide, 20\\% acetic acid, and 30\\% hydrogen peroxide. This approach, which takes up to 1 h, made it possible to isolate chitin from the tube-like skeleton of A. archeri and to demonstrate the presence of this biopolymer in this sponge for the first time. Additionally, this procedure does not deacetylate chitin to chitosan and enables the recovery of ready-to-use 3D chitin scaffolds without destruction of the unique tube-like fibrous interconnected structure of the isolated biomaterial. Furthermore, these mechanically stressed fibers still have the capacity for saturation with water, methylene blue dye, crude oil, and blood, which is necessary for the application of such renewable 3D chitinous centimeter-sized scaffolds in diverse technological and biomedical fields.},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Klinger, Christine and Żółtowska-Aksamitowska, Sonia and Wysokowski, Marcin and Tsurkan, Mikhail V. and Galli, Roberta and Petrenko, Iaroslav and Machałowski, Tomasz and Ereskovsky, Alexander and Martinović, Rajko and Muzychka, Lyubov and Smolii, Oleg B. and Bechmann, Nicole and Ivanenko, Viatcheslav and Schupp, Peter J. and Jesionowski, Teofil and Giovine, Marco and Joseph, Yvonne and Bornstein, Stefan R. and Voronkina, Alona and Ehrlich, Hermann},\n\tmonth = feb,\n\tyear = {2019},\n\tpages = {131},\n}\n\n

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\n \n\n \n \n \n \n \n \n Sponges from Zanzibar host diverse prokaryotic communities with potential for natural product synthesis.\n \n \n \n \n\n\n \n Helber, S. B, Steinert, G., Wu, Y., Rohde, S., Hentschel, U., Muhando, C. A, & Schupp, P. J\n\n\n \n\n\n\n FEMS Microbiology Ecology, 95(4). April 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Sponges$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{helber_sponges_2019,\n\ttitle = {Sponges from {Zanzibar} host diverse prokaryotic communities with potential for natural product synthesis},\n\tvolume = {95},\n\tissn = {1574-6941},\n\turl = {https://academic.oup.com/femsec/article/doi/10.1093/femsec/fiz026/5369420},\n\tdoi = {10.1093/femsec/fiz026},\n\tlanguage = {en},\n\tnumber = {4},\n\turldate = {2022-11-09},\n\tjournal = {FEMS Microbiology Ecology},\n\tauthor = {Helber, Stephanie B and Steinert, Georg and Wu, Yu-Chen and Rohde, Sven and Hentschel, Ute and Muhando, Christopher A and Schupp, Peter J},\n\tmonth = apr,\n\tyear = {2019},\n}\n\n

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\n \n\n \n \n \n \n \n \n New bioactive metabolites from the elicited marine sponge-derived bacterium Actinokineospora spheciospongiae sp. nov.\n \n \n \n \n\n\n \n Tawfike, A., Attia, E. Z., Desoukey, S. Y., Hajjar, D., Makki, A. A., Schupp, P. J., Edrada-Ebel, R., & Abdelmohsen, U. R.\n\n\n \n\n\n\n AMB Express, 9(1): 12. December 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"New$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{tawfike_new_2019,\n\ttitle = {New bioactive metabolites from the elicited marine sponge-derived bacterium {Actinokineospora} spheciospongiae sp. nov.},\n\tvolume = {9},\n\tissn = {2191-0855},\n\turl = {https://amb-express.springeropen.com/articles/10.1186/s13568-018-0730-0},\n\tdoi = {10.1186/s13568-018-0730-0},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {AMB Express},\n\tauthor = {Tawfike, Ahmed and Attia, Eman Zekry and Desoukey, Samar Yehia and Hajjar, Dina and Makki, Arwa A. and Schupp, Peter J. and Edrada-Ebel, RuAngelie and Abdelmohsen, Usama Ramadan},\n\tmonth = dec,\n\tyear = {2019},\n\tpages = {12},\n}\n\n

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\n \n\n \n \n \n \n \n \n Acclimation capability inferred by metabolic performance in two sea cucumber species from different latitudes.\n \n \n \n \n\n\n \n Kühnhold, H., Novais, S. C., Alves, L. M., Kamyab, E., Lemos, M. F., Slater, M. J., & Kunzmann, A.\n\n\n \n\n\n\n Journal of Thermal Biology, 84: 407–413. August 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Acclimation$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n \n \n \n \n \n \n \n \n\n\n\n

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@article{kuhnhold_acclimation_2019,\n\ttitle = {Acclimation capability inferred by metabolic performance in two sea cucumber species from different latitudes},\n\tvolume = {84},\n\tissn = {03064565},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0306456519302116},\n\tdoi = {10.1016/j.jtherbio.2019.07.019},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Thermal Biology},\n\tauthor = {Kühnhold, Holger and Novais, Sara C. and Alves, Luis M.F. and Kamyab, Elham and Lemos, Marco F.L. and Slater, Matthew J. and Kunzmann, Andreas},\n\tmonth = aug,\n\tyear = {2019},\n\tkeywords = {Energy metabolism, Eurytherms, Stenotherms, Temperature stress},\n\tpages = {407--413},\n}\n\n

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\n \n\n \n \n \n \n \n \n Neuroactive compounds induce larval settlement in the scleractinian coral Leptastrea purpurea.\n \n \n \n \n\n\n \n Moeller, M., Nietzer, S., & Schupp, P. J.\n\n\n \n\n\n\n Scientific Reports, 9(1): 2291. December 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Neuroactive$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{moeller_neuroactive_2019,\n\ttitle = {Neuroactive compounds induce larval settlement in the scleractinian coral {Leptastrea} purpurea},\n\tvolume = {9},\n\tissn = {2045-2322},\n\turl = {http://www.nature.com/articles/s41598-019-38794-2},\n\tdoi = {10.1038/s41598-019-38794-2},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Scientific Reports},\n\tauthor = {Moeller, Mareen and Nietzer, Samuel and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2019},\n\tpages = {2291},\n}\n\n

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\n \n\n \n \n \n \n \n \n The role of invasive marine plants for macrofauna nutrition in the Wadden Sea.\n \n \n \n \n\n\n \n Lange, G., Schmitt, J. A., Kröncke, I., Moorthi, S. D., Rohde, S., Scheu, S., & Schupp, P. J.\n\n\n \n\n\n\n Journal of Experimental Marine Biology and Ecology, 512: 1–11. March 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"The$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{lange_role_2019,\n\ttitle = {The role of invasive marine plants for macrofauna nutrition in the {Wadden} {Sea}},\n\tvolume = {512},\n\tissn = {00220981},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0022098118302843},\n\tdoi = {10.1016/j.jembe.2018.12.005},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Experimental Marine Biology and Ecology},\n\tauthor = {Lange, Gesine and Schmitt, Jennifer A. and Kröncke, Ingrid and Moorthi, Stefanie D. and Rohde, Sven and Scheu, Stefan and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2019},\n\tpages = {1--11},\n}\n\n

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\n \n\n \n \n \n \n \n \n Diet and growth of juvenile queen conch Lobatus gigas (Gastropoda: Strombidae) in native, mixed and invasive seagrass habitats.\n \n \n \n \n\n\n \n Boman, E., Bervoets, T, de Graaf, M, Dewenter, J, Maitz, A, Meijer Zu Schlochtern, M., Stapel, J, Smaal, A., & Nagelkerke, L.\n\n\n \n\n\n\n Marine Ecology Progress Series, 621: 143–154. July 2019.\n \n\n\n\n
\n\n\n\n \n \n $\"Diet$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{boman_diet_2019,\n\ttitle = {Diet and growth of juvenile queen conch {Lobatus} gigas ({Gastropoda}: {Strombidae}) in native, mixed and invasive seagrass habitats},\n\tvolume = {621},\n\tissn = {0171-8630, 1616-1599},\n\tshorttitle = {Diet and growth of juvenile queen conch {Lobatus} gigas ({Gastropoda}},\n\turl = {https://www.int-res.com/abstracts/meps/v621/p143-154/},\n\tdoi = {10.3354/meps12990},\n\tlanguage = {en},\n\turldate = {2022-11-10},\n\tjournal = {Marine Ecology Progress Series},\n\tauthor = {Boman, Em and Bervoets, T and de Graaf, M and Dewenter, J and Maitz, A and Meijer Zu Schlochtern, Mp and Stapel, J and Smaal, Ac and Nagelkerke, Laj},\n\tmonth = jul,\n\tyear = {2019},\n\tpages = {143--154},\n}\n\n

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\n \n 2018\n \n \n (2)\n \n \n

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\n \n\n \n \n \n \n \n \n Sponge chemical defenses are a possible mechanism for increasing sponge abundance on reefs in Zanzibar.\n \n \n \n \n\n\n \n Helber, S. B., Hoeijmakers, D. J. J., Muhando, C. A., Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n PLOS ONE, 13(6): e0197617. June 2018.\n \n\n\n\n
\n\n\n\n \n \n $\"Sponge$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{helber_sponge_2018,\n\ttitle = {Sponge chemical defenses are a possible mechanism for increasing sponge abundance on reefs in {Zanzibar}},\n\tvolume = {13},\n\tissn = {1932-6203},\n\turl = {https://dx.plos.org/10.1371/journal.pone.0197617},\n\tdoi = {10.1371/journal.pone.0197617},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2022-11-09},\n\tjournal = {PLOS ONE},\n\tauthor = {Helber, Stephanie B. and Hoeijmakers, Dieuwke J. J. and Muhando, Christopher A. and Rohde, Sven and Schupp, Peter J.},\n\teditor = {Pronzato, Roberto},\n\tmonth = jun,\n\tyear = {2018},\n\tpages = {e0197617},\n}\n\n

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\n \n\n \n \n \n \n \n \n Comparative Genomics Highlights Symbiotic Capacities and High Metabolic Flexibility of the Marine Genus Pseudovibrio.\n \n \n \n \n\n\n \n Versluis, D., Nijsse, B., Naim, M. A., Koehorst, J. J, Wiese, J., Imhoff, J. F, Schaap, P. J, van Passel, M. W J, Smidt, H., & Sipkema, D.\n\n\n \n\n\n\n Genome Biology and Evolution, 10(1): 125–142. January 2018.\n \n\n\n\n
\n\n\n\n \n \n $\"Comparative$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{versluis_comparative_2018,\n\ttitle = {Comparative {Genomics} {Highlights} {Symbiotic} {Capacities} and {High} {Metabolic} {Flexibility} of the {Marine} {Genus} {Pseudovibrio}},\n\tvolume = {10},\n\tissn = {1759-6653},\n\turl = {http://academic.oup.com/gbe/article/10/1/125/4793240},\n\tdoi = {10.1093/gbe/evx271},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Genome Biology and Evolution},\n\tauthor = {Versluis, Dennis and Nijsse, Bart and Naim, Mohd Azrul and Koehorst, Jasper J and Wiese, Jutta and Imhoff, Johannes F and Schaap, Peter J and van Passel, Mark W J and Smidt, Hauke and Sipkema, Detmer},\n\tmonth = jan,\n\tyear = {2018},\n\tpages = {125--142},\n}\n\n

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\n \n 2017\n \n \n (12)\n \n \n

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\n \n\n \n \n \n \n \n \n The sponge microbiome project.\n \n \n \n \n\n\n \n Moitinho-Silva, L., Nielsen, S., Amir, A., Gonzalez, A., Ackermann, G. L, Cerrano, C., Astudillo-Garcia, C., Easson, C., Sipkema, D., Liu, F., Steinert, G., Kotoulas, G., McCormack, G. P, Feng, G., Bell, J. J, Vicente, J., Björk, J. R, Montoya, J. M, Olson, J. B, Reveillaud, J., Steindler, L., Pineda, M., Marra, M. V, Ilan, M., Taylor, M. W, Polymenakou, P., Erwin, P. M, Schupp, P. J, Simister, R. L, Knight, R., Thacker, R. W, Costa, R., Hill, R. T, Lopez-Legentil, S., Dailianis, T., Ravasi, T., Hentschel, U., Li, Z., Webster, N. S, & Thomas, T.\n\n\n \n\n\n\n GigaScience, 6(10). October 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"The$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{moitinho-silva_sponge_2017,\n\ttitle = {The sponge microbiome project},\n\tvolume = {6},\n\tissn = {2047-217X},\n\turl = {https://academic.oup.com/gigascience/article/doi/10.1093/gigascience/gix077/4082886},\n\tdoi = {10.1093/gigascience/gix077},\n\tlanguage = {en},\n\tnumber = {10},\n\turldate = {2022-11-09},\n\tjournal = {GigaScience},\n\tauthor = {Moitinho-Silva, Lucas and Nielsen, Shaun and Amir, Amnon and Gonzalez, Antonio and Ackermann, Gail L and Cerrano, Carlo and Astudillo-Garcia, Carmen and Easson, Cole and Sipkema, Detmer and Liu, Fang and Steinert, Georg and Kotoulas, Giorgos and McCormack, Grace P and Feng, Guofang and Bell, James J and Vicente, Jan and Björk, Johannes R and Montoya, Jose M and Olson, Julie B and Reveillaud, Julie and Steindler, Laura and Pineda, Mari-Carmen and Marra, Maria V and Ilan, Micha and Taylor, Michael W and Polymenakou, Paraskevi and Erwin, Patrick M and Schupp, Peter J and Simister, Rachel L and Knight, Rob and Thacker, Robert W and Costa, Rodrigo and Hill, Russell T and Lopez-Legentil, Susanna and Dailianis, Thanos and Ravasi, Timothy and Hentschel, Ute and Li, Zhiyong and Webster, Nicole S and Thomas, Torsten},\n\tmonth = oct,\n\tyear = {2017},\n}\n\n

