The DNA-protein interaction modes of FEN-1 with gap substrates and their implication in preventing duplication mutations

Flap endonuclease-1 (FEN-1) is a structure-specific nuclease best known for its involvement in RNA primer removal and long-patch base excision repair. This enzyme is known to possess 5′-flap endo- (FEN) and 5′–3′ exo- (EXO) nuclease activities. Recently, FEN-1 has been reported to also possess a gap endonuclease (GEN) activity, which is possibly involved in apoptotic DNA fragmentation and the resolution of stalled DNA replication forks. In the current study, we compare the kinetics of these activities to shed light on the aspects of DNA structure and FEN-1 DNA-binding elements that affect substrate cleavage. By using DNA binding deficient mutants of FEN-1, we determine that the GEN activity is analogous to FEN activity in that the single-stranded DNA region of DNA substrates interacts with the clamp region of FEN-1. In addition, we show that the C-terminal extension of human FEN-1 likely interacts with the downstream duplex portion of all substrates. Taken together, a substrate-binding model that explains how FEN-1, which has a single active center, can have seemingly different activities is proposed. Furthermore, based on the evidence that GEN activity in complex with WRN protein cleaves hairpin and internal loop substrates, we suggest that the GEN activity may prevent repeat expansions and duplication mutations.     

The nature of the 5'-terminus is a major determinant for DNA processing by Schizosaccharomyces pombe Rad2p, a FEN-1 family nuclease

The nuclease activity of FEN-1 is essential for both DNA replication and repair. Intermediate DNA products formed during these processes possess a variety of structures and termini. We have previously demonstrated that the 5′→3′ exonuclease activity of the Schizosaccharomyces pombe FEN-1 protein Rad2p requires a 5′-phosphoryl moiety to efficiently degrade a nick-containing substrate in a reconstituted alternative excision repair system. Here we report the effect of different 5′-terminal moieties of a variety of DNA substrates on Rad2p activity. We also show that Rad2p possesses a 5′→3′ single-stranded exonuclease activity, similar to Saccharomyces cerevisiae Rad27p and phage T5 5′→3′ exonuclease (also a FEN-1 homolog). FEN-1 nucleases have been associated with the base excision repair pathway, specifically processing cleaved abasic sites. Because several enzymes cleave abasic sites through different mechanisms resulting in different 5′-termini, we investigated the ability of Rad2p to process several different types of cleaved abasic sites. With varying efficiency, Rad2p degrades the products of an abasic site cleaved by Escherichia coli endonuclease III and endonuclease IV (prototype AP endonucleases) and S.pombe Uve1p. These results provide important insights into the roles of Rad2p in DNA repair processes in S.pombe.     

Structure of an archaeal PCNA1-PCNA2-FEN1 complex: elucidating PCNA subunit and client enzyme specificity

The archaeal/eukaryotic proliferating cell nuclear antigen (PCNA) toroidal clamp interacts with a host of DNA modifying enzymes, providing a stable anchorage and enhancing their respective processivities. Given the broad range of enzymes with which PCNA has been shown to interact, relatively little is known about the mode of assembly of functionally meaningful combinations of enzymes on the PCNA clamp. We have determined the X-ray crystal structure of the Sulfolobus solfataricus PCNA1–PCNA2 heterodimer, bound to a single copy of the flap endonuclease FEN1 at 2.9 Å resolution. We demonstrate the specificity of interaction of the PCNA subunits to form the PCNA1–PCNA2–PCNA3 heterotrimer, as well as providing a rationale for the specific interaction of the C-terminal PIP-box motif of FEN1 for the PCNA1 subunit. The structure explains the specificity of the individual archaeal PCNA subunits for selected repair enzyme ‘clients’, and provides insights into the co-ordinated assembly of sequential enzymatic steps in PCNA-scaffolded DNA repair cascades.     

