Curated Optogenetic Publication Database

Abstract: The use of optogenetic tools offers an excellent method for spatially and temporally regulated gene and protein expression in cell therapeutic approaches. This could be useful as a concomitant therapeutic measure, especially in small body compartments such as the inner ear, for example, during cochlea implantation, to enhance neuronal cell survival and function. Here, we used the blue light activatable CRY2/CIB system to induce transcription of brain-derived neurotrophic factor (BDNF) in human cells. Transfection with three plasmids, encoding for the optogenetic system and the target, as well as illumination protocols were optimized with luciferase as a reporter to achieve the highest protein expression in human embryonic kidney cells 293. Illumination was performed either with a light-emitting diode or with a scanning laser setup. The optimized protocols were applied for the production of BDNF. We could demonstrate a 64.7-fold increase of BNDF expression upon light induction compared to the basal level. Light-induced BDNF was biologically active and enhanced survival and neurite growth of spiral ganglion neurons. The optogenetic approach can be transferred to autologous cell systems, such as bone marrow-derived mesenchymal stem cells, and thus represents the first optogenetic neurotrophic therapy for the inner ear.

Abstract: The field of optogenetics is rapidly growing in relevance and number of developed tools. Amongst other things, the optogenetic repertoire includes light-responsive ion channels and methods for gene regulation. This review will be confined to the optogenetic control of gene expression in mammalian cells as suitable models for clinical applications. Here optogenetic gene regulation might offer an excellent method for spatially and timely regulated gene and protein expression in cell therapeutic approaches. Well-known systems for gene regulation, such as the LOV-, CRY2/CIB-, PhyB/PIF-systems, as well as other, in mammalian cells not yet fully established systems will be described. Advantages and disadvantages with regard to clinical applications are outlined in detail. Among the many unanswered questions concerning the application of optogenetics, we discuss items such as the use of exogenous chromophores and their effects on the biology of the cells and methods for a gentle, but effective gene transfection method for optogenetic tools for in vivo applications. This article is protected by copyright. All rights reserved.