Retinal circadian rhythms and refractive development

视网膜昼夜节律和屈光发育

• 批准号: 8604713
• 负责人: RICHARD A STONE
• 金额: $ 55.72万
• 依托单位: UNIVERSITY OF PENNSYLVANIA
• 依托单位国家: 美国
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-02-01 至 2016-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8604713
• 关键词: Accounting; Acetylcholine; Address; Affect; Aminobutyric Acids; Biological; Brain; Cataract; Child; Circadian Rhythms; Clinical; Clinical Research; Complex; Core Facility; Development; Dimensions; Dopamine; Environmental Risk Factor; Etiology; Exhibits; Eye; Eye Development; Feedback; Gene Expression; Gene Expression Profile; Gene Expression Profiling; Genes; Genetic; Glaucoma; Goggles; Growth; Health; Human; Image; Investigation; Knowledge; Laboratories; Laboratory Animals; Laboratory Research; Learning; Length; Light; Lighting; Link; Mammals; Melatonin; Melatonin Receptors; Modeling; Molecular; Molecular Genetics; Mus; Mutant Strains Mice; Myopia; Optics; Output; Pattern; Pennsylvania; Pharmaceutical Preparations; Play; Process; Proteins; Public Health; Receptor Gene; Refractive Errors; Regulation; Reporting; Research; Research Personnel; Retina; Retinal; Retinal Diseases; Retinal Ganglion Cells; Risk Factors; Role; Sampling; Signal Pathway; Structure of retinal pigment epithelium; Testing; Time; Tissues; Universities; Visual; Visual impairment; Work; cholinergic; circadian pacemaker; deprivation; experience; gamma-Aminobutyric Acid; ganglion cell; improved; innovation; lens; melanopsin; novel; receptor; research study; tool

DESCRIPTION (provided by applicant): Refractive errors are a major cause of visual impairment from optical defocus and are risk factors for retinal disorders, as well as for glaucoma and cataract. Despite the public health impact, the etiologies of refractive errors are poorly understood; and clinically acceptable therapies to normalize refractive development in children do not exist. Image quality modulates refractive development, and the retina largely governs this process. In recently completed gene expression profiling of the retina/(retinal pigment epithelium) in eye growth models in chick, we identified an intriguing retinal gene network associated with refractive error: genes involved in intrinsic retinal clock and circadian rhythms. Extensively studied, the retina has many intrinsic circadian rhythms (e.g., disc shedding, melatonin secretion), and it achieves circadian timing through interconnected feedback loops involving clock genes and their protein products. Light is the major environmental input regulating the timing of circadian clocks. Many reports also have associated lighting (or putative surrogates of lighting) with disordered refractive development both in laboratory animals and in children. We propose the innovative hypothesis that intact intrinsic retinal circadian rhythms are fundamental to the mechanism controlling refractive development and that refractive errors might arise from disruptions of circadian control. Combining experienced investigators at Penn and Emory, we shall address this hypothesis with three inter-related Specific Aims: 1) identify the co-regulation of circadian genes and refractive development; 2) identify the role(s) of circadian clocks, melatonin receptors, and intrinsically photosensitive ganglion cells (ipRGCs) in refractive development and eye growth; and 3) establish the interaction of circadian genes and eye length rhythms with pharmacologic conditions known to modulate refractive development. Our approach offers great promise for establishing a long-sought framework to understand the biological mechanisms of refractive development and to learn how environmental factors might influence the process at a molecular level. We anticipate that this work will generate novel and useful hypotheses that can be applied not only in the laboratory but also to the study of refractive errors in children.

描述(申请人提供)：屈光不正是光学离焦造成视力损害的主要原因，也是视网膜疾病、青光眼和白内障的危险因素。尽管对公众健康有影响，但屈光不正的病因尚不清楚；临床上可接受的使儿童屈光发育正常化的治疗方法尚不存在。图像质量调节屈光发育，而视网膜在很大程度上控制着这一过程。在最近完成的鸡眼生长模型中视网膜(视网膜色素上皮)的基因表达谱中，我们发现了一个与屈光不正相关的有趣的视网膜基因网络：参与内在视网膜时钟和昼夜节律的基因。经过广泛的研究，视网膜有许多内在的昼夜节律(例如，视盘脱落、褪黑素分泌)，它通过涉及时钟基因及其蛋白质产物的相互连接的反馈环来实现昼夜节律。光是调节生物钟时间的主要环境输入。许多报告也将照明(或假定的照明替代品)与实验室动物和儿童的屈光发育紊乱联系在一起。我们提出了一个创新的假设，即完整的视网膜固有昼夜节律是屈光发育控制机制的基础，屈光不正可能源于昼夜节律控制的中断。结合宾夕法尼亚大学和埃默里大学经验丰富的研究人员，我们将用三个相互关联的具体目标来解决这一假说：1)确定昼夜节律基因和屈光不正的共同调节 其中包括：1)确定生物钟、褪黑素受体和固有感光神经节细胞(IPRGC)在屈光发育和眼睛生长中的作用(S)；3)确定昼夜节律基因和眼长节律与已知调节屈光发育的药物条件之间的相互作用。我们的方法为建立一个长期寻求的框架来理解屈光发育的生物学机制和了解环境因素如何在分子水平上影响屈光发育过程提供了巨大的希望。我们预计这项工作将产生新的和有用的假说，这些假说不仅可以在实验室中应用，而且可以用于儿童屈光不正的研究。