Shou Waga

DNA polymerase epsilon is required for coordinated and efficient chromosomal DNA replication in Xenopus egg extracts.

DNA polymerase ɛ (Polɛ) is thought to be involved in DNA replication, repair, and cell-cycle checkpoint control in eukaryotic cells. Although the requirement of other replicative DNA polymerases, DNA polymerases α and δ (Polα and δ), for chromosomal DNA replication has been well documented by genetic and biochemical studies, the precise role, if any, of Polɛ in chromosomal DNA replication is still obscure. Here we show, with the use of a cell-free replication system with Xenopus egg extracts, that Xenopus Polɛ is indeed required for chromosomal DNA replication. In Polɛ-depleted extracts, the elongation step of chromosomal DNA replication is markedly impaired, resulting in significant reduction of the overall DNA synthesis as well as accumulation of small replication intermediates. Moreover, despite the decreased DNA synthesis, excess amounts of Polα are loaded onto the chromatin template in Polɛ-depleted extracts, indicative of the failure of proper assembly of DNA synthesis machinery at the fork. These findings strongly suggest that Polɛ, along with Polα and Polδ, is necessary for coordinated chromosomal DNA replication in eukaryotic cells.

Cyclin-Dependent Kinase Inhibitor p21 Modulates the DNA Primer-Template Recognition Complex

ABSTRACT The p21 protein, a cyclin-dependent kinase (CDK) inhibitor, is capable of binding to both cyclin-CDK and the proliferating cell nuclear antigen (PCNA). Through its binding to PCNA, p21 can regulate the function of PCNA differentially in replication and repair. To gain an understanding of the precise mechanism by which p21 affects PCNA function, we have designed a new assay for replication factor C (RFC)-catalyzed loading of PCNA onto DNA, a method that utilizes a primer-template DNA attached to agarose beads via biotin-streptavidin. Using this assay, we showed that RFC remains transiently associated with PCNA on the DNA after the loading reaction. Addition of p21 did not inhibit RFC-dependent PCNA loading; rather, p21 formed a stable complex with PCNA on the DNA. In contrast, the formation of a p21-PCNA complex on the DNA resulted in the displacement of RFC from the DNA. The nonhydrolyzable analogs of ATP, adenosine-5′-O-(3-thiotriphosphate) (ATPγS) and adenyl-imidodiphosphate, each stabilized the primer recognition complex containing RFC and PCNA in the absence of p21. RFC in the ATPγS-activated complex was no longer displaced from the DNA by p21. We propose that p21 stimulates the dissociation of the RFC from the PCNA-DNA complex in a process that requires ATP hydrolysis and then inhibits subsequent PCNA-dependent events in DNA replication. The data suggest that the conformation of RFC in the primer recognition complex might change on hydrolysis of ATP. We also suggest that the p21-PCNA complex that remains attached to DNA might function to tether cyclin-CDK complexes to specific regions of the genome.

Distinct roles of DNA polymerases delta and epsilon at the replication fork in Xenopus egg extracts

DNA polymerases δ and ɛ (Polδ and Polɛ) are widely thought to be the major DNA polymerases that function in elongation during DNA replication in eukaryotic cells. However, the precise roles of these polymerases are still unclear. Here we comparatively analysed DNA replication in Xenopus egg extracts in which Polδ or Polɛ was immunodepleted. Depletion of either polymerase resulted in a significant decrease in DNA synthesis and accumulation of short nascent DNA products, indicating an elongation defect. Moreover, Polδ depletion caused a more severe defect in elongation, as shown by sustained accumulation of both short nascent DNA products and single‐stranded DNA gaps, and also by elevated chromatin binding of replication proteins that function more frequently during lagging strand synthesis. Therefore, our data strongly suggest the possibilities that Polδ is essential for lagging strand synthesis and that this function of Polδ cannot be substituted for by Polɛ.

Continued primer synthesis at stalled replication forks contributes to checkpoint activation.

An increased number of primer–template junctions generated by PCNA, Pol-δ, and Pol-ε at stalled replication forks activates Chk1.

