Piecing together cis-regulatory networks: insights from epigenomics studies in plants.

IF 7.9 Q1 Medicine
Shao-Shan C Huang, Joseph R Ecker
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引用次数: 16

Abstract

5-Methylcytosine, a chemical modification of DNA, is a covalent modification found in the genomes of both plants and animals. Epigenetic inheritance of phenotypes mediated by DNA methylation is well established in plants. Most of the known mechanisms of establishing, maintaining and modifying DNA methylation have been worked out in the reference plant Arabidopsis thaliana. Major functions of DNA methylation in plants include regulation of gene expression and silencing of transposable elements (TEs) and repetitive sequences, both of which have parallels in mammalian biology, involve interaction with the transcriptional machinery, and may have profound effects on the regulatory networks in the cell. Methylome and transcriptome dynamics have been investigated in development and environmental responses in Arabidopsis and agriculturally and ecologically important plants, revealing the interdependent relationship among genomic context, methylation patterns, and expression of TE and protein coding genes. Analyses of methylome variation among plant natural populations and species have begun to quantify the extent of genetic control of methylome variation vs. true epimutation, and model the evolutionary forces driving methylome evolution in both short and long time scales. The ability of DNA methylation to positively or negatively modulate binding affinity of transcription factors (TFs) provides a natural link from genome sequence and methylation changes to transcription. Technologies that allow systematic determination of methylation sensitivities of TFs, in native genomic and methylation context without confounding factors such as histone modifications, will provide baseline datasets for building cell-type- and individual-specific regulatory networks that underlie the establishment and inheritance of complex traits. This article is categorized under: Laboratory Methods and Technologies > Genetic/Genomic Methods Biological Mechanisms > Regulatory Biology.

拼凑顺式调控网络:来自植物表观基因组学研究的见解。
5-甲基胞嘧啶是DNA的一种化学修饰,是在植物和动物基因组中发现的共价修饰。DNA甲基化介导的表型表观遗传在植物中已经得到了很好的证实。大多数已知的DNA甲基化的建立、维持和修饰机制已经在参考植物拟南芥中得到了阐明。植物DNA甲基化的主要功能包括调控基因表达、转座因子(te)和重复序列的沉默,这两者在哺乳动物生物学中都有相似之处,涉及与转录机制的相互作用,并可能对细胞中的调控网络产生深远的影响。甲基组和转录组动力学在拟南芥和重要的农业和生态植物的发育和环境响应中进行了研究,揭示了基因组背景、甲基化模式、TE和蛋白质编码基因表达之间的相互依存关系。对植物自然种群和物种中甲基组变异的分析已经开始量化甲基组变异与真正进化的遗传控制程度,并在短期和长期尺度上模拟驱动甲基组进化的进化力量。DNA甲基化正或负调节转录因子结合亲和力的能力为基因组序列和甲基化变化与转录之间提供了天然的联系。在原生基因组和甲基化背景下,不受组蛋白修饰等混杂因素的影响,能够系统地测定tf甲基化敏感性的技术,将为构建细胞类型和个体特异性调控网络提供基线数据集,这些网络是复杂性状建立和遗传的基础。本文分类如下:实验室方法和技术>遗传/基因组方法生物学机制>调控生物学。
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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来源期刊
CiteScore
18.40
自引率
0.00%
发文量
0
审稿时长
>12 weeks
期刊介绍: Journal Name:Wiley Interdisciplinary Reviews-Systems Biology and Medicine Focus: Strong interdisciplinary focus Serves as an encyclopedic reference for systems biology research Conceptual Framework: Systems biology asserts the study of organisms as hierarchical systems or networks Individual biological components interact in complex ways within these systems Article Coverage: Discusses biology, methods, and models Spans systems from a few molecules to whole species Topical Coverage: Developmental Biology Physiology Biological Mechanisms Models of Systems, Properties, and Processes Laboratory Methods and Technologies Translational, Genomic, and Systems Medicine
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