Contrasting effects of Elg1-RFC and Ctf18-RFC inactivation in the absence of fully functional RFC in fission yeast

Proliferating cell nuclear antigen loading onto DNA by replication factor C (RFC) is a key step in eukaryotic DNA replication and repair processes. In this study, the C-terminal domain (CTD) of the large subunit of fission yeast RFC is shown to be essential for its function in vivo. Cells carrying a temperature-sensitive mutation in the CTD, rfc1-44, arrest with incompletely replicated chromosomes, are sensitive to DNA damaging agents, are synthetically lethal with other DNA replication mutants, and can be suppressed by mutations in rfc5. To assess the contribution of the RFC-like complexes Elg1–RFC and Ctf18–RFC to the viability of rfc1-44, genes encoding the large subunits of these complexes have been deleted and overexpressed. Inactivation of Ctf18–RFC by the deletion of ctf18⁺, dcc1⁺ or ctf8⁺ is lethal in an rfc1-44 background showing that full Ctf18–RFC function is required in the absence of fully functional RFC. In contrast, rfc1-44 elg1Δ cells are viable and overproduction of Elg1 in rfc1-44 is lethal, suggesting that Elg1–RFC plays a negative role when RFC function is inhibited. Consistent with this, the deletion of elg1⁺ is shown to restore viability to rfc1-44 ctf18Δ cells.     

Two modes of FEN1 binding to PCNA regulated by DNA

The FEN1 nuclease functions during Okazaki fragment maturation in the eukaryotic cell. Like many other proliferating cell nuclear antigen (PCNA)-binding proteins, FEN1 interacts with the interdomain connector loop (IDCL) of PCNA, and PCNA greatly stimulates FEN1 activity. A yeast IDCL mutant pcna-79 (IL126,128AA) failed to interact with FEN-1, but, surprisingly, pcna-79 was still very active in stimulating FEN1 activity. In contrast, a C-terminal mutant pcna-90 (PK252,253AA) showed wild-type binding to FEN1 in solution, but poorly stimulated FEN1 activity. When PCNA was loaded onto a DNA substrate coupled to magnetic beads, it stabilized retention of FEN1 on the DNA. In this DNA-dependent binding assay, pcna-79 also stabilized retention of FEN1, but pcna-90 was inactive. Therefore, in the absence of DNA, FEN1 interacts with PCNA mainly through the IDCL. However, when PCNA encircles the DNA, the C-terminal domain of PCNA rather than its IDCL is important for binding FEN1. An FF-->GA mutation in the PCNA-interaction domain of FEN1 severely decreased both modes of interaction with PCNA and resulted in replication and repair defects in vivo.     

Human Parvovirus B19 Infection Causes Cell Cycle Arrest of Human Erythroid Progenitors at Late S Phase That Favors Viral DNA Replication

Human parvovirus B19 (B19V) infection has a unique tropism to human erythroid progenitor cells (EPCs) in human bone marrow and the fetal liver. It has been reported that both B19V infection and expression of the large nonstructural protein NS1 arrested EPCs at a cell cycle status with a 4 N DNA content, which was previously claimed to be “G₂/M arrest.” However, a B19V mutant infectious DNA (M20^mTAD2) replicated well in B19V-semipermissive UT7/Epo-S1 cells but did not induce G₂/M arrest (S. Lou, Y. Luo, F. Cheng, Q. Huang, W. Shen, S. Kleiboeker, J. F. Tisdale, Z. Liu, and J. Qiu, J. Virol. 86:10748–10758, 2012). To further characterize cell cycle arrest during B19V infection of EPCs, we analyzed the cell cycle change using 5-bromo-2′-deoxyuridine (BrdU) pulse-labeling and DAPI (4′,6-diamidino-2-phenylindole) staining, which precisely establishes the cell cycle pattern based on both cellular DNA replication and nuclear DNA content. We found that although both B19V NS1 transduction and infection immediately arrested cells at a status of 4 N DNA content, B19V-infected 4 N cells still incorporated BrdU, indicating active DNA synthesis. Notably, the BrdU incorporation was caused neither by viral DNA replication nor by cellular DNA repair that could be initiated by B19V infection-induced cellular DNA damage. Moreover, several S phase regulators were abundantly expressed and colocalized within the B19V replication centers. More importantly, replication of the B19V wild-type infectious DNA, as well as the M20^mTAD2 mutant, arrested cells at S phase. Taken together, our results confirmed that B19V infection triggers late S phase arrest, which presumably provides cellular S phase factors for viral DNA replication.     

