Translesion synthesis by the UmuC family of DNA polymerases

UV-Induced DNA Repair Mechanisms and Their Effects on Mutagenesis and Culturability in Escherichia coli

Mutagenic processes drive evolutionary progress, with ultraviolet (UV) radiation significantly affecting evolution. Despite extensive research on SOS response-mediated mutagenesis, UV-induced repair mechanisms remain complex, and their effects on cell survival and mutagenesis are not fully understood. We previously observed a near-perfect correlation between RecA-mediated SOS response and mutation levels in Escherichia coli following UV treatment. However, prolonged UV exposure caused transient non-culturability and impaired SOS-mediated mutagenesis. Using fluorescent reporters, flow cytometry, promoter-reporter assays, single-gene deletions, knockouts, and clonogenic assays, we found that excessive UV exposure disrupts cellular translation, reducing SOS gene expression, albeit with minimal impact on membrane permeability or reactive oxygen species levels. While our findings underline the abundance of repair mechanisms in E. coli cells, enabling them to compensate when specific genes are disrupted, they also highlighted the differential impacts of gene deletions on mutagenesis versus culturability, leading to three major outcomes: (i) Disruption of proteins involved in DNA polymerase for translesion synthesis (UmuC and UmuD) or Holliday junction resolution (RuvC) results in significantly decreased mutagenesis levels while maintaining a transient non-culturability pattern after UV exposure. (ii) Disruption of proteins involved in homologous recombination (RecA and RecB) and nucleotide excision repair (UvrA) leads to both significantly reduced mutagenesis and a more severe transient non-culturability pattern after UV exposure, making these cells more sensitive to UV. (iii) Disruption of DNA Helicase II (UvrD), which functions in mismatch repair, does not affect mutagenesis levels from UV radiation but results in a very pronounced transient non-culturability pattern following UV exposure. Overall, our results further advance our understanding of bacterial adaptation mechanisms and the role of DNA repair pathways in shaping mutagenesis.

Comparative sequence analysis of pPATH pathogenicity plasmids in Pantoea agglomerans gall-forming bacteria

Acquisition of the pathogenicity plasmid pPATH that encodes a type III secretion system (T3SS) and effectors (T3Es) has likely led to the transition of a non-pathogenic bacterium into the tumorigenic pathogen Pantoea agglomerans. P. agglomerans pv. gypsophilae (Pag) forms galls on gypsophila (Gypsophila paniculata) and triggers immunity on sugar beet (Beta vulgaris), while P. agglomerans pv. betae (Pab) causes galls on both gypsophila and sugar beet. Draft sequences of the Pag and Pab genomes were previously generated using the MiSeq Illumina technology and used to determine partial T3E inventories of Pab and Pag. Here, we fully assembled the Pab and Pag genomes following sequencing with PacBio technology and carried out a comparative sequence analysis of the Pab and Pag pathogenicity plasmids pPATHpag and pPATHpab. Assembly of Pab and Pag genomes revealed a ~4 Mbp chromosome with a 55% GC content, and three and four plasmids in Pab and Pag, respectively. pPATHpag and pPATHpab share 97% identity within a 74% coverage, and a similar GC content (51%); they are ~156 kb and ~131 kb in size and consist of 198 and 155 coding sequences (CDSs), respectively. In both plasmids, we confirmed the presence of highly similar gene clusters encoding a T3SS, as well as auxin and cytokinins biosynthetic enzymes. Three putative novel T3Es were identified in Pab and one in Pag. Among T3SS-associated proteins encoded by Pag and Pab, we identified two novel chaperons of the ShcV and CesT families that are present in both pathovars with high similarity. We also identified insertion sequences (ISs) and transposons (Tns) that may have contributed to the evolution of the two pathovars. These include seven shared IS elements, and three ISs and two transposons unique to Pab. Finally, comparative sequence analysis revealed plasmid regions and CDSs that are present only in pPATHpab or in pPATHpag. The high similarity and common features of the pPATH plasmids support the hypothesis that the two strains recently evolved into host-specific pathogens.

Mechanistic Basis for the Bypass of a Bulky DNA Adduct Catalyzed by a Y-Family DNA Polymerase

1-Nitropyrene (1-NP), an environmental pollutant, induces DNA damage in vivo and is considered to be carcinogenic. The DNA adducts formed by the 1-NP metabolites stall replicative DNA polymerases but are presumably bypassed by error-prone Y-family DNA polymerases at the expense of replication fidelity and efficiency in vivo. Our running start assays confirmed that a site-specifically placed 8-(deoxyguanosin-N(2)-yl)-1-aminopyrene (dG(1,8)), one of the DNA adducts derived from 1-NP, can be bypassed by Sulfolobus solfataricus DNA polymerase IV (Dpo4), although this representative Y-family enzyme was paused strongly by the lesion. Pre-steady-state kinetic assays were employed to determine the low nucleotide incorporation fidelity and establish a minimal kinetic mechanism for the dG(1,8) bypass by Dpo4. To reveal a structural basis for dCTP incorporation opposite dG(1,8), we solved the crystal structures of the complexes of Dpo4 and DNA containing a templating dG(1,8) lesion in the absence or presence of dCTP. The Dpo4·DNA-dG(1,8) binary structure shows that the aminopyrene moiety of the lesion stacks against the primer/template junction pair, while its dG moiety projected into the cleft between the Finger and Little Finger domains of Dpo4. In the Dpo4·DNA-dG(1,8)·dCTP ternary structure, the aminopyrene moiety of the dG(1,8) lesion, is sandwiched between the nascent and junction base pairs, while its base is present in the major groove. Moreover, dCTP forms a Watson-Crick base pair with dG, two nucleotides upstream from the dG(1,8) site, creating a complex for "-2" frameshift mutation. Mechanistically, these crystal structures provide additional insight into the aforementioned minimal kinetic mechanism.

Recent insight into the kinetic mechanisms and conformational dynamics of Y-Family DNA polymerases

The kinetic mechanisms by which DNA polymerases catalyze DNA replication and repair have long been areas of active research. Recently discovered Y-family DNA polymerases catalyze the bypass of damaged DNA bases that would otherwise block replicative DNA polymerases and stall replication forks. Unlike DNA polymerases from the five other families, the Y-family DNA polymerases have flexible, solvent-accessible active sites that are able to tolerate various types of damaged template bases and allow for efficient lesion bypass. Their promiscuous active sites, however, also lead to fidelities that are much lower than those observed for other DNA polymerases and give rise to interesting mechanistic properties. Additionally, the Y-family DNA polymerases have several other unique structural features and undergo a set of conformational changes during substrate binding and catalysis different from those observed for replicative DNA polymerases. In recent years, pre-steady-state kinetic methods have been extensively employed to reveal a wealth of information about the catalytic properties of these fascinating noncanonical DNA polymerases. Here, we review many of the recent findings on the kinetic mechanisms of DNA polymerization with undamaged and damaged DNA substrates by the Y-family DNA polymerases, and the conformational dynamics employed by these error-prone enzymes during catalysis.

