ATM、ATR和DNA损伤介导的细胞周期阻滞

ATM和ATR属于PIKK家族,是DNA损伤检查点的主要成员。它们被不同类型的DNA损伤所激活,通过磷酸化相应的下游蛋白Chk1和Chk2等,调节细胞周期各个检查点,引起细胞周期阻滞,使DNA损伤得以修复。ATM和ATR在维持基因组的稳定性中起到至关重要的作用。本文着重综述有关ATM和ATR在DNA损伤介导的细胞周期阻滞中发挥的作用以及相互关系的最新研究进展。     

DNA双链断裂损伤反应及它的医学意义

DNA损伤应激反应是维持基因组稳定性的基石.细胞在长期进化中形成了由损伤监视、周期调控、损伤修复、凋亡诱导等在内的自稳平衡机制.一方面,借助感应、识别并启动精细而复杂的修复机制修复损伤;另一方面,通过DNA损伤应激活化的细胞周期检查点机制,延迟或阻断细胞周期进程,为损伤修复提供时间,使细胞能安全进入新一轮细胞周期;损伤无法修复时则诱导细胞凋亡.DNA双链断裂(double strand breaks,DSBs)是真核基因组后果最严重的损伤类型之一,其修复不利,同肿瘤等人类疾病的发生发展密切相关.新进展揭示:DSBs损伤反应信号分子ATM-Chk2-p53、H2AX等的组成性活化,是肿瘤形成早期所激活的细胞内可诱导的抗癌屏障,其信号网络的精确、精细调控在基因组稳定性维持中发挥重要作用.此外,HIV病毒整合进入宿主细胞基因组的过程也依赖于宿主细胞中ATM介导的DSBs损伤反应信号转导;ATM特异性的小分子抑制剂在抗HIV感染中显示重要的功能意义.文中重点讨论调控DSBs损伤应激反应信号网络的主要研究进展,及其在肿瘤发生、发展及抗HIV感染中的新医学意义.     

检验点激酶1的研究进展

检验点激酶1(checkpointkinase1,Chk1)为一种进化保守的蛋白激酶,是细胞检验点的转导因子。当电离辐射、紫外线等引起细胞DNA损伤或者DNA复制叉停滞时Chk1活化,诱导细胞产生细胞周期阻滞、DNA修复或细胞凋亡等特征。现对Chk1的结构、功能以及病毒通过Chk1调控宿主细胞周期等方面进行简述。     

表观遗传调控：基于染色质环境的DNA双链断裂修复

DNA双链断裂（DNA double-strand breaks, DSBs）是威胁基因组完整性和细胞存活的最有害的DNA损伤类型。同源重组（homologous recombination,HR）和非同源末端连接（non-homologous end joining,NHEJ）是修复DNA双链断裂的两种主要途径。DSB修复涉及到损伤部位修复蛋白的募集和染色质结构的改变。在DNA双链断裂诱导下,染色质结构的动态变化在时间和空间上受到严格调控,进而对DNA双链断裂修复过程进行精细调节。特定的染色质修饰形成利于修复的染色质状态,有助于DNA双链断裂修复机器的招募、修复途径的选择和DNA损伤检查点的活化;其中修复途径的选择对于基因组稳定性至关重要。修复不当或失败可导致基因组不稳定性,甚至促进肿瘤的发生。本文综述了染色质结构和染色质修饰的动态变化在DSB修复中的重要作用。此外,文章还总结了在癌症治疗中靶向关键染色质调控因子在基因组稳定性维持、肿瘤发生发展以及潜在临床应用价值等方面的进展。     

拟南芥多聚ADP核糖水解酶在ATM和ATR依赖的DNA损伤信号途径中的作用分析

DNA损伤响应是生物体感知DNA断裂并启动DNA修复过程的重要机制,对维护遗传物质的稳定性具有重要的意义.DNA损伤响应机制中有多种蛋白的参与.多聚ADP核糖水解酶(PARG)是参与蛋白质多聚ADP核糖化(poly(ADP-ribosyl)ation)修饰调控过程的一种重要酶,它通过水解去除蛋白质上的多聚ADP核糖来调节靶蛋白质的生理生化活性.目前已知多聚ADP核糖修饰相关蛋白可能通过修饰DNA修复相关蛋白参与DNA损伤反应,但其影响的信号途径和上下游关系并不清楚.本研究通过双突变体构建、遗传以及表达谱分析,揭示了PARG1可能在DNA损伤响应途径关键激酶ATM和ATR的上游,通过调节ATM和ATR的活性来反馈调节DNA损伤信号途径.     

