PTEN regulates RPA1 and protects DNA replication forks

Tumor suppressor PTEN regulates cellular activities and controls genome stability through multiple mechanisms. In this study, we report that PTEN is necessary for the protection of DNA replication forks against replication stress. We show that deletion of PTEN leads to replication fork collapse and chromosomal instability upon fork stalling following nucleotide depletion induced by hydroxyurea. PTEN is physically associated with replication protein A 1 (RPA1) via the RPA1 C-terminal domain. STORM and iPOND reveal that PTEN is localized at replication sites and promotes RPA1 accumulation on replication forks. PTEN recruits the deubiquitinase OTUB1 to mediate RPA1 deubiquitination. RPA1 deletion confers a phenotype like that observed in PTEN knockout cells with stalling of replication forks. Expression of PTEN and RPA1 shows strong correlation in colorectal cancer. Heterozygous disruption of RPA1 promotes tumorigenesis in mice. These results demonstrate that PTEN is essential for DNA replication fork protection. We propose that RPA1 is a target of PTEN function in fork protection and that PTEN maintains genome stability through regulation of DNA replication.     

Human CST complex protects stalled replication forks by directly blocking MRE11 degradation of nascent‐strand DNA

Degradation and collapse of stalled replication forks are main sources of genomic instability, yet the molecular mechanisms for protecting forks from degradation/collapse are not well understood. Here, we report that human CST (CTC1‐STN1‐TEN1) proteins, which form a single‐stranded DNA‐binding complex, localize at stalled forks and protect stalled forks from degradation by the MRE11 nuclease. CST deficiency increases MRE11 binding to stalled forks, leading to nascent‐strand degradation at reversed forks and ssDNA accumulation. In addition, purified CST complex binds to 5’ DNA overhangs and directly blocks MRE11 degradation in vitro, and the DNA‐binding ability of CST is required for blocking MRE11‐mediated nascent‐strand degradation. Our results suggest that CST inhibits MRE11 binding to reversed forks, thus antagonizing excessive nascent‐strand degradation. Finally, we uncover that CST complex inactivation exacerbates genome instability in BRCA2 deficient cells. Collectively, our findings identify the CST complex as an important fork protector that preserves genome integrity under replication perturbation.     

Rif1 provides a new DNA‐binding interface for the Bloom syndrome complex to maintain normal replication

BLM, the helicase defective in Bloom syndrome, is part of a multiprotein complex that protects genome stability. Here, we show that Rif1 is a novel component of the BLM complex and works with BLM to promote recovery of stalled replication forks. First, Rif1 physically interacts with the BLM complex through a conserved C‐terminal domain, and the stability of Rif1 depends on the presence of the BLM complex. Second, Rif1 and BLM are recruited with similar kinetics to stalled replication forks, and the Rif1 recruitment is delayed in BLM‐deficient cells. Third, genetic analyses in vertebrate DT40 cells suggest that BLM and Rif1 work in a common pathway to resist replication stress and promote recovery of stalled forks. Importantly, vertebrate Rif1 contains a DNA‐binding domain that resembles the αCTD domain of bacterial RNA polymerase α; and this domain preferentially binds fork and Holliday junction (HJ) DNA in vitro and is required for Rif1 to resist replication stress in vivo. Our data suggest that Rif1 provides a new DNA‐binding interface for the BLM complex to restart stalled replication forks.     

ATR protects ongoing and newly assembled DNA replication forks through distinct mechanisms

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Human DDK rescues stalled forks and counteracts checkpoint inhibition at unfired origins to complete DNA replication

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Tel1ATM dictates the replication timing of short yeast telomeres

Telomerase action is temporally linked to DNA replication. Although yeast telomeres are normally late replicating, telomere shortening leads to early firing of subtelomeric DNA replication origins. We show that double‐strand breaks flanked by short telomeric arrays cause origin firing early in S phase at late‐replicating loci and that this effect on origin firing time is dependent on the Tel1^ATM checkpoint kinase. The effect of Tel1^ATM on telomere replication timing extends to endogenous telomeres and is stronger than that elicited by Rif1 loss. These results establish that Tel1^ATM specifies not only the extent but also the timing of telomerase recruitment.     