Conformational dynamics of a Y-family DNA polymerase during substrate binding and catalysis as revealed by interdomain Förster resonance energy transfer

Numerous kinetic, structural, and theoretical studies have established that DNA polymerases adjust their domain structures to enclose nucleotides in their active sites and then rearrange critical active site residues and substrates for catalysis, with the latter conformational change acting to kinetically limit the correct nucleotide incorporation rate. Additionally, structural studies have revealed a large conformational change between the apoprotein and the DNA–protein binary state for Y-family DNA polymerases. In previous studies [Xu, C., Maxwell, B. A., Brown, J. A., Zhang, L., and Suo, Z. (2009) PLoS Biol.7, e1000225], a real-time Förster resonance energy transfer (FRET) method was developed to monitor the global conformational transitions of DNA polymerase IV from Sulfolobus solfataricus (Dpo4), a prototype Y-family enzyme, during nucleotide binding and incorporation by measuring changes in distance between locations on the enzyme and the DNA substrate. To elucidate further details of the conformational transitions of Dpo4 during substrate binding and catalysis, in this study, the real-time FRET technique was used to monitor changes in distance between various pairs of locations in the protein itself. In addition to providing new insight into the conformational changes as revealed in previous studies, the results here show that the previously described conformational change between the apo and DNA-bound states of Dpo4 occurs in a mechanistic step distinct from initial formation or dissociation of the binary complex of Dpo4 and DNA.

Following DNA chain extension and protein conformational changes in crystals of a Y-family DNA polymerase via Raman crystallography

Y-Family DNA polymerases are known to bypass DNA lesions in vitro and in vivo. Sulfolobus solfataricus DNA polymerase (Dpo4) was chosen as a model Y-family enzyme for investigating the mechanism of DNA synthesis in single crystals. Crystals of Dpo4 in complexes with DNA (the binary complex) in the presence or absence of an incoming nucleotide were analyzed by Raman microscopy. (13)C- and (15)N-labeled d*CTP, or unlabeled dCTP, were soaked into the binary crystals with G as the templating base. In the presence of the catalytic metal ions, Mg(2+) and Mn(2+), nucleotide incorporation was detected by the disappearance of the triphosphate band of dCTP and the retention of *C modes in the crystal following soaking out of noncovalently bound C(or *C)TP. The addition of the second coded base, thymine, was observed by adding cognate dTTP to the crystal following a single d*CTP addition. Adding these two bases caused visible damage to the crystal that was possibly caused by protein and/or DNA conformational change within the crystal. When d*CTP is soaked into the Dpo4 crystal in the absence of Mn(2+) or Mg(2+), the primer extension reaction did not occur; instead, a ternary protein·template·d*CTP complex was formed. In the Raman difference spectra of both binary and ternary complexes, in addition to the modes of d(*C)CTP, features caused by ring modes from the template/primer bases being perturbed and from the DNA backbone appear, as well as features from perturbed peptide and amino acid side chain modes. These effects are more pronounced in the ternary complex than in the binary complex. Using standardized Raman intensities followed as a function of time, the C(*C)TP population in the crystal was maximal at ∼20 min. These remained unchanged in the ternary complex but declined in the binary complexes as chain incorporation occurred.

The role of the bacterial mismatch repair system in SOS-induced mutagenesis: a theoretical background

A theoretical study is performed of the possible role of the methyl-directed mismatch repair system in the ultraviolet-induced mutagenesis of Escherichia coli bacterial cells. For this purpose, mathematical models of the SOS network, translesion synthesis and mismatch repair are developed. Within the proposed models, the key pathways of these repair systems were simulated on the basis of modern experimental data related to their mechanisms. Our model approach shows a possible mechanistic explanation of the hypothesis that the bacterial mismatch repair system is responsible for attenuation of mutation frequency during ultraviolet-induced SOS response via removal of the nucleotides misincorporated by DNA polymerase V (the UmuD'2C complex).

Complete nucleotide sequence of plasmid pST-III from Lactobacillus plantarum ST-III

The complete nucleotide sequence of the 53,560-bp plasmid pST-III from Lactobacillus plantarum ST-III has been determined. The plasmid contains 42 predicted protein-coding sequences, and the functions of 34 coding sequences could be assigned. Homology analysis for the replication protein and the typical features of the origin of replication suggested that pST-III replicates via the theta-type mechanism. Among the predicted genes, we identified a kdp gene cluster (a high-affinity K(+)-transport system) for the first time in the Lactobacillus genus and a system for osmolyte transport. Analysis of the plasmid-encoded functions and the plasmid-cured experiment showed that the genes of pST-III could serve for the niche adaptations of L. plantarum ST-III and make significant contributions to its viability under hyperosmotic conditions. Furthermore, the relative copy number of pST-III was determined to be 6.79±1.55 copies per cell.

A novel conjugative plasmid from Enterococcus faecalis E99 enhances resistance to ultraviolet radiation

Enterococcus faecalis has emerged as a prominent healthcare-associated pathogen frequently encountered in bacteremia, endocarditis, urinary tract infection, and as a leading cause of antibiotic-resistant infections. We recently demonstrated a capacity for high-level biofilm formation by a clinical E. faecalis isolate, E99. This high biofilm-forming phenotype was attributable to a novel locus, designated bee, specifying a pilus at the bacterial cell surface and localized to a large approximately 80 kb conjugative plasmid. To better understand the origin of the bee locus, as well as to potentially identify additional factors important to the biology and pathogenesis of strain E99, we sequenced the entire plasmid. The nucleotide sequence of the plasmid, designated pBEE99, revealed large regions of identity to the previously characterized conjugative plasmid pCF10. In addition to the bee locus, pBEE99 possesses an open reading frame potentially encoding aggregation substance, as well as open reading frames putatively encoding polypeptides with 60% to 99% identity at the amino acid level to proteins involved in regulation of the pheromone response and conjugal transfer of pCF10. However, strain E99 did not respond to the cCF10 pheromone in clumping assays. While pBEE99 was found to be devoid of any readily recognizable antibiotic resistance determinants, it carries two non-identical impB/mucB/samB-type genes, as well as genes potentially encoding a two-component bacteriocin similar to that encoded on pYI14. Although no bacteriocin activity was detected from an OG1RF transconjugant carrying pBEE99 against strain FA2-2, it was approximately an order of magnitude more resistant to ultraviolet radiation. Moreover, curing strain E99 of this plasmid significantly reduced its ability to survive UV exposure. Therefore, pBEE99 represents a novel conjugative plasmid that confers biofilm-forming and enhanced UV resistance traits that might potentially impact the virulence and/or fitness of E. faecalis.

Control of genome stability by SLX protein complexes

The six Saccharomyces cerevisiae SLX genes were identified in a screen for factors required for the viability of cells lacking Sgs1, a member of the RecQ helicase family involved in processing stalled replisomes and in the maintenance of genome stability. The six SLX gene products form three distinct heterodimeric complexes, and all three have catalytic activity. Slx3-Slx2 (also known as Mus81-Mms4) and Slx1-Slx4 are both heterodimeric endonucleases with a marked specificity for branched replication fork-like DNA species, whereas Slx5-Slx8 is a SUMO (small ubiquitin-related modifier)-targeted E3 ubiquitin ligase. All three complexes play important, but distinct, roles in different aspects of the cellular response to DNA damage and perturbed DNA replication. Slx4 interacts physically not only with Slx1, but also with Rad1-Rad10 [XPF (xeroderma pigmentosum complementation group F)-ERCC1 (excision repair cross-complementing 1) in humans], another structure-specific endonuclease that participates in the repair of UV-induced DNA damage and in a subpathway of recombinational DNA DSB (double-strand break) repair. Curiously, Slx4 is essential for repair of DSBs by Rad1-Rad10, but is not required for repair of UV damage. Slx4 also promotes cellular resistance to DNA-alkylating agents that block the progression of replisomes during DNA replication, by facilitating the error-free mode of lesion bypass. This does not require Slx1 or Rad1-Rad10, and so Slx4 has several distinct roles in protecting genome stability. In the present article, I provide an overview of our current understanding of the cellular roles of the Slx proteins, paying particular attention to the advances that have been made in understanding the cellular roles of Slx4. In particular, protein-protein interactions and underlying molecular mechanisms are discussed and I draw attention to the many questions that have yet to be answered.

