DNA polymerase κ‐dependent DNA synthesis at stalled replication forks is important for CHK1 activation

Formation of primed single‐stranded DNA at stalled replication forks triggers activation of the replication checkpoint signalling cascade resulting in the ATR‐mediated phosphorylation of the Chk1 protein kinase, thus preventing genomic instability. By using siRNA‐mediated depletion in human cells and immunodepletion and reconstitution experiments in Xenopus egg extracts, we report that the Y‐family translesion (TLS) DNA polymerase kappa (Pol κ) contributes to the replication checkpoint response and is required for recovery after replication stress. We found that Pol κ is implicated in the synthesis of short DNA intermediates at stalled forks, facilitating the recruitment of the 9‐1‐1 checkpoint clamp. Furthermore, we show that Pol κ interacts with the Rad9 subunit of the 9‐1‐1 complex. Finally, we show that this novel checkpoint function of Pol κ is required for the maintenance of genomic stability and cell proliferation in unstressed human cells.     

Ubiquitination of PCNA and the Polymerase Switch in Human Cells

Replicative DNA polymerases are blocked by damage in the template DNA. To get past this damage, the cell employs specialised translesion synthesis (TLS) polymerases, which have reduced stringency and are able to bypass different lesions. For example, DNA polymerase ? (pol?) is able to carry out TLS past UV-induced cyclobutane pyrimidine dimers. How does the cell bring about the switch from replicative to TLS polymerase? We have shown that, in human cells, when the replication machinery is blocked at DNA damage, PCNA, the sliding clamp required for DNA replication, is mono-ubiquitinated and that this modified form of PCNA has increased affinity for pol?. This provides a mechanism for the polymerase switch. In this Extra-View, we discuss the possible signals that might trigger ubiquitination of PCNA, whether PCNA becomes de-ubiquitinated after TLS has been accomplished and the role of the hREV1 protein in TLS. We point out some apparent differences between mechanisms in Saccharomyces cerevisiae and human cells.     

Rad8Rad5/Mms2–Ubc13 ubiquitin ligase complex controls translesion synthesis in fission yeast

Many DNA lesions cause pausing of replication forks at lesion sites; thus, generating gaps in the daughter strands that are filled‐in by post‐replication repair (PRR) pathways. In Saccharomyces cerevisiae, PRR involves translesion synthesis (TLS) mediated by Polη or Polζ, or Rad5‐dependent gap filling through a poorly characterized error‐free mechanism. We have developed an assay to monitor error‐free and mutagenic TLS across single DNA lesions in Schizosaccharomyces pombe. For both main UV photolesions, we have delineated a major error‐free pathway mediated by a distinct combination of TLS polymerases. Surprisingly, these TLS pathways require enzymes needed for poly‐ubiquitination of proliferating cell nuclear antigen (PCNA) as well as those required for mono‐ubiquitination. For pathways that require several TLS polymerases the poly‐ubiquitin chains of PCNA may facilitate their recruitment through specific interactions with their multiple ubiquitin‐binding motifs. These error‐free TLS pathways may at least partially account for the previously described poly‐ubiquitination‐dependent error‐free branch of PRR. This work highlights major differences in the control of lesion tolerance pathways between S. pombe and S. cerevisiae despite the homologous sets of PRR genes these organisms share.     

Two‐polymerase mechanisms dictate error‐free and error‐prone translesion DNA synthesis in mammals

DNA replication across blocking lesions occurs by translesion DNA synthesis (TLS), involving a multitude of mutagenic DNA polymerases that operate to protect the mammalian genome. Using a quantitative TLS assay, we identified three main classes of TLS in human cells: two rapid and error‐free, and the third slow and error‐prone. A single gene, REV3L, encoding the catalytic subunit of DNA polymerase ζ (polζ), was found to have a pivotal role in TLS, being involved in TLS across all lesions examined, except for a TT cyclobutane dimer. Genetic epistasis siRNA analysis indicated that discrete two‐polymerase combinations with polζ dictate error‐prone or error‐free TLS across the same lesion. These results highlight the central role of polζ in both error‐prone and error‐free TLS in mammalian cells, and show that bypass of a single lesion may involve at least three different DNA polymerases, operating in different two‐polymerase combinations.     

