The macro and micro of chromosome conformation capture.

Q1 Biochemistry, Genetics and Molecular Biology Wiley Interdisciplinary Reviews: Developmental Biology Pub Date : 2021-11-01 Epub Date: 2020-09-28 DOI:10.1002/wdev.395
Viraat Y Goel, Anders S Hansen
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引用次数: 22

Abstract

The 3D organization of the genome facilitates gene regulation, replication, and repair, making it a key feature of genomic function and one that remains to be properly understood. Over the past two decades, a variety of chromosome conformation capture (3C) methods have delineated genome folding from megabase-scale compartments and topologically associating domains (TADs) down to kilobase-scale enhancer-promoter interactions. Understanding the functional role of each layer of genome organization is a gateway to understanding cell state, development, and disease. Here, we discuss the evolution of 3C-based technologies for mapping 3D genome organization. We focus on genomics methods and provide a historical account of the development from 3C to Hi-C. We also discuss ChIP-based techniques that focus on 3D genome organization mediated by specific proteins, capture-based methods that focus on particular regions or regulatory elements, 3C-orthogonal methods that do not rely on restriction digestion and proximity ligation, and methods for mapping the DNA-RNA and RNA-RNA interactomes. We consider the biological discoveries that have come from these methods, examine the mechanistic contributions of CTCF, cohesin, and loop extrusion to genomic folding, and detail the 3D genome field's current understanding of nuclear architecture. Finally, we give special consideration to Micro-C as an emerging frontier in chromosome conformation capture and discuss recent Micro-C findings uncovering fine-scale chromatin organization in unprecedented detail. This article is categorized under: Gene Expression and Transcriptional Hierarchies > Regulatory Mechanisms Gene Expression and Transcriptional Hierarchies > Gene Networks and Genomics.

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染色体构象捕获的宏观和微观。
基因组的3D组织促进了基因调控、复制和修复,使其成为基因组功能的一个关键特征,还有待正确理解。在过去的二十年里,各种染色体构象捕获(3C)方法已经描述了基因组折叠,从兆碱基规模的区室和拓扑相关结构域(TAD)到千碱基规模的增强子-启动子相互作用。了解基因组组织每一层的功能作用是了解细胞状态、发育和疾病的途径。在这里,我们讨论了绘制3D基因组组织图的基于3C的技术的演变。我们专注于基因组学方法,并提供了从3C到Hi-C发展的历史记录。我们还讨论了基于ChIP的技术,该技术专注于由特定蛋白质介导的3D基因组组织,基于捕获的方法,该方法专注于特定区域或调控元件,不依赖于限制性消化和邻近连接的3C正交方法,以及绘制DNA-RNA和RNA-RNA相互作用体的方法。我们考虑了这些方法的生物学发现,研究了CTCF、粘蛋白和环挤压对基因组折叠的机制贡献,并详细介绍了3D基因组领域目前对核结构的理解。最后,我们特别考虑了Micro-C作为染色体构象捕获的一个新兴前沿,并以前所未有的细节讨论了最近Micro-C发现的精细染色质组织。本文分类如下:基因表达和转录层次结构>调控机制基因表达和翻译层次结构>基因网络和基因组学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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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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