Differential gene expression in Escherichia coli following exposure to nonthermal atmospheric pressure plasma

AIM

Nonthermal atmospheric-pressure plasmas offer significant advantages as an emerging disinfection approach. However the mechanisms of inactivation, and thus the means of optimizing them, are still poorly understood. The objective of this study, therefore, was to explore differential gene expression on a genome-wide scale in Escherichia coli following exposure to a nonthermal atmospheric-pressure argon plasma plume using high-density oligonucleotide microarrays.

METHODS AND RESULTS

Plasma exposure was found to significantly induce the SOS mechanism, consisting of about 20 genes. Other genes involved in regulating response to oxidative stress were also observed to be up-regulated. Conversely, the expression of several genes responsible for housekeeping functions, ion transport, and metabolism was observed to be down-regulated.

CONCLUSIONS

Elevated yet incomplete induction of various DNA damage repair processes, including translesion synthesis, suggests substantial DNA damage in E. coli. Oxidative stress also appeared to play a role. Thus it is proposed that the efficacy of plasma is due to the synergistic impact of UV photons and oxygen radicals on the bacteria.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study represents the first investigation of differential gene expression on a genome-wide scale in an organism following plasma exposure. The results of this study will help enable the design of safe and effective plasma decontamination devices.

Eukaryotic DNA damage tolerance and translesion synthesis through covalent modifications of PCNA

In addition to well-defined DNA repair pathways, all living organisms have evolved mechanisms to avoid cell death caused by replication fork collapse at a site where replication is blocked due to disruptive covalent modifications of DNA. The term DNA damage tolerance (DDT) has been employed loosely to include a collection of mechanisms by which cells survive replication-blocking lesions with or without associated genomic instability. Recent genetic analyses indicate that DDT in eukaryotes, from yeast to human, consists of two parallel pathways with one being error-free and another highly mutagenic. Interestingly, in budding yeast, these two pathways are mediated by sequential modifications of the proliferating cell nuclear antigen (PCNA) by two ubiquitination complexes Rad6-Rad18 and Mms2-Ubc13-Rad5. Damage-induced monoubiquitination of PCNA by Rad6-Rad18 promotes translesion synthesis (TLS) with increased mutagenesis, while subsequent polyubiquitination of PCNA at the same K164 residue by Mms2-Ubc13-Rad5 promotes error-free lesion bypass. Data obtained from recent studies suggest that the above mechanisms are conserved in higher eukaryotes. In particular, mammals contain multiple specialized TLS polymerases. Defects in one of the TLS polymerases have been linked to genomic instability and cancer.

Molecular modeling benzo[a]pyrene N2-dG adducts in the two overlapping active sites of the Y-family DNA polymerase Dpo4

The potent, ubiquitous environmental mutagen/carcinogen benzo[a]pyrene (B[a]P) induces a single major adduct [+ta]-B[a]P-N2-dG, whose bypass in most cases results in either no mutation (dCTP insertion) or a G-->T mutation (dATP insertion). Translesion synthesis (TLS) of [+ta]-B[a]P-N2-dG generally requires DNA polymerases (DNAPs) in the Y-family, which exist in cells to bypass DNA damage caused by chemicals and radiation. A molecular dynamics (MD) study is described with dCTP opposite [+ta]-B[a]P-N2-dG in Dpo4, which is the best studied Y-family DNAP from a structural point of view. Two orientations of B[a]P-N2-dG (BPmi5 and BPmi3) are considered, along with two orientations of the dCTP (AS1 and AS2), as outlined next. Based on NMR studies, the pyrene moiety of B[a]P-N2-dG is in the minor groove, when paired with dC, and can point toward either the base on the 5'-side (BPmi5) or the 3'-side (BPmi3). Based on published X-ray structures, Dpo4 appears to have two partially overlapping active sites. The architecture of active site 1 (AS1) is similar to all other families of DNAPs (e.g., the shape of the dNTP). Active site 2 (AS2), however, is non-canonical (e.g., the beta- and gamma-phosphates in AS2 are approximately where the alpha- and beta-phosphates are in AS1). In the Dpo4 models generated herein, using the BPmi3 orientation the pyrene moiety of [+ta]-B[a]P-N2-dG points toward the duplex region of the DNA, and is accommodated without distortions in AS1, but with distortions in AS2. Considering the BPmi5 orientation, the pyrene moiety points toward the ss-region of DNA in Dpo4, and sits in a hole defined by the fingers and little fingers domain ("chimney"); BPmi5 is accommodated in AS2 without significant distortions, but poorly in AS1. In summary, when dCTP is paired with [+ta]-B[a]P-N2-dG in the two overlapping active sites in Dpo4, the pyrene in the BPmi3 orientation is accommodated better in active site 1 (AS1), while the pyrene in the BPmi5 orientation is accommodated better in AS2. Finally, we discuss why Y-family DNAPs might have two catalytic active sites.

Biochemical evidence of a physical interaction between Sulfolobus solfataricus B-family and Y-family DNA polymerases

The hyper-thermophilic archaeon Sulfolobus solfataricus possesses two functional DNA polymerases belonging to the B-family (Sso DNA pol B1) and to the Y-family (Sso DNA pol Y1). Sso DNA pol B1 recognizes the presence of uracil and hypoxanthine in the template strand and stalls synthesis 3-4 bases upstream of this lesion ("read-ahead" function). On the other hand, Sso DNA pol Y1 is able to synthesize across these and other lesions on the template strand. Herein we report evidence that Sso DNA pol B1 physically interacts with DNA pol Y1 by surface plasmon resonance measurements and immuno-precipitation experiments. The region of DNA pol B1 responsible for this interaction has been mapped in the central portion of the polypeptide chain (from the amino acid residue 482 to 617), which includes an extended protease hyper-sensitive linker between the N- and C-terminal modules (amino acid residues Asn482-Ala497) and the alpha-helices forming the "fingers" sub-domain (alpha-helices R, R' and S). These results have important implications for understanding the polymerase-switching mechanism on the damaged template strand during genome replication in S. solfataricus.

Sequence analysis of the lactococcal plasmid pNP40: a mobile replicon for coping with environmental hazards

The conjugative lactococcal plasmid pNP40, identified in Lactococcus lactis subsp. diacetylactis DRC3, possesses a potent complement of bacteriophage resistance systems, which has stimulated its application as a fitness-improving, food-grade genetic element for industrial starter cultures. The complete sequence of this plasmid allowed the mapping of previously known functions including replication, conjugation, bacteriocin resistance, heavy metal tolerance, and bacteriophage resistance. In addition, functions for cold shock adaptation and DNA damage repair were identified, further confirming pNP40's contribution to environmental stress protection. A plasmid cointegration event appears to have been part of the evolution of pNP40, resulting in a "stockpiling" of bacteriophage resistance systems.

Analysis of UV-induced mutation spectra in Escherichia coli by DNA polymerase eta from Arabidopsis thaliana

DNA polymerase eta belongs to the Y-family of DNA polymerases, enzymes that are able to synthesize past template lesions that block replication fork progression. This polymerase accurately bypasses UV-associated cis-syn cyclobutane thymine dimers in vitro and therefore may contributes to resistance against sunlight in vivo, both ameliorating survival and decreasing the level of mutagenesis. We cloned and sequenced a cDNA from Arabidopsis thaliana which encodes a protein containing several sequence motifs characteristics of Pol eta homologues, including a highly conserved sequence reported to be present in the active site of the Y-family DNA polymerases. The gene, named AtPOLH, contains 14 exons and 13 introns and is expressed in different plant tissues. A strain from Saccharomyces cerevisiae, deficient in Pol eta activity, was transformed with a yeast expression plasmid containing the AtPOLH cDNA. The rate of survival to UV irradiation in the transformed mutant increased to similar values of the wild type yeast strain, showing that AtPOLH encodes a functional protein. In addition, when AtPOLH is expressed in Escherichia coli, a change in the mutational spectra is detected when bacteria are irradiated with UV light. This observation might indicate that AtPOLH could compete with DNA polymerase V and then bypass cyclobutane pyrimidine dimers incorporating two adenylates.

