大脑发育中的 3D 基因组:分子机理和实验方法的探索。

IF 2.9 Q2 NEUROSCIENCES
Neuroscience Insights Pub Date : 2024-10-29 eCollection Date: 2024-01-01 DOI:10.1177/26331055241293455
Samir Rahman, Panos Roussos
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引用次数: 0

摘要

人脑包含多种细胞类型,它们在空间上被组织成功能不同的区域。大脑的正常发育需要神经元和支持神经元功能的非神经元细胞类型中复杂的基因调控机制。过去十年的研究发现,基因组的三维核组织有助于调控大脑不同细胞类型的基因表达。在这篇综述中,我们描述了调控三维基因组的基本生化机制,并全面描述了有关小鼠和人类大脑发育的体外和体内研究,这些研究揭示了三维基因组在基因调控中的作用。我们强调了三维基因组在连接远端增强子和目标启动子方面的重要作用,这为精神和神经疾病的病因学提供了启示,因为与这些疾病相关的基因变异主要位于非编码调控区。我们还描述了调控神经元染色质折叠和基因表达的分子机制。此外,我们还介绍了从进化角度进行的研究,这些研究调查了从小鼠到人类的保守特征,以及人类获得的三维染色质特征。尽管有关疾病和分子机制的大部分见解都是从基于 3C 的大量实验中获得的,但我们也重点介绍了最近开发的其他方法,如单细胞 3C 方法和非 3C 方法。在对未来的展望中,我们强调了目前知识中的空白,并强调需要三维基因组工程和活细胞成像方法来分别阐明染色质相互作用的机制和时间动态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The 3D Genome in Brain Development: An Exploration of Molecular Mechanisms and Experimental Methods.

The human brain contains multiple cell types that are spatially organized into functionally distinct regions. The proper development of the brain requires complex gene regulation mechanisms in both neurons and the non-neuronal cell types that support neuronal function. Studies across the last decade have discovered that the 3D nuclear organization of the genome is instrumental in the regulation of gene expression in the diverse cell types of the brain. In this review, we describe the fundamental biochemical mechanisms that regulate the 3D genome, and comprehensively describe in vitro and ex vivo studies on mouse and human brain development that have characterized the roles of the 3D genome in gene regulation. We highlight the significance of the 3D genome in linking distal enhancers to their target promoters, which provides insights on the etiology of psychiatric and neurological disorders, as the genetic variants associated with these disorders are primarily located in noncoding regulatory regions. We also describe the molecular mechanisms that regulate chromatin folding and gene expression in neurons. Furthermore, we describe studies with an evolutionary perspective, which have investigated features that are conserved from mice to human, as well as human gained 3D chromatin features. Although most of the insights on disease and molecular mechanisms have been obtained from bulk 3C based experiments, we also highlight other approaches that have been developed recently, such as single cell 3C approaches, as well as non-3C based approaches. In our future perspectives, we highlight the gaps in our current knowledge and emphasize the need for 3D genome engineering and live cell imaging approaches to elucidate mechanisms and temporal dynamics of chromatin interactions, respectively.

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来源期刊
Neuroscience Insights
Neuroscience Insights Neuroscience-Neuroscience (all)
CiteScore
6.10
自引率
0.00%
发文量
24
审稿时长
9 weeks
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