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组蛋白H2B的结构域和N端的突变可绕过酵母中Swi-Snf的需求。

Mutations in both the structured domain and N-terminus of histone H2B bypass the requirement for Swi-Snf in yeast.

作者信息

Recht J, Osley M A

机构信息

Program in Molecular Biology, Sloan Kettering Cancer Center and Cornell University Graduate School of Medical Sciences, New York, NY 10021, USA.

出版信息

EMBO J. 1999 Jan 4;18(1):229-40. doi: 10.1093/emboj/18.1.229.

DOI:10.1093/emboj/18.1.229
PMID:9878065
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1171117/
Abstract

The chromatin elements targeted by the ATPdependent, Swi-Snf nucleosome-remodeling complex are unknown. To address this question, we generated mutations in yeast histone H2B that suppress phenotypes associated with the absence of Swi-Snf. Sin- (Swi-Snf-independent) mutations occur in residues involved in H2A-H2B dimer formation, dimer- tetramer association, and in the H2B N-terminus. The strongest and most pleiotropic Sin- mutation removed 20 amino acid residues from the H2B N-terminus. This mutation allowed active chromatin to be formed at the SUC2 locus in a snf5Delta mutant and resulted in hyperactivated levels of SUC2 mRNA under inducing conditions. Thus, the H2B N-terminus may be an important target of Swi-Snf in vivo. The GCN5 gene product, the catalytic subunit of several nuclear histone acetytransferase complexes that modify histone N-termini, was also found to act in conjunction with Swi-Snf. The phenotypes of double gcn5Deltasnf5Delta mutants suggest that histone acetylation may play both positive and negative roles in the activity of the Swi-Snf-remodeling factor.

摘要

依赖ATP的Swi-Snf核小体重塑复合体所靶向的染色质元件尚不清楚。为了解决这个问题,我们在酵母组蛋白H2B中产生了突变,这些突变可抑制与Swi-Snf缺失相关的表型。Swi-Snf非依赖型(Sin-)突变发生在参与H2A-H2B二聚体形成、二聚体-四聚体缔合以及H2B N端的残基中。最强且多效性的Sin-突变从H2B N端去除了20个氨基酸残基。该突变使得在snf5Δ突变体的SUC2基因座处能够形成活性染色质,并导致在诱导条件下SUC2 mRNA水平过度激活。因此,H2B N端可能是Swi-Snf在体内的一个重要靶点。还发现GCN5基因产物(几种修饰组蛋白N端的核组蛋白乙酰转移酶复合体的催化亚基)与Swi-Snf协同作用。双gcn5Δsnf5Δ突变体的表型表明,组蛋白乙酰化可能在Swi-Snf重塑因子的活性中发挥正负两方面的作用。

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Mutations in chromatin components suppress a defect of Gcn5 protein in Saccharomyces cerevisiae.染色质成分的突变抑制了酿酒酵母中Gcn5蛋白的缺陷。
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