Free-energy perturbation methods to study structure and energetics of DNA adducts: results for the major N2-dG adduct of benzo[a]pyrene in two conformations and different sequence contexts

The potent mutagen/carcinogen benzo[a]pyrene (B[a]P) is activated to (+)-anti-B[a]PDE, which induces a variety of mutations (e.g., G --> T, G --> A, etc.) via its major adduct [+ta]-B[a]P-N2-dG. One hypothesis is that adducts (such as [+ta]-B[a]P-N2-dG) induce different mutations via different conformations, probably when replicated by different lesion-bypass DNA polymerases (DNAPs). We showed that Escherichia coli DNAP V was responsible for G --> T mutations with [+ta]-B[a]P-N2-dG in a 5'-TGT sequence (Yin et al., (2004) DNA Repair 3, 323), so we wish to study conformations of this adduct/sequence context by molecular modeling. The development of a CHARMM-based molecular dynamics (MD) simulations protocol with free-energy calculations in the presence of solvent and counterions is described. A representative base-pairing and base-displaced conformation of [+ta]-B[a]P-N2-dG in the 5'-TGT sequence are used: (1) BPmi5, which has the B[a]P moiety in the minor groove pointing toward the base on the 5'-side of the adduct, and (2) Gma5, which has the B[a]P moiety stacked with the surrounding base pairs and the dG moiety displaced into the major groove. The MD output structures are reasonable when compared to known NMR structures. Changes in DNA sequence context dramatically affect the biological consequences (e.g., mutagenesis) of [+ta]-B[a]P-N2-dG. Consequently, we also developed a MD-based free-energy perturbation (FEP) protocol to study DNA sequence changes. FEP involves the gradual "fading-out" of atoms in a starting structure (A) and "fading-in" of atoms in a final structure (B), which allows a realistic assessment of the energetic and structural changes when two structures A and B are closely related. Two DNA sequence changes are described: (1) 5'-TGT --> 5'-TGG, which involves two steps [T:A --> T:C --> G:C], and (2) 5'-TGT --> 5'-TGC, which involves three steps [T:A --> T:2AP --> C:2AP --> C:G], where 2AP (2-aminopurine) is included, because T:2AP and C:2AP retain more-or-less normal pairing orientations between complementary bases. FEP is also used to evaluate the impact that a 5'-TGT to 5'-UGT sequence change might have on mutagenesis with [+ta]-B[a]P-N2-dG. In summary, we developed (1) a CHARMM-based molecular dynamics (MD) simulations protocol with free-energy calculations in the presence of solvent and counterions to study B[a]P-N2-dG adducts in DNA duplexes, and (2) a MD-based free-energy perturbation (FEP) protocol to study DNA sequence context changes around B[a]P-N2-dG adducts.

Mirror image stereoisomers of the major benzo[a]pyrene N2-dG adduct are bypassed by different lesion-bypass DNA polymerases in E. coli

The potent mutagen/carcinogen benzo[a]pyrene (B[a]P) is metabolically activated to (+)-anti-B[a]PDE, which induces a full spectrum of mutations (e.g., G-to-T, G-to-A, -1 frameshifts, etc.) via its major adduct [+ta]-B[a]P-N2-dG. We recently showed that the dominant G-to-T mutation depends on DNA polymerase V (DNAP V), but not DNAPs IV or II, when studied in a 5'-TG sequence in E. coli. Herein we investigate what DNAPs are responsible for non-mutagenic bypass with [+ta]-B[a]P-N2-dG, along with its mirror image adduct [-ta]-B[a]P-N2-dG. Each adduct is built into a 5'-TG sequence in a single stranded M13 phage vector, which is then transformed into eight different E. coli strains containing all combinations of proficiency and deficiency in the three lesion-bypass DNAPs II, IV and V. Based on M13 progeny output, non-mutagenic bypass with [-ta]-B[a]P-N2-dG depends on DNAP IV. In contrast, non-mutagenic bypass with [+ta]-B[a]P-N2-dG depends on both DNAPs IV and V, where arguments suggest that DNAP IV is involved in dCTP insertion, while DNAP V is involved in extension of the adduct-G:C base pair. Numerous findings indicate that DNAP II has a slight inhibitory effect on the bypass of [+ta]- and [-ta]-B[a]P-N2-dG in the case of both DNAPs IV and V. In conclusion, for efficient non-mutagenic bypass (dCTP insertion) in E. coli, [+ta]-B[a]P-N2-dG requires DNAPs IV and V, [-ta]-B[a]P-N2-dG requires only DNAP IV, while DNAP II is inhibitory to both, and experiments to investigate these differences should provide insights into the mechanism and purpose of these lesion-bypass DNAPs.

Specificity of replicative and SOS-inducible DNA polymerases in frameshift mutagenesis: mutability of Salmonella typhimurium strains overexpressing SOS-inducible DNA polymerases to 30 chemical mutagens

DNA replication is frequently hindered because of the presence of DNA lesions induced by endogenous and exogenous genotoxic agents. To circumvent the replication block, cells are endowed with multiple specialized DNA polymerases that can bypass a variety of DNA damage. To better understand the specificity of specialized DNA polymerases to bypass lesions, we have constructed a set of derivatives of Salmonella typhimurium TA1538 harboring plasmids carrying the polB, dinB or mucAB genes encoding Escherichia coli DNA polymerase II, DNA polymerase IV or DNA polymerase RI, respectively, and examined the mutability to 30 chemicals. The parent strain TA1538 possesses CGCGCGCG hotspot sequence for -2 frameshift. Interestingly, the chemicals could be classified into four groups based on the mutagenicity to the derivatives: group I whose mutagenicity was highest in strain YG5161 harboring plasmid carrying dinB; group II whose mutagenicity was almost equally high in strain YG5161 and strain TA98 harboring plasmid carrying mucAB; group III whose mutagenicity was highest in strain TA98; group IV whose mutagenicity was not affected by the introduction of any of the plasmids. Introduction of plasmid carrying polB did not enhance the mutagenicity except for benz[a]anthracene. We also introduced a plasmid carrying polA encoding E. coli DNA polymerase I to strain TA1538. Strikingly, the introduction of the plasmid reduced the mutagenicity of chemicals belonging to groups I, II and III, but not the chemicals of group IV, to the levels observed in the derivative whose SOS-inducible DNA polymerases were all deleted. These results suggest that (i) DNA polymerase IV and DNA polymerase RI possess distinct but partly overlapping specificity to bypass lesions leading to -2 frameshift, (ii) the replicative DNA polymerase, i.e., DNA polymerase III, participates in the mutagenesis and (iii) the enhanced expression of E. coli polA may suppress the access of Y-family DNA polymerases to the replication complex.