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\n \n\n \n \n \n \n \n \n Secondary metabolome and its defensive role in the aeolidoidean Phyllodesmium longicirrum , (Gastropoda, Heterobranchia, Nudibranchia).\n \n \n \n \n\n\n \n Bogdanov, A., Hertzer, C., Kehraus, S., Nietzer, S., Rohde, S., Schupp, P. J, Wägele, H., & König, G. M\n\n\n \n\n\n\n Beilstein Journal of Organic Chemistry, 13: 502–519. March 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Secondary$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{bogdanov_secondary_2017,\n\ttitle = {Secondary metabolome and its defensive role in the aeolidoidean \\textit{{Phyllodesmium} longicirrum} , ({Gastropoda}, {Heterobranchia}, {Nudibranchia})},\n\tvolume = {13},\n\tissn = {1860-5397},\n\turl = {https://www.beilstein-journals.org/bjoc/articles/13/50},\n\tdoi = {10.3762/bjoc.13.50},\n\tabstract = {Phyllodesmium longicirrum\n              is the largest aeolidoidean species known to date, and extremely rich in terpenoid chemistry. Herein we report the isolation of a total of 19 secondary metabolites from a single specimen of this species, i.e., steroids\n              1–4\n              , cembranoid diterpenes\n              5–13\n              , complex biscembranoids\n              14\n              and\n              15\n              , and the chatancin-type diterpenes\n              16–19\n              . These compounds resemble those from soft corals of the genus\n              Sarcophyton\n              , of which to date, however, only\n              S. trocheliophorum\n              is described as a food source for\n              P. longicirrum\n              . Fish feeding deterrent activity was determined using the tropical puffer fish\n              Canthigaster solandri\n              , and showed activity for (2\n              S\n              )-isosarcophytoxide (\n              10\n              ), cembranoid bisepoxide\n              12\n              and 4-oxochatancin (\n              16\n              ). Determining the metabolome of\n              P. longicirrum\n              and its bioactivity, makes it evident that this seemingly vulnerable soft bodied animal is well protected from fish by its chemical arsenal.},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {Beilstein Journal of Organic Chemistry},\n\tauthor = {Bogdanov, Alexander and Hertzer, Cora and Kehraus, Stefan and Nietzer, Samuel and Rohde, Sven and Schupp, Peter J and Wägele, Heike and König, Gabriele M},\n\tmonth = mar,\n\tyear = {2017},\n\tpages = {502--519},\n}\n\n

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\n \n\n \n \n \n \n \n \n Determination of the Halogenated Skeleton Constituents of the Marine Demosponge Ianthella basta.\n \n \n \n \n\n\n \n Ueberlein, S., Machill, S., Schupp, P., & Brunner, E.\n\n\n \n\n\n\n Marine Drugs, 15(2): 34. February 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Determination$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{ueberlein_determination_2017,\n\ttitle = {Determination of the {Halogenated} {Skeleton} {Constituents} of the {Marine} {Demosponge} {Ianthella} basta},\n\tvolume = {15},\n\tissn = {1660-3397},\n\turl = {http://www.mdpi.com/1660-3397/15/2/34},\n\tdoi = {10.3390/md15020034},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {Marine Drugs},\n\tauthor = {Ueberlein, Susanne and Machill, Susanne and Schupp, Peter and Brunner, Eike},\n\tmonth = feb,\n\tyear = {2017},\n\tpages = {34},\n}\n\n

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\n \n\n \n \n \n \n \n \n Comparison of antifouling properties of native and invasive Sargassum (Fucales, Phaeophyceae) species.\n \n \n \n \n\n\n \n Schwartz, N., Dobretsov, S., Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n European Journal of Phycology, 52(1): 116–131. January 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Comparison$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schwartz_comparison_2017,\n\ttitle = {Comparison of antifouling properties of native and invasive \\textit{{Sargassum}} ({Fucales}, {Phaeophyceae}) species},\n\tvolume = {52},\n\tissn = {0967-0262, 1469-4433},\n\turl = {https://www.tandfonline.com/doi/full/10.1080/09670262.2016.1231345},\n\tdoi = {10.1080/09670262.2016.1231345},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {European Journal of Phycology},\n\tauthor = {Schwartz, Nicole and Dobretsov, Sergey and Rohde, Sven and Schupp, Peter J.},\n\tmonth = jan,\n\tyear = {2017},\n\tpages = {116--131},\n}\n\n

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\n \n\n \n \n \n \n \n \n Host-specific assembly of sponge-associated prokaryotes at high taxonomic ranks.\n \n \n \n \n\n\n \n Steinert, G., Rohde, S., Janussen, D., Blaurock, C., & Schupp, P. J.\n\n\n \n\n\n\n Scientific Reports, 7(1): 2542. December 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Host-specific$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{steinert_host-specific_2017,\n\ttitle = {Host-specific assembly of sponge-associated prokaryotes at high taxonomic ranks},\n\tvolume = {7},\n\tissn = {2045-2322},\n\turl = {http://www.nature.com/articles/s41598-017-02656-6},\n\tdoi = {10.1038/s41598-017-02656-6},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Scientific Reports},\n\tauthor = {Steinert, Georg and Rohde, Sven and Janussen, Dorte and Blaurock, Claudia and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2017},\n\tpages = {2542},\n}\n\n

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\n \n\n \n \n \n \n \n \n Novel chitin scaffolds derived from marine sponge Ianthella basta for tissue engineering approaches based on human mesenchymal stromal cells: Biocompatibility and cryopreservation.\n \n \n \n \n\n\n \n Mutsenko, V. V., Gryshkov, O., Lauterboeck, L., Rogulska, O., Tarusin, D. N., Bazhenov, V. V., Schütz, K., Brüggemeier, S., Gossla, E., Akkineni, A. R., Meißner, H., Lode, A., Meschke, S., Fromont, J., Stelling, A. L., Tabachnik, K. R., Gelinsky, M., Nikulin, S., Rodin, S., Tonevitsky, A. G., Petrenko, A. Y., Glasmacher, B., Schupp, P. J., & Ehrlich, H.\n\n\n \n\n\n\n International Journal of Biological Macromolecules, 104: 1955–1965. November 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Novel$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{mutsenko_novel_2017,\n\ttitle = {Novel chitin scaffolds derived from marine sponge {Ianthella} basta for tissue engineering approaches based on human mesenchymal stromal cells: {Biocompatibility} and cryopreservation},\n\tvolume = {104},\n\tissn = {01418130},\n\tshorttitle = {Novel chitin scaffolds derived from marine sponge {Ianthella} basta for tissue engineering approaches based on human mesenchymal stromal cells},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0141813016326605},\n\tdoi = {10.1016/j.ijbiomac.2017.03.161},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {International Journal of Biological Macromolecules},\n\tauthor = {Mutsenko, Vitalii V. and Gryshkov, Oleksandr and Lauterboeck, Lothar and Rogulska, Olena and Tarusin, Dmitriy N. and Bazhenov, Vasilii V. and Schütz, Kathleen and Brüggemeier, Sophie and Gossla, Elke and Akkineni, Ashwini R. and Meißner, Heike and Lode, Anja and Meschke, Stephan and Fromont, Jane and Stelling, Allison L. and Tabachnik, Konstantin R. and Gelinsky, Michael and Nikulin, Sergey and Rodin, Sergey and Tonevitsky, Alexander G. and Petrenko, Alexander Y. and Glasmacher, Birgit and Schupp, Peter J. and Ehrlich, Hermann},\n\tmonth = nov,\n\tyear = {2017},\n\tpages = {1955--1965},\n}\n\n

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\n \n\n \n \n \n \n \n \n Diversity of two widespread Indo-Pacific demosponge species revisited.\n \n \n \n \n\n\n \n Erpenbeck, D., Aryasari, R., Benning, S., Debitus, C., Kaltenbacher, E., Al-Aidaroos, A. M., Schupp, P., Hall, K., Hooper, J. N. A., Voigt, O., de Voogd, N. J., & Wörheide, G.\n\n\n \n\n\n\n Marine Biodiversity, 47(4): 1035–1043. December 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Diversity$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{erpenbeck_diversity_2017,\n\ttitle = {Diversity of two widespread {Indo}-{Pacific} demosponge species revisited},\n\tvolume = {47},\n\tissn = {1867-1616, 1867-1624},\n\turl = {http://link.springer.com/10.1007/s12526-017-0783-3},\n\tdoi = {10.1007/s12526-017-0783-3},\n\tlanguage = {en},\n\tnumber = {4},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biodiversity},\n\tauthor = {Erpenbeck, Dirk and Aryasari, Ratih and Benning, Sarah and Debitus, Cécile and Kaltenbacher, Emilie and Al-Aidaroos, Ali M. and Schupp, Peter and Hall, Kathryn and Hooper, John N. A. and Voigt, Oliver and de Voogd, Nicole J. and Wörheide, Gert},\n\tmonth = dec,\n\tyear = {2017},\n\tpages = {1035--1043},\n}\n\n

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\n \n\n \n \n \n \n \n \n Chitin of poriferan origin and the bioelectrometallurgy of copper/copper oxide.\n \n \n \n \n\n\n \n Petrenko, I., Bazhenov, V. V., Galli, R., Wysokowski, M., Fromont, J., Schupp, P. J., Stelling, A. L., Niederschlag, E., Stöker, H., Kutsova, V. Z., Jesionowski, T., & Ehrlich, H.\n\n\n \n\n\n\n International Journal of Biological Macromolecules, 104: 1626–1632. November 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Chitin$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{petrenko_chitin_2017,\n\ttitle = {Chitin of poriferan origin and the bioelectrometallurgy of copper/copper oxide},\n\tvolume = {104},\n\tissn = {01418130},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0141813016326915},\n\tdoi = {10.1016/j.ijbiomac.2017.01.084},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {International Journal of Biological Macromolecules},\n\tauthor = {Petrenko, Iaroslav and Bazhenov, Vasilii V. and Galli, Roberta and Wysokowski, Marcin and Fromont, Jane and Schupp, Peter J. and Stelling, Allison L. and Niederschlag, Elke and Stöker, Hartmut and Kutsova, Valentina Z. and Jesionowski, Teofil and Ehrlich, Hermann},\n\tmonth = nov,\n\tyear = {2017},\n\tpages = {1626--1632},\n}\n\n

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\n \n\n \n \n \n \n \n \n Only half of the truth: Managing invasive alien species by rapid assessment.\n \n \n \n \n\n\n \n Rohde, S., Schupp, P. J., Markert, A., & Wehrmann, A.\n\n\n \n\n\n\n Ocean & Coastal Management, 146: 26–35. September 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Only$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{rohde_only_2017,\n\ttitle = {Only half of the truth: {Managing} invasive alien species by rapid assessment},\n\tvolume = {146},\n\tissn = {09645691},\n\tshorttitle = {Only half of the truth},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0964569116303155},\n\tdoi = {10.1016/j.ocecoaman.2017.05.013},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {Ocean \\& Coastal Management},\n\tauthor = {Rohde, Sven and Schupp, Peter J. and Markert, Alexandra and Wehrmann, Achim},\n\tmonth = sep,\n\tyear = {2017},\n\tpages = {26--35},\n}\n\n

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\n \n\n \n \n \n \n \n \n Anti-predatory effects of organic extracts of 10 common reef sponges from Zanzibar.\n \n \n \n \n\n\n \n Helber, S. B., de Voogd, N. J., Muhando, C. A., Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n Hydrobiologia, 790(1): 247–258. April 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Anti-predatory$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{helber_anti-predatory_2017,\n\ttitle = {Anti-predatory effects of organic extracts of 10 common reef sponges from {Zanzibar}},\n\tvolume = {790},\n\tissn = {0018-8158, 1573-5117},\n\turl = {http://link.springer.com/10.1007/s10750-016-3036-8},\n\tdoi = {10.1007/s10750-016-3036-8},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Hydrobiologia},\n\tauthor = {Helber, S. B. and de Voogd, N. J. and Muhando, C. A. and Rohde, S. and Schupp, P. J.},\n\tmonth = apr,\n\tyear = {2017},\n\tpages = {247--258},\n}\n\n

