沉默信息调节复合物在酵母转录调节和 DNA 损伤反应中的双重活动

IF 4.5 Q1 MICROBIOLOGY mLife Pub Date : 2024-05-15 DOI:10.1002/mlf2.12108
Josephine Rybchuk, Wei Xiao
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引用次数: 0

摘要

酿酒酵母(Saccharomyces cerevisiae)沉默信息调节因子(silencing information regulator,SIR)复合体包含多达四个蛋白,即Sir1、Sir2、Sir3和Sir4。 Sir2编码一种NAD依赖性组蛋白去乙酰化酶,其他SIR蛋白主要通过与各种蛋白的物理相互作用发挥结构和支架元件的功能。SIR复合体的构象和组成各不相同,包括Sir2同源三聚体、Sir1-4异源四聚体、Sir2-4异源三聚体及其衍生物,它们循环往复地迁移到不同的染色体区域。SIR 复合物的主要活动是通过染色体重塑和 DNA 双断裂修复途径的调节来抑制转录。这些活动使 SIR 复合物能够参与交配类型的维持和转换、端粒和副端粒基因沉默、促进非同源末端连接、抑制同源重组以及控制细胞衰老。本综述探讨了 SIR 复合物在各种条件下赋予表观遗传调控和 DNA 损伤反应之间的潜在联系,旨在了解其在平衡细胞存活和基因组稳定性以应对内部和环境压力方面的作用。由于 SIR 复合物的核心活动在真核生物(从酵母到人类)中高度保守,在酵母中获得的知识可能适用于哺乳动物的 Sirtuin 同源物和相关疾病。
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Dual activities of a silencing information regulator complex in yeast transcriptional regulation and DNA‐damage response
The Saccharomyces cerevisiae silencing information regulator (SIR) complex contains up to four proteins, namely Sir1, Sir2, Sir3, and Sir4. While Sir2 encodes a NAD‐dependent histone deacetylase, other SIR proteins mainly function as structural and scaffold components through physical interaction with various proteins. The SIR complex displays different conformation and composition, including Sir2 homotrimer, Sir1‐4 heterotetramer, Sir2‐4 heterotrimer, and their derivatives, which recycle and relocate to different chromosomal regions. Major activities of the SIR complex are transcriptional silencing through chromosomal remodeling and modulation of DNA double‐strand‐break repair pathways. These activities allow the SIR complex to be involved in mating‐type maintenance and switching, telomere and subtelomere gene silencing, promotion of nonhomologous end joining, and inhibition of homologous recombination, as well as control of cell aging. This review explores the potential link between epigenetic regulation and DNA damage response conferred by the SIR complex under various conditions aiming at understanding its roles in balancing cell survival and genomic stability in response to internal and environmental stresses. As core activities of the SIR complex are highly conserved in eukaryotes from yeast to humans, knowledge obtained in the yeast may apply to mammalian Sirtuin homologs and related diseases.
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