泛素E3连接酶接头蛋白SPOP和MDM2在DNA损伤修复中的作用

DNA损伤修复是维持细胞基因组稳定性和完整性的基础,越来越多的研究发现,E3泛素连接酶在DNA损伤修复中起着重要的作用。该文将介绍DNA损伤修复的机制、DNA损伤修复与疾病的关系、及E3泛素连接酶接头蛋白MDM2和SPOP在DNA损伤修复中的作用。重点围绕DNA损伤修复的两条通路:E3泛素连接酶接头蛋白SPOP与ATM/ATR信号通路以及MDM2/p53信号通路对DNA修复的分子机制进行总结,以期为DNA损伤修复提供新思路。     

c-Abl与应激损伤调控

非受体酪氨酸激酶c-Abl广泛表达于人和哺乳动物等的细胞中并受到严格调控,通过蛋白之间相互作用、与DNA相互作用及其酪氨酸激酶活性在一系列的重要生命活动中发挥调节作用。在应激损伤反应如DNA损伤反应中．c-Abl的Ser^465被ATM和DNA-PK磷酸化而激活,通过与Rad51、p53和p73等分子的相互作用参与DNA重组修复、细胞周期和细胞凋亡等的调控,不同信号途径之间的平衡决定细胞的生存和死亡。     

DNA损伤检验点调控的分子机制

多种因素可以引起DNA损伤而最终导致基因产生错义突变、缺失或错误重组。为确保遗传准确性,细胞形成了复杂的细胞周期监督机制,即细胞周期检验点。其中DNA损伤检验点由许多检验点相关蛋白组成,可以识别损伤的DNA,经复杂的信号转导途径引发蛋白激酶的级联反应,减慢或阻滞细胞周期进程,从而为细胞修复损伤的DNA赢得时间。     

共济失调毛细血管扩张症突变基因与端粒不稳定性关系研究进展

在电离辐射等因素造成的DNA损伤修复信号传导过程中,共济失调毛细血管扩张症突变基因(ATM)起关键作用。同时,ATM属于P13K家族成员,其功能与保持端粒长度有关。端粒是真核细胞内染色体末端的重复的DNA序列,端粒的长短和稳定性决定了细胞的寿命。ATM突变导致端粒的不稳定性,包括端粒连接、端粒染色质结构变化,影响端粒聚集等。     

53BP1与DNA双链断裂损伤修复

DNA的精确复制和遗传对维持基因组稳定性有重要作用。DNA双链断裂损伤可能诱导细胞凋亡和染色质重排,在肿瘤的发生发展过程中发挥作用。53BP1是DNA双链断裂修复中的重要调节蛋白质之一,对调控损伤修复平衡和维持基因组稳定性起着重要作用。本文主要对53BP1的结构、生物学功能、信号通路、分子机制和翻译后修饰做一浅显的总结和展望,希望能为53BP1的深入研究提供一些理论基础。     

DNA Damage Checkpoint, Damage Repair, and Genome Stability

Genomic DNA is under constant attack from both endogenous and exogenous sources of DNA damaging agents. Without proper care, the ensuing DNA damages would lead to alteration of genomic structure thus affecting the faithful transmission of genetic information. During the process of evolution, organisms have acquired a series of mechanisms responding to and repairing DNA damage, thus assuring the maintenance of genome stability and faithful transmission of genetic information. DNA damage checkpoint is one such important mechanism by which, in the face of DNA damage, a cell can respond to amplified damage signals, either by actively halting the cell cycle until it ensures that critical processes such as DNA replication or mitosis are complete or by initiating apoptosis as a last resort. Over the last decade, complex hierarchical interactions between the key components like ATM/ATR in the checkpoint pathway and various other mediators, effectors including DNA damage repair proteins have begun to emerge. In the meantime, an intimate relationship between mechanisms of damage checkpoint pathway, DNA damage repair, and genome stability was also uncovered. Reviewed hereinare the recent findings on both the mechanisms of activation of checkpoint pathways and their coordination with DNA damage repair machinery as well as their effect on genomic integrity.     

