An Ultra-Sensitive Step-Function Opsin for Minimally Invasive Optogenetic Stimulation in Mice and Macaques

Optogenetics is among the most widely employed techniques to manipulate neuronal activity. However, a major drawback is the need for invasive implantation of optical fibers. To develop a minimally invasive optogenetic method that overcomes this challenge, we engineered a new step-function opsin with...

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Published inNeuron (Cambridge, Mass.) Vol. 107; no. 1; pp. 38 - 51.e8
Main Authors Gong, Xin, Mendoza-Halliday, Diego, Ting, Jonathan T., Kaiser, Tobias, Sun, Xuyun, Bastos, André M., Wimmer, Ralf D., Guo, Baolin, Chen, Qian, Zhou, Yang, Pruner, Maxwell, Wu, Carolyn W.-H., Park, Demian, Deisseroth, Karl, Barak, Boaz, Boyden, Edward S., Miller, Earl K., Halassa, Michael M., Fu, Zhanyan, Bi, Guoqiang, Desimone, Robert, Feng, Guoping
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 08.07.2020
Elsevier Limited
Subjects
Animal models
Animals
Brain
Brain - physiology
Firing pattern
Genetics
Information processing
Light
Macaca
Mice
Models, Animal
Mutation
Neurological diseases
Neurons - physiology
Opsins
Optics
Optogenetics - methods
Oscillations
Rodents
Transplants & implants
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Summary:Optogenetics is among the most widely employed techniques to manipulate neuronal activity. However, a major drawback is the need for invasive implantation of optical fibers. To develop a minimally invasive optogenetic method that overcomes this challenge, we engineered a new step-function opsin with ultra-high light sensitivity (SOUL). We show that SOUL can activate neurons located in deep mouse brain regions via transcranial optical stimulation and elicit behavioral changes in SOUL knock-in mice. Moreover, SOUL can be used to modulate neuronal spiking and induce oscillations reversibly in macaque cortex via optical stimulation from outside the dura. By enabling external light delivery, our new opsin offers a minimally invasive tool for manipulating neuronal activity in rodent and primate models with fewer limitations on the depth and size of target brain regions and may further facilitate the development of minimally invasive optogenetic tools for the treatment of neurological disorders. •We introduce SOUL, a new step-function opsin with ultra-high light sensitivity•SOUL activates deep mouse brain and change behaviors via transcranial illumination•SOUL activates macaque cortical neurons via illumination through the dura•Transdural activation of SOUL in macaques induces oscillatory activity reversibly Is it possible to turn on and off neurons inside the brain by shining light from outside the head? Now it is. SOUL, a newly developed light-responsive molecule, is so sensitive to light that it can activate neurons inside the brain of mice and monkeys with external illumination.
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AUTHOR CONTRIBUTIONS
X.G., D.M.-H., J.T.T., R.D. and G.F. designed the project. X.G., D.M.-H. and J.T.T. contributed equally to this work, performed opsin and SOUL knock-in mouse generation, immunohistochemistry, virus injections in mice and macaque, optogenetic behavior testing, electrophysiology experiments in macaque, and analyzed the collected data. T.K. contributed to slice recording experiments. X.S. and A.B. contributed to the analysis of electrophysiology data in macaque. R.D.W. conducted in vivo recordings in mice and analyzed the data. Y.Z. performed mouse ES cell targeting. B.G and Z.F performed recordings in cultured neurons. Q.C. and M.P. performed dark and light c-fos activation experiment. D.P., E.S.B., C.W. and B.B. contributed to pilot experiments. A.B., R.D.W., K.D., E.K.M., M.M.H., G.B., R.D., and G.F. interpreted the results and commented on the manuscript. X.G. and D.M.-H wrote the manuscript with editing and comments from J.T.T., T.K. and X.S. G.F. and R.D. supervised all aspects of the project.
ISSN:0896-6273
1097-4199
1097-4199
DOI:10.1016/j.neuron.2020.03.032