The long N-terminus of the C. elegans DNA repair enzyme APN-1 targets the protein to the nucleus of a heterologous system

We previously isolated from a Caenorhabditis elegans cDNA library, designed for two-hybrid screening, a gene encoding the DNA repair enzyme APN-1 using cross-specie complementation analysis of the Saccharomyces cerevisiae apn1? apn2? tpp1? triple mutant deficient in the ability to repair several types of DNA lesions including apurinic/apyrimidinic (AP) sites. We subsequently purified the APN-1 from this yeast mutant and demonstrated that it possesses four distinct DNA repair activities. However, following the re-annotation of the C. elegans genome we discovered that the functionally active APN-1 encoded by the cDNA from the library might lack 108 amino acid residues from the N-terminus. We therefore synthesized the entire C. elegans apn-1 gene encoding the putative full-length APN-1 and created several N-terminal deletion mutants lacking either 63, 83 or 118 amino acid residues. The full-length APN-1, APN-1 (1–63Δ) and APN-1 (1–83Δ), but not APN-1 (1–118Δ) were stably expressed in the yeast triple mutant and cleaved the AP site substrate. However, only the full-length APN-1 rescued the yeast mutant from the genotoxicity caused by methyl methane sulfonate, a DNA damaging agent that creates AP sites in the genome. The full-length APN-1 was localized to the yeast nucleus, while APN-1 (1–63Δ) and APN-1 (1–83Δ) retained a cytoplasmic distribution. Our data suggest that the N-terminal region has no direct role in the DNA repair functions of APN-1 other than to target the protein to the nucleus and possibly to maintain its stability. Thus, the truncated APN-1, previously isolated from the two-hybrid library, ability to complement the yeast triple mutant depends on the engineered SV40 nuclear localization signal.     

p300-mediated Acetylation of Histone H3 Lysine 56 Functions in DNA Damage Response in Mammals

The packaging of newly replicated and repaired DNA into chromatin is crucial for the maintenance of genomic integrity. Acetylation of histone H3 core domain lysine 56 (H3K56ac) has been shown to play a crucial role in compaction of DNA into chromatin following replication and repair in Saccharomyces cerevisiae. However, the occurrence and function of such acetylation has not been reported in mammals. Here we show that H3K56 is acetylated and that this modification is regulated in a cell cycle-dependent manner in mammalian cells. We also demonstrate that the histone acetyltransferase p300 acetylates H3K56 in vitro and in vivo, whereas hSIRT2 and hSIRT3 deacetylate H3K56ac in vivo. Further we show that following DNA damage H3K56 acetylation levels increased, and acetylated H3K56, which is localized at the sites of DNA repair. It also colocalized with other proteins involved in DNA damage signaling pathways such as phospho-ATM, CHK2, and p53. Interestingly, analysis of occurrence of H3K56 acetylation using ChIP-on-chip revealed its genome-wide spread, affecting genes involved in several pathways that are implicated in tumorigenesis such as cell cycle, DNA damage response, DNA repair, and apoptosis.     

The role of MutY homolog (Myh1) in controlling the histone deacetylase Hst4 in the fission yeast Schizosaccharomyces pombe

The DNA glycosylase MutY homolog (Myh1) excises adenines misincorporated opposite guanines or 7,8-dihydro-8-oxo-guanines on DNA by base excision repair thereby preventing G:C to T:A mutations. Schizosaccharomyces pombe (Sp) Hst4 is an NAD⁺-dependent histone/protein deacetylase involved in gene silencing and maintaining genomic integrity. Hst4 regulates deacetylation of histone 3 Lys56 at the entry and exit points of the nucleosome core particle. Here, we demonstrate that the hst4 mutant is more sensitive to H₂O₂ than wild-type cells. H₂O₂ treatment results in an SpMyh1-dependent decrease in SpHst4 protein level and hyperacetylation of histone 3 Lys56. Furthermore, SpHst4 interacts with SpMyh1 and the cell cycle checkpoint Rad9-Rad1-Hus1 (9-1-1) complex. SpHst4, SpMyh1, and SpHus1 are physically bound to telomeres. Following oxidative stress, there is an increase in the telomeric association of SpMyh1. Conversely, the telomeric association of spHst4 is decreased. Deletion of SpMyh1 strongly abrogated telomeric association of SpHst4 and SpHus1. However, telomeric association of SpMyh1 is enhanced in hst4Δ cells in the presence of chronic DNA damage. These results suggest that SpMyh1 repair regulates the functions of SpHst4 and the 9-1-1 complex in maintaining genomic stability.     

dRecQ4 Is Required for DNA Synthesis and Essential for Cell Proliferation in Drosophila

Background

The family of RecQ DNA helicases plays an important role in the maintenance of genomic integrity. Mutations in three of the five known RecQ family members in humans, BLM, WRN and RecQ4, lead to disorders that are characterized by predisposition to cancer and premature aging.