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\n \n\n \n \n \n \n \n \n Persistent outbreaks of the “black disease” sponge Terpios hoshinota in Indonesian coral reefs.\n \n \n \n \n\n\n \n Madduppa, H., Schupp, P. J., Faisal, M. R., Sastria, M. Y., & Thoms, C.\n\n\n \n\n\n\n Marine Biodiversity, 47(1): 149–151. March 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Persistent$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{madduppa_persistent_2017,\n\ttitle = {Persistent outbreaks of the “black disease” sponge {Terpios} hoshinota in {Indonesian} coral reefs},\n\tvolume = {47},\n\tissn = {1867-1616, 1867-1624},\n\turl = {http://link.springer.com/10.1007/s12526-015-0426-5},\n\tdoi = {10.1007/s12526-015-0426-5},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biodiversity},\n\tauthor = {Madduppa, Hawis and Schupp, Peter J. and Faisal, Muhammad Reza and Sastria, Mustami Yuda and Thoms, Carsten},\n\tmonth = mar,\n\tyear = {2017},\n\tpages = {149--151},\n}\n\n

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\n \n\n \n \n \n \n \n \n Low sediment loads affect survival of coral recruits: the first weeks are crucial.\n \n \n \n \n\n\n \n Moeller, M., Nietzer, S., Schils, T., & Schupp, P. J.\n\n\n \n\n\n\n Coral Reefs, 36(1): 39–49. March 2017.\n \n\n\n\n
\n\n\n\n \n \n $\"Low$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{moeller_low_2017,\n\ttitle = {Low sediment loads affect survival of coral recruits: the first weeks are crucial},\n\tvolume = {36},\n\tissn = {0722-4028, 1432-0975},\n\tshorttitle = {Low sediment loads affect survival of coral recruits},\n\turl = {http://link.springer.com/10.1007/s00338-016-1513-1},\n\tdoi = {10.1007/s00338-016-1513-1},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Coral Reefs},\n\tauthor = {Moeller, Mareen and Nietzer, Samuel and Schils, Tom and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2017},\n\tpages = {39--49},\n}\n\n

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\n \n 2016\n \n \n (8)\n \n \n

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\n \n\n \n \n \n \n \n \n Predicting the spread of marine species introduced by global shipping.\n \n \n \n \n\n\n \n Seebens, H., Schwartz, N., Schupp, P. J., & Blasius, B.\n\n\n \n\n\n\n Proceedings of the National Academy of Sciences, 113(20): 5646–5651. May 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"Predicting$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{seebens_predicting_2016,\n\ttitle = {Predicting the spread of marine species introduced by global shipping},\n\tvolume = {113},\n\tissn = {0027-8424, 1091-6490},\n\turl = {https://pnas.org/doi/full/10.1073/pnas.1524427113},\n\tdoi = {10.1073/pnas.1524427113},\n\tabstract = {Significance\n            Predicting the arrival of alien species remains a big challenge, which is assumed to be a consequence of the complexity of the invasion process. Here, we demonstrate that spreading of alien marine species can be predicted by a simple model using only global shipping intensities, environmental variables, and species occurrence data. We provide species lists of the next potentially invading species in a local habitat or species causing harmful algal blooms with their associated probability of invasion. This will help to improve mitigation strategies to reduce the further introduction of alien species. Although this study focuses on marine algae, the model approach can be easily adopted to other taxonomic groups and their respective drivers of invasion.\n          , \n            The human-mediated translocation of species poses a distinct threat to nature, human health, and economy. Although existing models calculate the invasion probability of any species, frameworks for species-specific forecasts are still missing. Here, we developed a model approach using global ship movements and environmental conditions to simulate the successive global spread of marine alien species that allows predicting the identity of those species likely to arrive next in a given habitat. In a first step, we simulated the historical stepping-stone spreading dynamics of 40 marine alien species and compared predicted and observed alien species ranges. With an accuracy of 77\\%, the model correctly predicted the presence/absence of an alien species in an ecoregion. Spreading dynamics followed a common pattern with an initial invasion of most suitable habitats worldwide and a subsequent spread into neighboring habitats. In a second step, we used the reported distribution of 97 marine algal species with a known invasion history, and six species causing harmful algal blooms, to determine the ecoregions most likely to be invaded next under climate warming. Cluster analysis revealed that species can be classified according to three characteristic spreading profiles: emerging species, high-risk species, and widespread species. For the North Sea, the model predictions could be confirmed because two of the predicted high-risk species have recently invaded the North Sea. This study highlights that even simple models considering only shipping intensities and habitat matches are able to correctly predict the identity of the next invading marine species.},\n\tlanguage = {en},\n\tnumber = {20},\n\turldate = {2022-11-09},\n\tjournal = {Proceedings of the National Academy of Sciences},\n\tauthor = {Seebens, Hanno and Schwartz, Nicole and Schupp, Peter J. and Blasius, Bernd},\n\tmonth = may,\n\tyear = {2016},\n\tpages = {5646--5651},\n}\n\n

\n

\n\n\n

\n Significance Predicting the arrival of alien species remains a big challenge, which is assumed to be a consequence of the complexity of the invasion process. Here, we demonstrate that spreading of alien marine species can be predicted by a simple model using only global shipping intensities, environmental variables, and species occurrence data. We provide species lists of the next potentially invading species in a local habitat or species causing harmful algal blooms with their associated probability of invasion. This will help to improve mitigation strategies to reduce the further introduction of alien species. Although this study focuses on marine algae, the model approach can be easily adopted to other taxonomic groups and their respective drivers of invasion. , The human-mediated translocation of species poses a distinct threat to nature, human health, and economy. Although existing models calculate the invasion probability of any species, frameworks for species-specific forecasts are still missing. Here, we developed a model approach using global ship movements and environmental conditions to simulate the successive global spread of marine alien species that allows predicting the identity of those species likely to arrive next in a given habitat. In a first step, we simulated the historical stepping-stone spreading dynamics of 40 marine alien species and compared predicted and observed alien species ranges. With an accuracy of 77%, the model correctly predicted the presence/absence of an alien species in an ecoregion. Spreading dynamics followed a common pattern with an initial invasion of most suitable habitats worldwide and a subsequent spread into neighboring habitats. In a second step, we used the reported distribution of 97 marine algal species with a known invasion history, and six species causing harmful algal blooms, to determine the ecoregions most likely to be invaded next under climate warming. Cluster analysis revealed that species can be classified according to three characteristic spreading profiles: emerging species, high-risk species, and widespread species. For the North Sea, the model predictions could be confirmed because two of the predicted high-risk species have recently invaded the North Sea. This study highlights that even simple models considering only shipping intensities and habitat matches are able to correctly predict the identity of the next invading marine species.\n

\n\n\n

\n \n\n \n \n \n \n \n \n Genetic structure of the crown-of-thorns seastar in the Pacific Ocean, with focus on Guam.\n \n \n \n \n\n\n \n Tusso, S., Morcinek, K., Vogler, C., Schupp, P. J., Caballes, C. F., Vargas, S., & Wörheide, G.\n\n\n \n\n\n\n PeerJ, 4: e1970. May 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"Genetic$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{tusso_genetic_2016,\n\ttitle = {Genetic structure of the crown-of-thorns seastar in the {Pacific} {Ocean}, with focus on {Guam}},\n\tvolume = {4},\n\tissn = {2167-8359},\n\turl = {https://peerj.com/articles/1970},\n\tdoi = {10.7717/peerj.1970},\n\tabstract = {Population outbreaks of the corallivorous crown-of-thorns seastar (COTS),\n              Acanthaster ‘planci’ L.\n              , are among the most important biological disturbances of tropical coral reefs. Over the past 50 years, several devastating outbreaks have been documented around Guam, an island in the western Pacific Ocean. Previous analyses have shown that in the Pacific Ocean, COTS larval dispersal may be geographically restricted to certain regions. Here, we assess the genetic structure of Pacific COTS populations and compared samples from around Guam with a number of distant localities in the Pacific Ocean, and focused on determining the degree of genetic structure among populations previously considered to be isolated. Using microsatellites, we document substantial genetic structure between 14 localities from different geographical regions in the Pacific Ocean. Populations from the 14 locations sampled were found to be structured in three significantly differentiated groups: (1) all locations immediately around Guam, as well as Kingman Reef and Swains Island; (2) Japan, Philippines, GBR and Vanuatu; and (3) Johnston Atoll, which was significantly different from all other localities. The lack of genetic differentiation between Guam and extremely distant populations from Kingman Reef and Swains Island suggests potential long-distance dispersal of COTS in the Pacific.},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {PeerJ},\n\tauthor = {Tusso, Sergio and Morcinek, Kerstin and Vogler, Catherine and Schupp, Peter J. and Caballes, Ciemon F. and Vargas, Sergio and Wörheide, Gert},\n\tmonth = may,\n\tyear = {2016},\n\tpages = {e1970},\n}\n\n

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\n \n\n \n \n \n \n \n \n In four shallow and mesophotic tropical reef sponges from Guam the microbial community largely depends on host identity.\n \n \n \n \n\n\n \n Steinert, G., Taylor, M. W., Deines, P., Simister, R. L., de Voogd, N. J., Hoggard, M., & Schupp, P. J.\n\n\n \n\n\n\n PeerJ, 4: e1936. April 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"In$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{steinert_four_2016,\n\ttitle = {In four shallow and mesophotic tropical reef sponges from {Guam} the microbial community largely depends on host identity},\n\tvolume = {4},\n\tissn = {2167-8359},\n\turl = {https://peerj.com/articles/1936},\n\tdoi = {10.7717/peerj.1936},\n\tabstract = {Sponges (phylum Porifera) are important members of almost all aquatic ecosystems, and are renowned for hosting often dense and diverse microbial communities. While the specificity of the sponge microbiota seems to be closely related to host phylogeny, the environmental factors that could shape differences within local sponge-specific communities remain less understood. On tropical coral reefs, sponge habitats can span from shallow areas to deeper, mesophotic sites. These habitats differ in terms of environmental factors such as light, temperature, and food availability, as well as anthropogenic impact. In order to study the host specificity and potential influence of varying habitats on the sponge microbiota within a local area, four tropical reef sponges,\n              Rhabdastrella globostellata\n              ,\n              Callyspongia\n              sp.,\n              Rhaphoxya\n              sp., and\n              Acanthella cavernosa\n              , were collected from exposed shallow reef slopes and a deep reef drop-off. Based on 16S rRNA gene pyrosequencing profiles, beta diversity analyses revealed that each sponge species possessed a specific microbiota that was significantly different to those of the other species and exhibited attributes that are characteristic of high- and/or low-microbial-abundance sponges. These findings emphasize the influence of host identity on the associated microbiota. Dominant sponge- and seawater-associated bacterial phyla were Chloroflexi, Cyanobacteria, and Proteobacteria. Comparison of individual sponge taxa and seawater samples between shallow and deep reef sites revealed no significant variation in alpha diversity estimates, while differences in microbial beta diversity (variation in community composition) were significant for\n              Callyspongia\n              sp. sponges and seawater samples. Overall, the sponge-associated microbiota is significantly shaped by host identity across all samples, while the effect of habitat differentiation seems to be less predominant in tropical reef sponges.},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {PeerJ},\n\tauthor = {Steinert, Georg and Taylor, Michael W. and Deines, Peter and Simister, Rachel L. and de Voogd, Nicole J. and Hoggard, Michael and Schupp, Peter J.},\n\tmonth = apr,\n\tyear = {2016},\n\tpages = {e1936},\n}\n\n

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\n \n\n \n \n \n \n \n \n Defensive Diterpene from the Aeolidoidean Phyllodesmium longicirrum.\n \n \n \n \n\n\n \n Bogdanov, A., Hertzer, C., Kehraus, S., Nietzer, S., Rohde, S., Schupp, P. J., Wägele, H., & König, G. M.\n\n\n \n\n\n\n Journal of Natural Products, 79(3): 611–615. March 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"Defensive$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{bogdanov_defensive_2016,\n\ttitle = {Defensive {Diterpene} from the {Aeolidoidean} \\textit{{Phyllodesmium} longicirrum}},\n\tvolume = {79},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/acs.jnatprod.5b00860},\n\tdoi = {10.1021/acs.jnatprod.5b00860},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Bogdanov, Alexander and Hertzer, Cora and Kehraus, Stefan and Nietzer, Samuel and Rohde, Sven and Schupp, Peter J. and Wägele, Heike and König, Gabriele M.},\n\tmonth = mar,\n\tyear = {2016},\n\tpages = {611--615},\n}\n\n

