Optical delivery of multiple opsin-encoding genes leads to targeted expression and white-light activation

In photodegenerative diseases such as retinitis pigmentosa(RP)and age-related macular degeneration(AMD),progressive loss of vision occurs as a result of degeneration of the periphery of the retina and the macula,respectively.Current optogenetic stimulation-based approaches to vision restoration offer the advantages of cellular specificity,high resolution,and minimal invasiveness over electrode arrays;however,the clinical translation of optogenetic activation suffers from the lack of a method for the delivery of opsins into spatially targeted regions of a retina that has degenerated.Non-targeted opsin delivery through viral or non-viral methods to non-photodegenerated retinal areas will perturb these already functioning retinal regions.Furthermore,viral methods are subject to limitations on the delivery of large plasmids,such as fusion constructs of multiple spectrally separated opsins(e.g.,channelrhodopsin-2(ChR2),chimeric opsin variants(C1V1),ReaChR),which can provide higher photo-excitability than can a single narrow-band opsin under ambient light conditions.Here,we report the ultrafast near-infrared laser-based spatially targeted transfection of single and multiple opsins and present a comparison with the opsin expression distribution achieved using another non-viral,but non-targeted,transfection method,lipofection.Functional evaluation of cells transfected with multiple opsins using the laser method revealed a significantly higher white-light-induced photocurrent than in cells expressing a single opsin(ChR2).The laser-assisted targeted delivery of multiple opsin-encoding genes to the peripheral retina/macula is ideal for sensitizing retinal areas that have degenerated,thus paving the way toward the restoration of lost vision in RP/AMD patients.