Human RECQL5β stimulates flap endonuclease 1

Human RECQL5 is a member of the RecQ helicase family which is implicated in genome maintenance. Five human members of the family have been identified; three of them, BLM, WRN and RECQL4 are associated with elevated cancer risk. RECQL1 and RECQL5 have not been linked to any human disorder yet; cells devoid of RECQL1 and RECQL5 display increased chromosomal instability. Here, we report the physical and functional interaction of the large isomer of RECQL5, RECQL5β, with the human flap endonuclease 1, FEN1, which plays a critical role in DNA replication, recombination and repair. RECQL5β dramatically stimulates the rate of FEN1 cleavage of flap DNA substrates. Moreover, we show that RECQL5β and FEN1 interact physically and co-localize in the nucleus in response to DNA damage. Our findings, together with the previous literature on WRN, BLM and RECQL4’s stimulation of FEN1, suggests that the ability of RecQ helicases to stimulate FEN1 may be a general feature of this class of enzymes. This could indicate a common role for the RecQ helicases in the processing of oxidative DNA damage.     

Mitochondria-targeted Ogg1 and Aconitase-2 Prevent Oxidant-induced Mitochondrial DNA Damage in Alveolar Epithelial Cells

Mitochondria-targeted human 8-oxoguanine DNA glycosylase (mt-hOgg1) and aconitase-2 (Aco-2) each reduce oxidant-induced alveolar epithelial cell (AEC) apoptosis, but it is unclear whether protection occurs by preventing AEC mitochondrial DNA (mtDNA) damage. Using quantitative PCR-based measurements of mitochondrial and nuclear DNA damage, mtDNA damage was preferentially noted in AEC after exposure to oxidative stress (e.g. amosite asbestos (5–25 μg/cm²) or H₂O₂ (100–250 μm)) for 24 h. Overexpression of wild-type mt-hOgg1 or mt-long α/β 317–323 hOgg1 mutant incapable of DNA repair (mt-hOgg1-Mut) each blocked A549 cell oxidant-induced mtDNA damage, mitochondrial p53 translocation, and intrinsic apoptosis as assessed by DNA fragmentation and cleaved caspase-9. In contrast, compared with controls, knockdown of Ogg1 (using Ogg1 shRNA in A549 cells or primary alveolar type 2 cells from ogg1^−/− mice) augmented mtDNA lesions and intrinsic apoptosis at base line, and these effects were increased further after exposure to oxidative stress. Notably, overexpression of Aco-2 reduced oxidant-induced mtDNA lesions, mitochondrial p53 translocation, and apoptosis, whereas siRNA for Aco-2 (siAco-2) enhanced mtDNA damage, mitochondrial p53 translocation, and apoptosis. Finally, siAco-2 attenuated the protective effects of mt-hOgg1-Mut but not wild-type mt-hOgg1 against oxidant-induced mtDNA damage and apoptosis. Collectively, these data demonstrate a novel role for mt-hOgg1 and Aco-2 in preserving AEC mtDNA integrity, thereby preventing oxidant-induced mitochondrial dysfunction, p53 mitochondrial translocation, and intrinsic apoptosis. Furthermore, mt-hOgg1 chaperoning of Aco-2 in preventing oxidant-mediated mtDNA damage and apoptosis may afford an innovative target for the molecular events underlying oxidant-induced toxicity.     