Poleta, Polzeta and Rev1 together are required for G to T transversion mutations induced by the (+)- and (-)-trans-anti-BPDE-N2-dG DNA adducts in yeast cells

Benzo[a]pyrene is an important environmental mutagen and carcinogen. Its metabolism in cells yields the mutagenic, key ultimate carcinogen 7R,8S,9S,10R-anti-benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide, (+)-anti-BPDE, which reacts via its 10-position with N²-dG in DNA to form the adduct (+)-trans-anti-BPDE-N²-dG. To gain molecular insights into BPDE-induced mutagenesis, we examined in vivo translesion synthesis and mutagenesis in yeast cells of a site-specific 10S (+)-trans-anti-BPDE-N²-dG adduct and the stereoisomeric 10R (−)-trans-anti-BPDE-N²-dG adduct. In wild-type cells, bypass products consisted of 76% C, 14% A and 7% G insertions opposite (+)-trans-anti-BPDE-N²-dG; and 89% C, 4% A and 4% G insertions opposite (−)-trans-anti-BPDE-N²-dG. Translesion synthesis was reduced by ∼26–37% in rad30 mutant cells lacking Polη, but more deficient in rev1 and almost totally deficient in rev3 (lacking Polζ) mutants. C insertion opposite the lesion was reduced by ∼24–33% in rad30 mutant cells, further reduced in rev1 mutant, and mostly disappeared in the rev3 mutant strain. The insertion of A was largely abolished in cells lacking either Polη, Polζ or Rev1. The insertion of G was not detected in either rev1 or rev3 mutant cells. The rad30 rev3 double mutant exhibited a similar phenotype as the single rev3 mutant with respect to translesion synthesis and mutagenesis. These results show that while the Polζ pathway is generally required for translesion synthesis and mutagenesis of the (+)- and (−)-trans-anti-BPDE-N²-dG DNA adducts, Polη, Polζ and Rev1 together are required for G→T transversion mutations, a major type of mutagenesis induced by these lesions. Based on biochemical and genetic results, we present mechanistic models of translesion synthesis of these two DNA adducts, involving both the one-polymerase one-step and two-polymerase two-step models.

Homology modeling of four Y-family, lesion-bypass DNA polymerases: the case that E. coli Pol IV and human Pol kappa are orthologs, and E. coli Pol V and human Pol eta are orthologs

Y-family DNA polymerases (DNAPs) are a superfamily of evolutionarily related proteins that exist in cells to bypass DNA damage caused by both radiation and chemicals. Cells have multiple Y-family DNAPs, presumably to conduct translesion synthesis (TLS) on DNA lesions of varying structure and conformation. The potent, ubiquitous environmental mutagen/carcinogen benzo[a]pyrene (B[a]P) induces all classes of mutations with G-->T base substitutions predominating. We recently showed that a G-->T mutagenesis pathway for the major adduct of B[a]P ([+ta]-B[a]P-N2-dG) in Escherichia coli depends on Y-family member DNAP V. Since no X-ray crystal study for DNAP V has been reported, no structure is available to help in understanding the structural basis for dATP insertion associated with G-->T mutations from [+ta]-B[a]P-N2-dG. Herein, we do homology modeling to construct a model for UmuC, which is the polymerase subunit of DNAP V. The sequences of eight Y-family DNAPs were aligned based on the positioning of conserved amino acids and an analysis of conserved predicted secondary structure, as well as insights gained from published X-ray structures of five Y-family members. Starting coordinates for UmuC were generated from the backbone coordinates for the Y-family polymerase Dpo4 for reasons discussed, and were refined using molecular dynamics with CHARMM 27. A survey of the literature revealed that E. coli DNAP V and human DNAP eta show a similar pattern of dNTP insertion opposite a variety of DNA lesions. Furthermore, E. coli DNAP IV and human DNAP kappa show a similar dNTP insertional pattern with these same DNA lesions, although the insertional pattern for DNAP IV/kappa differs from the pattern for DNAPs V/eta. These comparisons prompted us to construct and refine models for E. coli DNAP IV and human DNAPs eta and kappa as well. The dNTP/template binding pocket of all four DNAPs was inspected, focusing on the array of seven amino acids that contact the base of the incoming dNTP, as well as the template base. DNAPs V and eta show similarities in this array, and DNAPs IV and kappa also show similarities, although the arrays are different for the two pairs of DNAPs. Thus, there is a correlation between structural similarities and insertional similarities for the pairs DNAPs V/eta and DNAPs IV/kappa. Although the significance of this correlation remains to be elucidated, these observations point the way for future experimental studies.

Roles of replicative and specialized DNA polymerases in frameshift mutagenesis: mutability of Salmonella typhimurium strains lacking one or all of SOS-inducible DNA polymerases to 26 chemicals

Progression of DNA replication is occasionally blocked by endogenous and exogenous DNA damage. To circumvent the stalling of DNA replication, cells possess a variety of specialized DNA polymerases that replicate through DNA damage. Salmonella typhimurium strain TA1538 has six DNA polymerases and four of them are encoded by damage-inducible SOS genes, i.e. polB(ST) (pol II), dinB(ST) (pol IV), umuDC(ST) (pol V) and samAB. The strain has been used for the detection of a variety of chemical mutagens because of the high sensitivity to -2 frameshift occurring in CGCGCGCG sequence. To assign the role of each DNA polymerase in the frameshift mutagenesis, we have constructed the derivatives lacking one or all of SOS-inducible DNA polymerases and examined the mutability to 26 chemical mutagens. Interestingly, the chemicals could be categorized into four classes: class I whose mutagenicity was reduced by the deletion of dinB(ST) (1-aminoanthracene and other four chemicals); class II whose mutagenicity was reduced by the deletion of either dinB(ST) or umuDC(ST) plus samAB (7,12-dimethylbenz[a]anthracene and other three chemicals); class III whose mutagenicity largely depended on the presence of umuDC(ST) plus samAB (1-N-6-azabenzo[a]pyrene and other three chemicals) and class IV whose mutagenicity was not reduced by deletion of any of the genes encoding SOS-inducible DNA polymerases (Glu-P-1 and other 12 chemicals). Deletion of polB(ST) reduced by 30-60% the mutagenicity of six chemicals of classes II and III. These results suggest that multiple DNA polymerases including the replicative DNA polymerase, i.e. DNA polymerase III holoenzyme, play important roles in chemically induced -2 frameshift and also that different sets of DNA polymerases are engaged in the translesion bypass of different DNA lesions.

The p-benzoquinone DNA adducts derived from benzene are highly mutagenic

Benzene is a human leukemia carcinogen, resulting from its cellular metabolism. A major benzene metabolite is p-benzoquinone (pBQ), which can damage DNA by forming the exocyclic base adducts pBQ-dC, pBQ-dA, and pBQ-dG in vitro. To gain insights into the role of pBQ in benzene genotoxicity, we examined in vitro translesion synthesis and in vivo mutagenesis of these pBQ adducts. Purified REV1 and Polkappa were essentially incapable of translesion synthesis in response to the pBQ adducts. Opposite pBQ-dA and pBQ-dC, purified human Poliota was capable of error-prone nucleotide insertion, but was unable to perform extension synthesis. Error-prone translesion synthesis was observed with Poleta. However, DNA synthesis largely stopped opposite the lesion. Consistent with in vitro results, replication of site-specifically damaged plasmids was strongly inhibited by pBQ adducts in yeast cells, which depended on both Polzeta and Poleta. In wild-type cells, the majority of translesion products were deletions at the site of damage, accounting for 91%, 90%, and 76% for pBQ-dA, pBQ-dG, and pBQ-dC, respectively. These results show that the pBQ-dC, pBQ-dA, and pBQ-dG adducts are strong blocking lesions, and are highly mutagenic by predominantly inducing deletion mutations. These results are consistent with the lesion structures predicted by molecular dynamics simulation. Our results led to the following model. Translesion synthesis normally occurs by directly copying the lesion site through base insertion and extension synthesis. When the lesion becomes incompatible in accommodating a base opposite the lesion in DNA, translesion synthesis occurs by a less efficient lesion loop-out mechanism, resulting in avoiding copying the damaged base and leading to deletion.

