Understanding How Photoswitches Restore Visual Function in Blind Mice

了解光电开关如何恢复失明小鼠的视觉功能

基本信息

批准号：
9330653
负责人：
RICHARD H KRAMER
金额：
$ 7.8万
依托单位：
UNIVERSITY OF CALIFORNIA BERKELEY
依托单位国家：
美国
项目类别：
财政年份：
2015
资助国家：
美国
起止时间：
2015-09-01 至 2020-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9330653
关键词：
Action Potentials Age related macular degeneration Area Behavior Blindness Brain Calcium Chemicals Degenerative Disorder Development Disease Exhibits Face Fire - disasters Gene Expression Goals Health Human Image Injection of therapeutic agent Ion Channel Knowledge Label Left Light Macular degeneration Mediating Mus Names Neurons Operative Surgical Procedures Optics Patients Pattern Pharmaceutical Preparations Photophobia Photoreceptors Photosensitization Potassium Channel Preclinical Testing Property Rest Retina Retinal Retinal Ganglion Cells Retinitis Pigmentosa Signal Transduction Stimulus Testing Tissue Sample Tissues Toxic effect Vertebrate Photoreceptors Vision Visual Visual system structure Work blind cone-rod degeneration design drug candidate drug development human tissue improved in vivo in vivo imaging mouse model neural circuit photoreceptor degeneration research study response restoration retinal neuron voltage gated channel

项目摘要

DESCRIPTION (provided by applicant): Retinitis pigmentosa (RP) and age-related macular degeneration (AMD) are blinding diseases caused by the degeneration of rods and cones, leaving the rest of the visual system intact but unable to respond to light. A synthetic chemical photoswitch, named DENAQ, can restore visual responses in blind mouse models of RP. Previous studies showed that DENAQ imparts light-sensitivity on action potential firing in retinal ganglion cells (RGC), but how this occurs is unclear. The goal of this project is to elucidate the mechanism of DENAQ photosensitization, crucial for enabling discovery of improved drug candidates and for optimizing photo- stimulation strategies for vision restoration. The first aim i to understand why DENAQ selectively photosensitizes retinas from mice with dead rods and cones while having no effect on healthy retinas with intact rods and cones. We will test the hypothesis that degeneration leads to enhanced entry of DENAQ into RGCs and/or enhanced action on ion channels underlying spontaneous firing in RGCs. The second aim is to identify which RGCs are photosensitized by DENAQ. In the healthy retina, some RGCs fire at light onset, some at offset, and some at onset and offset. Studies will determine which are photosensitized by DENAQ, and whether local degeneration of rods and cones leads to spatially constrained RGC photosensitization, of particular relevance for AMD, a localized degenerative disease. Other studies will reveal whether DENAQ photosensitization applies to human RGCs in tissue samples obtained during surgical retinectomy. The third aim is to exploit our findings to optimize vision restoration. Information about the ion channels targeted by DENAQ will enable development of more specific photoswitches. Subcellular localization of these channels in RGCs will enable more spatially-precise photo-control. Finally imaging studies in vivo will reveal signals transmitted from the DENAQ-treated retina to the brain of blind mice, validating the functional integrity of the visual system and providing a platform for optimizing retinal stimulatin patterns to best recapitulate normal visual responses.

描述（由申请人提供）：色素性视网膜炎（RP）和年龄相关性黄斑变性（AMD）是由视杆细胞和视锥细胞退化引起的致盲疾病，视觉系统的其余部分完好无损，但无法对光做出反应。化学光开关，称为 DENAQ，可以恢复 RP 失明小鼠模型的视觉反应，之前的研究表明 DENAQ 赋予视网膜神经节细胞动作电位放电光敏感性。（RGC），但该项目的目标是阐明 DENAQ 光敏化机制，这对于发现改进的候选药物和优化视力恢复的光刺激策略至关重要。为什么 DENAQ 选择性地使视杆细胞和视锥细胞死亡的小鼠的视网膜光敏化，而对视杆细胞和视锥细胞完整的健康视网膜没有影响我们将检验退化导致 DENAQ 增强进入的假设。 RGC 和/或对 RGC 中自发放电的离子通道的增强作用第二个目的是确定哪些 RGC 被 DENAQ 光敏化。在健康的视网膜中，一些 RGC 在光开始时放电，一些在光开始时放电，一些在光开始时放电。研究将确定哪些是 DENAQ 光敏的，以及视杆细胞和视锥细胞的局部变性是否会导致空间受限的 RGC 光敏化，这与 AMD（一种局部退行性疾病）特别相关。其他研究将揭示 DENAQ 光敏化是否适用于视网膜切除术中获得的组织样本中的人类 RGC。第三个目标是利用我们的研究结果来优化视力恢复，有关 DENAQ 靶向离子通道的信息将有助于开发更具体的光开关。 RGC 中的这些通道将实现更空间精确的光控制，最终体内成像研究将揭示从经过 DENAQ 处理的视网膜传输到失明小鼠大脑的信号，从而验证视觉功能的完整性。系统并提供一个优化视网膜刺激模式的平台，以最好地重现正常的视觉反应。