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\n \n\n \n \n \n \n \n \n Impact of explantation techniques on the microbiota of the marine sponge Ecionemia alata.\n \n \n \n \n\n\n \n Meyer, K. M., Deines, P., Schupp, P. J., & Taylor, M. W.\n\n\n \n\n\n\n Journal of Experimental Marine Biology and Ecology, 484: 11–15. November 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"Impact$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{meyer_impact_2016,\n\ttitle = {Impact of explantation techniques on the microbiota of the marine sponge {Ecionemia} alata},\n\tvolume = {484},\n\tissn = {00220981},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0022098116301241},\n\tdoi = {10.1016/j.jembe.2016.08.003},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Experimental Marine Biology and Ecology},\n\tauthor = {Meyer, Kyle M. and Deines, Peter and Schupp, Peter J. and Taylor, Michael W.},\n\tmonth = nov,\n\tyear = {2016},\n\tpages = {11--15},\n}\n\n

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\n \n\n \n \n \n \n \n \n First record of the non-native Pacific bryozoan Smittoidea prolifica Osburn, 1952 at the German North Sea coast.\n \n \n \n \n\n\n \n Markert, A., Matsuyama, K., Rohde, S., Schupp, P., & Wehrmann, A.\n\n\n \n\n\n\n Marine Biodiversity, 46(3): 717–723. September 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"First$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{markert_first_2016,\n\ttitle = {First record of the non-native {Pacific} bryozoan {Smittoidea} prolifica {Osburn}, 1952 at the {German} {North} {Sea} coast},\n\tvolume = {46},\n\tissn = {1867-1616, 1867-1624},\n\turl = {http://link.springer.com/10.1007/s12526-015-0415-8},\n\tdoi = {10.1007/s12526-015-0415-8},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biodiversity},\n\tauthor = {Markert, Alexandra and Matsuyama, Kei and Rohde, Sven and Schupp, Peter and Wehrmann, Achim},\n\tmonth = sep,\n\tyear = {2016},\n\tpages = {717--723},\n}\n\n

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\n \n\n \n \n \n \n \n \n Understanding the invasion success of Sargassum muticum: herbivore preferences for native and invasive Sargassum spp.\n \n \n \n \n\n\n \n Schwartz, N., Rohde, S., Hiromori, S., & Schupp, P. J.\n\n\n \n\n\n\n Marine Biology, 163(9): 181. September 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"Understanding$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schwartz_understanding_2016,\n\ttitle = {Understanding the invasion success of {Sargassum} muticum: herbivore preferences for native and invasive {Sargassum} spp},\n\tvolume = {163},\n\tissn = {0025-3162, 1432-1793},\n\tshorttitle = {Understanding the invasion success of {Sargassum} muticum},\n\turl = {http://link.springer.com/10.1007/s00227-016-2953-4},\n\tdoi = {10.1007/s00227-016-2953-4},\n\tlanguage = {en},\n\tnumber = {9},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biology},\n\tauthor = {Schwartz, Nicole and Rohde, Sven and Hiromori, Shimabukuro and Schupp, Peter J.},\n\tmonth = sep,\n\tyear = {2016},\n\tpages = {181},\n}\n\n

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\n \n\n \n \n \n \n \n \n Diversity, structure and convergent evolution of the global sponge microbiome.\n \n \n \n \n\n\n \n Thomas, T., Moitinho-Silva, L., Lurgi, M., Björk, J. R., Easson, C., Astudillo-García, C., Olson, J. B., Erwin, P. M., López-Legentil, S., Luter, H., Chaves-Fonnegra, A., Costa, R., Schupp, P. J., Steindler, L., Erpenbeck, D., Gilbert, J., Knight, R., Ackermann, G., Victor Lopez, J., Taylor, M. W., Thacker, R. W., Montoya, J. M., Hentschel, U., & Webster, N. S.\n\n\n \n\n\n\n Nature Communications, 7(1): 11870. September 2016.\n \n\n\n\n
\n\n\n\n \n \n $\"Diversity,$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{thomas_diversity_2016,\n\ttitle = {Diversity, structure and convergent evolution of the global sponge microbiome},\n\tvolume = {7},\n\tissn = {2041-1723},\n\turl = {http://www.nature.com/articles/ncomms11870},\n\tdoi = {10.1038/ncomms11870},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Nature Communications},\n\tauthor = {Thomas, Torsten and Moitinho-Silva, Lucas and Lurgi, Miguel and Björk, Johannes R. and Easson, Cole and Astudillo-García, Carmen and Olson, Julie B. and Erwin, Patrick M. and López-Legentil, Susanna and Luter, Heidi and Chaves-Fonnegra, Andia and Costa, Rodrigo and Schupp, Peter J. and Steindler, Laura and Erpenbeck, Dirk and Gilbert, Jack and Knight, Rob and Ackermann, Gail and Victor Lopez, Jose and Taylor, Michael W. and Thacker, Robert W. and Montoya, Jose M. and Hentschel, Ute and Webster, Nicole S.},\n\tmonth = sep,\n\tyear = {2016},\n\tpages = {11870},\n}\n\n

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\n \n 2015\n \n \n (3)\n \n \n

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\n \n\n \n \n \n \n \n \n Prevalence and Mechanisms of Dynamic Chemical Defenses in Tropical Sponges.\n \n \n \n \n\n\n \n Rohde, S., Nietzer, S., & Schupp, P. J.\n\n\n \n\n\n\n PLOS ONE, 10(7): e0132236. July 2015.\n \n\n\n\n
\n\n\n\n \n \n $\"Prevalence$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{rohde_prevalence_2015,\n\ttitle = {Prevalence and {Mechanisms} of {Dynamic} {Chemical} {Defenses} in {Tropical} {Sponges}},\n\tvolume = {10},\n\tissn = {1932-6203},\n\turl = {https://dx.plos.org/10.1371/journal.pone.0132236},\n\tdoi = {10.1371/journal.pone.0132236},\n\tlanguage = {en},\n\tnumber = {7},\n\turldate = {2022-11-09},\n\tjournal = {PLOS ONE},\n\tauthor = {Rohde, Sven and Nietzer, Samuel and Schupp, Peter J.},\n\teditor = {Bell, James},\n\tmonth = jul,\n\tyear = {2015},\n\tpages = {e0132236},\n}\n\n

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\n \n\n \n \n \n \n \n \n Chemical mediation of coral larval settlement by crustose coralline algae.\n \n \n \n \n\n\n \n Tebben, J., Motti, C. A, Siboni, N., Tapiolas, D. M., Negri, A. P., Schupp, P. J., Kitamura, M., Hatta, M., Steinberg, P. D., & Harder, T.\n\n\n \n\n\n\n Scientific Reports, 5(1): 10803. September 2015.\n \n\n\n\n
\n\n\n\n \n \n $\"Chemical$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{tebben_chemical_2015,\n\ttitle = {Chemical mediation of coral larval settlement by crustose coralline algae},\n\tvolume = {5},\n\tissn = {2045-2322},\n\turl = {http://www.nature.com/articles/srep10803},\n\tdoi = {10.1038/srep10803},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Scientific Reports},\n\tauthor = {Tebben, J. and Motti, C. A and Siboni, Nahshon and Tapiolas, D. M. and Negri, A. P. and Schupp, P. J. and Kitamura, Makoto and Hatta, Masayuki and Steinberg, P. D. and Harder, T.},\n\tmonth = sep,\n\tyear = {2015},\n\tpages = {10803},\n}\n\n

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\n \n\n \n \n \n \n \n \n Diversity of Actinobacteria Associated with the Marine Ascidian Eudistoma toealensis.\n \n \n \n \n\n\n \n Steinert, G., Taylor, M. W., & Schupp, P. J.\n\n\n \n\n\n\n Marine Biotechnology, 17(4): 377–385. August 2015.\n \n\n\n\n
\n\n\n\n \n \n $\"Diversity$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{steinert_diversity_2015,\n\ttitle = {Diversity of {Actinobacteria} {Associated} with the {Marine} {Ascidian} {Eudistoma} toealensis},\n\tvolume = {17},\n\tissn = {1436-2228, 1436-2236},\n\turl = {http://link.springer.com/10.1007/s10126-015-9622-3},\n\tdoi = {10.1007/s10126-015-9622-3},\n\tlanguage = {en},\n\tnumber = {4},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biotechnology},\n\tauthor = {Steinert, Georg and Taylor, Michael W. and Schupp, Peter J.},\n\tmonth = aug,\n\tyear = {2015},\n\tpages = {377--385},\n}\n\n

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\n \n 2014\n \n \n (2)\n \n \n

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\n \n\n \n \n \n \n \n \n Application of Diffusion Growth Chambers for the Cultivation of Marine Sponge-Associated Bacteria.\n \n \n \n \n\n\n \n Steinert, G., Whitfield, S., Taylor, M. W., Thoms, C., & Schupp, P. J.\n\n\n \n\n\n\n Marine Biotechnology, 16(5): 594–603. October 2014.\n \n\n\n\n
\n\n\n\n \n \n $\"Application$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{steinert_application_2014,\n\ttitle = {Application of {Diffusion} {Growth} {Chambers} for the {Cultivation} of {Marine} {Sponge}-{Associated} {Bacteria}},\n\tvolume = {16},\n\tissn = {1436-2228, 1436-2236},\n\turl = {http://link.springer.com/10.1007/s10126-014-9575-y},\n\tdoi = {10.1007/s10126-014-9575-y},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biotechnology},\n\tauthor = {Steinert, Georg and Whitfield, Susanna and Taylor, Michael W. and Thoms, Carsten and Schupp, Peter J.},\n\tmonth = oct,\n\tyear = {2014},\n\tpages = {594--603},\n}\n\n

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\n\n\n

\n \n\n \n \n \n \n \n \n The HMA-LMA Dichotomy Revisited: an Electron Microscopical Survey of 56 Sponge Species.\n \n \n \n \n\n\n \n Gloeckner, V., Wehrl, M., Moitinho-Silva, L., Gernert, C., Schupp, P., Pawlik, J. R., Lindquist, N. L., Erpenbeck, D., Wörheide, G., & Hentschel, U.\n\n\n \n\n\n\n The Biological Bulletin, 227(1): 78–88. August 2014.\n \n\n\n\n
\n\n\n\n \n \n $\"The$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{gloeckner_hma-lma_2014,\n\ttitle = {The {HMA}-{LMA} {Dichotomy} {Revisited}: an {Electron} {Microscopical} {Survey} of 56 {Sponge} {Species}},\n\tvolume = {227},\n\tissn = {0006-3185, 1939-8697},\n\tshorttitle = {The {HMA}-{LMA} {Dichotomy} {Revisited}},\n\turl = {https://www.journals.uchicago.edu/doi/10.1086/BBLv227n1p78},\n\tdoi = {10.1086/BBLv227n1p78},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {The Biological Bulletin},\n\tauthor = {Gloeckner, Volker and Wehrl, Markus and Moitinho-Silva, Lucas and Gernert, Christine and Schupp, Peter and Pawlik, Joseph R. and Lindquist, Niels L. and Erpenbeck, Dirk and Wörheide, Gert and Hentschel, Ute},\n\tmonth = aug,\n\tyear = {2014},\n\tpages = {78--88},\n}\n\n

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\n\n\n\n\n\n

\n

\n \n 2013\n \n \n (3)\n \n \n

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\n \n \n

\n \n\n \n \n \n \n \n \n Preparation of chitin–silica composites by in vitro silicification of two-dimensional Ianthella basta demosponge chitinous scaffolds under modified Stöber conditions.\n \n \n \n \n\n\n \n Wysokowski, M., Behm, T., Born, R., Bazhenov, V. V., Meißner, H., Richter, G., Szwarc-Rzepka, K., Makarova, A., Vyalikh, D., Schupp, P., Jesionowski, T., & Ehrlich, H.\n\n\n \n\n\n\n Materials Science and Engineering: C, 33(7): 3935–3941. October 2013.\n \n\n\n\n
\n\n\n\n \n \n $\"Preparation$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{wysokowski_preparation_2013,\n\ttitle = {Preparation of chitin–silica composites by in vitro silicification of two-dimensional {Ianthella} basta demosponge chitinous scaffolds under modified {Stöber} conditions},\n\tvolume = {33},\n\tissn = {09284931},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0928493113003184},\n\tdoi = {10.1016/j.msec.2013.05.030},\n\tlanguage = {en},\n\tnumber = {7},\n\turldate = {2022-11-09},\n\tjournal = {Materials Science and Engineering: C},\n\tauthor = {Wysokowski, Marcin and Behm, Thomas and Born, René and Bazhenov, Vasilii V. and Meißner, Heike and Richter, Gert and Szwarc-Rzepka, Karolina and Makarova, Anna and Vyalikh, Denis and Schupp, Peter and Jesionowski, Teofil and Ehrlich, Hermann},\n\tmonth = oct,\n\tyear = {2013},\n\tpages = {3935--3941},\n}\n\n

