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CAF-I对酿酒酵母后期促进复合物介导的有丝分裂染色质组装的作用。

Contribution of CAF-I to anaphase-promoting-complex-mediated mitotic chromatin assembly in Saccharomyces cerevisiae.

作者信息

Harkness Troy A A, Arnason Terra G, Legrand Charmaine, Pisclevich Marnie G, Davies Gerald F, Turner Emma L

机构信息

Department of Anatomy and Cell Biology, College of Medicine, University of Saskatchewan, Saskatoon, Saskatchewan, Canada.

出版信息

Eukaryot Cell. 2005 Apr;4(4):673-84. doi: 10.1128/EC.4.4.673-684.2005.

DOI:10.1128/EC.4.4.673-684.2005
PMID:15821127
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1087812/
Abstract

The anaphase-promoting complex (APC) is required for mitotic progression and genomic stability. Recently, we demonstrated that the APC is also required for mitotic chromatin assembly and longevity. Here, we investigated the role the APC plays in chromatin assembly. We show that apc5(CA) mutations genetically interact with the CAF-I genes as well as ASF1, HIR1, and HIR2. When present in multiple copies, the individual CAF-I genes, CAC1, CAC2, and MSI1, suppress apc5(CA) phenotypes in a CAF-1- and Asf1p-independent manner. CAF-I and the APC functionally overlap, as cac1delta cac2delta msi1delta (caf1delta) cells expressing apc5(CA) exhibit a phenotype more severe than that of apc5(CA) or caf1delta. The Ts- phenotypes observed in apc5(CA) and apc5(CA) caf mutants may be rooted in compromised histone metabolism, as coexpression of histones H3 and H4 suppressed the Ts- defects. Synthetic genetic interactions were also observed in apc5(CA) asf1delta cells. Furthermore, increased expression of genes encoding Asf1p, Hir1p, and Hir2p suppressed the apc5(CA) Ts- defect in a CAF-I-dependent manner. Together, these results suggest the existence of a complex molecular mechanism controlling APC-dependent chromatin assembly. Our data suggest the APC functions with the individual CAF-I subunits, Asf1p, and the Hir1p and Hir2p proteins. However, Asf1p and an intact CAF-I complex are dispensable for CAF-I subunit suppression, whereas CAF-I is necessary for ASF1, HIR1, and HIR2 suppression of apc5(CA) phenotypes. We discuss the implications of our observations.

摘要

后期促进复合物(APC)是有丝分裂进程和基因组稳定性所必需的。最近,我们证明APC也是有丝分裂染色质组装和寿命所必需的。在这里,我们研究了APC在染色质组装中所起的作用。我们发现apc5(CA)突变与CAF-I基因以及ASF1、HIR1和HIR2在遗传上相互作用。当以多拷贝存在时,单个CAF-I基因CAC1、CAC2和MSI1以不依赖CAF-1和Asf1p的方式抑制apc5(CA)表型。CAF-I和APC在功能上重叠,因为表达apc5(CA)的cac1delta cac2delta msi1delta(caf1delta)细胞表现出比apc5(CA)或caf1delta更严重的表型。在apc5(CA)和apc5(CA)caf突变体中观察到的温度敏感(Ts-)表型可能源于受损的组蛋白代谢,因为组蛋白H3和H4的共表达抑制了Ts-缺陷。在apc5(CA)asf1delta细胞中也观察到了合成遗传相互作用。此外,编码Asf1p、Hir1p和Hir2p的基因的表达增加以依赖CAF-I的方式抑制了apc5(CA)的Ts-缺陷。总之,这些结果表明存在一种控制APC依赖性染色质组装的复杂分子机制。我们的数据表明APC与单个CAF-I亚基、Asf1p以及Hir1p和Hir2p蛋白一起发挥作用。然而,Asf1p和完整的CAF-I复合物对于CAF-I亚基的抑制是可有可无的,而CAF-I对于ASF1、HIR1和HIR2对apc5(CA)表型的抑制是必需的。我们讨论了我们观察结果的意义。

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