Application and research progress of optogenetic technology in retinal diseases / 中华实验眼科杂志

Optogenetics is a technique combining optics and the power of light with genetics;it uses light-mediated protein-protein interactions to control the open/closed state of channels or the activation/inactivation states of signaling components within live cells.Recently developed optogenetic tools offer exciting opportunities by enabling signaling regulation with superior temporal and spatial resolution.The eye is a light-bioelectric conversion system.Compared with diseases of other organs,there are great advantages to apply optogenetics to the treatment of ophthalmic conditions,as new optical genetic tools are rapidly emerging.This article will focus on the main methods of optogenetic control of cells and the current status and outlook of its application in retinal diseases.

Application and research progress of optogenetic technology in retinal diseases / 中华实验眼科杂志

Optogenetics is a technique combining optics and the power of light with genetics; it uses light-mediated protein-protein interactions to control the open/closed state of channels or the activation/inactivation states of signaling components within live cells.Recently developed optogenetic tools offer exciting opportunities by enabling signaling regulation with superior temporal and spatial resolution.The eye is a light-bioelectric conversion system.Compared with diseases of other organs, there are great advantages to apply optogenetics to the treatment of ophthalmic conditions, as new optical genetic tools are rapidly emerging.This article will focus on the main methods of optogenetic control of cells and the current status and outlook of its application in retinal diseases.

The evolution of opsins and color vision: connecting genotype to a complex phenotype / Conectando el genotipo a un fenotipo complejo: evolución de las opsinas y la visión a color

Dissecting the genetic basis of adaptive traits is key to our understanding of evolutionary processes. A major and essential step in the study of evolutionary genetics is drawing link between genotype and phenotype, which depends on the difficult process of defining the phenotype at different levels, from functional to organismal. Visual pigments are a key component of the visual system and their evolution could also provide important clues on the evolution of visual sensory system in response to sexual and natural selection. As a system in which genotype can be linked to phenotype, I will use visual pigments and color vision, particularly in birds, as a case of a complex phenotype. I aim to emphasize the difficulties in drawing the genotype-phenotype relationship for complex phenotypes and to highlight the challenges of doing so for color vision. The use of vision-based receiver models to quantify animal colors and patterns is increasingly important in many fields of evolutionary research, spanning studies of mate choice, predation, camouflage and sensory ecology. Given these models impact on evolution and ecology, it is important to provide other researchers with the opportunity to better understand animal vision and the corresponding advantages and limitations of these models.

Entender la base genética de los rasgos adaptativos es un paso crítico en el estudio de los procesos evolutivos. Para estudiar la conexión entre genotipo y fenotipo es importante definir el fenotipo a diferentes niveles: desde las proteínas que se construyen con base en un gen, hasta las características finales presentes en un organismo. Las opsinas y los fotopigmentos son elementos primordiales de la visión y entender cómo han evolucionado es fundamental en el estudio de la visión en los animales como un caracter derivado de selección natural o sexual. Este artículo se enfoca en este sistema, en el que se pueden conectar genotipo y fenotipo, como ejemplo de fenotipo complejo para ilustrar las dificultades de establecer una relación clara entre genotipo y fenotipo. Adicionalmente, este artículo tiene como objetivo discutir el funcionamiento del sistema de fotorrecepción, con énfasis particular en las aves, con el fin de enumerar varios factores que deben ser tenidos en cuenta para predecir cambios en la visión a partir del estudio de los fotopigmentos. Dado que los modelos basados en la visión de aves son cada vez más usados en diversas áreas de la biología evolutiva tales como: selección de pareja, depredación y camuflaje; se hace relevante entender los fundamentos y limitaciones de estos modelos. Por esta razón, en este artículo discuto los detalles y aspectos prácticos del uso de los modelos de visión existentes para aves, con el fin de facilitar su uso en futuras investigaciones en diversas áreas de evolución.

The application of optogenetics in the treatment of retinal degeneration disease / 中华眼底病杂志

Optogenetics is a novel technique which combines optics with genetics.Using genetic means,a selected opsin protein is ectopically expressed in target neurons,which are then stimulated by light to moderate the neuronal circuit,as a consequence to regulate the animal's behaviors.Retinal degeneration like retinitis pigmentosa and aged macular degeneration causes visual impairment and eventual blindness.Optogenetics techniques have opened the door to creating artificial photoreceptors in the remaining retinal circuits of retinal degeneration retinas via gene therapy.However,there are still limitations in optogenetics technique,for example,potential risk in virus infection,the choice of target cells and the low visual resolution of the experiment animal.It has been reported that vision was successfully restored to a certain extent in animal model using optogenetics technique.With higher photosensitivity of opsin protein,longer activation kinetics and higher transfection efficiency of virus vector,optogenetics techniques' application in ophthalmology will be improved.