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\n\n\n\n

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\n \n\n \n \n \n \n \n \n Relative configuration of luminaolide.\n \n \n \n \n\n\n \n Maru, N., Inuzuka, T., Yamamoto, K., Kitamura, M., Schupp, P. J., Yamada, K., & Uemura, D.\n\n\n \n\n\n\n Tetrahedron Letters, 54(33): 4385–4387. August 2013.\n \n\n\n\n
\n\n\n\n \n \n $\"Relative$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{maru_relative_2013,\n\ttitle = {Relative configuration of luminaolide},\n\tvolume = {54},\n\tissn = {00404039},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0040403913009349},\n\tdoi = {10.1016/j.tetlet.2013.05.143},\n\tlanguage = {en},\n\tnumber = {33},\n\turldate = {2022-11-09},\n\tjournal = {Tetrahedron Letters},\n\tauthor = {Maru, Norihito and Inuzuka, Toshiyasu and Yamamoto, Keita and Kitamura, Makoto and Schupp, Peter J. and Yamada, Kaoru and Uemura, Daisuke},\n\tmonth = aug,\n\tyear = {2013},\n\tpages = {4385--4387},\n}\n\n

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\n \n\n \n \n \n \n \n \n Temporal molecular and isotopic analysis of active bacterial communities in two New Zealand sponges.\n \n \n \n \n\n\n \n Simister, R., Taylor, M. W., Rogers, K. M., Schupp, P. J., & Deines, P.\n\n\n \n\n\n\n FEMS Microbiology Ecology, 85(1): 195–205. July 2013.\n \n\n\n\n
\n\n\n\n \n \n $\"Temporal$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{simister_temporal_2013,\n\ttitle = {Temporal molecular and isotopic analysis of active bacterial communities in two {New} {Zealand} sponges},\n\tvolume = {85},\n\tissn = {01686496},\n\turl = {https://academic.oup.com/femsec/article-lookup/doi/10.1111/1574-6941.12109},\n\tdoi = {10.1111/1574-6941.12109},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {FEMS Microbiology Ecology},\n\tauthor = {Simister, Rachel and Taylor, Michael W. and Rogers, Karyne M. and Schupp, Peter J. and Deines, Peter},\n\tmonth = jul,\n\tyear = {2013},\n\tpages = {195--205},\n}\n\n

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\n \n 2012\n \n \n (5)\n \n \n

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\n \n\n \n \n \n \n \n \n Interspecific transmission and recovery of TCBS-induced disease between Acanthaster planci and Linckia guildingi.\n \n \n \n \n\n\n \n Caballes, C., Schupp, P., Pratchett, M., & Rivera-Posada, J.\n\n\n \n\n\n\n Diseases of Aquatic Organisms, 100(3): 263–267. September 2012.\n \n\n\n\n
\n\n\n\n \n \n $\"Interspecific$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{caballes_interspecific_2012,\n\ttitle = {Interspecific transmission and recovery of {TCBS}-induced disease between {Acanthaster} planci and {Linckia} guildingi},\n\tvolume = {100},\n\tissn = {0177-5103, 1616-1580},\n\turl = {http://www.int-res.com/abstracts/dao/v100/n3/p263-267/},\n\tdoi = {10.3354/dao02480},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Diseases of Aquatic Organisms},\n\tauthor = {Caballes, Cf and Schupp, Pj and Pratchett, Ms and Rivera-Posada, Ja},\n\tmonth = sep,\n\tyear = {2012},\n\tpages = {263--267},\n}\n\n

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\n\n\n\n

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\n \n\n \n \n \n \n \n \n Twilight Zone Sponges from Guam Yield Theonellin Isocyanate and Psammaplysins I and J.\n \n \n \n \n\n\n \n Wright, A. D., Schupp, P. J., Schrör, J., Engemann, A., Rohde, S., Kelman, D., de Voogd, N., Carroll, A., & Motti, C. A.\n\n\n \n\n\n\n Journal of Natural Products, 75(3): 502–506. March 2012.\n \n\n\n\n
\n\n\n\n \n \n $\"Twilight$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{wright_twilight_2012,\n\ttitle = {Twilight {Zone} {Sponges} from {Guam} {Yield} {Theonellin} {Isocyanate} and {Psammaplysins} {I} and {J}},\n\tvolume = {75},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/np200939d},\n\tdoi = {10.1021/np200939d},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Wright, Anthony D. and Schupp, Peter J. and Schrör, Jan-Philipp and Engemann, Anna and Rohde, Sven and Kelman, Dovi and de Voogd, Nicole and Carroll, Anthony and Motti, Cherie A.},\n\tmonth = mar,\n\tyear = {2012},\n\tpages = {502--506},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Spatial Variability in Secondary Metabolites of the Indo-Pacific Sponge Stylissa massa.\n \n \n \n \n\n\n \n Rohde, S., Gochfeld, D. J., Ankisetty, S., Avula, B., Schupp, P. J., & Slattery, M.\n\n\n \n\n\n\n Journal of Chemical Ecology, 38(5): 463–475. May 2012.\n \n\n\n\n
\n\n\n\n \n \n $\"Spatial$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{rohde_spatial_2012,\n\ttitle = {Spatial {Variability} in {Secondary} {Metabolites} of the {Indo}-{Pacific} {Sponge} {Stylissa} massa},\n\tvolume = {38},\n\tissn = {0098-0331, 1573-1561},\n\turl = {http://link.springer.com/10.1007/s10886-012-0124-8},\n\tdoi = {10.1007/s10886-012-0124-8},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Chemical Ecology},\n\tauthor = {Rohde, Sven and Gochfeld, Deborah J. and Ankisetty, Sridevi and Avula, Bharathi and Schupp, Peter J. and Slattery, Marc},\n\tmonth = may,\n\tyear = {2012},\n\tpages = {463--475},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n Effects of ocean acidification on metamorphosis: brooding and spawning larvae.\n \n \n \n\n\n \n Chua, C., Schupp, P., Leggat, W., & Baird, A.\n\n\n \n\n\n\n In 2012. \n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@inproceedings{chua_effects_2012,\n\ttitle = {Effects of ocean acidification on metamorphosis: brooding and spawning larvae},\n\tauthor = {Chua, Chia-Miin and Schupp, Peter and Leggat, William and Baird, Andrew},\n\tyear = {2012},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Assessing the complex sponge microbiota: core, variable and species-specific bacterial communities in marine sponges.\n \n \n \n \n\n\n \n Schmitt, S., Tsai, P., Bell, J., Fromont, J., Ilan, M., Lindquist, N., Perez, T., Rodrigo, A., Schupp, P. J, Vacelet, J., Webster, N., Hentschel, U., & Taylor, M. W\n\n\n \n\n\n\n The ISME Journal, 6(3): 564–576. March 2012.\n \n\n\n\n
\n\n\n\n \n \n $\"Assessing$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schmitt_assessing_2012,\n\ttitle = {Assessing the complex sponge microbiota: core, variable and species-specific bacterial communities in marine sponges},\n\tvolume = {6},\n\tissn = {1751-7362, 1751-7370},\n\tshorttitle = {Assessing the complex sponge microbiota},\n\turl = {http://www.nature.com/articles/ismej2011116},\n\tdoi = {10.1038/ismej.2011.116},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {The ISME Journal},\n\tauthor = {Schmitt, Susanne and Tsai, Peter and Bell, James and Fromont, Jane and Ilan, Micha and Lindquist, Niels and Perez, Thierry and Rodrigo, Allen and Schupp, Peter J and Vacelet, Jean and Webster, Nicole and Hentschel, Ute and Taylor, Michael W},\n\tmonth = mar,\n\tyear = {2012},\n\tpages = {564--576},\n}\n\n

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\n\n\n\n\n\n

\n

\n \n 2011\n \n \n (2)\n \n \n

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\n \n \n

\n \n\n \n \n \n \n \n \n Allocation of chemical and structural defenses in the sponge Melophlus sarasinorum.\n \n \n \n \n\n\n \n Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n Journal of Experimental Marine Biology and Ecology, 399(1): 76–83. March 2011.\n \n\n\n\n
\n\n\n\n \n \n $\"Allocation$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{rohde_allocation_2011,\n\ttitle = {Allocation of chemical and structural defenses in the sponge {Melophlus} sarasinorum},\n\tvolume = {399},\n\tissn = {00220981},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0022098111000256},\n\tdoi = {10.1016/j.jembe.2011.01.012},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Experimental Marine Biology and Ecology},\n\tauthor = {Rohde, Sven and Schupp, Peter J.},\n\tmonth = mar,\n\tyear = {2011},\n\tpages = {76--83},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Growth and regeneration of the elephant ear sponge Ianthella basta (Porifera).\n \n \n \n \n\n\n \n Rohde, S., & Schupp, P. J.\n\n\n \n\n\n\n In Maldonado, M., Turon, X., Becerro, M., & Jesús Uriz, M., editor(s), Ancient Animals, New Challenges, pages 219–226. Springer Netherlands, Dordrecht, 2011.\n \n\n\n\n
\n\n\n\n \n \n $\"Growth$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@incollection{maldonado_growth_2011,\n\taddress = {Dordrecht},\n\ttitle = {Growth and regeneration of the elephant ear sponge {Ianthella} basta ({Porifera})},\n\tisbn = {978-94-007-4687-9 978-94-007-4688-6},\n\turl = {http://link.springer.com/10.1007/978-94-007-4688-6_18},\n\tlanguage = {en},\n\turldate = {2022-11-09},\n\tbooktitle = {Ancient {Animals}, {New} {Challenges}},\n\tpublisher = {Springer Netherlands},\n\tauthor = {Rohde, Sven and Schupp, Peter J.},\n\teditor = {Maldonado, Manuel and Turon, Xavier and Becerro, Mikel and Jesús Uriz, Maria},\n\tyear = {2011},\n\tdoi = {10.1007/978-94-007-4688-6_18},\n\tpages = {219--226},\n}\n\n

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\n\n\n\n

\n\n\n\n\n\n

\n

\n \n 2010\n \n \n (5)\n \n \n

\n

\n \n \n

\n \n\n \n \n \n \n \n \n Cytotoxic Halogenated Macrolides and Modified Peptides from the Apratoxin-Producing Marine Cyanobacterium Lyngbya bouillonii from Guam.\n \n \n \n \n\n\n \n Matthew, S., Salvador, L. A., Schupp, P. J., Paul, V. J., & Luesch, H.\n\n\n \n\n\n\n Journal of Natural Products, 73(9): 1544–1552. September 2010.\n \n\n\n\n
\n\n\n\n \n \n $\"Cytotoxic$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{matthew_cytotoxic_2010,\n\ttitle = {Cytotoxic {Halogenated} {Macrolides} and {Modified} {Peptides} from the {Apratoxin}-{Producing} {Marine} {Cyanobacterium} \\textit{{Lyngbya} bouillonii} from {Guam}},\n\tvolume = {73},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/np1004032},\n\tdoi = {10.1021/np1004032},\n\tlanguage = {en},\n\tnumber = {9},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Matthew, Susan and Salvador, Lilibeth A. and Schupp, Peter J. and Paul, Valerie J. and Luesch, Hendrik},\n\tmonth = sep,\n\tyear = {2010},\n\tpages = {1544--1552},\n}\n\n

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\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Depsipeptides from a Guamanian marine cyanobacterium, Lyngbya bouillonii, with selective inhibition of serine proteases.\n \n \n \n \n\n\n \n Rubio, B. K., Parrish, S. M., Yoshida, W., Schupp, P. J., Schils, T., & Williams, P. G.\n\n\n \n\n\n\n Tetrahedron Letters, 51(51): 6718–6721. December 2010.\n \n\n\n\n
\n\n\n\n \n \n $\"Depsipeptides$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{rubio_depsipeptides_2010,\n\ttitle = {Depsipeptides from a {Guamanian} marine cyanobacterium, {Lyngbya} bouillonii, with selective inhibition of serine proteases},\n\tvolume = {51},\n\tissn = {00404039},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0040403910018393},\n\tdoi = {10.1016/j.tetlet.2010.10.062},\n\tlanguage = {en},\n\tnumber = {51},\n\turldate = {2022-11-09},\n\tjournal = {Tetrahedron Letters},\n\tauthor = {Rubio, Brent K. and Parrish, Stephen M. and Yoshida, Wesley and Schupp, Peter J. and Schils, Tom and Williams, Philip G.},\n\tmonth = dec,\n\tyear = {2010},\n\tpages = {6718--6721},\n}\n\n

