Mutation of the mouse Rad17 gene leads to embryonic lethality and reveals a role in DNA damage-dependent recombination

Genetic defects in DNA repair mechanisms and cell cycle checkpoint (CCC) genes result in increased genomic instability and cancer predisposition. Discovery of mammalian homologs of yeast CCC genes suggests conservation of checkpoint mechanisms between yeast and mammals. However, the role of many CCC genes in higher eukaryotes remains elusive. Here, we report that targeted deletion of an N-terminal part of mRad17, the mouse homolog of the Schizosaccharomyces pombe Rad17 checkpoint clamp-loader component, resulted in embryonic lethality during early/mid-gestation. In contrast to mouse embryos, embryonic stem (ES) cells, isolated from mRad17(5'Delta/5'Delta) embryos, produced truncated mRad17 and were viable. These cells displayed hypersensitivity to various DNA-damaging agents. Surprisingly, mRad17(5'Delta/5'Delta) ES cells were able to arrest cell cycle progression upon induction of DNA damage. However, they displayed impaired homologous recombination as evidenced by a strongly reduced gene targeting efficiency. In addition to a possible role in DNA damage-induced CCC, based on sequence homology, our results indicate that mRad17 has a function in DNA damage-dependent recombination that may be responsible for the sensitivity to DNA-damaging agents.     

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。     

A FOXO-dependent replication checkpoint restricts proliferation of damaged cells

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APOBEC3A damages the cellular genome during DNA replication

The human APOBEC3 family of DNA-cytosine deaminases comprises 7 members (A3A-A3H) that act on single-stranded DNA (ssDNA). The APOBEC3 proteins function within the innate immune system by mutating DNA of viral genomes and retroelements to restrict infection and retrotransposition. Recent evidence suggests that APOBEC3 enzymes can also cause damage to the cellular genome. Mutational patterns consistent with APOBEC3 activity have been identified by bioinformatic analysis of tumor genome sequences. These mutational signatures include clusters of base substitutions that are proposed to occur due to APOBEC3 deamination. It has been suggested that transiently exposed ssDNA segments provide substrate for APOBEC3 deamination leading to mutation signatures within the genome. However, the mechanisms that produce single-stranded substrates for APOBEC3 deamination in mammalian cells have not been demonstrated. We investigated ssDNA at replication forks as a substrate for APOBEC3 deamination. We found that APOBEC3A (A3A) expression leads to DNA damage in replicating cells but this is reduced in quiescent cells. Upon A3A expression, cycling cells activate the DNA replication checkpoint and undergo cell cycle arrest. Additionally, we find that replication stress leaves cells vulnerable to A3A-induced DNA damage. We propose a model to explain A3A-induced damage to the cellular genome in which cytosine deamination at replication forks and other ssDNA substrates results in mutations and DNA breaks. This model highlights the risk of mutagenesis by A3A expression in replicating progenitor cells, and supports the emerging hypothesis that APOBEC3 enzymes contribute to genome instability in human tumors.     

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。     

Identification of the proteome complement of humanTLK1 reveals it binds and phosphorylates NEK1 regulating its activity

The Tousled Like kinases (TLKs) are involved in numerous cellular functions, including the DNA Damage Response (DDR), but only a handful of substrates have been identified thus far. Through a novel proteomic screen, we have now identified 165 human proteins interacting with TLK1, and we have focused this work on NEK1 because of its known role in the DDR, upstream of ATR and Chk1. TLK1 and NEK1 were found to interact by coIP, and their binding is strengthened following exposure of cells to H2O2. Following incubation with doxorubicin, TLK1 and NEK1 relocalize with nuclear repair foci along with γH2AX. TLK1 phosphorylated NEK1 at T141, which lies in the kinase domain, and caused an increase in its activity. Following DNA damage, addition of the TLK1 inhibitor, THD, or overexpression of NEK1-T141A mutant impaired ATR and Chk1 activation, indicating the existence of a TLK1>NEK1>ATR>Chk1 pathway. Indeed, overexpression of the NEK1-T141A mutant resulted in an altered cell cycle response after exposure of cells to oxidative stress, including bypass of G1 arrest and implementation of an intra S-phase checkpoint.     