Crystal structure of DNA polymerase III β sliding clamp from Mycobacterium tuberculosis

The sliding clamp is a key component of DNA polymerase III (Pol III) required for genome replication. It is known to function with diverse DNA repair proteins and cell cycle-control proteins, making it a potential drug target. To extend our understanding of the structure/function relationship of the sliding clamp, we solved the crystal structure of the sliding clamp from Mycobacterium tuberculosis (M. tuberculosis), a human pathogen that causes most cases of tuberculosis (TB). The sliding clamp from M. tuberculosis forms a ring-shaped head-to-tail dimer with three domains per subunit. Each domain contains two α helices in the inner ring that lie against two β sheets in the outer ring. Previous studies have indicated that many Escherichia coli clamp-binding proteins have a conserved LF sequence, which is critical for binding to the hydrophobic region of the sliding clamp. Here, we analyzed the binding affinities of the M. tuberculosis sliding clamp and peptides derived from the α and δ subunits of Pol III, which indicated that the LF motif also plays an important role in the binding of the α and δ subunits to the sliding clamp of M. tuberculosis.     

The 9-1-1 checkpoint clamp physically interacts with polzeta and is partially required for spontaneous polzeta-dependent mutagenesis in Saccharomyces cerevisiae

The use of translesion synthesis (TLS) polymerases to bypass DNA lesions during replication constitutes an important mechanism to restart blocked/stalled DNA replication forks. Because TLS polymerases generally have low fidelity on undamaged DNA, the cell must regulate the interaction of TLS polymerases with damaged versus undamaged DNA to maintain genome integrity. The Saccharomyces cerevisiae checkpoint proteins Ddc1, Rad17, and Mec3 form a clamp-like structure (the 9-1-1 clamp) that has physical similarity to the homotrimeric sliding clamp proliferating cell nuclear antigen, which interacts with and promotes the processivity of the replicative DNA polymerases. In this work, we demonstrate both an in vivo and in vitro physical interaction between the Mec3 and Ddc1 subunits of the 9-1-1 clamp and the Rev7 subunit of the Polzeta TLS polymerase. In addition, we demonstrate that loss of Mec3, Ddc1, or Rad17 results in a decrease in Polzeta-dependent spontaneous mutagenesis. These results suggest that, in addition to its checkpoint signaling role, the 9-1-1 clamp may physically regulate Polzeta-dependent mutagenesis by controlling the access of Polzeta to damaged DNA.     

DNA polymerase IV mediates efficient and quick recovery of replication forks stalled at N2-dG adducts

Escherichia coli DNA polymerase IV (Pol IV, also known as DinB) is a Y-family DNA polymerase capable of catalyzing translesion DNA synthesis (TLS) on certain DNA lesions, and accumulating data suggest that Pol IV may play an important role in copying various kinds of spontaneous DNA damage including N²-dG adducts and alkylated bases. Pol IV has a unique ability to coexist with Pol III on the same β clamp and to positively dissociate Pol III from β clamp in a concentration-dependent manner. Reconstituting the entire process of TLS in vitro using E. coli replication machinery and Pol IV, we observed that a replication fork stalled at (−)-trans-anti-benzo[a]pyrene-N²-dG lesion on the leading strand was efficiently and quickly recovered via two sequential switches from Pol III to Pol IV and back to Pol III. Our results suggest that TLS by Pol IV smoothes the way for the replication fork with minimal interruption.     