Heteroduplex Repair as an Intermediate Step of Uv Mutagenesis in Yeast

We have measured UV-induced mutation frequencies in yeast in a forward, nonselective assay system by scoring white adex ade2 double auxotrophs among parental red-pigmented ade2 clones. The frequencies of sectored and pure mutant clones were determined separately. In excision-defective strains carrying the genes rad1–1, rad3–2 and rad4–4, as well as in the double mutants, rad 1–1 rad 3–2 and rad 1–1 rad 4–4, considerably more sectored than pure clones are induced in the low-dose range; in repair-competent strains, pure mutant clones substantially outnumber the sectored clones. These results can be explained on the basis of known differences in the timing of error-prone repair during the cell division cycle; that is, we assume that error-prone repair occurs primarily before replication in RAD wild-type strains but after replication in excision-deficient mutants. It has been suggested that excision deficiency has a pleiotropic effect on heteroduplex repair and nucleotide excision repair; however, the high percentage (36.6%) of half-sectored clones found in the rad1–1 strain is hard to reconcile with this hypothesis. We propose that heteroduplex repair occurs subsequent to error-prone repair in both excision-proficient and excision-deficient strains.     

A sensitive scanning technology for low frequency nuclear point mutations in human genomic DNA

Knowledge of the kinds and numbers of nuclear point mutations in human tissues is essential to the understanding of the mutation mechanisms underlying genetic diseases. However, nuclear point mutant fractions in normal humans are so low that few methods exist to measure them. We have now developed a means to scan for point mutations in 100 bp nuclear single copy sequences at mutant fractions as low as 10^–6. Beginning with about 10⁸ human cells we first enrich for the desired nuclear sequence 10 000-fold from the genomic DNA by sequence-specific hybridization coupled with a biotin–streptavidin capture system. We next enrich for rare mutant sequences 100-fold against the wild-type sequence by wide bore constant denaturant capillary electrophoresis (CDCE). The mutant-enriched sample is subsequently amplified by high fidelity PCR using fluorescein-labeled primers. Amplified mutant sequences are further enriched via two rounds of CDCE coupled with high fidelity PCR. Individual mutants, seen as distinct peaks on CDCE, are then isolated and sequenced. We have tested this approach by measuring N-methyl-N ′-nitro-N-nitrosoguanidine (MNNG)-induced point mutations in a 121 bp sequence of the adenomatous polyposis coli gene (APC) in human lymphoblastoid MT1 cells. Twelve different MNNG-induced GC→AT transitions were reproducibly observed in MNNG-treated cells at mutant fractions between 2 × 10^–6 and 9 × 10^–6. The sensitivity of this approach was limited by the fidelity of Pfu DNA polymerase, which created 14 different GC→TA transversions at a mutant fraction equivalent to ~10^–6 in the original samples. The approach described herein should be general for all DNA sequences suitable for CDCE analysis. Its sensitivity and capacity would permit detection of stem cell mutations in tissue sectors consisting of ~10⁸ cells.     

Stability of 2'-deoxyxanthosine in DNA

The deamination of nucleobases in DNA occurs by a variety of mechanisms and results in the formation of hypoxanthine from adenine, uracil from cytosine, and xanthine and oxanine from guanine. 2′-Deoxyxanthosine (dX) has been assumed to be an unstable lesion in cells, yet no study has been performed under biological conditions. We now report that dX is a relatively stable lesion at pH 7, 37°C and 110 mM ionic strength, with a half-life (t_1/2) of 2.4 years in double-stranded DNA. The stability of dX as a 2′-deoxynucleoside (t_1/2 = 3.7 min at pH 2; 1104 h at pH 6) was increased substantially upon incorporation into a single-stranded oligodeoxynucleotide, in which the half-life of dX at different pH values was found to range from 7.7 h at pH 2 to 17 700 h at pH 7. Incorporation of dX into a double-stranded oligodeoxynucleotide resulted in a statistically insignificant increase in the half-life to 20 900 h at pH 7. Data for the pH dependence of the stability of dX in single-stranded DNA were used to determine the rate constants for the acid-catalyzed (2.6 × 10^–5 s^–1) and pH-independent (1.4 × 10^–8 s^–1) depurination reactions for dX as well as the dissociation constant for the N⁷ position of dX (6.1 × 10^–4 M). We conclude that dX is a relatively stable lesion that could play a role in deamination-induced mutagenesis.     

