Reverse optogenetics of G protein signaling by zebrafish non-visual opsin Opn7b for synchronization of neuronal networks

Opn7b is a non-visual G protein-coupled receptor expressed in zebrafish. Here we find that Opn7b expressed in HEK cells constitutively activates the G(i/o) pathway and illumination with blue/green light inactivates G protein-coupled inwardly rectifying potassium channels. This suggests that light acts as an inverse agonist for Opn7b and can be used as an optogenetic tool to inhibit neuronal networks in the dark and interrupt constitutive inhibition in the light. Consistent with this prediction, illumination of recombinant expressed Opn7b in cortical pyramidal cells results in increased neuronal activity. In awake mice, light stimulation of Opn7b expressed in pyramidal cells of somatosensory cortex reliably induces generalized epileptiform activity within a short (<10s) delay after onset of stimulation. Our study demonstrates a reversed mechanism for G protein-coupled receptor control and Opn7b as a tool for controlling neural circuit properties. Microbial rhodopsins can be used to control action potentials, while animal opsins can be used to control intracellular signaling pathways. The authors identify Opn7b as constitutively active G(i/o) coupled receptor that can be deactivated by light and used to modulate neuronal activity.

Automated summary

Opn7b is a non-visual G protein-coupled receptor expressed in zebrafish that can be controlled by light to modulate neuronal activity and neural circuit properties.