The helicase FBH1 is tightly regulated by PCNA via CRL4(Cdt2)-mediated proteolysis in human cells

During replication, DNA damage can challenge replication fork progression and cell viability. Homologous Recombination (HR) and Translesion Synthesis (TLS) pathways appear as major players involved in the resumption and completion of DNA replication. How both pathways are coordinated in human cells to maintain genome stability is unclear. Numerous helicases are involved in HR regulation. Among them, the helicase FBH1 accumulates at sites of DNA damage and potentially constrains HR via its anti-recombinase activity. However, little is known about its regulation in vivo. Here, we report a mechanism that controls the degradation of FBH1 after DNA damage. Firstly, we found that the sliding clamp Proliferating Cell Nuclear Antigen (PCNA) is critical for FBH1 recruitment to replication factories or DNA damage sites. We then showed the anti-recombinase activity of FBH1 is partially dependent on its interaction with PCNA. Intriguingly, after its re-localization, FBH1 is targeted for degradation by the Cullin-ring ligase 4-Cdt2 (CRL4^Cdt2)–PCNA pathway via a PCNA-interacting peptide (PIP) degron. Importantly, expression of non-degradable FBH1 mutant impairs the recruitment of the TLS polymerase eta to chromatin in UV-irradiated cells. Thus, we propose that after DNA damage, FBH1 might be required to restrict HR and then degraded by the Cdt2–proteasome pathway to facilitate TLS pathway.     

A direct proofreader–clamp interaction stabilizes the Pol III replicase in the polymerization mode

Processive DNA synthesis by the αεθ core of the Escherichia coli Pol III replicase requires it to be bound to the β₂ clamp via a site in the α polymerase subunit. How the ε proofreading exonuclease subunit influences DNA synthesis by α was not previously understood. In this work, bulk assays of DNA replication were used to uncover a non‐proofreading activity of ε. Combination of mutagenesis with biophysical studies and single‐molecule leading‐strand replication assays traced this activity to a novel β‐binding site in ε that, in conjunction with the site in α, maintains a closed state of the αεθ–β₂ replicase in the polymerization mode of DNA synthesis. The ε–β interaction, selected during evolution to be weak and thus suited for transient disruption to enable access of alternate polymerases and other clamp binding proteins, therefore makes an important contribution to the network of protein–protein interactions that finely tune stability of the replicase on the DNA template in its various conformational states.     

A Genetic Selection for dinB Mutants Reveals an Interaction between DNA Polymerase IV and the Replicative Polymerase That Is Required for Translesion Synthesis

Translesion DNA synthesis (TLS) by specialized DNA polymerases (Pols) is a conserved mechanism for tolerating replication blocking DNA lesions. The actions of TLS Pols are managed in part by ring-shaped sliding clamp proteins. In addition to catalyzing TLS, altered expression of TLS Pols impedes cellular growth. The goal of this study was to define the relationship between the physiological function of Escherichia coli Pol IV in TLS and its ability to impede growth when overproduced. To this end, 13 novel Pol IV mutants were identified that failed to impede growth. Subsequent analysis of these mutants suggest that overproduced levels of Pol IV inhibit E. coli growth by gaining inappropriate access to the replication fork via a Pol III-Pol IV switch that is mechanistically similar to that used under physiological conditions to coordinate Pol IV-catalyzed TLS with Pol III-catalyzed replication. Detailed analysis of one mutant, Pol IV-T120P, and two previously described Pol IV mutants impaired for interaction with either the rim (Pol IV^R) or the cleft (Pol IV^C) of the β sliding clamp revealed novel insights into the mechanism of the Pol III-Pol IV switch. Specifically, Pol IV-T120P retained complete catalytic activity in vitro but, like Pol IV^R and Pol IV^C, failed to support Pol IV TLS function in vivo. Notably, the T120P mutation abrogated a biochemical interaction of Pol IV with Pol III that was required for Pol III-Pol IV switching. Taken together, these results support a model in which Pol III-Pol IV switching involves interaction of Pol IV with Pol III, as well as the β clamp rim and cleft. Moreover, they provide strong support for the view that Pol III-Pol IV switching represents a vitally important mechanism for regulating TLS in vivo by managing access of Pol IV to the DNA.     

