Both phosphorylation and phosphatase activity of PTEN are required to prevent replication fork progression during stress by inducing heterochromatin

IF 1.5 4区医学 Q4 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Mutation Research-Fundamental and Molecular Mechanisms of Mutagenesis Pub Date : 2022-07-01 DOI:10.1016/j.mrfmmm.2022.111800

Sandip Misra , Sougata Ghosh Chowdhury , Ginia Ghosh , Ananda Mukherjee , Parimal Karmakar

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引用次数: 2

Abstract

PTEN is a tumor suppressor protein frequently altered in various cancers. PTEN-null cells have a characteristic of rapid proliferation with an unstable genome. Replication stress is one of the causes of the accumulation of genomic instability if not sensed by the cellular signaling. Though PTEN-null cells have shown to be impaired in replication progression and stalled fork recovery, the association between the catalytic function of PTEN regulated by posttranslational modulation and cellular response to replication stress has not been studied explicitly. To understand molecular mechanism, we find that PTEN-null cells display unrestrained replication fork progression with accumulation of damaged DNA after treatment with aphidicolin which can be rescued by ectopic expression of full-length PTEN, as evident from DNA fiber assay. Moreover, the C-terminal phosphorylation (Ser 380, Thr 382/383) of PTEN is essential for its chromatin association and sensing replication stress that, in response, induce cell cycle arrest. Further, we observed that PTEN induces HP1α expression and H3K9me3 foci formation in a C-terminal phosphorylation-dependent manner. However, phosphatase dead PTEN cannot sense replication stress though it can be associated with chromatin. Together, our results suggest that DNA replication perturbation by aphidicolin enables chromatin association of PTEN through C-terminal phosphorylation, induces heterochromatin formation by stabilizing and up-regulating H3K9me3 foci and augments CHK1 activation. Thereby, PTEN prevents DNA replication fork elongation and simultaneously causes G1-S phase cell cycle arrest to limit cell proliferation in stress conditions. Thus PTEN act as stress sensing protein during replication arrest to maintain genomic stability.

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在逆境中，PTEN的磷酸化和磷酸酶活性都需要通过诱导异染色质来阻止复制叉的进展

PTEN是一种肿瘤抑制蛋白，在各种癌症中经常发生改变。PTEN-null细胞具有快速增殖和基因组不稳定的特点。复制胁迫是基因组不稳定性积累的原因之一，如果不被细胞信号所感知。尽管PTEN缺失的细胞在复制过程中受损，分叉恢复停滞，但翻译后调节的PTEN的催化功能与细胞对复制应激的反应之间的关系尚未得到明确的研究。为了了解分子机制，我们发现PTEN-null细胞在aphidicolin处理后表现出无限制的复制叉进展，并积累受损的DNA，这可以通过全长PTEN的异位表达来挽救，这一点从DNA纤维检测中可以看出。此外，PTEN的c端磷酸化(Ser 380, Thr 382/383)对于其染色质关联和感知复制应激至关重要，从而诱导细胞周期阻滞。此外，我们观察到PTEN以c端磷酸化依赖的方式诱导HP1α表达和H3K9me3病灶形成。然而，磷酸酶死亡的PTEN虽然可以与染色质相关，但不能感知复制应激。总之，我们的研究结果表明，aphidicolin对DNA复制的干扰通过c端磷酸化使PTEN的染色质结合，通过稳定和上调H3K9me3位点诱导异染色质形成，并增强CHK1的激活。因此，PTEN阻止DNA复制叉伸长，同时导致G1-S期细胞周期阻滞，以限制应激条件下的细胞增殖。因此，PTEN在复制停滞期间作为应激传感蛋白，以维持基因组的稳定性。

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

Mutation Research-Fundamental and Molecular Mechanisms of Mutagenesis 生物-毒理学

CiteScore

4.90

自引率

0.00%

发文量

审稿时长

51 days

期刊介绍： Mutation Research (MR) provides a platform for publishing all aspects of DNA mutations and epimutations, from basic evolutionary aspects to translational applications in genetic and epigenetic diagnostics and therapy. Mutations are defined as all possible alterations in DNA sequence and sequence organization, from point mutations to genome structural variation, chromosomal aberrations and aneuploidy. Epimutations are defined as alterations in the epigenome, i.e., changes in DNA methylation, histone modification and small regulatory RNAs. MR publishes articles in the following areas: Of special interest are basic mechanisms through which DNA damage and mutations impact development and differentiation, stem cell biology and cell fate in general, including various forms of cell death and cellular senescence. The study of genome instability in human molecular epidemiology and in relation to complex phenotypes, such as human disease, is considered a growing area of importance. Mechanisms of (epi)mutation induction, for example, during DNA repair, replication or recombination; novel methods of (epi)mutation detection, with a focus on ultra-high-throughput sequencing. Landscape of somatic mutations and epimutations in cancer and aging. Role of de novo mutations in human disease and aging; mutations in population genomics. Interactions between mutations and epimutations. The role of epimutations in chromatin structure and function. Mitochondrial DNA mutations and their consequences in terms of human disease and aging. Novel ways to generate mutations and epimutations in cell lines and animal models.