Metazoan origins of DNA replication: Regulation through dynamic chromatin structure

DNA replication in eukaryotes is initiated at multiple replication origins distributed over the entire genome, which are normally activated once per cell cycle. Due to the complexity of the metazoan genome, the study of metazoan replication origins and their activity profiles has been less advanced than in simpler genome systems. DNA replication in eukaryotes involves many protein–protein and protein–DNA interactions, occurring in multiple stages. As in prokaryotes, control over the timing and frequency of initiation is exerted at the initiation site. A prerequisite for understanding the regulatory mechanisms of eukaryotic DNA replication is the identification and characterization of the cis‐acting sequences that serve as replication origins and the trans‐acting factors (proteins) that interact with them. Furthermore, in order to understand how DNA replication may become deregulated in malignant cells, the distinguishing features between normal and malignant origins of DNA replication as well as the proteins that interact with them must be determined. Based on advances that were made using simple genome model systems, several proteins involved in DNA replication have been identified. This review summarizes the current findings about metazoan origins of DNA replication and their interacting proteins as well as the role of chromatin structure in their regulation. Furthermore, progress in origin identification and isolation procedures as well as potential mechanisms to inhibit their activation in cancer development and progression are discussed. J. Cell. Biochem. 106: 512–520, 2009. © 2009 Wiley‐Liss, Inc.     

Origin plasticity during budding yeast DNA replication in vitro

The separation of DNA replication origin licensing and activation in the cell cycle is essential for genome stability across generations in eukaryotic cells. Pre‐replicative complexes (pre‐RCs) license origins by loading Mcm2‐7 complexes in inactive form around DNA. During origin firing in S phase, replisomes assemble around the activated Mcm2‐7 DNA helicase. Budding yeast pre‐RCs have previously been reconstituted in vitro with purified proteins. Here, we show that reconstituted pre‐RCs support replication of plasmid DNA in yeast cell extracts in a reaction that exhibits hallmarks of cellular replication initiation. Plasmid replication in vitro results in the generation of covalently closed circular daughter molecules, indicating that the system recapitulates the initiation, elongation, and termination stages of DNA replication. Unexpectedly, yeast origin DNA is not strictly required for DNA replication in vitro, as heterologous DNA sequences could support replication of plasmid molecules. Our findings support the notion that epigenetic mechanisms are important for determining replication origin sites in budding yeast, highlighting mechanistic principles of replication origin specification that are common among eukaryotes.     

Chromatin assembly at kinetochores is uncoupled from DNA replication

The specification of metazoan centromeres does not depend strictly on centromeric DNA sequences, but also requires epigenetic factors. The mechanistic basis for establishing a centromeric "state" on the DNA remains unclear. In this work, we have directly examined replication timing of the prekinetochore domain of human chromosomes. Kinetochores were labeled by expression of epitope-tagged CENP-A, which stably marks prekinetochore domains in human cells. By immunoprecipitating CENP-A mononucleosomes from synchronized cells pulsed with [(3)H]thymidine we demonstrate that CENP-A-associated DNA is replicated in mid-to-late S phase. Cytological analysis of DNA replication further demonstrated that centromeres replicate asynchronously in parallel with numerous other genomic regions. In contrast, quantitative Western blot analysis demonstrates that CENP-A protein synthesis occurs later, in G2. Quantitative fluorescence microscopy and transient transfection in the presence of aphidicolin, an inhibitor of DNA replication, show that CENP-A can assemble into centromeres in the absence of DNA replication. Thus, unlike most genomic chromatin, histone synthesis and assembly are uncoupled from DNA replication at the kinetochore. Uncoupling DNA replication from CENP-A synthesis suggests that regulated chromatin assembly or remodeling could play a role in epigenetic centromere propagation.     

Identification and functional analysis of a human homologue of the monkey replication origin ors8

We previously isolated from African green monkey (CV-1) cells a replication origin, ors8, that is active at the onset of S-phase. Here, its homologous sequence (hors8, accession number: DQ230978) was amplified from human cells, using the monkey-ors8-specific primers. Sequence alignment between the monkey and the human fragment revealed a 92% identity. Nascent DNA abundance analysis, involving quantification by real-time PCR, indicated that hors8 is an active replication origin, as the abundance of nascent DNA from a genomic region containing it was 97-fold higher relative to a non-origin region in the same locus. Furthermore, the data showed that the hors8 fragment is capable of supporting the episomal replication of its plasmid, when cloned into pBlueScript (pBS), as assayed by the DpnI resistance assay after transfection of HeLa cells. A quantitative chromatin immunoprecipitation (ChIP) assay, using antibodies against Ku, Orc2, and Cdc6, showed that these DNA replication initiator proteins were associated in vivo with the human ors8 (hors8). Finally, nascent DNA abundance experiments from human cells synchronized at different phases of the cell cycle revealed that hors8 is a late-firing origin of DNA replication, having the highest activity 8 h after release from late G(1).     