Methodology/Principal Findings

To address the in vivo functions of Drosophila RecQ4 (dRecQ4), we generated mutant alleles of dRecQ4 using the targeted gene knock-out technique. Our data show that dRecQ4 mutants are homozygous lethal with defects in DNA replication, cell cycle progression and cell proliferation. Two sets of experiments suggest that dRecQ4 also plays a role in DNA double strand break repair. First, mutant animals exhibit sensitivity to gamma irradiation. Second, the efficiency of DsRed reconstitution via single strand annealing repair is significantly reduced in the dRecQ4 mutant animals. Rescue experiments further show that both the N-terminal domain and the helicase domain are essential to dRecQ4 function in vivo. The N-terminal domain is sufficient for the DNA repair function of dRecQ4.

Conclusions/Significance

Together, our results show that dRecQ4 is an essential gene that plays an important role in not only DNA replication but also DNA repair and cell cycle progression in vivo.     

Anti-cancer drug KP1019 modulates epigenetics and induces DNA damage response in Saccharomyces cerevisiae

KP1019 comprises a class of ruthenium compounds having promising anticancer activity. Here, we investigated the molecular targets of KP1019 using Saccharomyces cerevisiae as a model organism. Our results revealed that in the absence of the N-terminal tail of histone H3, the growth inhibitory effect of KP1019 was markedly enhanced. Furthermore, H3K56A or rtt109Δ mutants exhibit hypersensitivity for KP1019. Moreover, KP1019 evicts histones from the mononucleosome and interacts specifically with histone H3. We have also shown that KP1019 treatment causes induction of Ribonucleotide Reductase (RNR) genes and degradation of Sml1p. Our results also suggest that DNA damage induced by KP1019 is primarily repaired through double-strand break repair (DSBR). In summary, KP1019 targets histone proteins, with important consequences for DNA damage responses and epigenetics.     

Biochemical and mutational analysis of EcoRII functional domains reveals evolutionary links between restriction enzymes

The archetypal Type IIE restriction endonuclease EcoRII is a dimer that has a modular structure. DNA binding studies indicate that the isolated C-terminal domain dimer has an interface that binds a single cognate DNA molecule whereas the N-terminal domain is a monomer that also binds a single copy of cognate DNA. Hence, the full-length EcoRII contains three putative DNA binding interfaces: one at the C-terminal domain dimer and two at each of the N-terminal domains. Mutational analysis indicates that the C-terminal domain shares conserved active site architecture and DNA binding elements with the tetrameric restriction enzyme NgoMIV. Data provided here suggest possible evolutionary relationships between different subfamilies of restriction enzymes.     

Trinucleotide repeat expansions catalyzed by human cell-free extracts

Trinucleotide repeat expansions cause 17 heritable human neurological disorders. In some diseases, somatic expansions occur in non-proliferating tissues such as brain where DNA replication is limited. This finding stimulated significant interest in replication-independent expansion mechanisms. Aberrant DNA repair is a likely source, based in part on mouse studies showing that somatic expansions are provoked by the DNA repair protein MutSβ (Msh2-Msh3 complex). Biochemical studies to date used cell-free extracts or purified DNA repair proteins to yield partial reactions at triplet repeats. The findings included expansions on one strand but not the other, or processing of DNA hairpin structures thought to be important intermediates in the expansion process. However, it has been difficult to recapitulate complete expansions in vitro, and the biochemical role of MutSβ remains controversial. Here, we use a novel in vitro assay to show that human cell-free extracts catalyze expansions and contractions of trinucleotide repeats without the requirement for DNA replication. The extract promotes a size range of expansions that is similar to certain diseases, and triplet repeat length and sequence govern expansions in vitro as in vivo. MutSβ stimulates expansions in the extract, consistent with aberrant repair of endogenous DNA damage as a source of expansions. Overall, this biochemical system retains the key characteristics of somatic expansions in humans and mice, suggesting that this important mutagenic process can be restored in the test tube.     