DNA Damage Checkpoints and Cancer

DNA damage checkpoint is one of the surveillance systems to maintain genomic integrity. Checkpoint systems sense the DNA damage and execute cell cycle arrest through inhibiting the activity of cell cycle regulators. This pathway is essential for the maintenance of genome stability and prevention of tumor development. Recent studies have showed that the cellular responses towards DNA damage, such as cell cycle arrest, DNA repair, chromatin remodeling, and apoptosis are well coordinated. Here we describe the molecular mechanisms of checkpoint activation in response to DNA damage and the correlation between checkpoint gene mutation and genomic instability.     

The fission yeast Crb2/Chk1 pathway coordinates the DNA damage and spindle checkpoint in response to replication stress induced by topoisomerase I inhibitor

Living organisms experience constant threats that challenge their genome stability. The DNA damage checkpoint pathway coordinates cell cycle progression with DNA repair when DNA is damaged, thus ensuring faithful transmission of the genome. The spindle assembly checkpoint inhibits chromosome segregation until all chromosomes are properly attached to the spindle, ensuring accurate partition of the genetic material. Both the DNA damage and spindle checkpoint pathways participate in genome integrity. However, no clear connection between these two pathways has been described. Here, we analyze mutants in the BRCT domains of fission yeast Crb2, which mediates Chk1 activation, and provide evidence for a novel function of the Chk1 pathway. When the Crb2 mutants experience damaged replication forks upon inhibition of the religation activity of topoisomerase I, the Chk1 DNA damage pathway induces sustained activation of the spindle checkpoint, which in turn delays metaphase-to-anaphase transition in a Mad2-dependent fashion. This new pathway enhances cell survival and genome stability when cells undergo replicative stress in the absence of a proficient G(2)/M DNA damage checkpoint.     

细胞DNA损伤检控点

细胞周期检控点是维持细胞基因组稳定性的一个重要机制,主要包括。DNA损伤检控点、DNA复制检控点和纺锤体组装检控点。其中DNA损伤检控点能检测细胞在生命活动过程中出现的DNA损伤并引发细胞周期阻滞,为修复损伤提供足够的时间,以保证细胞遗传的稳定性。有关DNA损伤检控点的研究近年来已经取得了突破性进展,现简要介绍近年来在DNA损伤检控点研究中的一些新进展。     

Checkpoint mechanisms at the intersection between DNA damage and repair

In response to genomic insults cells trigger a signal transduction pathway, known as DNA damage checkpoint, whose role is to help the cell to cope with the damage by coordinating cell cycle progression, DNA replication and DNA repair mechanisms. Accumulating evidence suggests that activation of the first checkpoint kinase in the cascade is not due to the lesion itself, but it requires recognition and initial processing of the lesion by a specific repair mechanism. Repair enzymes likely convert a variety of physically and chemically different lesions to a unique common structure, a ssDNA region, which is the checkpoint triggering signal. Checkpoint kinases can modify the activity of repair mechanisms, allowing for efficient repair, on one side, and modulating the generation of the ssDNA signal, on the other. This strategy may be important to allow the most effective repair and a prompt recovery from the damage condition. Interestingly, at least in some cases, if the damage level is low enough the cell can deal with the lesions and it does not need to activate the checkpoint response. On the other hand if damage level is high or if the lesions are not rapidly repairable, checkpoint mechanisms become important for cell survival and preservation of genome integrity.     

