ACTIVITY-DEPENDENT MATURATION OF INNER RETINAL CIRCUITRY

视网膜内环路的活动依赖性成熟

• 批准号: 6208856
• 负责人: Rene Carlos Renteria
• 金额: $ 3.24万
• 依托单位: UNIVERSITY OF CALIFORNIA, SAN FRANCISCO
• 依托单位国家: 美国
• 财政年份: 2000
• 资助国家: 美国
• 起止时间: 2000-09-01 至
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/6208856
• 关键词: amacrine cells; calcium flux; cell cell interaction; developmental neurobiology; glutamates; laboratory mouse; light adaptations; neurogenesis; neurotransmitter biosynthesis; retinal bipolar neuron; retinal ganglion

Activity plays an important role in guiding the normal development of many areas in the central nervous system (CNS), and the retina is no exception. Interfering with normal sensory input at young ages has profound effects on the development of nervous tissue and can lead to permanent deficits in function. Raising rodents in the dark ("dark rearing") alters responses recorded in the output neurons of the retina, the retinal ganglion cells (RGCs). In order to identify how activity can guide maturation of CNS circuitry, the specific aims of this proposal seek to determine the alterations in retinal circuitry leading to these known changes in retinal output resulting from light-deprivation during development. The RGCs receive their input from bipolar cells, which release glutamate in response to photoreceptor activity. Inhibitory amacrine cells are important for proper control of this bipolar input to RGCs. Using whole- cell patch clamp techniques, the development of amacrine cell inputs to bipolar cells will be examined in the retinas of both normally reared and dark reared animals by recording spontaneous events and by evoking responses from reciprocal synapses made between bipolar terminals and amacrine dendrites. The ability of bipolar cells from different rearing conditions to release glutamate will also be studied by recording evoked responses in RGCs and by measuring calcium entry into isolated bipolar cell terminals, using calcium indicator dyes and fluorescent imaging of acutely isolated bipolar cells in culture. The goal is to determine whether these bipolar cell inputs and/or bipolar cell glutamate release properties are altered by activity deprivation during early development. These properties critically affect RGC output.

活动在指导中枢神经系统（CNS）许多区域的正常发育中起着重要作用，视网膜也不例外。 在年轻时干扰正常的感觉输入对神经组织的发育有深远的影响，并可能导致永久性的功能缺陷。在黑暗中饲养啮齿动物（“黑暗饲养”）会改变视网膜输出神经元（视网膜神经节细胞（RGC））中记录的反应。 为了确定活动如何引导CNS回路的成熟，本提案的具体目的是确定视网膜回路的改变，这些改变导致发育期间光剥夺引起的视网膜输出的这些已知变化。 RGCs从双极细胞接收它们的输入，双极细胞响应感光细胞的活动而释放谷氨酸。 抑制性无长突细胞对于正确控制向RGCs的双极输入是重要的。 使用全细胞膜片钳技术，通过记录自发事件和诱发双极终末和无长突树突之间形成的相互突触的反应，在正常饲养和黑暗饲养动物的视网膜中检查无长突细胞向双极细胞输入的发育。 还将通过记录RGCs中的诱发反应和通过测量进入分离的双极细胞末端的钙，使用钙指示剂染料和培养中急性分离的双极细胞的荧光成像来研究来自不同饲养条件的双极细胞释放谷氨酸的能力。 我们的目标是确定这些双极细胞的输入和/或双极细胞谷氨酸释放特性是否改变活动剥夺在早期发展。 这些特性严重影响研资局的产出。