Isolation and Characterization of pso Mutants Sensitive to Photo-Addition of Psoralen Derivatives in SACCHAROMYCES CEREVISIAE

We have isolated mutants sensitive to photo-addition of bi-functional and mono-functional derivatives of psoralen in Saccharomyces cerevisiae. Three of these pso mutants were analyzed in detail. They segregate in meiosis like Mendelian genes and complement each other, as well as existing radiation-sensitive (rad and rev) mutants. The study of heterozygous diploid strains (PSO⁺/pso) indicates that the three pso genes are recessive. The mutant pso1–1 demonstrates a cross-sensitivity to UV and γ-rays, whereas mutants pso2–1 and pso3–1 are specifically sensitive to photo-addition of psoralen derivatives. The comparison of exponentially growing cells to stationary-phase cells demonstrates that for the three mutants the defect in repair capacity of DNA cross-links and monoadducts concerns G1 and early S-phase cells. The pso2–1 mutant is, however, also defective in G2 repair and loses diploid resistance when it is in the homozygous state.—The block in repair capacity in these novel mutants is discussed in relation to the three other repair pathways known to be involved in the repair of furocoumarins photo-induced lesions in yeast DNA.     

Role of EXO1 nuclease activity in genome maintenance,the immune response and tumor suppression in Exo1D173A mice

DNA damage response pathways rely extensively on nuclease activity to process DNA intermediates. Exonuclease 1 (EXO1) is a pleiotropic evolutionary conserved DNA exonuclease involved in various DNA repair pathways, replication, antibody diversification, and meiosis. But, whether EXO1 facilitates these DNA metabolic processes through its enzymatic or scaffolding functions remains unclear. Here, we dissect the contribution of EXO1 enzymatic versus scaffolding activity by comparing Exo1^DA/DA mice expressing a proven nuclease-dead mutant form of EXO1 to entirely EXO1-deficient Exo1^−/− and EXO1 wild type Exo1^+/+ mice. We show that Exo1^DA/DA and Exo1^–/– mice are compromised in canonical DNA repair processing, suggesting that the EXO1 enzymatic role is important for error-free DNA mismatch and double-strand break repair pathways. However, in non-canonical repair pathways, EXO1 appears to have a more nuanced function. Next-generation sequencing of heavy chain V region in B cells showed the mutation spectra of Exo1^DA/DA mice to be intermediate between Exo1^+/+ and Exo1^–/– mice, suggesting that both catalytic and scaffolding roles of EXO1 are important for somatic hypermutation. Similarly, while overall class switch recombination in Exo1^DA/DA and Exo1^–/– mice was comparably defective, switch junction analysis suggests that EXO1 might fulfill an additional scaffolding function downstream of class switching. In contrast to Exo1^−/− mice that are infertile, meiosis progressed normally in Exo1^DA/DA and Exo1^+/+ cohorts, indicating that a structural but not the nuclease function of EXO1 is critical for meiosis. However, both Exo1^DA/DA and Exo1^–/– mice displayed similar mortality and cancer predisposition profiles. Taken together, these data demonstrate that EXO1 has both scaffolding and enzymatic functions in distinct DNA repair processes and suggest a more composite and intricate role for EXO1 in DNA metabolic processes and disease.     