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\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Bacterial Acquisition in Juveniles of Several Broadcast Spawning Coral Species.\n \n \n \n \n\n\n \n Sharp, K. H., Ritchie, K. B., Schupp, P. J., Ritson-Williams, R., & Paul, V. J.\n\n\n \n\n\n\n PLoS ONE, 5(5): e10898. May 2010.\n \n\n\n\n
\n\n\n\n \n \n $\"Bacterial$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{sharp_bacterial_2010,\n\ttitle = {Bacterial {Acquisition} in {Juveniles} of {Several} {Broadcast} {Spawning} {Coral} {Species}},\n\tvolume = {5},\n\tissn = {1932-6203},\n\turl = {https://dx.plos.org/10.1371/journal.pone.0010898},\n\tdoi = {10.1371/journal.pone.0010898},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-09},\n\tjournal = {PLoS ONE},\n\tauthor = {Sharp, Koty H. and Ritchie, Kim B. and Schupp, Peter J. and Ritson-Williams, Raphael and Paul, Valerie J.},\n\teditor = {Vollmer, Steve},\n\tmonth = may,\n\tyear = {2010},\n\tpages = {e10898},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Three-dimensional chitin-based scaffolds from Verongida sponges (Demospongiae: Porifera). Part II: Biomimetic potential and applications.\n \n \n \n \n\n\n \n Ehrlich, H., Steck, E., Ilan, M., Maldonado, M., Muricy, G., Bavestrello, G., Kljajic, Z., Carballo, J., Schiaparelli, S., Ereskovsky, A., Schupp, P., Born, R., Worch, H., Bazhenov, V., Kurek, D., Varlamov, V., Vyalikh, D., Kummer, K., Sivkov, V., Molodtsov, S., Meissner, H., Richter, G., Hunoldt, S., Kammer, M., Paasch, S., Krasokhin, V., Patzke, G., Brunner, E., & Richter, W.\n\n\n \n\n\n\n International Journal of Biological Macromolecules, 47(2): 141–145. August 2010.\n \n\n\n\n
\n\n\n\n \n \n $\"Three-dimensional$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{ehrlich_three-dimensional_2010-1,\n\ttitle = {Three-dimensional chitin-based scaffolds from {Verongida} sponges ({Demospongiae}: {Porifera}). {Part} {II}: {Biomimetic} potential and applications},\n\tvolume = {47},\n\tissn = {01418130},\n\tshorttitle = {Three-dimensional chitin-based scaffolds from {Verongida} sponges ({Demospongiae}},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0141813010001637},\n\tdoi = {10.1016/j.ijbiomac.2010.05.009},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {International Journal of Biological Macromolecules},\n\tauthor = {Ehrlich, H. and Steck, E. and Ilan, M. and Maldonado, M. and Muricy, G. and Bavestrello, G. and Kljajic, Z. and Carballo, J.L. and Schiaparelli, S. and Ereskovsky, A. and Schupp, P. and Born, R. and Worch, H. and Bazhenov, V.V. and Kurek, D. and Varlamov, V. and Vyalikh, D. and Kummer, K. and Sivkov, V.V. and Molodtsov, S.L. and Meissner, H. and Richter, G. and Hunoldt, S. and Kammer, M. and Paasch, S. and Krasokhin, V. and Patzke, G. and Brunner, E. and Richter, W.},\n\tmonth = aug,\n\tyear = {2010},\n\tpages = {141--145},\n}\n\n

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\n \n\n \n \n \n \n \n \n Three-dimensional chitin-based scaffolds from Verongida sponges (Demospongiae: Porifera). Part I. Isolation and identification of chitin.\n \n \n \n \n\n\n \n Ehrlich, H., Ilan, M., Maldonado, M., Muricy, G., Bavestrello, G., Kljajic, Z., Carballo, J., Schiaparelli, S., Ereskovsky, A., Schupp, P., Born, R., Worch, H., Bazhenov, V., Kurek, D., Varlamov, V., Vyalikh, D., Kummer, K., Sivkov, V., Molodtsov, S., Meissner, H., Richter, G., Steck, E., Richter, W., Hunoldt, S., Kammer, M., Paasch, S., Krasokhin, V., Patzke, G., & Brunner, E.\n\n\n \n\n\n\n International Journal of Biological Macromolecules, 47(2): 132–140. August 2010.\n \n\n\n\n
\n\n\n\n \n \n $\"Three-dimensional$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{ehrlich_three-dimensional_2010,\n\ttitle = {Three-dimensional chitin-based scaffolds from {Verongida} sponges ({Demospongiae}: {Porifera}). {Part} {I}. {Isolation} and identification of chitin},\n\tvolume = {47},\n\tissn = {01418130},\n\tshorttitle = {Three-dimensional chitin-based scaffolds from {Verongida} sponges ({Demospongiae}},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0141813010001613},\n\tdoi = {10.1016/j.ijbiomac.2010.05.007},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {International Journal of Biological Macromolecules},\n\tauthor = {Ehrlich, H. and Ilan, M. and Maldonado, M. and Muricy, G. and Bavestrello, G. and Kljajic, Z. and Carballo, J.L. and Schiaparelli, S. and Ereskovsky, A. and Schupp, P. and Born, R. and Worch, H. and Bazhenov, V.V. and Kurek, D. and Varlamov, V. and Vyalikh, D. and Kummer, K. and Sivkov, V.V. and Molodtsov, S.L. and Meissner, H. and Richter, G. and Steck, E. and Richter, W. and Hunoldt, S. and Kammer, M. and Paasch, S. and Krasokhin, V. and Patzke, G. and Brunner, E.},\n\tmonth = aug,\n\tyear = {2010},\n\tpages = {132--140},\n}\n\n

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\n \n 2009\n \n \n (5)\n \n \n

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\n \n\n \n \n \n \n \n \n Structure of Pseudocerosine, an Indolic Azafulvene Alkaloid from the Flatworm Pseudoceros indicus.\n \n \n \n \n\n\n \n Schupp, P. J., Kohlert-Schupp, C., Yoshida, W. Y., & Hemscheidt, T. K.\n\n\n \n\n\n\n Organic Letters, 11(5): 1111–1114. March 2009.\n \n\n\n\n
\n\n\n\n \n \n $\"Structure$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schupp_structure_2009,\n\ttitle = {Structure of {Pseudocerosine}, an {Indolic} {Azafulvene} {Alkaloid} from the {Flatworm} \\textit{{Pseudoceros} indicus}},\n\tvolume = {11},\n\tissn = {1523-7060, 1523-7052},\n\turl = {https://pubs.acs.org/doi/10.1021/ol8027785},\n\tdoi = {10.1021/ol8027785},\n\tlanguage = {en},\n\tnumber = {5},\n\turldate = {2022-11-09},\n\tjournal = {Organic Letters},\n\tauthor = {Schupp, Peter J. and Kohlert-Schupp, Claudia and Yoshida, Wesley Y. and Hemscheidt, Thomas K.},\n\tmonth = mar,\n\tyear = {2009},\n\tpages = {1111--1114},\n}\n\n

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\n \n\n \n \n \n \n \n \n Aromatic Cyclic Peroxides and Related Keto-Compounds from the Plakortis sp. Component of a Sponge Consortium.\n \n \n \n \n\n\n \n Manzo, E., Ciavatta, M. L., Melck, D., Schupp, P., de Voogd, N., & Gavagnin, M.\n\n\n \n\n\n\n Journal of Natural Products, 72(8): 1547–1551. August 2009.\n \n\n\n\n
\n\n\n\n \n \n $\"Aromatic$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{manzo_aromatic_2009,\n\ttitle = {Aromatic {Cyclic} {Peroxides} and {Related} {Keto}-{Compounds} from the \\textit{{Plakortis}} sp. {Component} of a {Sponge} {Consortium}},\n\tvolume = {72},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/np900310j},\n\tdoi = {10.1021/np900310j},\n\tlanguage = {en},\n\tnumber = {8},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Manzo, Emiliano and Ciavatta, M. Letizia and Melck, Dominique and Schupp, Peter and de Voogd, Nicole and Gavagnin, Margherita},\n\tmonth = aug,\n\tyear = {2009},\n\tpages = {1547--1551},\n}\n\n

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\n \n\n \n \n \n \n \n \n Cancer Chemopreventive and Anticancer Evaluation of Extracts and Fractions from Marine Macro- and Microorganisms Collected from Twilight Zone Waters around Guam $^{\\textrm{[1]}}$.\n \n \n \n \n\n\n \n Schupp, P. J., Kohlert-Schupp, C., Whitefield, S., Engemann, A., Rohde, S., Hemscheidt, T., Pezzuto, J. M., Kondratyuk, T. P., Park, E., Marler, L., Rostama, B., & Wright, A. D.\n\n\n \n\n\n\n Natural Product Communications, 4(12): 1934578X0900401. December 2009.\n \n\n\n\n
\n\n\n\n \n \n $\"Cancer$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schupp_cancer_2009,\n\ttitle = {Cancer {Chemopreventive} and {Anticancer} {Evaluation} of {Extracts} and {Fractions} from {Marine} {Macro}- and {Microorganisms} {Collected} from {Twilight} {Zone} {Waters} around {Guam} $^{\\textrm{[1]}}$},\n\tvolume = {4},\n\tissn = {1934-578X, 1555-9475},\n\turl = {http://journals.sagepub.com/doi/10.1177/1934578X0900401222},\n\tdoi = {10.1177/1934578X0900401222},\n\tabstract = {The cancer chemopreventive and cytotoxic properties of 50 extracts derived from Twilight Zone (50–150 m) sponges, gorgonians and associated bacteria, together with 15 extracts from shallow water hard corals, as well as 16 fractions derived from the methanol solubles of the Twilight Zone sponge Suberea sp, were assessed in a series of bioassays. These assays included: Induction of quinone reductase (QR), inhibition of TNF-α activated nuclear factor kappa B (NFκB), inhibition of aromatase, interaction with retinoid X receptor (RXR), inhibition of nitric oxide (NO) synthase, inhibition 2,2-diphenyl-1-picrylhydrazyl radical scavenging (DPPH), and inhibition of HL-60 and MCF-7 cell proliferation. The results of these assays showed that at least 10 extracts and five fractions inhibited NFκB by greater than 60\\%, two extracts and two fractions inhibited DPPH by more than 50\\%, nine extracts and two fractions affected the survival of HL-60 cells, no extracts or fractions affected RXR, three extracts and six fractions affected quinone reductase (QR), three extracts and 12 fractions significantly inhibited aromatase, four extracts and five fractions inhibited nitric oxide synthase, and one extract and no fractions inhibited the growth of MCF-7 cells by more than 95\\%. These data revealed the tested samples to have many and varied activities, making them, as shown with the extract of the Suberea species, useful starting points for further fractionation and purification. Moreover, the large number of samples demonstrating activity in only one or sometimes two assays accentuates the potential of the Twilight Zone, as a largely unexplored habitat, for the discovery of selectively bioactive compounds. The overall high hit rate in many of the employed assays is considered to be a significant finding in terms of “normal” hit rates associated with similar samples from shallower depths.},\n\tlanguage = {en},\n\tnumber = {12},\n\turldate = {2022-11-09},\n\tjournal = {Natural Product Communications},\n\tauthor = {Schupp, Peter J. and Kohlert-Schupp, Claudia and Whitefield, Susanna and Engemann, Anna and Rohde, Sven and Hemscheidt, Thomas and Pezzuto, John M. and Kondratyuk, Tamara P. and Park, Eun-Jung and Marler, Laura and Rostama, Bahman and Wright, Anthony D.},\n\tmonth = dec,\n\tyear = {2009},\n\tpages = {1934578X0900401},\n}\n\n

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\n \n\n \n \n \n \n \n \n Chitin-based scaffolds are an integral part of the skeleton of the marine demosponge Ianthella basta.\n \n \n \n \n\n\n \n Brunner, E., Ehrlich, H., Schupp, P., Hedrich, R., Hunoldt, S., Kammer, M., Machill, S., Paasch, S., Bazhenov, V., Kurek, D., Arnold, T., Brockmann, S., Ruhnow, M., & Born, R.\n\n\n \n\n\n\n Journal of Structural Biology, 168(3): 539–547. December 2009.\n \n\n\n\n
\n\n\n\n \n \n $\"Chitin-based$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{brunner_chitin-based_2009,\n\ttitle = {Chitin-based scaffolds are an integral part of the skeleton of the marine demosponge {Ianthella} basta},\n\tvolume = {168},\n\tissn = {10478477},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S1047847709001695},\n\tdoi = {10.1016/j.jsb.2009.06.018},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Structural Biology},\n\tauthor = {Brunner, E. and Ehrlich, H. and Schupp, P. and Hedrich, R. and Hunoldt, S. and Kammer, M. and Machill, S. and Paasch, S. and Bazhenov, V.V. and Kurek, D.V. and Arnold, T. and Brockmann, S. and Ruhnow, M. and Born, R.},\n\tmonth = dec,\n\tyear = {2009},\n\tpages = {539--547},\n}\n\n