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损伤检验点与损伤修复及基因组稳定性

生物有机体基因组DNA经常会受到内源或外源因素的影响而导致结构发生变化,产生损伤;在长期进化过程中,有机体也相应形成了一系列应对与修复损伤DNA,并维持染色体基因组正常结构功能的机制。其中DNA损伤检验点（DNA damage checkpoint）就是在感应DNA损伤的基础上,对损伤感应信号进行转导,或引起细胞周期的暂停,从而使细胞有足够的时间对损伤DNA进行修复,或最终导致细胞发生凋亡。DNA损伤检验点信号转导途径是一个高度保守的信号感应过程,整个途径大致可以分为损伤感应、信号传递及信号效应3个组成部分。其中3-磷脂酰肌醇激酶家族类成员ATM（ataxia-telangiectasia mutated）和ATR（ataxia-telangiectasia and Rad3-related）活性的增加构成整个途径活化的第一步。它们通过激活下游的效应激酶,Chk2／Chk1,通过协同作用许多其他调控细胞周期、DNA复制、DNA损伤修复及细胞凋亡等过程的蛋白质因子来实现细胞对DNA损伤的高度协调反应。近十几年,随着此领域研究的不断深入,人们逐步揭示了DNA损伤检验点途径发生过程中,各种核心组分通过与不同调节因子、效应因子及DNA损伤修复蛋白间的复杂相互作用,以实现监测感应异常DNA结构并实施相应反应的机制;其中,检验点衔接因子（mediators）及染色质结构,尤其是核小体组蛋白的共价修饰在调控ATM／ATR活性,促进ATM／ATR与底物间的相互作用以及介导DNA损伤位点周围染色质区域上多蛋白复合物在时间与空间上的动态形成发挥着重要的作用。同时,人们也开始发现DNA损伤检验点途径与DNA损伤修复、基因组稳定性以及肿瘤发生等过程之间某些内在的联系。该反应途径在通过协调细胞针对DNA损伤做出各种反应的基础上,直接或间接地参与或调控DNA损伤修复过程,并与DNA损伤修复途径协同作用最终保证染色体基凶组结构的完整性,而检验点途径的改变,则会引起基因组不稳定的发生,包括从突变频率的提高到大范围的染色体重排,以及染色体数量的畸变。如：突变发生在肿瘤形成早期,会大大增加肿瘤发生的几率。文章将对DNA损伤检验点途径机制及其对DNA损伤修复、基因组稳定性影响的最新进展进行综述。     

DNA damage-induced replication arrest in Xenopus egg extracts

Chromosomal replication is sensitive to the presence of DNA-damaging alkylating agents, such as methyl methanesulfonate (MMS). MMS is known to inhibit replication though activation of the DNA damage checkpoint and through checkpoint-independent slowing of replication fork progression. Using Xenopus egg extracts, we now report an additional pathway that is stimulated by MMS-induced damage. We show that, upon incubation in egg extracts, MMS-treated DNA activates a diffusible inhibitor that blocks, in trans, chromosomal replication. The downstream effect of the inhibitor is a failure to recruit proliferating cell nuclear antigen, but not DNA polymerase alpha, to the nascent replication fork. Thus, alkylation damage activates an inhibitor that intercepts the replication pathway at a point between the polymerase alpha and proliferating cell nuclear antigen execution steps. We also show that activation of the inhibitor does not require the DNA damage checkpoint; rather, stimulation of the pathway described here results in checkpoint activation. These data describe a novel replication arrest pathway, and they also provide an example of how subpathways within the DNA damage response network are integrated to promote efficient cell cycle arrest in response to damaged DNA.     

Spatial separation between replisome‐ and template‐induced replication stress signaling

Polymerase‐blocking DNA lesions are thought to elicit a checkpoint response via accumulation of single‐stranded DNA at stalled replication forks. However, as an alternative to persistent fork stalling, re‐priming downstream of lesions can give rise to daughter‐strand gaps behind replication forks. We show here that the processing of such structures by an exonuclease, Exo1, is required for timely checkpoint activation, which in turn prevents further gap erosion in S phase. This Rad9‐dependent mechanism of damage signaling is distinct from the Mrc1‐dependent, fork‐associated response to replication stress induced by conditions such as nucleotide depletion or replisome‐inherent problems, but reminiscent of replication‐independent checkpoint activation by single‐stranded DNA. Our results indicate that while replisome stalling triggers a checkpoint response directly at the stalled replication fork, the response to replication stress elicited by polymerase‐blocking lesions mainly emanates from Exo1‐processed, postreplicative daughter‐strand gaps, thus offering a mechanistic explanation for the dichotomy between replisome‐ versus template‐induced checkpoint signaling.     

