Step‐function luminopsins for bimodal prolonged neuromodulation

Step‐function luminopsins for bimodal prolonged neuromodulation

Although molecular tools for controlling neuronal activity by light have vastly expanded, there are still unmet needs which require development and refinement. For example, light delivery into the brain is still a major practical challenge that hinders potential translation of optogenetics in human...

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Veröffentlicht in:Journal of neuroscience research 2020-03, Vol.98 (3), p.422-436
Hauptverfasser: Berglund, Ken, Fernandez, Alejandra M., Gutekunst, Claire‐Anne N., Hochgeschwender, Ute, Gross, Robert E.
Format: Artikel
Sprache:eng
Schlagworte:
Animal models
behavior
Bioluminescence
Brain
Cell surface
coelenterazine
Deactivation
Energy transfer
Fiber optics
Fusion protein
Genetics
In vivo methods and tests
Information processing
LED
Mutation
Neuromodulation
opsin
Opsins
Optical fibers
Optics
Photoelectric effect
Photoelectric emission
Substantia nigra
Substrates
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container_end_page 436
container_issue 3
container_start_page 422
container_title Journal of neuroscience research
container_volume 98
creator Berglund, Ken
Fernandez, Alejandra M.
Gutekunst, Claire‐Anne N.
Hochgeschwender, Ute
Gross, Robert E.
description Although molecular tools for controlling neuronal activity by light have vastly expanded, there are still unmet needs which require development and refinement. For example, light delivery into the brain is still a major practical challenge that hinders potential translation of optogenetics in human patients. In addition, it would be advantageous to manipulate neuronal activity acutely and precisely as well as chronically and non‐invasively, using the same genetic construct in animal models. We have previously addressed these challenges by employing bioluminescence and have created a new line of opto‐chemogenetic probes termed luminopsins by fusing light‐sensing opsins with light‐emitting luciferases. In this report, we incorporated Chlamydomonas channelrhodopsin 2 with step‐function mutations as the opsin moiety in the new luminopsin fusion protein termed step‐function luminopsin (SFLMO). Bioluminescence‐induced photocurrent lasted longer than the bioluminescence signal due to very slow deactivation of the mutated channel. In addition, bioluminescence was able to activate most of the channels on the cell surface due to the extremely high light sensitivity of the channel. This efficient channel activation was partly mediated by radiationless bioluminescence resonance energy transfer due to the proximity of luciferase and opsin. To test the utility of SFLMOs in vivo, we transduced the substantia nigra unilaterally via a viral vector in male rats. Injection of the luciferase substrate as well as conventional photostimulation via fiber optics elicited circling behaviors. Thus, SFLMOs expand the current approaches for manipulation of neuronal activity in the brain and add more versatility and practicality to optogenetics in freely behaving animals. Step‐function luminopsins allow activation of targeted neural circuits by a chemical (left) or physical light (center) to elicit specific behaviors in rodents (bottom). Its action can be terminated by illumination of yellow/red light (right).
doi_str_mv 10.1002/jnr.24424
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subjects Animal models
behavior
Bioluminescence
Brain
Cell surface
coelenterazine
Deactivation
Energy transfer
Fiber optics
Fusion protein
Genetics
In vivo methods and tests
Information processing
LED
Mutation
Neuromodulation
opsin
Opsins
Optical fibers
Optics
Photoelectric effect
Photoelectric emission
Substantia nigra
Substrates
title Step‐function luminopsins for bimodal prolonged neuromodulation
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