Engineering luminopsins with improved coupling efficiencies. Slaviero, A. N., Gorantla, N., Simkins, J., Crespo, E. L., Ikefuama, E. C., Tree, M. O., Prakash, M., Björefeldt, A., Barnett, L. M., Lambert, G. G., Lipscombe, D., Moore, C. I., Shaner, N. C., & Hochgeschwender, U. Neurophotonics, 11(2):024208, April, 2024. Place: United States
doi  abstract   bibtex   
SIGNIFICANCE: Luminopsins (LMOs) are bioluminescent-optogenetic tools with a luciferase fused to an opsin that allow bimodal control of neurons by providing both optogenetic and chemogenetic access. Determining which design features contribute to the efficacy of LMOs will be beneficial for further improving LMOs for use in research. AIM: We investigated the relative impact of luciferase brightness, opsin sensitivity, pairing of emission and absorption wavelength, and arrangement of moieties on the function of LMOs. APPROACH: We quantified efficacy of LMOs through whole cell patch clamp recordings in HEK293 cells by determining coupling efficiency, the percentage of maximum LED induced photocurrent achieved with bioluminescent activation of an opsin. We confirmed key results by multielectrode array recordings in primary neurons. RESULTS: Luciferase brightness and opsin sensitivity had the most impact on the efficacy of LMOs, and N-terminal fusions of luciferases to opsins performed better than C-terminal and multi-terminal fusions. Precise paring of luciferase emission and opsin absorption spectra appeared to be less critical. CONCLUSIONS: Whole cell patch clamp recordings allowed us to quantify the impact of different characteristics of LMOs on their function. Our results suggest that coupling brighter bioluminescent sources to more sensitive opsins will improve LMO function. As bioluminescent activation of opsins is most likely based on Förster resonance energy transfer, the most effective strategy for improving LMOs further will be molecular evolution of luciferase-fluorescent protein-opsin fusions.
@article{slaviero_engineering_2024,
	title = {Engineering luminopsins with improved coupling efficiencies.},
	volume = {11},
	copyright = {© 2024 The Authors.},
	issn = {2329-423X 2329-4248},
	doi = {10.1117/1.NPh.11.2.024208},
	abstract = {SIGNIFICANCE: Luminopsins (LMOs) are bioluminescent-optogenetic tools with a luciferase fused to an opsin that allow bimodal control of neurons by providing  both optogenetic and chemogenetic access. Determining which design features  contribute to the efficacy of LMOs will be beneficial for further improving LMOs  for use in research. AIM: We investigated the relative impact of luciferase  brightness, opsin sensitivity, pairing of emission and absorption wavelength, and  arrangement of moieties on the function of LMOs. APPROACH: We quantified efficacy  of LMOs through whole cell patch clamp recordings in HEK293 cells by determining  coupling efficiency, the percentage of maximum LED induced photocurrent achieved  with bioluminescent activation of an opsin. We confirmed key results by  multielectrode array recordings in primary neurons. RESULTS: Luciferase  brightness and opsin sensitivity had the most impact on the efficacy of LMOs, and  N-terminal fusions of luciferases to opsins performed better than C-terminal and  multi-terminal fusions. Precise paring of luciferase emission and opsin  absorption spectra appeared to be less critical. CONCLUSIONS: Whole cell patch  clamp recordings allowed us to quantify the impact of different characteristics  of LMOs on their function. Our results suggest that coupling brighter  bioluminescent sources to more sensitive opsins will improve LMO function. As  bioluminescent activation of opsins is most likely based on Förster resonance  energy transfer, the most effective strategy for improving LMOs further will be  molecular evolution of luciferase-fluorescent protein-opsin fusions.},
	language = {eng},
	number = {2},
	journal = {Neurophotonics},
	author = {Slaviero, Ashley N. and Gorantla, Nipun and Simkins, Jacob and Crespo, Emmanuel L. and Ikefuama, Ebenezer C. and Tree, Maya O. and Prakash, Mansi and Björefeldt, Andreas and Barnett, Lauren M. and Lambert, Gerard G. and Lipscombe, Diane and Moore, Christopher I. and Shaner, Nathan C. and Hochgeschwender, Ute},
	month = apr,
	year = {2024},
	pmid = {38559366},
	pmcid = {PMC10980360},
	note = {Place: United States},
	keywords = {bioluminescence, Förster resonance energy transfer, luciferase, opsin, optogenetics, whole cell patch clamp recording},
	pages = {024208},
}

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