NbEXPA1, an α‐expansin,is plasmodesmata‐specific and a novel host factor for potyviral infection

Plasmodesmata (PD), unique to the plant kingdom, are structurally complex microchannels that cross the cell wall to establish symplastic communication between neighbouring cells. Viral intercellular movement occurs through PD. To better understand the involvement of PD in viral infection, we conducted a quantitative proteomic study on the PD‐enriched fraction from Nicotiana benthamiana leaves in response to infection by Turnip mosaic virus (TuMV). We report the identification of a total of 1070 PD protein candidates, of which 100 (≥2‐fold increase) and 48 (≥2‐fold reduction) are significantly differentially accumulated in the PD‐enriched fraction, when compared with protein levels in the corresponding healthy control. Among the differentially accumulated PD protein candidates, we show that an α‐expansin designated NbEXPA1, a cell wall loosening protein, is PD‐specific. TuMV infection downregulates NbEXPA1 mRNA expression and protein accumulation. We further demonstrate that NbEXPA1 is recruited to the viral replication complex via the interaction with NIb, the only RNA‐dependent RNA polymerase of TuMV. Silencing of NbEXPA1 inhibits plant growth and TuMV infection, whereas overexpression of NbEXPA1 promotes viral replication and intercellular movement. These data suggest that NbEXPA1 is a host factor for potyviral infection. This study not only generates a PD‐proteome dataset that is useful in future studies to expound PD biology and PD‐mediated virus–host interactions but also characterizes NbEXPA1 as the first PD‐specific cell wall loosening protein and its essential role in potyviral infection.     

Mycobacterium tuberculosis class II apurinic/apyrimidinic‐endonuclease/3′‐5′ exonuclease III exhibits DNA regulated modes of interaction with the sliding DNA β‐clamp

The class‐II AP‐endonuclease (XthA) acts on abasic sites of damaged DNA in bacterial base excision repair. We identified that the sliding DNA β‐clamp forms in vivo and in vitro complexes with XthA in Mycobacterium tuberculosis. A novel ₂₃₉QLRFPKK₂₄₅ motif in the DNA‐binding domain of XthA was found to be important for the interactions. Likewise, the peptide binding‐groove (PBG) and the C‐terminal of β‐clamp located on different domains interact with XthA. The β‐clamp‐XthA complex can be disrupted by clamp binding peptides and also by a specific bacterial clamp inhibitor that binds at the PBG. We also identified that β‐clamp stimulates the activities of XthA primarily by increasing its affinity for the substrate and its processivity. Additionally, loading of the β‐clamp onto DNA is required for activity stimulation. A reduction in XthA activity stimulation was observed in the presence of β‐clamp binding peptides supporting that direct interactions between the proteins are necessary to cause stimulation. Finally, we found that in the absence of DNA, the PBG located on the second domain of the β‐clamp is important for interactions with XthA, while the C‐terminal domain predominantly mediates functional interactions in the substrate's presence.     

Replication of damaged DNA by translesion synthesis in human cells

Most types of DNA damage block the passage of the replication machinery. In order to bypass these blocks, cells employ special translesion synthesis (TLS) DNA polymerases, which have lower stringency than replicative polymerases. DNA polymerase eta is the major polymerase responsible for bypassing UV lesions in DNA and its absence results in the variant form of the genetic disorder, xeroderma pigmentosum. Other TLS polymerases have specificities for different types of damage, but their precise roles inside the cell have not yet been established. These polymerases are located in replication factories during DNA replication and the polymerase sliding clamp PCNA plays an important role in mediating switching between different polymerases.     

