用人核小体重设酵母表观基因组

Resetting the Yeast Epigenome with Human Nucleosomes.

作者信息

Truong David M, Boeke Jef D

机构信息

Institute for Systems Genetics, Department of Biochemistry and Molecular Pharmacology, NYU Langone Health, New York, NY 10016, USA.

出版信息

Cell. 2017 Dec 14;171(7):1508-1519.e13. doi: 10.1016/j.cell.2017.10.043. Epub 2017 Nov 30.

DOI:10.1016/j.cell.2017.10.043

PMID:29198523

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5732057/

Abstract

Humans and yeast are separated by a billion years of evolution, yet their conserved histones retain central roles in gene regulation. Here, we "reset" yeast to use core human nucleosomes in lieu of their own (a rare event taking 20 days), which initially only worked with variant H3.1. The cells adapt by acquiring suppressor mutations in cell-division genes or by acquiring certain aneuploid states. Converting five histone residues to their yeast counterparts restored robust growth. We reveal that humanized nucleosomes are positioned according to endogenous yeast DNA sequence and chromatin-remodeling network, as judged by a yeast-like nucleosome repeat length. However, human nucleosomes have higher DNA occupancy, globally reduce RNA content, and slow adaptation to new conditions by delaying chromatin remodeling. These humanized yeasts (including H3.3) pose fundamental new questions about how chromatin is linked to many cell processes and provide a platform to study histone variants via yeast epigenome reprogramming.

摘要

人类和酵母在进化上相隔十亿年，但它们保守的组蛋白在基因调控中仍发挥着核心作用。在这里，我们“重置”酵母，使其使用核心人类核小体来替代自身的核小体（这是一个罕见事件，需要20天），最初这仅适用于变体H3.1。细胞通过在细胞分裂基因中获得抑制突变或获得某些非整倍体状态来适应。将五个组蛋白残基转换为酵母对应物可恢复强劲生长。我们发现，通过类似酵母的核小体重复长度判断，人源化核小体是根据内源性酵母DNA序列和染色质重塑网络定位的。然而，人类核小体具有更高的DNA占有率，会整体降低RNA含量，并通过延迟染色质重塑减缓对新条件的适应。这些人源化酵母（包括H3.3）提出了关于染色质如何与许多细胞过程相关联的全新基本问题，并提供了一个通过酵母表观基因组重编程来研究组蛋白变体的平台。

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