细胞DNA损伤检控系统在维持端粒稳定中的功能

真核生物的DNA损伤检控系统是维持细胞基因组稳定的一个重要机制,该系统能检测细胞在生命活动过程中出现的DNA损伤并引发细胞周期阻滞,对DNA损伤进行修复,以维持细胞遗传的稳定性。端粒是位于真核细胞染色体末端由重复DNA序列和蛋白质组成的复合物,具有保护染色体、介导染色体复制、引导减数分裂时的同源染色体配对和调节细胞衰老等作用。虽然端粒与DNA双链断裂都具有作为线性染色体末端的共同特点,但正常端粒并不像DNA双链断裂那样激活DNA损伤检控系统。另一方面,端粒又与DNA损伤相似,因为多种DNA损伤检控蛋白在端粒长度稳定中起重要作用。因此DNA损伤检控系统既参与了维持正常端粒的完整性,又可对端粒损伤作出应答。现就DNA损伤检控系统在维持端粒稳定中的作用及其对功能缺陷端粒的应答作一简要综述。     

DNA decay and limited Rad53 activation after liquid holding of UV-treated nucleotide excision repair deficient S. cerevisiae cells

The DNA damage checkpoint is a surveillance mechanism activated by DNA lesions and devoted to the maintenance of genome stability. It is considered as a signal transduction cascade, involving a sensing step, the activation of a set of protein kinases and the transmission and amplification of the damage signal through several phosphorylation events. In budding yeast many players of this pathway have been identified. Recent work showed that G1 and G2 checkpoint activation in response to UV irradiation requires prior recognition and processing of UV lesions by nucleotide excision repair (NER) factors that likely recruit checkpoint proteins near the damage. However, another report suggested that NER was not required for checkpoint function. Since the functional relationship between repair mechanisms and checkpoint activation is a very important issue in the field, we analyzed, under different experimental conditions, whether lesion processing by NER is required for checkpoint activation. We found that DNA damage checkpoint can be triggered in an NER-independent manner only if cells are subjected to liquid holding after UV treatment. This incubation causes a time-dependent breakage of DNA strands in NER-deficient cells and leads to partial activation of the checkpoint kinase. The analysis of the genetic requirements for this alternative activation pathway suggest that it requires Mec1 and the Rad17 complex and that the observed DNA breaks are likely to be due to spontaneous decay of damaged DNA.     

The interplay of DNA polymerase λ in diverse DNA damage repair pathways in higher plant genome in response to environmental and genotoxic stress factors

DNA repair mechanisms are essential for the maintenance of genomic stability, proper cellular function and survival for all organisms. Plants, with their intrinsic immobility, are vastly exposed to a wide range of environmental agents and also endogenous processes which frequently cause damage to DNA and impose genotoxic stress. Therefore, in order to survive under frequent and extreme environmental stress conditions, plants have developed a vast array of efficient and powerful DNA damage repair mechanisms to ensure rapid and precise repair of genetic material for maintaining genome stability and faithful transfer of genetic information over generations.¹ Recently, we have defined the role of DNA polymerase λ in repair of UV-B-induced photoproducts in Arabidopsis thaliana via nucleotide excision repair pathway.² Here, we have further discussed potential function of DNA polymerase λ in various DNA repair pathways in higher plant genome in response to environmental and genotoxic stress factors.     

细胞周期检控点

细胞周期是高度有组织的时序调控过程,受到DNA损伤检控点、DNA复制检控点和纺锤体检控点等细胞周期检控点的精确调控。细胞周期检控点的作用主要是调节细胞周期的时序转换,以确保DNA复制、染色体分离等细胞重要生命活动的高度精确性,并对DNA损伤、DNA复制受阻、纺锤体组装和染色体分离异常等细胞损伤及时做出反应,以防止突变和遗传不稳定的发生。细胞周期检控点的功能缺陷,将导致细胞基因组的不稳定,与细胞癌变密切相关。因此细胞周期检控点对于维持细胞遗传信息的稳定性和完整性以及防止细胞癌变和遗传疾病的发生起着至关重要的作用。