New insights in the ϕ29 terminal protein DNA‐binding and host nucleoid localization functions

Protein‐primed DNA replication constitutes a strategy to initiate viral DNA synthesis in a variety of prokaryotic and eukaryotic organisms. Although the main function of viral terminal proteins (TPs) is to provide a free hydroxyl group to start initiation of DNA replication, there are compelling evidences that TPs can also play other biological roles. In the case of Bacillus subtilis bacteriophage ?29, the N‐terminal domain of the TP organizes viral DNA replication at the bacterial nucleoid being essential for an efficient phage DNA replication, and it contains a nuclear localization signal (NLS) that is functional in eukaryotes. Here we provide information about the structural properties of the ?29 TP N‐terminal domain, which possesses sequence‐independent DNA‐binding capacity, and dissect the amino acid residues important for its biological function. By mutating all the basic residues of the TP N‐terminal domain we identify the amino acids responsible for its interaction with the B. subtilis genome, establishing a correlation between the capacity of DNA‐binding and nucleoid localization of the protein. Significantly, these residues are important to recruit the DNA polymerase at the bacterial nucleoid and, subsequently, for an efficient phage DNA replication.     

Essential domains of phosphatidylinositol‐4 kinase III β required for enterovirus replication

Phosphatidylinositol‐4 kinase III β (PI4KB) is a host factor that is required for enterovirus (EV) replication. In this study, the importance of host proteins that interact with PI4KB in EV replication was analyzed by trans complementation with PI4KB mutants in a PI4KB‐knockout cell line. Ectopically expressed PI4KB mutants, which lack binding regions for ACBD3, RAB11, and 14‐3‐3 proteins, rescued replication of poliovirus and enterovirus 71. These findings suggest that interaction of PI4KB with these host proteins is not essential for EV replication once PI4KB has been expressed and that PI4KB is functionally independent from these host proteins regarding EV replication.     

PCNA ubiquitination and REV1 define temporally distinct mechanisms for controlling translesion synthesis in the avian cell line DT40

Translesion synthesis (TLS) is a potentially mutagenic method of bypassing DNA damage encountered during replication that requires the recruitment of specialized DNA polymerases to stalled replication forks or postreplicative gaps. Current models suggest that TLS is activated by monoubiquitination of the DNA sliding clamp PCNA. However, in higher organisms, fully effective TLS also requires a noncatalytic function of the Y family polymerase REV1. Using the genetically tractable chicken cell line DT40, we show that TLS at stalled replication forks requires that both the translesion polymerase-interaction domain and ubiquitin-binding domain in the C terminus of REV1 are intact. Surprisingly, however, PCNA ubiquitination is not required to maintain normal fork progression on damaged DNA. Conversely, PCNA ubiquitination is essential for filling postreplicative gaps. Thus, PCNA ubiquitination and REV1 play distinct roles in the coordination of DNA damage bypass that are temporally separated relative to replication fork arrest.     

Mutant forms of the Escherichia colibeta sliding clamp that distinguish between its roles in replication and DNA polymerase V-dependent translesion DNA synthesis

The Escherichia colibeta sliding clamp is proposed to play an important role in regulating DNA polymerase traffic at the replication fork. As part of an ongoing effort to understand how organisms manage the actions of their multiple DNA polymerases, we examined the ability of several mutant forms of the beta clamp to function in DNA polymerase V- (pol V-) dependent translesion DNA synthesis (TLS) in vivo. Our results indicate that a dnaN159 strain, which expresses a temperature sensitive form of the beta clamp, was impaired for pol V-dependent TLS at the permissive temperature of 37 degrees C. This defect was complemented by a plasmid that expressed near-physiological levels of the wild-type clamp. Using a dnaN159 mutant strain, together with various plasmids expressing mutant forms of the clamp, we determined that residues H148 through R152, which comprise a portion of a solvent exposed loop, as well as position P363, which is located in the C-terminal tail of the beta clamp, are critically important for pol V-dependent TLS in vivo. In contrast, these same residues appear to be less critical for pol III-dependent replication. Taken together, these findings indicate that: (i) the beta clamp plays an essential role in pol V-dependent TLS in vivo and (ii) pol III and pol V interact with non-identical surfaces of the beta clamp.     