Mutagenesis studies with four stereoisomeric N2-dG benzo[a]pyrene adducts in the identical 5′-CGC sequence used in NMR studies: G→T mutations dominate in each case

Benzo[a]pyrene (B[a]P) is a polycyclic aromatic hydrocarbon (PAH) and a potent mutagen/carcinogen found ubiquitously in the environment. B[a]P is primarily metabolized to diol epoxides, which react principally at N2-dG in DNA. B[a]P-N2-dG adducts have been shown to induce a variety of mutations, notably G-->T, G-->A, G-->C and -1 frameshifts. Four stereoisomers of B[a]P-N2-dG (designated: [+ta]-;, [+ca]-, [-ta] and [-ca]) were studied by NMR in duplex 11mers in a 5'-CGC sequence context, and each adopted a different adduct conformation (Geacintov, et al. (1997) Chem. Res. Toxicol., 10, 111). Herein these four identical B[a]P-containing 11mers are built into duplex plasmid genomes and mutagenesis studied in Escherichia coli following SOS-induction. In nucleotide excision repair (NER) proficient E.coli, no adduct-derived mutants are detected. In NER deficient E.coli, G-->T mutations dominate for all four stereoisomers [+ta]-, [+ca]-, [-ta] and [-ca]-B[a]P-N(2)-dG, and mutation frequency is similar. Thus, the mutagenic pattern for these four B[a]P-N2-dG stereoisomers is the same, in spite of the fact that they adopt dramatically different conformations in ds-oligonucleotides as determined by NMR. These findings suggest that adduct conformation must be fluid enough in the 5'-CGC sequence that the duplex DNA conformation can interconvert to mutagenic and non-mutagenic conformations during lesion-bypass. A comparison of all published studies with these four B[a]P-N2-dG stereoisomers in E.coli reveals that B[a]P-N2-dG adduct stereochemistry tends to have a lesser impact on mutagenic pattern (e.g. G-->T versus G-->A mutations) than does DNA sequence context, which is discussed.

Thermodynamic and in vitro replication studies of an intrastrand G[8-5]C cross-link lesion

We recently identified, from the gamma-irradiation mixture of duplex DNA, a new intrastrand G[8-5]C cross-link lesion, in which the C8 atom of guanine and the C5 atom of its 3' neighboring cytosine are covalently bonded, and carried out in vitro replication studies for the lesion-bearing substrate with a translesion synthesis polymerase, yeast polymerase eta. Here we extended the in vitro replication studies to two replicative polymerases, exonuclease-deficient bacteriophage T7 DNA polymerase (T7(-)) and HIV reverse transcriptase (HIV-RT). Primer extension assays showed that both polymerases stopped synthesis after incorporating a nucleotide opposite the 3'-cytosine in the G[8-5]C lesion. Steady-state kinetic measurements for nucleotide incorporation opposite the 3'-cytosine of the lesion showed that both T7(-) and HIV-RT preferentially incorporated the correct nucleotide, dGMP. We also examined the thermal stabilities and base pairing properties of G[8-5]C in d(ATGGCG[8-5]CGCTAT). The G[8-5]C lesion destabilizes the duplex form by approximately 4 kcal/mol in free energy at 25 degrees C relative to the undamaged parent duplex, and the thermally most stable duplex has natural bases opposite the lesion.

Evidence for Watson-Crick and not Hoogsteen or wobble base pairing in the selection of nucleotides for insertion opposite pyrimidines and a thymine dimer by yeast DNA pol eta

We have recently reported that pyrene nucleotide is preferentially inserted opposite an abasic site, the 3'-T of a thymine dimer, and most undamaged bases by yeast DNA polymerase eta (pol eta). Because pyrene is a nonpolar molecule with no H-bonding ability, the unusually high efficiencies of dPMP insertion are ascribed to its superior base stacking ability, and underscore the importance of base stacking in the selection of nucleotides by pol eta. To investigate the role of H-bonding and base pair geometry in the selection of nucleotides by pol eta, we determined the insertion efficiencies of the base-modified nucleotides 2,6-diaminopurine, 2-aminopurine, 6-chloropurine, and inosine which would make a different number of H-bonds with the template base depending on base pair geometry. Watson-Crick base pairing appears to play an important role in the selection of nucleotide analogues for insertion opposite C and T as evidenced by the decrease in the relative insertion efficiencies with a decrease in the number of Watson-Crick H-bonds and an increase in the number of donor-donor and acceptor-acceptor interactions. The selectivity of nucleotide insertion is greater opposite the 5'-T than the 3'-T of the thymine dimer, in accord with previous work suggesting that the 5'-T is held more rigidly than the 3'-T. Furthermore, insertion of A opposite both Ts of the dimer appears to be mediated by Watson-Crick base pairing and not by Hoogsteen base pairing based on the almost identical insertion efficiencies of A and 7-deaza-A, the latter of which lacks H-bonding capability at N7. The relative efficiencies for insertion of nucleotides that can form Watson-Crick base pairs parallel those for the Klenow fragment, whereas the Klenow fragment more strongly discriminates against mismatches, in accord with its greater shape selectivity. These results underscore the importance of H-bonding and Watson-Crick base pair geometry in the selection of nucleotides by both pol eta and the Klenow fragment, and the lesser role of shape selection in insertion by pol eta due to its more open and less constrained active site.

Ddb1 controls genome stability and meiosis in fission yeast

The human UV-damaged DNA-binding protein Ddb1 associates with cullin 4 ubiquitin ligases implicated in nucleotide excision repair (NER). These complexes also contain the signalosome (CSN), but NER-relevant ubiquitination targets have not yet been identified. We report that fission yeast Ddb1, Cullin 4 (Pcu4), and CSN subunits Csn1 and Csn2 are required for degradation of the ribonucleotide reductase (RNR) inhibitor protein Spd1. Ddb1-deficient cells have >20-fold increased spontaneous mutation rate. This is partly dependent on the error-prone translesion DNA polymerases. Spd1 deletion substantially reduced the mutation rate, suggesting that insufficient RNR activity accounts for approximately 50% of observed mutations. Epistasis analysis indicated that Ddb1 contributed to mutation avoidance and tolerance to DNA damage in a pathway distinct from NER. Finally, we show that Ddb1/Csn1/Cullin 4-mediated Spd1 degradation becomes essential when cells differentiate into meiosis. These results suggest that Ddb1, along with Cullin 4 and the signalosome, constitute a major pathway controlling genome stability, repair, and differentiation via RNR regulation.

Components of nucleotide excision repair and DNA damage tolerance in Arabidopsis thaliana

As obligate phototrophs, and despite shielding strategies, plants sustain DNA damage caused by UV radiation in sunlight. By inhibiting DNA replication and transcription, such damage may contribute to the detrimental effects of UV radiation on the growth, productivity, and genetic stability of higher plants. However, there is evidence that plants can reverse UV-induced DNA damage by photoreactivation or remove it via nucleotide excision repair. In addition, plants may have mechanisms for tolerating UV photoproducts as a means of avoiding replicative arrest. Recently, phenotypic characterization of plant mutants, functional complementation studies, and cDNA analysis have implicated genes isolated from the model plant Arabidopsis thaliana in nucleotide excision repair or tolerance of UV-induced DNA damage. Here, we briefly review features of these processes in human cells, collate information on Arabidopsis homologs of the relevant genes, and summarize the experimental findings that link certain of these plant genes to nucleotide excision repair or damage tolerance.