Human origin recognition complex binds preferentially to G-quadruplex-preferable RNA and single-stranded DNA

Background: ORC binds to replication origins, but human ORC does not exhibit apparent sequence-specificity. Results: G-quadruplex (G4)-preferable RNA or single-stranded DNA competes for DNA binding of ORC. Conclusion: Human ORC binds preferentially to RNA and single-stranded DNA that form G4, and the certain domain in ORC1 is involved in this binding. Significance: This ability may correlate with the G4-formable motif in human replication origins. Origin recognition complex (ORC), consisting of six subunits ORC1–6, is known to bind to replication origins and function in the initiation of DNA replication in eukaryotic cells. In contrast to the fact that Saccharomyces cerevisiae ORC recognizes the replication origin in a sequence-specific manner, metazoan ORC has not exhibited strict sequence-specificity for DNA binding. Here we report that human ORC binds preferentially to G-quadruplex (G4)-preferable G-rich RNA or single-stranded DNA (ssDNA). We mapped the G-rich RNA-binding domain in the ORC1 subunit, in a region adjacent to its ATPase domain. This domain itself has an ability to preferentially recognize G4-preferable sequences of ssDNA. Furthermore, we found, by structure modeling, that the G-rich RNA-binding domain is similar to the N-terminal portion of AdoMet_MTase domain of mammalian DNA methyltransferase 1. Therefore, in contrast with the binding to double-stranded DNA, human ORC has an apparent sequence preference with respect to its RNA/ssDNA binding. Interestingly, this specificity coincides with the common signature present in most of the human replication origins. We expect that our findings provide new insights into the regulations of function and chromatin binding of metazoan ORCs.

Regulation of the Rev1-pol ζ complex during bypass of a DNA interstrand cross-link.

DNA interstrand cross‐links (ICLs) are repaired in S phase by a complex, multistep mechanism involving translesion DNA polymerases. After replication forks collide with an ICL, the leading strand approaches to within one nucleotide of the ICL (“approach”), a nucleotide is inserted across from the unhooked lesion (“insertion”), and the leading strand is extended beyond the lesion (“extension”). How DNA polymerases bypass the ICL is incompletely understood. Here, we use repair of a site‐specific ICL in Xenopus egg extracts to study the mechanism of lesion bypass. Deep sequencing of ICL repair products showed that the approach and extension steps are largely error‐free. However, a short mutagenic tract is introduced in the vicinity of the lesion, with a maximum mutation frequency of ~1%. Our data further suggest that approach is performed by a replicative polymerase, while extension involves a complex of Rev1 and DNA polymerase ζ. Rev1–pol ζ recruitment requires the Fanconi anemia core complex but not FancI–FancD2. Our results begin to illuminate how lesion bypass is integrated with chromosomal DNA replication to limit ICL repair‐associated mutagenesis.

Dynamics of DNA Binding of Replication Initiation Proteins during de Novo Formation of Pre-replicative Complexes in Xenopus Egg Extracts

We investigated the dynamics of DNA binding of replication initiation proteins during formation of the pre-replicative complex (pre-RC) on plasmids in Xenopus egg extracts. The pre-RC was efficiently formed on plasmids at 23 °C, with one or a few origin recognition complex (ORC) molecules and ∼10–20 mini-chromosome maintenance 2 (MCM2) molecules loaded onto each plasmid. Although geminin inhibited MCM loading, MCM interacted weakly but stoichiometrically with the plasmid in an ORC-dependent manner, even in the presence of geminin (with ∼10 MCM2 molecules per plasmid). Interestingly, DNA binding of ORC, CDC6, and CDT1 was significantly stabilized in the presence of geminin, under which conditions ∼10–20 molecules each of ORC and CDC6 were bound. Moreover, a similarly stable ORC-CDC6-CDT1 complex rapidly formed on DNA at lower temperature (0 °C) without geminin, with ∼10–20 molecules each of ORC and CDC6 bound to the plasmid, but almost no binding of MCM. However, upon shifting the temperature to 23 °C, most ORC, CDC6, and CDT1 molecules were displaced from the DNA, leaving about one ORC molecule on the plasmid, whereas ∼10 MCM2 molecules were loaded onto each plasmid. Furthermore, it was possible to load MCM onto DNA when the isolated ORC-CDC6-CDT1-DNA complex was mixed with purified MCM proteins. These results suggest that an ORC-CDC6-CDT1 complex pre-formed on DNA is directly involved in MCM loading and imply that each DNA-bound ORC molecule loads only one or a few MCM2–7 complexes during metazoan pre-RC formation.