Functional characterization of the Caenorhabditis elegans DNA repair enzyme APN-1

Caenorhabditis elegans possesses two distinct DNA repair enzymes EXO-3 and APN-1 that have been identified by cross-specie complementation analysis of the Saccharomyces cerevisiae apn1Δ apn2Δ tpp1Δ triple mutant deficient in the ability to repair apurinic/apyrimidinc (AP) sites and DNA strand breaks with blocked 3′-ends. While purified EXO-3 directly incises AP sites and removes 3′-blocking groups, such characterization has not been previously reported for APN-1. We recently documented that C. elegans knockdown for apn-1 is unable to maintain integrity of the genome. Despite the presence of EXO-3, the apn-1 knockdown animals are also defective in the division of the P1 blastomere, an observation consistent with the accumulation of unrepaired DNA lesions suggesting a unique role for APN-1 DNA repair functions. Herein, we show that C. elegans APN-1 is stably expressed as GST-fusion protein in S. cerevisiae only when it carries a nuclear localization signal, and with this requirement rescued the DNA repair defects of the S. cerevisiae apn1Δ apn2Δ tpp1Δ triple mutant. We purified the APN-1 from the yeast expression system and established that it displays AP endonuclease and 3′-diesterase activities. In addition, we showed that APN-1 also possesses a 3′- to 5′-exonuclease and the nucleotide incision repair activity. This latter activity is capable of directly incising DNA at the 5′-side of various oxidatively damaged bases, as previously observed for Escherichia coli endonuclease IV and S. cerevisiae Apn1, underscoring the importance of this family of enzymes in removing these types of lesions. Glycine substitution of the conserved amino acid residue Glu261 of APN-1, corresponding to Glu145 involved in coordinating Zn²⁺ ions in the active site pocket of E. coli endonuclease IV, resulted in an inactive variant that lose the ability to rescue the DNA repair defects of S. cerevisiae apn1Δ apn2Δ tpp1Δ mutant. Interestingly, the Glu261Gly variant did not sustain purification and yielded a truncated polypeptide. These data suggest that the Glu261 residue of APN-1 may have a broader role in maintaining the structure of the protein.     

Repressor-operator interaction in the lac operon: III. Nuclear magnetic resonance observations with altered amino-terminal DNA binding domains

We have examined the N-terminal 56 amino acid fragment, the domain that can bind DNA independently, from 3-fluorotyrosine-substituted Escherichia coli lac repressor by ¹⁹F-nuclear magnetic resonance. The fragments or “headpieces” from four altered repressers missing each of the tyrosines in turn were examined in parallel. When the wild-type N-terminal fragment is titrated with a 36 base-pair lac operator DNA sequence, the ¹⁹F resonances undergo changes in their chemical shifts that are different from those changes when the N-terminal fragment is titrated with non-specific DNA fragments. By looking at these operator-induced changes as well as pH-dependent effects with all four altered N-terminal fragments, we show systematic correlations with the genetic data. The data lead us to conclude that upon operator DNA binding: (1) tyrosine 7 is displaced to a less polar environment and the higher than normal pK value of the phenolic OH group is decreased; (2) tyrosine 12 does not change much in either its mobility or environment; and (3) tyrosine 17 is involved, as suggested by the genetic data, when the headpiece forms a complex with operator DNA.     

Low-Molecular-Weight DNA Replication Intermediates in Escherichia coli: Mechanism of Formation and Strand Specificity

Chromosomal DNA replication intermediates, revealed in ligase-deficient conditions in vivo, are of low molecular weight (LMW) independently of the organism, suggesting discontinuous replication of both the leading and the lagging DNA strands. Yet, in vitro experiments with purified enzymes replicating sigma-structured substrates show continuous synthesis of the leading DNA strand in complete absence of ligase, supporting the textbook model of semi-discontinuous DNA replication. The discrepancy between the in vivo and in vitro results is rationalized by proposing that various excision repair events nick continuously synthesized leading strands after synthesis, producing the observed LMW intermediates. Here, we show that, in an Escherichia coli ligase-deficient strain with all known excision repair pathways inactivated, new DNA is still synthesized discontinuously. Furthermore, hybridization to strand-specific targets demonstrates that the LMW replication intermediates come from both the lagging and the leading strands. These results support the model of discontinuous leading strand synthesis in E. coli.     