Regulation and Functional Contribution of Thymidine Kinase 1 in Repair of DNA Damage

Cellular supply of dNTPs is essential in the DNA replication and repair processes. Here we investigated the regulation of thymidine kinase 1 (TK1) in response to DNA damage and found that genotoxic insults in tumor cells cause up-regulation and nuclear localization of TK1. During recovery from DNA damage, TK1 accumulates in p53-null cells due to a lack of mitotic proteolysis as these cells are arrested in the G₂ phase by checkpoint activation. We show that in p53-proficient cells, p21 expression in response to DNA damage prohibits G₁/S progression, resulting in a smaller G₂ fraction and less TK1 accumulation. Thus, the p53 status of tumor cells affects the level of TK1 after DNA damage through differential cell cycle control. Furthermore, it was shown that in HCT-116 p53^−/− cells, TK1 is dispensable for cell proliferation but crucial for dTTP supply during recovery from DNA damage, leading to better survival. Depletion of TK1 decreases the efficiency of DNA repair during recovery from DNA damage and generates more cell death. Altogether, our data suggest that more dTTP synthesis via TK1 take place after genotoxic insults in tumor cells, improving DNA repair during G₂ arrest.     

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.     

PARP-1 ensures regulation of replication fork progression by homologous recombination on damaged DNA

Poly-ADP ribose polymerase 1 (PARP-1) is activated by DNA damage and has been implicated in the repair of single-strand breaks (SSBs). Involvement of PARP-1 in other DNA damage responses remains controversial. In this study, we show that PARP-1 is required for replication fork slowing on damaged DNA. Fork progression in PARP-1^−/− DT40 cells is not slowed down even in the presence of DNA damage induced by the topoisomerase I inhibitor camptothecin (CPT). Mammalian cells treated with a PARP inhibitor or PARP-1–specific small interfering RNAs show similar results. The expression of human PARP-1 restores fork slowing in PARP-1^−/− DT40 cells. PARP-1 affects SSB repair, homologous recombination (HR), and nonhomologous end joining; therefore, we analyzed the effect of CPT on DT40 clones deficient in these pathways. We find that fork slowing is correlated with the proficiency of HR-mediated repair. Our data support the presence of a novel checkpoint pathway in which the initiation of HR but not DNA damage delays the fork progression.     

Okazaki fragment maturation involves α-segment error editing by the mammalian FEN1/MutSα functional complex

During nuclear DNA replication, proofreading-deficient DNA polymerase α (Pol α) initiates Okazaki fragment synthesis with lower fidelity than bulk replication by proofreading-proficient Pol δ or Pol ε. Here, we provide evidence that the exonuclease activity of mammalian flap endonuclease (FEN1) excises Pol α replication errors in a MutSα-dependent, MutLα-independent mismatch repair process we call Pol α-segment error editing (AEE). We show that MSH2 interacts with FEN1 and facilitates its nuclease activity to remove mismatches near the 5′ ends of DNA substrates. Mouse cells and mice encoding FEN1 mutations display AEE deficiency, a strong mutator phenotype, enhanced cellular transformation, and increased cancer susceptibility. The results identify a novel role for FEN1 in a specialized mismatch repair pathway and a new cancer etiological mechanism.     

Differential processing of UV mimetic and interstrand crosslink damage by XPF cell extracts

We have recently developed a mammalian cell free assay in which interstrand crosslinks induce DNA synthesis in both damaged and undamaged plasmids co-incubated in the same extract. We have also shown using hamster mutants that both ERCC1 and XPF are required for the observed incorporation. Here, we show that extracts from an XPF patient cell line differentially process UV mimetic damage and interstrand crosslinks in vitro. XPF extracts are highly defective in the stimulation of repair synthesis by N-acetoxy-N- acetylaminofluorene, but are proficient in the stimulation of DNA synthesis by psoralen interstrand crosslinks. In addition, we show that extracts from the hamster UV140 mutant, which has high UV sensitivity, but moderate mitomycin C sensitivity, are similar in both assays to XPF cell extracts. These findings support the hypothesis that the activities of XPF in nucleotide excision repair (NER) and crosslink repair are separable, and that mutations in XPF patients result in the abolition of NER, but not recombinational repair pathways, which are likely to be essential as has been observed in ERCC1 homozygous –/– mice.