WRNIP1 protects stalled forks from degradation and promotes fork restart after replication stress

Accurate handling of stalled replication forks is crucial for the maintenance of genome stability. RAD51 defends stalled replication forks from nucleolytic attack, which otherwise can threaten genome stability. However, the identity of other factors that can collaborate with RAD51 in this task is poorly elucidated. Here, we establish that human Werner helicase interacting protein 1 (WRNIP1) is localized to stalled replication forks and cooperates with RAD51 to safeguard fork integrity. We show that WRNIP1 is directly involved in preventing uncontrolled MRE11‐mediated degradation of stalled replication forks by promoting RAD51 stabilization on ssDNA. We further demonstrate that replication fork protection does not require the ATPase activity of WRNIP1 that is however essential to achieve the recovery of perturbed replication forks. Loss of WRNIP1 or its catalytic activity causes extensive DNA damage and chromosomal aberrations. Intriguingly, downregulation of the anti‐recombinase FBH1 can compensate for loss of WRNIP1 activity, since it attenuates replication fork degradation and chromosomal aberrations in WRNIP1‐deficient cells. Therefore, these findings unveil a unique role for WRNIP1 as a replication fork‐protective factor in maintaining genome stability.     

SCFDia2 regulates DNA replication forks during S‐phase in budding yeast

Dia2 is an F‐box protein, which is involved in the regulation of DNA replication in the budding yeast Saccharomyces cerevisiae. The function of Dia2, however, remains largely unknown. In this study, we report that Dia2 is associated with the replication fork and regulates replication fork progression. Using modified yeast two‐hybrid screening, we have identified components of the replisome (Mrc1, Ctf4 and Mcm2), as Dia2‐binding proteins. Mrc1 and Ctf4 were ubiquitinated by SCF^Dia2 both in vivo and in vitro. Domain analysis of Dia2 revealed that the leucine‐rich repeat motif was indispensable for the regulation of replisome progression, whereas the tetratricopeptide repeat (TPR) motif was involved in the interaction with replisome components. In addition, the TPR motif was shown to be involved in Dia2 stability; deleting the TPR stabilized Dia2, mimicking the effect of DNA damage. ChIP‐on‐chip analysis illustrated that Dia2 localizes to the replication fork and regulates fork progression on hydroxyurea treatment. These results demonstrate that Dia2 is involved in the regulation of replisome activity through a direct interaction with replisome components.     

Single-copy locus proteomics of early- and late-firing DNA replication origins identifies a role of Ask1/DASH complex in replication timing control

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Partial purification and characterization of a cellular protein that binds to the SV40 core origin of DNA replication

A monkey cell factor that interacts specifically with double- and single-stranded DNA sequences in the early domain of the simian virus 40 (SV40) core origin of replication was identified using gel-retention assays. The protein was enriched over 1200-fold using ion-exchange and affinity chromatography on single-strand DNA cellulose. Binding of protein to mutant origin DNA restriction fragments was correlated with replication activity of the mutant DNAs. Exonuclease footprint experiments on single-stranded DNA revealed prominent pause sites in the early domain of the core origin. The results suggest that this cellular protein may be involved in SV40 DNA replication.     

Regulation of eukaryotic DNA replication and nuclearstructure

In eukaryote,nuclear structure is a key component for the functions of eukaryotic cells.More and more evidences show that the nuclear structure plays important role in regulating DNA replication.The nuclear structure provides a physical barrier for the replication licensing,participates in the decision where DNA replication initiates,and organizes replication proteins as replication factory for DNA replication.Through these works,new concepts on the regulation of DNA replication have emerged,which will be discussed in this minireview.     

Interaction of replication factor Sld3 and histone acetyl transferase Esa1 alleviates gene silencing and promotes the activation of late and dormant replication origins

DNA replication in eukaryotes is a multi-step process that consists of three main reactions: helicase loading (licensing), helicase activation (firing), and nascent DNA synthesis (elongation). Although the contributions of some chromatin regulatory factors in the licensing and elongation reaction have been determined, their functions in the firing reaction remain elusive. In the budding yeast Saccharomyces cerevisiae, Sld3, Sld7, and Cdc45 (3–7–45) are rate-limiting in the firing reaction and simultaneous overexpression of 3–7–45 causes untimely activation of late and dormant replication origins. Here, we found that 3–7–45 overexpression not only activated dormant origins in the silenced locus, HMLα, but also exerted an anti-silencing effect at this locus. For these, interaction between Sld3 and Esa1, a conserved histone acetyltransferase, was responsible. Moreover, the Sld3–Esa1 interaction was required for the untimely activation of late origins. These results reveal the Sld3–Esa1 interaction as a novel level of regulation in the firing reaction.