调节突触特异性和视网膜回路形成的分子机制。

Q1 Biochemistry, Genetics and Molecular Biology Wiley Interdisciplinary Reviews: Developmental Biology Pub Date : 2021-01-01 Epub Date: 2020-04-08 DOI:10.1002/wdev.379
Hannah K Graham, Xin Duan
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引用次数: 3

摘要

中枢神经系统(CNS)是由精确组装的电路组成的,这些电路支持各种生理功能和行为。这些电路包括具有独特形态、电学性质和分子特性的多种神经元亚型。这些组成部分如何精确地连接起来一直是发育神经生物学领域非常感兴趣的话题,并对我们对许多神经系统疾病和精神疾病的病因学的理解产生影响。迄今为止,许多参与突触选择和特异性的分子已经被确定,包括几个细胞粘附分子家族的成员(CAMs),这是细胞表面分子,介导细胞间接触和随后的细胞内信号传导。一个受欢迎的假设是,cam的独特表达模式定义了特定的神经元亚型群体,并根据这些独特的cam的表达确定了兼容的突触前和突触后神经元伙伴。由于小鼠视网膜具有明确定义的神经元亚型和独特的回路,因此它已成为研究哺乳动物CAM相互作用的理想模型。此外,视网膜易于实现电路组织的可视化和电路功能的电生理测量。最近遗传学、基因组学和成像技术的出现,为鉴定突触特异性的新分子决定因素开辟了大规模、无偏见的方法。因此,在本文综述的基础上,我们可以期待该领域的快速扩展,利用小鼠视网膜作为模型来理解突触特异性和功能电路组装的分子基础。本文分类如下:神经系统发育>脊椎动物:一般原理神经系统发育>脊椎动物:区域发育。
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Molecular mechanisms regulating synaptic specificity and retinal circuit formation.

The central nervous system (CNS) is composed of precisely assembled circuits which support a variety of physiological functions and behaviors. These circuits include multiple subtypes of neurons with unique morphologies, electrical properties, and molecular identities. How these component parts are precisely wired-up has been a topic of great interest to the field of developmental neurobiology and has implications for our understanding of the etiology of many neurological disorders and mental illnesses. To date, many molecules involved in synaptic choice and specificity have been identified, including members of several families of cell-adhesion molecules (CAMs), which are cell-surface molecules that mediate cell-cell contacts and subsequent intracellular signaling. One favored hypothesis is that unique expression patterns of CAMs define specific neuronal subtype populations and determine compatible pre- and postsynaptic neuronal partners based on the expression of these unique CAMs. The mouse retina has served as a beautiful model for investigations into mammalian CAM interactions due to its well-defined neuronal subtypes and distinct circuits. Moreover, the retina is readily amenable to visualization of circuit organization and electrophysiological measurement of circuit function. The advent of recent genetic, genomic, and imaging technologies has opened the field up to large-scale, unbiased approaches for identification of new molecular determinants of synaptic specificity. Thus, building on the foundation of work reviewed here, we can expect rapid expansion of the field, harnessing the mouse retina as a model to understand the molecular basis for synaptic specificity and functional circuit assembly. This article is categorized under: Nervous System Development > Vertebrates: General Principles Nervous System Development > Vertebrates: Regional Development.

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期刊介绍: Developmental biology is concerned with the fundamental question of how a single cell, the fertilized egg, ultimately produces a complex, fully patterned adult organism. This problem is studied on many different biological levels, from the molecular to the organismal. Developed in association with the Society for Developmental Biology, WIREs Developmental Biology will provide a unique interdisciplinary forum dedicated to fostering excellence in research and education and communicating key advances in this important field. The collaborative and integrative ethos of the WIREs model will facilitate connections to related disciplines such as genetics, systems biology, bioengineering, and psychology. The topical coverage of WIREs Developmental Biology includes: Establishment of Spatial and Temporal Patterns; Gene Expression and Transcriptional Hierarchies; Signaling Pathways; Early Embryonic Development; Invertebrate Organogenesis; Vertebrate Organogenesis; Nervous System Development; Birth Defects; Adult Stem Cells, Tissue Renewal and Regeneration; Cell Types and Issues Specific to Plants; Comparative Development and Evolution; and Technologies.
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Zebrafish models of acute leukemias: Current models and future directions. The macro and micro of chromosome conformation capture. Human pluripotent stem cell-derived lung organoids: Potential applications in development and disease modeling. Single-cell RNA sequencing in Drosophila: Technologies and applications. Schwann cell development: From neural crest to myelin sheath.
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