Roles of PCNA ubiquitination and TLS polymerases κ and η in the bypass of methyl methanesulfonate-induced DNA damage

Translesion synthesis (TLS) provides a highly conserved mechanism that enables DNA synthesis on a damaged template. TLS is performed by specialized DNA polymerases of which polymerase (Pol) κ is important for the cellular response to DNA damage induced by benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE), ultraviolet (UV) light and the alkylating agent methyl methanesulfonate (MMS). As TLS polymerases are intrinsically error-prone, tight regulation of their activity is required. One level of control is provided by ubiquitination of the homotrimeric DNA clamp PCNA at lysine residue 164 (PCNA-Ub). We here show that Polκ can function independently of PCNA modification and that Polη can function as a backup during TLS of MMS-induced lesions. Compared to cell lines deficient for PCNA modification (Pcna^K164R) or Polκ, double mutant cell lines display hypersensitivity to MMS but not to BPDE or UV-C. Double mutant cells also displayed delayed post-replicative TLS, accumulate higher levels of replication stress and delayed S-phase progression. Furthermore, we show that Polη and Polκ are redundant in the DNA damage bypass of MMS-induced DNA damage. Taken together, we provide evidence for PCNA-Ub-independent activation of Polκ and establish Polη as an important backup polymerase in the absence of Polκ in response to MMS-induced DNA damage.     

Motif WFYY of human PrimPol is crucial to stabilize the incoming 3′-nucleotide during replication fork restart

PrimPol is the second primase in human cells, the first with the ability to start DNA chains with dNTPs. PrimPol contributes to DNA damage tolerance by restarting DNA synthesis beyond stalling lesions, acting as a TLS primase. Multiple alignment of eukaryotic PrimPols allowed us to identify a highly conserved motif, WxxY near the invariant motif A, which contains two active site metal ligands in all members of the archeo-eukaryotic primase (AEP) superfamily. In vivo and in vitro analysis of single variants of the WFYY motif of human PrimPol demonstrated that the invariant Trp⁸⁷ and Tyr⁹⁰ residues are essential for both primase and polymerase activities, mainly due to their crucial role in binding incoming nucleotides. Accordingly, the human variant F88L, altering the WFYY motif, displayed reduced binding of incoming nucleotides, affecting its primase/polymerase activities especially during TLS reactions on UV-damaged DNA. Conversely, the Y89D mutation initially associated with High Myopia did not affect the ability to rescue stalled replication forks in human cells. Collectively, our data suggest that the WFYY motif has a fundamental role in stabilizing the incoming 3′-nucleotide, an essential requisite for both its primase and TLS abilities during replication fork restart.     

Exchange between Escherichia coli polymerases II and III on a processivity clamp

Escherichia coli has three DNA polymerases implicated in the bypass of DNA damage, a process called translesion synthesis (TLS) that alleviates replication stalling. Although these polymerases are specialized for different DNA lesions, it is unclear if they interact differently with the replication machinery. Of the three, DNA polymerase (Pol) II remains the most enigmatic. Here we report a stable ternary complex of Pol II, the replicative polymerase Pol III core complex and the dimeric processivity clamp, β. Single-molecule experiments reveal that the interactions of Pol II and Pol III with β allow for rapid exchange during DNA synthesis. As with another TLS polymerase, Pol IV, increasing concentrations of Pol II displace the Pol III core during DNA synthesis in a minimal reconstitution of primer extension. However, in contrast to Pol IV, Pol II is inefficient at disrupting rolling-circle synthesis by the fully reconstituted Pol III replisome. Together, these data suggest a β-mediated mechanism of exchange between Pol II and Pol III that occurs outside the replication fork.