Compensation for the absence of the catalytically active half of DNA polymerase ε in yeast by positively selected mutations in CDC28

Current eukaryotic replication models postulate that leading and lagging DNA strands are replicated predominantly by dedicated DNA polymerases. The catalytic subunit of the leading strand DNA polymerase ε, Pol2, consists of two halves made of two different ancestral B-family DNA polymerases. Counterintuitively, the catalytically active N-terminal half is dispensable, while the inactive C-terminal part is required for viability. Despite extensive studies of yeast Saccharomyces cerevisiae strains lacking the active N-terminal half, it is still unclear how these strains survive and recover. We designed a robust method for constructing mutants with only the C-terminal part of Pol2. Strains without the active polymerase part show severe growth defects, sensitivity to replication inhibitors, chromosomal instability, and elevated spontaneous mutagenesis. Intriguingly, the slow-growing mutant strains rapidly accumulate fast-growing clones. Analysis of genomic DNA sequences of these clones revealed that the adaptation to the loss of the catalytic N-terminal part of Pol2 occurs by a positive selection of mutants with improved growth. Elevated mutation rates help generate sufficient numbers of these variants. Single nucleotide changes in the cell cycle-dependent kinase gene, CDC28, improve the growth of strains lacking the N-terminal part of Pol2, and rescue their sensitivity to replication inhibitors and, in parallel, lower mutation rates. Our study predicts that changes in mammalian homologs of cyclin-dependent kinases may contribute to cellular responses to the leading strand polymerase defects.     

Characterization of two naturally truncated, Ssb-like proteins from the nitrogen-fixing cyanobacterium, Anabaena sp. PCC7120

Single-stranded (ss) DNA-binding (Ssb) proteins are vital for all DNA metabolic processes and are characterized by an N-terminal OB-fold followed by P/G-rich spacer region and a C-terminal tail. In the genome of the heterocystous, nitrogen-fixing cyanobacterium, Anabaena sp. strain PCC 7120, two genes alr0088 and alr7579 are annotated as ssb, but the corresponding proteins have only the N-terminal OB-fold and no P/G-rich region or acidic tail, thereby rendering them unable to interact with genome maintenance proteins. Both the proteins were expressed under normal growth conditions in Anabaena PCC7120 and regulated differentially under abiotic stresses which induce DNA damage, indicating that these are functional genes. Constitutive overexpression of Alr0088 in Anabaena enhanced the tolerance to DNA-damaging stresses which caused formation of DNA adducts such as UV and MitomycinC, but significantly decreased the tolerance to γ-irradiation, which causes single- and double-stranded DNA breaks. On the other hand, overexpression of Alr7579 had no significant effect on normal growth or stress tolerance of Anabaena. Thus, of the two truncated Ssb-like proteins, Alr0088 may be involved in protection of ssDNA from damage, but due to the absence of acidic tail, it may not aid in repair of damaged DNA. These two proteins are present across cyanobacterial genera and unique to them. These initial studies pave the way to the understanding of DNA repair in cyanobacteria, which is not very well documented.     

Characterization of the specific DNA-binding properties of Tnp26, the transposase of insertion sequence IS26

The bacterial insertion sequence (IS) IS26 mobilizes and disseminates antibiotic resistance genes. It differs from bacterial IS that have been studied to date as it exclusively forms cointegrates via either a copy-in (replicative) or a recently discovered targeted conservative mode. To investigate how the Tnp26 transposase recognizes the 14-bp terminal inverted repeats (TIRs) that bound the IS, amino acids in two domains in the N-terminal (amino acids M1–P56) region were replaced. These changes substantially reduced cointegration in both modes. Tnp26 was purified as a maltose-binding fusion protein and shown to bind specifically to dsDNA fragments that included an IS26 TIR. However, Tnp26 with an R49A or a W50A substitution in helix 3 of a predicted trihelical helix–turn–helix domain (amino acids I13–R53) or an F4A or F9A substitution replacing the conserved amino acids in a unique disordered N-terminal domain (amino acids M1–D12) did not bind. The N-terminal M1–P56 fragment also bound to the TIR but only at substantially higher concentrations, indicating that other parts of Tnp26 enhance the binding affinity. The binding site was confined to the internal part of the TIR, and a G to T nucleotide substitution in the TGT at positions 6 to 8 of the TIR that is conserved in most IS26 family members abolished binding of both Tnp26 (M1–M234) and Tnp26 M1–P56 fragment. These findings indicate that the helix–turn–helix and disordered domains of Tnp26 play a role in Tnp26–TIR complex formation. Both domains are conserved in all members of the IS26 family.     

