High-throughput characterization of cortical microtubule arrays response to anisotropic tensile stress. Demes, E. & Verger, S. BMC Biology, 21(1):154, July, 2023. Paper doi abstract bibtex Plants can perceive and respond to mechanical signals. For instance, cortical microtubule (CMT) arrays usually reorganize following the predicted maximal tensile stress orientation at the cell and tissue level. While research in the last few years has started to uncover some of the mechanisms mediating these responses, much remains to be discovered, including in most cases the actual nature of the mechanosensors. Such discovery is hampered by the absence of adequate quantification tools that allow the accurate and sensitive detection of phenotypes, along with high throughput and automated handling of large datasets that can be generated with recent imaging devices.
@article{demes_high-throughput_2023,
title = {High-throughput characterization of cortical microtubule arrays response to anisotropic tensile stress},
volume = {21},
issn = {1741-7007},
url = {https://doi.org/10.1186/s12915-023-01654-7},
doi = {10.1186/s12915-023-01654-7},
abstract = {Plants can perceive and respond to mechanical signals. For instance, cortical microtubule (CMT) arrays usually reorganize following the predicted maximal tensile stress orientation at the cell and tissue level. While research in the last few years has started to uncover some of the mechanisms mediating these responses, much remains to be discovered, including in most cases the actual nature of the mechanosensors. Such discovery is hampered by the absence of adequate quantification tools that allow the accurate and sensitive detection of phenotypes, along with high throughput and automated handling of large datasets that can be generated with recent imaging devices.},
number = {1},
urldate = {2023-07-14},
journal = {BMC Biology},
author = {Demes, Elsa and Verger, Stéphane},
month = jul,
year = {2023},
keywords = {Image analysis, Mechanical stress, Microtubules, Plants},
pages = {154},
}
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