Mechanisms of replication fork protection: a safeguard for genome stability

During S-phase, the genome is extremely vulnerable and the progression of replication forks is often threatened by exogenous and endogenous challenges. When replication fork progression is halted, the intra S-phase checkpoint is activated to promote structural stability of stalled forks, preventing the dissociation of replisome components. This ensures the rapid resumption of replication following DNA repair. Failure in protecting and/or restarting the stalled forks contributes to alterations of the genome. Several human genetic diseases coupled to an increased cancer predisposition are caused by mutations in genes involved in safeguarding genome integrity during DNA replication. Both the ATR (ataxia telangiectasia and Rad3-related protein) kinase and the Replication pausing complex (RPC) components Tipin, Tim1 and Claspin play key roles in activating the intra S-phase checkpoint and in stabilizing the stalled replication forks. Here, we discuss the specific contribution of these factors in preserving fork structure and ensuring accurate completion of DNA replication.     

母型-合子型过渡的研究进展

母型-合子型过渡,是许多动物胚胎发育的一个重要时期。在这一时期,大批合子型基因开始转录,胚胎发育由母型因子调控转为合子型基因调控,细胞周期逐步加长,细胞分裂不再同步。这些变化对于保证早期胚胎顺利过渡到后期发育阶段至关重要。目前母型-合子型过渡的分子机制还不是很清楚,但研究表明,启动母型-合子型过渡的因素主要集中在以下几个方面,如核质比、周期蛋白和周期蛋白依赖性激酶、DNA复制/损伤检测点、DNA结构的改变以及母型因子的降解和一些合子型基因的转录等。现主要对母型-合子型过渡的特征以及启动母型-合子型过渡的机制作一简要综述。     

Phenacetin acts as a weak genotoxic compound preferentially in the kidney of DNA repair deficient Xpa mice

Cell cycle checkpoints and DNA repair capacity are critical for the maintenance of genome integrity. We hypothesized that, in comparison to healthy controls, esophageal cancer patients might have a higher frequency of deficiencies in cell cycle checkpoints and/or DNA repair system. Using flow cytometry and comet assay, we assessed the γ-radiation-induced S phase and G2-M phase accumulation, and benzo(a)pyrene-diol-epoxide (BPDE)- and γ-radiation-induced DNA damage, in peripheral blood lymphocytes of 99 newly diagnosed esophageal cancer patients and 112 age-, gender-, and ethnicity-matched healthy controls. The mean γ-radiation-induced cell accumulation at G2-M phase was significantly lower in esophageal cancer patients than the control subjects (case versus control: 5.27% ± 5.11% versus. 7.06% ± 5.04%, P = 0.013). The less G2-M phase cell accumulation resulted in a significant increased risk for esophageal cancer with an odds ratio of 2.08 (95% confidence interval 1.15–3.77). After normalization to baseline S fraction, the radiation-induced increment in the 4N/2N ratio was also significantly lower in esophageal cancer patients than in controls (case versus control: 0.76% versus 1.04%, P = 0.0039). The less increment in the radiation-induced 4N/2N ratio was associated with 2.24(95% confidence interval 1.22–4.11)-fold increase of esophageal cancer risk. We also compared the mutagen-induced DNA damage level among individuals with different S or G2-M phase cell accumulation. We found that the less G2-M phase accumulation was associated with both high BPDE induced and γ-radiation-induced DNA damage in the healthy controls (P for trend = 0.023 and 0.015, respectively). Similar pattern was observed for S phase accumulation (P for trend = 0.033 and 0.022, respectively). However, such association was not seen in esophageal cancer patients. This study provides the first molecular epidemiologic evidence linking increased esophageal cancer risk with defects in cell-cycle checkpoints and DNA repair capacity.     

生理条件下的S期检查点

细胞周期检查点在细胞遭遇DNA损伤因子的攻击或遇到营养缺乏等不利因素作用时,能够暂时阻止或减慢细胞周期的进程,是细胞在长期进化中发展起来的抵御DNA损伤的重要机制.不仅如此,最近的研究表明,在正常生理条件下,存在一种S期检查点,对DNA复制的速度进行调控.从分子水平而言,这种调控作用可能是通过一系列细胞周期调控蛋白如ATR、9-1-1复合体、Chk1、Cdc25A和CDK2等的作用来实现的.这种调节作用对细胞至关重要,它使DNA复制速度不致于过快,从而减少复制过程中发生错误的几率,维护基因组的稳定性.