Interaction of hREV1 with three human Y-family DNA polymerases

Polkappa is one of many DNA polymerases involved in translesion DNA synthesis (TLS). It belongs to the Y-family of polymerases along with Poleta, Poliota and hREV1. Unlike Poleta encoded by the xeroderma pigmentosum variant (XPV) gene, Polkappa is unable to bypass UV-induced DNA damage in vitro, but it is able to bypass benzo[a]pyrene (B[a]P)-adducted guanines accurately and efficiently. In an attempt to identify factor(s) targeting Polkappa to its cognate DNA lesion(s), we searched for Polkappa-interacting proteins by using the yeast two-hybrid assay. We found that Polkappa interacts with a C-terminal region of hREV1. Poleta and Poliota were also found to interact with the same region of hREV1. The interaction between Polkappa and hREV1 was confirmed by pull-down and co-immunoprecipitation assays. The C-terminal region of hREV1 is known to interact with hREV7, a non-catalytic subunit of Polzeta that is another structurally unrelated TLS enzyme, and we show that Polkappa and hREV7 bind to the same C-terminal region of hREV1. Thus, our results suggest that hREV1 plays a pivotal role in the multi-enzyme, multi-step process of translesion DNA synthesis.

Role of base stacking and sequence context in the inhibition of yeast DNA polymerase eta by pyrene nucleotide

The Y family DNA polymerase yeast pol eta inserts pyrene deoxyribose monophosphate (dPMP) in preference to A opposite an abasic site, the 3'-T of a thymine dimer, and a normal T with almost equal efficiency. In contrast, pol A family polymerases such as Klenow fragment and T7 DNA polymerase only insert dPMP efficiently opposite an abasic site and the 3'-T of a thymine dimer but not opposite undamaged DNA. Pyrene nucleotide is also an efficient chain-terminating inhibitor of DNA synthesis by pol eta but not by Klenow fragment or T7 DNA polymerase. To better understand the origin of the efficiency and sequence specificity of dPMP insertion by pol eta, the kinetics of dPMP insertion opposite various templates have been determined. In one sequence context, the efficiency of dPMP insertion increases 4.6-fold opposite G < A << T < C, suggesting that the templating nucleotide modulates dPMP insertion efficiency by having to destack prior to dPTP binding. The efficiency of insertion of dPMP opposite T in the same sequence context increases 7-fold for primers terminating in G < A < C < T and is similar to that observed for nontemplated blunt-end extension, suggesting that stacking interactions between the pyrene and the primer terminus are also important. On heterogeneous templates, the average selectivity for dPMP insertion relative to the complementary dNMP decreases in the order of dAMP > dGMP > dTMP > dCMP, from a high of 5.8 when dAMP is to be inserted following a T to a low of 0.5 when dCMP is to be inserted following a C. The relative preference for dPMP insertion at a given site can be largely explained by the energetic cost of destacking the templating base and stacking of pyrene nucleotide relative to that of stacking and base pairing the complementary nucleotide. Thus, pyrene nucleotide represents a novel class of nucleotide-based chain-terminating DNA synthesis inhibitors whose base portion consists of a hydrophobic, non-hydrogen bonding, base-pair mimic.

Transcript copy number of genes for DNA repair and translesion synthesis in yeast: contribution of transcription rate and mRNA stability to the steady-state level of each mRNA along with growth in glucose-fermentative medium

We quantitated the copy number of mRNAs (NTG1, NTG2, OGG1, APN1, APN2, MSH2, MSH6, REV3, RAD30) encoding different DNA repair enzymes and translesion-synthesis polymerases in yeast. Quantitations reported examine how the steady-state number of each transcript is modulated in association with the growth in glucose-fermentative medium, and evaluate the respective contribution of the rate of mRNA degradation and transcription initiation to the specific mRNA level profile of each gene. Each transcript displayed a unique growth-related profile, therefore altering the relative abundance of mRNAs coding for proteins with similar functions, as cells proceed from exponential to stationary phase. Nonetheless, as general trend, they exhibited maximal levels when cells proliferate rapidly and minimal values when cells cease proliferation. We found that previous calculations on the stability of the investigated mRNAs might be biased, in particular regarding those that respond to heat shock stress. Overall, the mRNAs experienced drastic increments in their stabilities in response to gradual depletion of essential nutrients in the culture. However, differences among the mRNA stability profiles suggest a dynamic modulation rather than a passive process. As general rule, the investigated genes were much more frequently transcribed during the fermentative growth than later during the diauxic arrest and the stationary phase, this finding conciliating low steady-state levels with increased mRNA stabilities. Interestingly, while the rate at which each gene is transcribed appeared as the only determinant of the number of mRNA copies at the exponential growth, later, when cell growth is arrested, the rate of mRNA degradation becomes also a key factor for gene expression. In short, our results raise the question of how important the respective contribution of transcription and mRNA stability mechanisms is for the steady-state profile of a given transcript, and how this contribution may change in response to nutrient-availability.

Yeast MPH1 gene functions in an error-free DNA damage bypass pathway that requires genes from Homologous recombination, but not from postreplicative repair

The MPH1 gene from Saccharomyces cerevisiae, encoding a member of the DEAH family of proteins, had been identified by virtue of the spontaneous mutator phenotype of respective deletion mutants. Genetic analysis suggested that MPH1 functions in a previously uncharacterized DNA repair pathway that protects the cells from damage-induced mutations. We have now analyzed genetic interactions of mph1 with a variety of mutants from different repair systems with respect to spontaneous mutation rates and sensitivities to different DNA-damaging agents. The dependence of the mph1 mutator phenotype on REV3 and REV1 and the synergy with mutations in base and nucleotide excision repair suggest an involvement of MPH1 in error-free bypass of lesions. However, although we observed an unexpected partial suppression of the mph1 mutator phenotype by rad5, genetic interactions with other mutations in postreplicative repair imply that MPH1 does not belong to this pathway. Instead, mutations from the homologous recombination pathway were found to be epistatic to mph1 with respect to both spontaneous mutation rates and damage sensitivities. Determination of spontaneous mitotic recombination rates demonstrated that mph1 mutants are not deficient in homologous recombination. On the contrary, in an sgs1 background we found a pronounced hyperrecombination phenotype. Thus, we propose that MPH1 is involved in a branch of homologous recombination that is specifically dedicated to error-free bypass.

The DNA-polymerase-X family: controllers of DNA quality?

Synthesis of the genetic material of the cell is achieved by a large number of DNA polymerases. Besides replicating the genome, they are involved in DNA-repair processes. Recent studies have indicated that certain DNA-polymerase-X-family members can synthesize unusual DNA structures, and we propose that these DNA structures might serve as 'flag wavers' for the induction of DNA-repair and/or DNA-damage-checkpoint pathways.

Long-term effect of mutagenic DNA repair on accumulation of mutations in Pseudomonas syringae B86-17

Forty replicate lineages of Pseudomonas syringae B86-17 cells expressing the rulAB mutagenic DNA repair (MDR) determinant or the rulB::Km MDR-deficient mutant GWS242 were passaged through single-cell bottlenecks (60 cycles), with a UV radiation (UVR) exposure given to half of the lineages at the beginning of each cycle. After every 10th bottleneck cycle, single-colony isolates from all 80 lineages were subjected to 39 phenotypic screens, with newly arising mutations detected in 60 and 0% of UVR-exposed or non-UVR-exposed B86-17 lineages, respectively, by the 60th cycle. Cellular fitness, measured as growth rate in a minimal medium, of UVR-exposed lineages of both B86-17 and GWS242 after 60 cycles was not significantly different from that of the ancestral strains. Although UVR exposure and MDR activity increased the occurrence of mutations in cells, a significant reduction in overall fitness was not observed.