Repair of DNA damage induced by anthanthrene, a polycyclic aromatic hydrocarbon (PAH) without bay or fjord regions

Polycyclic aromatic hydrocarbons (PAHs) are environmental pollutants, formed during incomplete burning of coal, oil and gas. Several PAHs have carcinogenic and mutagenic potencies, but these compounds must be activated in order to exert their mutagenic effects. One of the principal pathways proposed for metabolic activation of PAHs involves the cytochrome P450 enzymes. The DNA damaging potential of cytochrome P450-activated PAHs is generally associated with their bay and fjord regions, and the DNA repair response of PAHs containing such regions has been thoroughly studied. However, little is known about the repair of DNA damage resulting from metabolites from PAHs without bay and fjord regions. We have investigated the six-ringed PAH anthanthrene (dibenzo[def,mno]chrysene), which does not posses bay or fjord motifs. We analyzed the repair profile of human cell extracts and of cell cultures in response to DNA damage induced by cytochrome P450-activated anthanthrene. In cell extracts, functional nucleotide excision repair (NER) and mismatch repair (MMR) activities were necessary to trigger a response to anthanthrene metabolite-induced DNA damage. In cell cultures, NER was responsible for the repair of anthanthrene metabolite-induced DNA damage. However, when the NER pathway was inactivated, a residual repair pathway performed the DNA repair.     

Bcl2 inhibits recruitment of Mre11 complex to DNA double-strand breaks in response to high-linear energy transfer radiation

High-linear energy transfer ionizing radiation, derived from high charge (Z) and energy (E) (HZE) particles, induces clustered/complex DNA double-strand breaks (DSBs) that include small DNA fragments, which are not repaired by the non-homologous end-joining (NHEJ) pathway. The homologous recombination (HR) DNA repair pathway plays a major role in repairing DSBs induced by HZE particles. The Mre11 complex (Mre11/Rad50/NBS1)-mediated resection of DSB ends is a required step in preparing for DSB repair via the HR DNA repair pathway. Here we found that expression of Bcl2 results in decreased HR activity and retards the repair of DSBs induced by HZE particles (i.e. ⁵⁶iron and ²⁸silicon) by inhibiting Mre11 complex activity. Exposure of cells to ⁵⁶iron or ²⁸silicon promotes Bcl2 to interact with Mre11 via the BH1 and BH4 domains. Purified Bcl2 protein directly suppresses Mre11 complex-mediated DNA resection in vitro. Expression of Bcl2 reduces the ability of Mre11 to bind DNA following exposure of cells to HZE particles. Our findings suggest that, after cellular exposure to HZE particles, Bcl2 may inhibit Mre11 complex-mediated DNA resection leading to suppression of the HR-mediated DSB repair in surviving cells, which may potentially contribute to tumor development.     

Pathways for Double-strand Break Repair in Genetically Unstable Z-DNA-forming Sequences

DNA can adopt many structures that differ from the canonical B-form, and several of these non-canonical DNA structures have been implicated in genetic instability associated with human disease. Earlier, we found that Z-DNA causes DNA double-strand breaks (DSBs) in mammalian cells that can result in large-scale deletions and rearrangements. In contrast, the same Z-DNA-forming CG repeat in Escherichia coli resulted in only small contractions or expansions within the repeat. This difference in the Z-DNA-induced mutation spectrum between mammals and bacteria might be due to different mechanisms for DSB repair; in mammalian cells, non-homologous end-joining (NHEJ) is a major DSB repair pathway, while E. coli do not contain this system and typically use homologous recombination (HR) to process DSBs. To test the extent to which the different DSB repair pathways influenced the Z-DNA-induced mutagenesis, we engineered bacterial E.coli strains to express an inducible NHEJ system, to mimic the situation in mammalian cells. Mycobacterium tuberculosis NHEJ proteins Ku and ligase D (LigD) were expressed in E.coli cells in the presence or absence of HR, and the Z-DNA-induced mutations were characterized. We found that the presence of the NHEJ mechanism markedly shifted the mutation spectrum from small deletions/insertions to large-scale deletions (from 2% to 24%). Our results demonstrate that NHEJ plays a role in the generation of Z-DNA-induced large-scale deletions, suggesting that this pathway is associated with DNA structure-induced destabilization of genomes from prokaryotes to eukaryotes.