Restoring vision with a new optogenetic tool
By Stavroula Kousta
Millions of people worldwide suffer from progressive degeneration of the eye’s photoreceptors (the light-sensing cells), leading ultimately to blindness. A recent therapeutic approach for restoring vision in blind retinas involves introducing light-sensing proteins into surviving retinal cells that normally cannot sense light, turning them into “replacement photoreceptors”. This so-called “optogenetic” method, however, has several limitations, because traditional light-sensitive proteins require extremely high light intensities, which can be harmful, and use a mechanism alien to the cells.
In a new PLOS Biology paper, Michiel van Wyk, Sonja Kleinlogel and their colleagues bring this promising technology closer to medical application by engineering a new light-sensing protein that is compatible with the cells’ own signalling mechanism but retains all the advantages of traditional optogenetic proteins: fast responsiveness and resistance to light damage (“bleaching”).
This new protein, termed Opto-mGluR6, is a chimeric protein that consists of two “local” retinal proteins: the light-sensing domains of the retinal photopigment melanopsin and the signaling domain of the metabotropic glutamate receptor 6 (mGluR6). mGluR6 is a protein found in retinal ON-bipolar cells that is naturally activated by the neurotransmitter glutamate released from the photoreceptors, thereby amplifying the incoming signal.
Because ON-bipolar cells naturally receive direct input from the photoreceptors, turning the native chemically activated receptor mGluR6 into a light-activated receptor means that signaling mechanisms in the ON-bipolar cells are preserved, conferring high light-sensitivity and fast “normal” responsiveness. And using the extracellular domain of melanopsin as a “light antenna” provides resistance to bleaching: No matter how hard the protein is hit by light, the response of Opto-mGluR6 never attenuates……..
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Source: Blogs PLOS