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\n \n\n \n \n \n \n \n \n Luminaolide, a novel metamorphosis-enhancing macrodiolide for scleractinian coral larvae from crustose coralline algae.\n \n \n \n \n\n\n \n Kitamura, M., Schupp, P. J., Nakano, Y., & Uemura, D.\n\n\n \n\n\n\n Tetrahedron Letters, 50(47): 6606–6609. November 2009.\n \n\n\n\n
\n\n\n\n \n \n $\"Luminaolide,$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{kitamura_luminaolide_2009,\n\ttitle = {Luminaolide, a novel metamorphosis-enhancing macrodiolide for scleractinian coral larvae from crustose coralline algae},\n\tvolume = {50},\n\tissn = {00404039},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0040403909017870},\n\tdoi = {10.1016/j.tetlet.2009.09.065},\n\tlanguage = {en},\n\tnumber = {47},\n\turldate = {2022-11-09},\n\tjournal = {Tetrahedron Letters},\n\tauthor = {Kitamura, Makoto and Schupp, Peter J. and Nakano, Yoshikatsu and Uemura, Daisuke},\n\tmonth = nov,\n\tyear = {2009},\n\tpages = {6606--6609},\n}\n\n

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\n \n 2008\n \n \n (6)\n \n \n

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\n \n\n \n \n \n \n \n \n Ten-Membered Lactones from the Marine-Derived Fungus Curvularia sp.\n \n \n \n \n\n\n \n Greve, H., Schupp, P. J., Eguereva, E., Kehraus, S., & König, G. M.\n\n\n \n\n\n\n Journal of Natural Products, 71(9): 1651–1653. September 2008.\n \n\n\n\n
\n\n\n\n \n \n $\"Ten-Membered$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{greve_ten-membered_2008,\n\ttitle = {Ten-{Membered} {Lactones} from the {Marine}-{Derived} {Fungus} \\textit{{Curvularia}} sp.},\n\tvolume = {71},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/np8003326},\n\tdoi = {10.1021/np8003326},\n\tlanguage = {en},\n\tnumber = {9},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Greve, Hendrik and Schupp, Peter J. and Eguereva, Ekaterina and Kehraus, Stefan and König, Gabriele M.},\n\tmonth = sep,\n\tyear = {2008},\n\tpages = {1651--1653},\n}\n\n

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\n \n\n \n \n \n \n \n \n Marine Biofilm Bacteria Evade Eukaryotic Predation by Targeted Chemical Defense.\n \n \n \n \n\n\n \n Matz, C., Webb, J. S., Schupp, P. J., Phang, S. Y., Penesyan, A., Egan, S., Steinberg, P., & Kjelleberg, S.\n\n\n \n\n\n\n PLoS ONE, 3(7): e2744. July 2008.\n \n\n\n\n
\n\n\n\n \n \n $\"Marine$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{matz_marine_2008,\n\ttitle = {Marine {Biofilm} {Bacteria} {Evade} {Eukaryotic} {Predation} by {Targeted} {Chemical} {Defense}},\n\tvolume = {3},\n\tissn = {1932-6203},\n\turl = {https://dx.plos.org/10.1371/journal.pone.0002744},\n\tdoi = {10.1371/journal.pone.0002744},\n\tlanguage = {en},\n\tnumber = {7},\n\turldate = {2022-11-09},\n\tjournal = {PLoS ONE},\n\tauthor = {Matz, Carsten and Webb, Jeremy S. and Schupp, Peter J. and Phang, Shui Yen and Penesyan, Anahit and Egan, Suhelen and Steinberg, Peter and Kjelleberg, Staffan},\n\teditor = {McClain, Craig R.},\n\tmonth = jul,\n\tyear = {2008},\n\tpages = {e2744},\n}\n\n

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\n \n\n \n \n \n \n \n \n Apratoxin E, a Cytotoxic Peptolide from a Guamanian Collection of the Marine Cyanobacterium Lyngbya bouillonii.\n \n \n \n \n\n\n \n Matthew, S., Schupp, P. J., & Luesch, H.\n\n\n \n\n\n\n Journal of Natural Products, 71(6): 1113–1116. June 2008.\n \n\n\n\n
\n\n\n\n \n \n $\"Apratoxin$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{matthew_apratoxin_2008,\n\ttitle = {Apratoxin {E}, a {Cytotoxic} {Peptolide} from a {Guamanian} {Collection} of the {Marine} {Cyanobacterium} \\textit{{Lyngbya} bouillonii}},\n\tvolume = {71},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/np700717s},\n\tdoi = {10.1021/np700717s},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Matthew, Susan and Schupp, Peter J. and Luesch, Hendrik},\n\tmonth = jun,\n\tyear = {2008},\n\tpages = {1113--1116},\n}\n\n

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\n \n\n \n \n \n \n \n \n Rapid tissue reduction and recovery in the sponge Aplysinella sp.\n \n \n \n \n\n\n \n Thoms, C., Hentschel, U., Schmitt, S., & Schupp, P. J.\n\n\n \n\n\n\n Marine Biology, 156(2): 141–153. December 2008.\n \n\n\n\n
\n\n\n\n \n \n $\"Rapid$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{thoms_rapid_2008,\n\ttitle = {Rapid tissue reduction and recovery in the sponge {Aplysinella} sp.},\n\tvolume = {156},\n\tissn = {0025-3162, 1432-1793},\n\turl = {http://link.springer.com/10.1007/s00227-008-1071-3},\n\tdoi = {10.1007/s00227-008-1071-3},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biology},\n\tauthor = {Thoms, Carsten and Hentschel, Ute and Schmitt, Susanne and Schupp, Peter J.},\n\tmonth = dec,\n\tyear = {2008},\n\tpages = {141--153},\n}\n\n

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\n \n\n \n \n \n \n \n \n Apralactone A and a New Stereochemical Class of Curvularins from the Marine Fungus Curvularia sp.\n \n \n \n \n\n\n \n Greve, H., Schupp, P. J., Eguereva, E., Kehraus, S., Kelter, G., Maier, A., Fiebig, H., & König, G. M.\n\n\n \n\n\n\n European Journal of Organic Chemistry, 2008(30): 5085–5092. October 2008.\n \n\n\n\n
\n\n\n\n \n \n $\"Apralactone$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{greve_apralactone_2008,\n\ttitle = {Apralactone {A} and a {New} {Stereochemical} {Class} of {Curvularins} from the {Marine} {Fungus} \\textit{{Curvularia}} sp.},\n\tvolume = {2008},\n\tissn = {1434193X, 10990690},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1002/ejoc.200800522},\n\tdoi = {10.1002/ejoc.200800522},\n\tlanguage = {en},\n\tnumber = {30},\n\turldate = {2022-11-09},\n\tjournal = {European Journal of Organic Chemistry},\n\tauthor = {Greve, Hendrik and Schupp, Peter J. and Eguereva, Ekaterina and Kehraus, Stefan and Kelter, Gerhard and Maier, Armin and Fiebig, Heinz-Herbert and König, Gabriele M.},\n\tmonth = oct,\n\tyear = {2008},\n\tpages = {5085--5092},\n}\n\n

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\n \n\n \n \n \n \n \n \n Activated Chemical Defense in Marine Sponges—a Case Study on Aplysinella rhax.\n \n \n \n \n\n\n \n Thoms, C., & Schupp, P. J.\n\n\n \n\n\n\n Journal of Chemical Ecology, 34(9): 1242–1252. September 2008.\n \n\n\n\n
\n\n\n\n \n \n $\"Activated$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{thoms_activated_2008,\n\ttitle = {Activated {Chemical} {Defense} in {Marine} {Sponges}—a {Case} {Study} on {Aplysinella} rhax},\n\tvolume = {34},\n\tissn = {0098-0331, 1573-1561},\n\turl = {http://link.springer.com/10.1007/s10886-008-9518-z},\n\tdoi = {10.1007/s10886-008-9518-z},\n\tlanguage = {en},\n\tnumber = {9},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Chemical Ecology},\n\tauthor = {Thoms, Carsten and Schupp, Peter J.},\n\tmonth = sep,\n\tyear = {2008},\n\tpages = {1242--1252},\n}\n\n

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\n\n\n\n\n\n

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\n \n 2007\n \n \n (3)\n \n \n

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\n \n\n \n \n \n \n \n \n Chemistry of Glossodoris Nudibranchs: Specific Occurrence of 12-Keto Scalaranes.\n \n \n \n \n\n\n \n Manzo, E., Gavagnin, M., Somerville, M. J., Mao, S., Ciavatta, M. L., Mollo, E., Schupp, P. J., Garson, M. J., Guo, Y., & Cimino, G.\n\n\n \n\n\n\n Journal of Chemical Ecology, 33(12): 2325–2336. December 2007.\n \n\n\n\n
\n\n\n\n \n \n $\"Chemistry$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{manzo_chemistry_2007,\n\ttitle = {Chemistry of {Glossodoris} {Nudibranchs}: {Specific} {Occurrence} of 12-{Keto} {Scalaranes}},\n\tvolume = {33},\n\tissn = {0098-0331, 1573-1561},\n\tshorttitle = {Chemistry of {Glossodoris} {Nudibranchs}},\n\turl = {http://link.springer.com/10.1007/s10886-007-9387-x},\n\tdoi = {10.1007/s10886-007-9387-x},\n\tlanguage = {en},\n\tnumber = {12},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Chemical Ecology},\n\tauthor = {Manzo, Emiliano and Gavagnin, Margherita and Somerville, Michael J. and Mao, Shui-Chun and Ciavatta, M. Letizia and Mollo, Ernesto and Schupp, Peter J. and Garson, Mary J. and Guo, Yue-Wei and Cimino, Guido},\n\tmonth = dec,\n\tyear = {2007},\n\tpages = {2325--2336},\n}\n\n

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\n \n\n \n \n \n \n \n \n Antifouling Activity of Bromotyrosine-Derived Sponge Metabolites and Synthetic Analogues.\n \n \n \n \n\n\n \n Ortlepp, S., Sjögren, M., Dahlström, M., Weber, H., Ebel, R., Edrada, R., Thoms, C., Schupp, P., Bohlin, L., & Proksch, P.\n\n\n \n\n\n\n Marine Biotechnology, 9(6): 776–785. November 2007.\n \n\n\n\n
\n\n\n\n \n \n $\"Antifouling$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{ortlepp_antifouling_2007,\n\ttitle = {Antifouling {Activity} of {Bromotyrosine}-{Derived} {Sponge} {Metabolites} and {Synthetic} {Analogues}},\n\tvolume = {9},\n\tissn = {1436-2228, 1436-2236},\n\turl = {http://link.springer.com/10.1007/s10126-007-9029-x},\n\tdoi = {10.1007/s10126-007-9029-x},\n\tlanguage = {en},\n\tnumber = {6},\n\turldate = {2022-11-09},\n\tjournal = {Marine Biotechnology},\n\tauthor = {Ortlepp, Sofia and Sjögren, Martin and Dahlström, Mia and Weber, Horst and Ebel, Rainer and Edrada, RuAngelie and Thoms, Carsten and Schupp, Peter and Bohlin, Lars and Proksch, Peter},\n\tmonth = nov,\n\tyear = {2007},\n\tpages = {776--785},\n}\n\n

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\n \n\n \n \n \n \n \n Chemical defense strategies in sponges: a review.\n \n \n \n\n\n \n Thoms, C., Schupp, P. J, Custódio, M., Lôbo-Hajdu, G, Hajdu, E, & Muricy, G\n\n\n \n\n\n\n In Porifera research: biodiversity, Innovation and sustainability, volume 28, pages 627–637. 2007.\n Publisher: Série Livros\n\n\n\n
\n\n\n\n \n\n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@incollection{thoms_chemical_2007,\n\ttitle = {Chemical defense strategies in sponges: a review},\n\tvolume = {28},\n\tisbn = {85-7427-023-7 978-85-7427-023-4},\n\tbooktitle = {Porifera research: biodiversity, {Innovation} and sustainability},\n\tauthor = {Thoms, Carsten and Schupp, Peter J and Custódio, MR and Lôbo-Hajdu, G and Hajdu, E and Muricy, G},\n\tyear = {2007},\n\tnote = {Publisher: Série Livros},\n\tpages = {627--637},\n}\n\n

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\n\n\n\n\n\n

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\n \n 2006\n \n \n (2)\n \n \n

