Structure, function, and adaptability of parallel pathways in mammalian retina

哺乳动物视网膜平行通路的结构、功能和适应性

• 批准号: 8601079
• 负责人: Felice A Dunn
• 金额: $ 9万
• 依托单位: UNIVERSITY OF WASHINGTON
• 依托单位国家: 美国
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-01-01 至 2014-12-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8601079
• 关键词: Ablation; Affect; Blindness; Cells; Cellular Structures; Cessation of life; Cone; DNA Sequence Rearrangement; Development; Disease; Electrophysiology (science); Exhibits; Glutamate Receptor; Goals; Image; Knowledge; Lasers; Light; Measures; Modeling; Neurons; Outcome; Output; Pathway interactions; Pattern; Phase; Photoreceptors; Physiological; Population; Process; Property; Prosthesis; Public Health; Reaction; Recovery; Research; Retina; Retinal; Retinal Cone; Retinal Diseases; Shapes; Signal Transduction; Stereotyping; Stimulus; Structure; Synapses; Testing; Time; TimeLine; Transgenic Organisms; Translating; Vision; Visual system structure; Work; base; cell type; information processing; innovation; insight; photoreceptor degeneration; postsynaptic; presynaptic; public health relevance; receptive field; resilience; response; restoration; retinal neuron; visual information

DESCRIPTION (provided by applicant): To restore vision, we must understand how information is processed in the mature retina and how structural and functional organization are affected during degeneration. The divergence of signals at the first synapse in the visual system, where a single cone provides input to 10-12 types of cone bipolar cells, provides a unique opportunity to study the origin of parallel pathways. This synapse also exhibits convergence, where each type of cone bipolar cell receives inputs from a stereotyped number of cones. Our recent work demonstrates that three types of cone bipolar cells establish their unique patterns of structural contact with presynaptic cone photoreceptors according to different strategies and segregated timelines. However, we know little about how these differences translate into functional properties in the mature circuit. Moreover, how cone bipolar cell types respond to progressive loss of photoreceptors during disease is unclear. The long-term goal of the proposed work is to understand how visual information is parsed and processed in the retina at the cone-to-cone bipolar synapse, and to determine how this information is perturbed in disease. The objectives of the proposed work are to determine the functional properties of three morphologically characterized bipolar cells types, for which we already know structural connectivity patterns, and to determine these bipolars' structural and functional changes in a degenerating retina. In Aim 1, we will determine how cone convergence and divergence shapes the functional properties of three types of cone bipolar cells. We will make functional measures of the bipolar cells' spatial, temporal, and gain properties. In Aim 2, we will identify the effect of cone degeneration on bipolar cell structure, connectivity, and function. Many retinal diseases leading to blindness originate with death of photoreceptors. How disease progresses to affect postsynaptic neurons remains largely unknown. We will use laser ablation and transgenic approaches to control the extent and timing of cone death. Imaging and electrophysiology will allow us to determine the structural connectivity patterns, glutamate receptor distributions, and responses to light stimuli of bipolar cells following controlled cone death. The approach is innovative because we are separately determining the function and response of specific bipolar cell types to photoreceptor degeneration. The proposed work is significant because it will reveal how a bipolar cell's functional properties are determined by its anatomical connections with cones and will provide an understanding of how bipolar cells respond to photoreceptor degeneration as a model of potential circuit rearrangements in retinal disease.

描述（由申请人提供）：为了恢复视力，我们必须了解信息在成熟视网膜中是如何处理的，以及在变性过程中结构和功能组织是如何受到影响的。在视觉系统的第一个突触处，单个视锥向10-12种类型的视锥双极细胞提供输入，信号的发散为研究平行通路的起源提供了独特的机会。这种突触也表现出会聚，其中每种类型的锥双极细胞接收来自固定数量的锥的输入。我们最近的工作表明，三种类型的锥双极细胞建立其独特的结构模式与突触前视锥光感受器根据不同的策略和隔离的时间线。然而，我们对这些差异如何转化为成熟电路中的功能特性知之甚少。此外，视锥双极细胞类型如何应对疾病期间光感受器的逐渐丧失尚不清楚。这项拟议工作的长期目标是了解视觉信息如何在视网膜的视锥-视锥双极突触处进行解析和处理，并确定这些信息在疾病中如何受到干扰。所提出的工作的目标是确定三种形态特征的双极细胞类型的功能特性，我们已经知道结构连接模式，并确定这些双极细胞在退化视网膜中的结构和功能变化。在目标1中，我们将确定锥收敛和发散如何塑造三种类型的锥双极细胞的功能特性。我们将对双极细胞的空间、时间和增益特性进行功能测量。在目标2中，我们将确定视锥细胞变性对双极细胞结构、连接性和功能的影响。许多导致失明的视网膜疾病起源于光感受器的死亡。疾病如何发展到影响突触后神经元仍然是未知的。我们将使用激光消融和转基因的方法来控制锥死亡的程度和时间。成像和电生理学将使我们能够确定结构连接模式，谷氨酸受体分布，以及控制锥死亡后双极细胞对光刺激的反应。该方法是创新的，因为我们分别确定特定双极细胞类型对光感受器变性的功能和反应。拟议的工作是重要的，因为它将揭示如何双极细胞的功能特性是由其与视锥细胞的解剖连接决定的，并将提供一个了解双极细胞如何响应感光细胞变性作为视网膜疾病中潜在电路重排的模型。