The DNA polymerase activity of Pol ε holoenzyme is required for rapid and efficient chromosomal DNA replication in Xenopus egg extracts

BackgroundDNA polymerase ε (Pol ε) is involved in DNA replication, repair, and cell-cycle checkpoint control in eukaryotic cells. Although the roles of replicative Pol α and Pol δ in chromosomal DNA replication are relatively well understood and well documented, the precise role of Pol ε in chromosomal DNA replication is not well understood.ResultsThis study uses a Xenopus egg extract DNA replication system to further elucidate the replicative role(s) played by Pol ε. Previous studies show that the initiation timing and elongation of chromosomal DNA replication are markedly impaired in Pol ε-depleted Xenopus egg extracts, with reduced accumulation of replicative intermediates and products. This study shows that normal replication is restored by addition of Pol ε holoenzyme to Pol ε-depleted extracts, but not by addition of polymerase-deficient forms of Pol ε, including polymerase point or deletion mutants or incomplete enzyme complexes. Evidence is also provided that Pol ε holoenzyme interacts directly with GINS, Cdc45p and Cut5p, each of which plays an important role in initiation of chromosomal DNA replication in eukaryotic cells.ConclusionThese results indicate that the DNA polymerase activity of Pol ε holoenzyme plays an essential role in normal chromosomal DNA replication in Xenopus egg extracts. These are the first biochemical data to show the DNA polymerase activity of Pol ε holoenzyme is essential for chromosomal DNA replication in higher eukaryotes, unlike in yeasts.

Redundant and differential regulation of multiple licensing factors ensures prevention of re-replication in normal human cells

When human cells enter S-phase, overlapping differential inhibitory mechanisms downregulate the replication licensing factors ORC1, CDC6 and Cdt1. Such regulation prevents re-replication so that deregulation of any individual factor alone would not be expected to induce overt re-replication. However, this has been challenged by the fact that overexpression of Cdt1 or Cdt1+CDC6 causes re-replication in some cancer cell lines. We thought it important to analyze licensing regulations in human non-cancerous cells that are resistant to Cdt1-induced re-replication and examined whether simultaneous deregulation of these licensing factors induces re-replication in two such cell lines, including human fibroblasts immortalized by telomerase. Individual overexpression of either Cdt1, ORC1 or CDC6 induced no detectable re-replication. However, with Cdt1+ORC1 or Cdt1+CDC6, some re-replication was detectable and coexpression of Cdt1+ORC1+CDC6 synergistically acted to give strong re-replication with increased mini-chromosome maintenance (MCM) loading. Coexpression of ORC1+CDC6 was without effect. These results suggest that, although Cdt1 regulation is the key step, differential regulation of multiple licensing factors ensures prevention of re-replication in normal human cells. Our findings also show for the first time the importance of ORC1 regulation for prevention of re-replication.

Deregulated Cdc6 inhibits DNA replication and suppresses Cdc7-mediated phosphorylation of Mcm2–7 complex

Mcm2–7 is recruited to eukaryotic origins of DNA replication by origin recognition complex, Cdc6 and Cdt1 thereby licensing the origins. Cdc6 is essential for origin licensing during DNA replication and is readily destabilized from chromatin after Mcm2–7 loading. Here, we show that after origin licensing, deregulation of Cdc6 suppresses DNA replication in Xenopus egg extracts without the involvement of ATM/ATR-dependent checkpoint pathways. DNA replication is arrested specifically after chromatin binding of Cdc7, but before Cdk2-dependent pathways and deregulating Cdc6 after this step does not impair activation of origin firing or elongation. Detailed analyses revealed that Cdc6 deregulation leads to strong suppression of Cdc7-mediated hyperphosphorylation of Mcm4 and subsequent chromatin loading of Cdc45, Sld5 and DNA polymerase α. Mcm2 phosphorylation is also repressed although to a lesser extent. Remarkably, Cdc6 itself does not directly inhibit Cdc7 kinase activity towards Mcm2–4–6–7 in purified systems, rather modulates Mcm2–7 phosphorylation on chromatin context. Taken together, we propose that Cdc6 on chromatin acts as a modulator of Cdc7-mediated phosphorylation of Mcm2–7, and thus destabilization of Cdc6 from chromatin after licensing is a key event ensuring proper transition to the initiation of DNA replication.