Molecular mechanisms of proliferative senescence and genomic instability in Werner syndrome and the WRN gene network.

IF 1.3 4区生物学 Q4 CELL BIOLOGY

Cytogenetic and Genome Research Pub Date : 2025-09-19 DOI:10.1159/000548500

Martin Poot

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引用次数: 0

Abstract

Background: Ageing is a general, intrinsic and progressively deleterious process that affects all cells, tissues and organs albeit at different extent and rate in each individual. The complexity and universality of its phenotypic manifestations suggest a multifactorial origin. The autosomal recessive disorder Werner syndrome likely represents a segmental progeroid disorder since patients show several, but not all phenotypes of premature ageing.

Summary: Proliferative senescence of diploid cells in culture provided a model system in which ageing can be studied experimentally. Cultures of cells from patients with Werner syndrome experienced an extreme form of proliferative senescence and a clonal succession of translocations, known as variegated translocation mosaicism. In addition, Werner syndrome cells showed spontaneous deletion formation and a prolongation of and arrest in the S phase of the cell cycle. The WRN protein harbors a helicase, an exonuclease and a RecQ interaction domain. With the latter the WRN protein may interact with NBS1, RPA, MRE11, TREX1, MUTYH, POT1, TRF1, FEN-1, PAPRP-1, p97/VCP, TRF2, DNA polymerase(beta), Ku76/80, EXO-1, NEIL1, and p53, which are key to DNA damage response pathways including canonical NHEJ, homologous recombination, base excision repair and telomere maintenance. The WRN exonuclease domain is a target of WRNIP1 binding, which links WRN to resolution of stalled replication due to collision with transcription and the ATM-mediated cell cycle checkpoint. . Patients with an incomplete complement of Werner syndrome phenotypes, called atypical Werner syndrome patients, were found to carry variants in LMNA, POLD1, SPRTN, MDM2, CTC1, SAMHD1.

Key messages: These findings broaden the genotypic landscape and the phenotypic spectrum of Werner syndrome. In this review potential molecular mechanisms underlying genomic instability in Werner syndrome, including chromothripsis due to asynchronous S phase traverse and telomere crises followed by bridge fusion breakage cycles are discussed. The participation of WRN in multiple gene networks is consistent with the multifactorial nature of ageing in general.

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Werner综合征和WRN基因网络中增殖性衰老和基因组不稳定的分子机制。

背景：衰老是一个普遍的、内在的、逐渐有害的过程，它影响到所有的细胞、组织和器官，尽管在每个人身上的程度和速度不同。其表型表现的复杂性和普遍性表明其多因素起源。常染色体隐性遗传病Werner综合征可能代表一种节段性类早衰症，因为患者表现出几种，但不是所有的早衰表型。摘要：培养二倍体细胞的增殖衰老为衰老的实验研究提供了一个模型系统。来自维尔纳综合征患者的细胞培养经历了极端形式的增殖性衰老和易位的克隆继承，称为杂色易位镶嵌。此外，Werner综合征细胞表现为自发缺失形成，细胞周期S期延长和停滞。WRN蛋白含有解旋酶、核酸外切酶和RecQ相互作用结构域。对于后者，WRN蛋白可与NBS1、RPA、MRE11、TREX1、MUTYH、POT1、TRF1、fen1、PAPRP-1、p97/VCP、TRF2、DNA聚合酶（β）、Ku76/80、EXO-1、NEIL1和p53等DNA损伤应答通路相互作用，这些通路是典型NHEJ、同源重组、碱基切除修复和端粒维持等DNA损伤应答通路的关键。WRN外切酶结构域是WRNIP1结合的靶标，它将WRN与转录和atm介导的细胞周期检查点碰撞导致的停滞复制的解决联系起来。Werner综合征表型不完全补体的患者称为非典型Werner综合征患者，发现其携带LMNA、POLD1、SPRTN、MDM2、CTC1、SAMHD1的变异。这些发现拓宽了维尔纳综合征的基因型格局和表型谱。本文讨论了Werner综合征基因组不稳定的潜在分子机制，包括由于异步S相穿越和端粒危机导致的染色体断裂，以及随后的桥融合断裂周期。一般来说，WRN参与多基因网络与衰老的多因子性质是一致的。

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

Cytogenetic and Genome Research 生物-细胞生物学

CiteScore

3.10

自引率

5.90%

发文量

审稿时长

1 months

期刊介绍： During the last decades, ''Cytogenetic and Genome Research'' has been the leading forum for original reports and reviews in human and animal cytogenetics, including molecular, clinical and comparative cytogenetics. In recent years, most of its papers have centered on genome research, including gene cloning and sequencing, gene mapping, gene regulation and expression, cancer genetics, comparative genetics, gene linkage and related areas. The journal also publishes key papers on chromosome aberrations in somatic, meiotic and malignant cells. Its scope has expanded to include studies on invertebrate and plant cytogenetics and genomics. Also featured are the vast majority of the reports of the International Workshops on Human Chromosome Mapping, the reports of international human and animal chromosome nomenclature committees, and proceedings of the American and European cytogenetic conferences and other events. In addition to regular issues, the journal has been publishing since 2002 a series of topical issues on a broad variety of themes from cytogenetic and genome research.