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\n \n \n

\n \n\n \n \n \n \n \n \n The distribution of dimethylsulfoniopropionate in tropical Pacific coral reef invertebrates.\n \n \n \n \n\n\n \n Van Alstyne, K. L., Schupp, P., & Slattery, M.\n\n\n \n\n\n\n Coral Reefs, 25(3): 321–327. August 2006.\n \n\n\n\n
\n\n\n\n \n \n $\"The$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{van_alstyne_distribution_2006,\n\ttitle = {The distribution of dimethylsulfoniopropionate in tropical {Pacific} coral reef invertebrates},\n\tvolume = {25},\n\tissn = {0722-4028, 1432-0975},\n\turl = {https://link.springer.com/10.1007/s00338-006-0114-9},\n\tdoi = {10.1007/s00338-006-0114-9},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Coral Reefs},\n\tauthor = {Van Alstyne, Kathryn L. and Schupp, Peter and Slattery, Marc},\n\tmonth = aug,\n\tyear = {2006},\n\tpages = {321--327},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Chemical and physical defenses against predators in Cystodytes (Ascidiacea).\n \n \n \n \n\n\n \n López-Legentil, S., Turon, X., & Schupp, P.\n\n\n \n\n\n\n Journal of Experimental Marine Biology and Ecology, 332(1): 27–36. May 2006.\n \n\n\n\n
\n\n\n\n \n \n $\"Chemical$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{lopez-legentil_chemical_2006,\n\ttitle = {Chemical and physical defenses against predators in {Cystodytes} ({Ascidiacea})},\n\tvolume = {332},\n\tissn = {00220981},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S0022098105004971},\n\tdoi = {10.1016/j.jembe.2005.11.002},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Experimental Marine Biology and Ecology},\n\tauthor = {López-Legentil, Susanna and Turon, Xavier and Schupp, Peter},\n\tmonth = may,\n\tyear = {2006},\n\tpages = {27--36},\n}\n\n

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\n \n 2005\n \n \n (2)\n \n \n

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\n \n\n \n \n \n \n \n \n Use of solid-phase extraction to enable enhanced detection of acyl homoserine lactones (AHLs) in environmental samples.\n \n \n \n \n\n\n \n Schupp, P. J., Charlton, T. S., Taylor, M. W., Kjelleberg, S., & Steinberg, P. D.\n\n\n \n\n\n\n Analytical and Bioanalytical Chemistry, 383(1): 132–137. September 2005.\n \n\n\n\n
\n\n\n\n \n \n $\"Use$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schupp_use_2005,\n\ttitle = {Use of solid-phase extraction to enable enhanced detection of acyl homoserine lactones ({AHLs}) in environmental samples},\n\tvolume = {383},\n\tissn = {1618-2642, 1618-2650},\n\turl = {http://link.springer.com/10.1007/s00216-005-3387-x},\n\tdoi = {10.1007/s00216-005-3387-x},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2022-11-09},\n\tjournal = {Analytical and Bioanalytical Chemistry},\n\tauthor = {Schupp, Peter J. and Charlton, Timothy S. and Taylor, Michael W. and Kjelleberg, Staffan and Steinberg, Peter D.},\n\tmonth = sep,\n\tyear = {2005},\n\tpages = {132--137},\n}\n\n

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\n\n\n\n

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\n \n\n \n \n \n \n \n \n Biogeography of bacteria associated with the marine sponge Cymbastela concentrica.\n \n \n \n \n\n\n \n Taylor, M. W., Schupp, P. J., de Nys, R., Kjelleberg, S., & Steinberg, P. D.\n\n\n \n\n\n\n Environmental Microbiology, 7(3): 419–433. March 2005.\n \n\n\n\n
\n\n\n\n \n \n $\"Biogeography$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{taylor_biogeography_2005,\n\ttitle = {Biogeography of bacteria associated with the marine sponge {Cymbastela} concentrica},\n\tvolume = {7},\n\tissn = {1462-2912, 1462-2920},\n\turl = {https://onlinelibrary.wiley.com/doi/10.1111/j.1462-2920.2004.00711.x},\n\tdoi = {10.1111/j.1462-2920.2004.00711.x},\n\tlanguage = {en},\n\tnumber = {3},\n\turldate = {2022-11-09},\n\tjournal = {Environmental Microbiology},\n\tauthor = {Taylor, Michael W. and Schupp, Peter J. and de Nys, Rocky and Kjelleberg, Staffan and Steinberg, Peter D.},\n\tmonth = mar,\n\tyear = {2005},\n\tpages = {419--433},\n}\n\n

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\n

\n \n 2004\n \n \n (2)\n \n \n

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\n \n \n

\n \n\n \n \n \n \n \n \n Evidence for Acyl Homoserine Lactone Signal Production in Bacteria Associated with Marine Sponges.\n \n \n \n \n\n\n \n Taylor, M. W., Schupp, P. J., Baillie, H. J., Charlton, T. S., de Nys, R., Kjelleberg, S., & Steinberg, P. D.\n\n\n \n\n\n\n Applied and Environmental Microbiology, 70(7): 4387–4389. July 2004.\n \n\n\n\n
\n\n\n\n \n \n $\"Evidence$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{taylor_evidence_2004,\n\ttitle = {Evidence for {Acyl} {Homoserine} {Lactone} {Signal} {Production} in {Bacteria} {Associated} with {Marine} {Sponges}},\n\tvolume = {70},\n\tissn = {0099-2240, 1098-5336},\n\turl = {https://journals.asm.org/doi/10.1128/AEM.70.7.4387-4389.2004},\n\tdoi = {10.1128/AEM.70.7.4387-4389.2004},\n\tabstract = {ABSTRACT\n            We report for the first time the production of acyl homoserine lactones (AHLs) by bacteria associated with marine sponges. Given the involvement of AHLs in bacterial colonization of many higher organisms, we speculate that such quorum sensing signals could play a part in interactions between sponges and the dense bacterial communities living within them.},\n\tlanguage = {en},\n\tnumber = {7},\n\turldate = {2022-11-09},\n\tjournal = {Applied and Environmental Microbiology},\n\tauthor = {Taylor, Michael W. and Schupp, Peter J. and Baillie, Harriet J. and Charlton, Timothy S. and de Nys, Rocky and Kjelleberg, Staffan and Steinberg, Peter D.},\n\tmonth = jul,\n\tyear = {2004},\n\tpages = {4387--4389},\n}\n\n

\n

\n\n\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Host specificity in marine sponge-associated bacteria, and potential implications for marine microbial diversity: Host specificity and diversity in marine bacteria.\n \n \n \n \n\n\n \n Taylor, M. W., Schupp, P. J., Dahllöf, I., Kjelleberg, S., & Steinberg, P. D.\n\n\n \n\n\n\n Environmental Microbiology, 6(2): 121–130. February 2004.\n \n\n\n\n
\n\n\n\n \n \n $\"Host$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{taylor_host_2004,\n\ttitle = {Host specificity in marine sponge-associated bacteria, and potential implications for marine microbial diversity: {Host} specificity and diversity in marine bacteria},\n\tvolume = {6},\n\tissn = {14622912},\n\tshorttitle = {Host specificity in marine sponge-associated bacteria, and potential implications for marine microbial diversity},\n\turl = {http://doi.wiley.com/10.1046/j.1462-2920.2003.00545.x},\n\tdoi = {10.1046/j.1462-2920.2003.00545.x},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {Environmental Microbiology},\n\tauthor = {Taylor, Michael W. and Schupp, Peter J. and Dahllöf, Ingela and Kjelleberg, Staffan and Steinberg, Peter D.},\n\tmonth = feb,\n\tyear = {2004},\n\tpages = {121--130},\n}\n\n

\n

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\n\n\n\n\n\n

\n

\n \n 2003\n \n \n (3)\n \n \n

\n

\n \n \n

\n \n\n \n \n \n \n \n \n Eudistomins W and X, Two New β-Carbolines from the Micronesian Tunicate Eudistoma sp.\n \n \n \n \n\n\n \n Schupp, P., Poehner, T., Edrada, R., Ebel, R., Berg, A., Wray, V., & Proksch, P.\n\n\n \n\n\n\n Journal of Natural Products, 66(2): 272–275. February 2003.\n \n\n\n\n
\n\n\n\n \n \n $\"Eudistomins$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{schupp_eudistomins_2003,\n\ttitle = {Eudistomins {W} and {X}, {Two} {New} β-{Carbolines} from the {Micronesian} {Tunicate} \\textit{{Eudistoma}} sp.},\n\tvolume = {66},\n\tissn = {0163-3864, 1520-6025},\n\turl = {https://pubs.acs.org/doi/10.1021/np020315n},\n\tdoi = {10.1021/np020315n},\n\tlanguage = {en},\n\tnumber = {2},\n\turldate = {2022-11-09},\n\tjournal = {Journal of Natural Products},\n\tauthor = {Schupp, Peter and Poehner, Timo and Edrada, RuAngelie and Ebel, Rainer and Berg, Albrecht and Wray, Victor and Proksch, Peter},\n\tmonth = feb,\n\tyear = {2003},\n\tpages = {272--275},\n}\n\n

\n

\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Detection of pharmacologically active natural products using ecology. Selected examples from Indopacific marine invertebrates and sponge-derived fungi.\n \n \n \n \n\n\n \n Proksch, P., Ebel, R., Edrada, R. A., Schupp, P., Lin, W. H., Sudarsono, Wray, V., & Steube, K.\n\n\n \n\n\n\n Pure and Applied Chemistry, 75(2-3): 343–352. January 2003.\n \n\n\n\n
\n\n\n\n \n \n $\"Detection$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{proksch_detection_2003,\n\ttitle = {Detection of pharmacologically active natural products using ecology. {Selected} examples from {Indopacific} marine invertebrates and sponge-derived fungi},\n\tvolume = {75},\n\tissn = {1365-3075, 0033-4545},\n\turl = {https://www.degruyter.com/document/doi/10.1351/pac200375020343/html},\n\tdoi = {10.1351/pac200375020343},\n\tabstract = {Abstract\n            This review article presents our group's recent research findings with regard to bioactive natural products from marine sponges and tunicates, as well as from sponge derived fungi. The organisms discussed originate in the Indopacific region, which has an exceptionally rich marine biodiversity. Major topics that are covered in our review include the chemical ecology of sponges, focusing on defense against fishes, as well as the isolation and identification of new bioactive constituents from sponges and tunicates. Sponge derived fungi are introduced as an emerging source for new bioactive metabolites, reflecting the currently growing interest in natural products from marine microorganisms.},\n\tlanguage = {en},\n\tnumber = {2-3},\n\turldate = {2022-11-09},\n\tjournal = {Pure and Applied Chemistry},\n\tauthor = {Proksch, P. and Ebel, R. and Edrada, R. A. and Schupp, P. and Lin, W. H. and {Sudarsono} and Wray, V. and Steube, K.},\n\tmonth = jan,\n\tyear = {2003},\n\tpages = {343--352},\n}\n\n

\n

\n\n\n\n\n\n

\n\n\n

\n \n\n \n \n \n \n \n \n Differential effects of staurosporine and its analogues on chemokine release by promyelocytic leukemia cell line NB-4.\n \n \n \n \n\n\n \n Steube, K. G., Meyer, C., Schupp, P., Proksch, P., & Drexler, H. G.\n\n\n \n\n\n\n Leukemia Research, 27(10): 957–963. October 2003.\n \n\n\n\n
\n\n\n\n \n \n $\"Differential$ Paper\n \n \n\n \n \n doi\n \n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

\n

@article{steube_differential_2003,\n\ttitle = {Differential effects of staurosporine and its analogues on chemokine release by promyelocytic leukemia cell line {NB}-4},\n\tvolume = {27},\n\tissn = {01452126},\n\turl = {https://linkinghub.elsevier.com/retrieve/pii/S014521260300047X},\n\tdoi = {10.1016/S0145-2126(03)00047-X},\n\tlanguage = {en},\n\tnumber = {10},\n\turldate = {2022-11-09},\n\tjournal = {Leukemia Research},\n\tauthor = {Steube, Klaus G. and Meyer, Corinna and Schupp, Peter and Proksch, Peter and Drexler, Hans G.},\n\tmonth = oct,\n\tyear = {2003},\n\tpages = {957--963},\n}\n\n

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\n\n\n\n\n\n

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\n \n 2002\n \n \n (1)\n \n \n

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\n \n \n

\n \n\n \n \n \n \n \n A new species of pseudocerotid flatworm (Platyhelminthes, Polycladida) from the Indo-Pacific.\n \n \n \n\n\n \n Newman, L. J, & Schupp, P.\n\n\n \n\n\n\n Micronesica, 34(2): 177–184. 2002.\n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n \n \n \n\n\n\n

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@article{newman_new_2002,\n\ttitle = {A new species of pseudocerotid flatworm ({Platyhelminthes}, {Polycladida}) from the {Indo}-{Pacific}},\n\tvolume = {34},\n\tissn = {0026-279X},\n\tnumber = {2},\n\tjournal = {Micronesica},\n\tauthor = {Newman, LESLIE J and Schupp, Peter},\n\tyear = {2002},\n\tpages = {177--184},\n}\n\n

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