LC-MS/MS identification and yeast polymerase eta bypass of a novel gamma-irradiation-induced intrastrand cross-link lesion G[8-5]C

Reactive oxygen species can give rise to intrastrand cross-link lesions, where two neighboring nucleobases are covalently bonded. Here, we employed LC-MS/MS and demonstrated for the first time that gamma irradiation of a synthetic duplex oligodeoxyribonucleotide can give rise to an intrastrand cross-link lesion G[8-5]C, where the C8 carbon atom of guanine and the C5 carbon atom of its 3'-neighboring cytosine are covalently bonded. We also carried out in vitro replication studies of a substrate containing a site-specifically incorporated G[8-5]C, and our results showed that yeast Saccharomyces cerevisiae DNA polymerase eta (pol eta) was able to replicate past the cross-link lesion. Steady-state kinetic analyses for nucleotide incorporation by pol eta showed that the 3'-cytosine moiety of the cross-link did not significantly affect either the efficiency or the fidelity of nucleotide incorporation. The 5' guanine portion of the cross-link lesion, however, markedly reduced both the efficiency and the fidelity of nucleotide incorporation; the insertion of dGMP or dAMP was slightly favored over the insertion of the correct nucleotide, dCMP, which was in turn favored over the insertion of dTMP. The above results support that the oxidative cross-link lesion, if not repaired, can be mutagenic.

Role of DNA polymerase eta in the bypass of abasic sites in yeast cells

Abasic (AP) sites are major DNA lesions and are highly mutagenic. AP site-induced mutagenesis largely depends on translesion synthesis. We have examined the role of DNA polymerase eta (Poleta) in translesion synthesis of AP sites by replicating a plasmid containing a site-specific AP site in yeast cells. In wild-type cells, AP site bypass resulted in preferred C insertion (62%) over A insertion (21%), as well as -1 deletion (3%), and complex event (14%) containing multiple mutations. In cells lacking Poleta (rad30), Rev1, Polzeta (rev3), and both Poleta and Polzeta, translesion synthesis was reduced to 30%, 30%, 15% and 3% of the wild-type level, respectively. C insertion opposite the AP site was reduced in rad30 mutant cells and was abolished in cells lacking Rev1 or Polzeta, but significant A insertion was still detected in these mutant cells. While purified yeast Polalpha effectively inserted an A opposite the AP site in vitro, purified yeast Poldelta was much less effective in A insertion opposite the lesion due to its 3'-->5' proofreading exonuclease activity. Purified yeast Poleta performed extension synthesis from the primer 3' A opposite the lesion. These results show that Poleta is involved in translesion synthesis of AP sites in yeast cells, and suggest that an important role of Poleta is to catalyze extension following A insertion opposite the lesion. Consistent with these conclusions, rad30 mutant cells were sensitive to methyl methanesulfonate (MMS), and rev1 rad30 or rev3 rad30 double mutant cells were synergistically more sensitive to MMS than the respective single mutant strains.

Mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase IV

The kinetic mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) is resolved by pre-steady-state kinetic analysis of single-nucleotide (dTTP) incorporation into a DNA 21/41-mer. Like replicative DNA polymerases, Dpo4 utilizes an "induced-fit" mechanism to select correct incoming nucleotides. The affinity of DNA and a matched incoming nucleotide for Dpo4 was measured to be 10.6 nM and 230 microM, respectively. Dpo4 binds DNA with an affinity similar to that of replicative polymerases due to the presence of an atypical little finger domain and a highly charged tether that links this novel domain to its small thumb domain. On the basis of the elemental effect between the incorporations of dTTP and its thio analogue S(p)-dTTPalphaS, the incorporation of a correct incoming nucleotide by Dpo4 was shown to be limited by the protein conformational change step preceding the chemistry step. In contrast, the chemistry step limited the incorporation of an incorrect nucleotide. The measured dissociation rates of the enzyme.DNA binary complex (0.02-0.07 s(-1)), the enzyme.DNA.dNTP ternary complex (0.41 s(-1)), and the ternary complex after the protein conformational change (0.004 s(-1)) are significantly different and support the existence of a bona fide protein conformational change step. The rate-limiting protein conformational change was further substantiated by the observation of different reaction amplitudes between pulse-quench and pulse-chase experiments. Additionally, the processivity of Dpo4 was calculated to be 16 at 37 degrees C from analysis of a processive polymerization experiment. The structural basis for both the protein conformational change and the low processivity of Dpo4 was discussed.

Yeast MPH1 Gene Functions in an Error-Free DNA Damage Bypass Pathway That Requires Genes From Homologous Recombination, but Not From Postreplicative Repair

The MPH1 gene from Saccharomyces cerevisiae, encoding a member of the DEAH family of proteins, had been identified by virtue of the spontaneous mutator phenotype of respective deletion mutants. Genetic analysis suggested that MPH1 functions in a previously uncharacterized DNA repair pathway that protects the cells from damage-induced mutations. We have now analyzed genetic interactions of mph1 with a variety of mutants from different repair systems with respect to spontaneous mutation rates and sensitivities to different DNA-damaging agents. The dependence of the mph1 mutator phenotype on REV3 and REV1 and the synergy with mutations in base and nucleotide excision repair suggest an involvement of MPH1 in error-free bypass of lesions. However, although we observed an unexpected partial suppression of the mph1 mutator phenotype by rad5, genetic interactions with other mutations in postreplicative repair imply that MPH1 does not belong to this pathway. Instead, mutations from the homologous recombination pathway were found to be epistatic to mph1 with respect to both spontaneous mutation rates and damage sensitivities. Determination of spontaneous mitotic recombination rates demonstrated that mph1 mutants are not deficient in homologous recombination. On the contrary, in an sgs1 background we found a pronounced hyperrecombination phenotype. Thus, we propose that MPH1 is involved in a branch of homologous recombination that is specifically dedicated to error-free bypass.

Peripheral sequences of the Serratia entomophila pADAP virulence-associated region

Some strains of the Enterobacteriaceae Serratia entomophila and Serratia proteamaculans cause amber disease in the grass grub, Costelytra zealandica (Coleoptera: Scarabaeidae), an important pasture pest in New Zealand. The genes responsible for this disease reside on a large, 155-kb plasmid designated amber disease-associated plasmid (pADAP). Herein, we report the DNA sequencing of approximately 50 kb upstream and 10 kb downstream of the virulence-encoding region. Based on similarity with proteins in the current databases, and potential ribosome-binding sites, 63 potential ORFs were determined. Eleven of these ORFs belong to a type IV pilus cluster (pilL-V) and a further eight have similarities to the translated products of the plasmid transfer traH-N genes of the plasmid R64. In addition, a degenerate 785-nt direct repeat flanks a 44.7-kb region with the potential to encode three Bacillus subtilis Yee-type proteins, a fimbrial gene cluster, the sep virulence-associated genes and several remnant IS elements.

Translesion synthesis of acetylaminofluorene-dG adducts by DNA polymerase zeta is stimulated by yeast Rev1 protein

Translesion synthesis is an important mechanism in response to unrepaired DNA lesions during replication. The DNA polymerase zeta (Polzeta) mutagenesis pathway is a major error-prone translesion synthesis mechanism requiring Polzeta and Rev1. In addition to its dCMP transferase, a non-catalytic function of Rev1 is suspected in cellular response to certain types of DNA lesions. However, it is not well understood about the non-catalytic function of Rev1 in translesion synthesis. We have analyzed the role of Rev1 in translesion synthesis of an acetylaminofluorene (AAF)-dG DNA adduct. Purified yeast Rev1 was essentially unresponsive to a template AAF-dG DNA adduct, in contrast to its efficient C insertion opposite a template 1,N6-ethenoadenine adduct. Purified yeast Polzeta was very inefficient in the bypass of the AAF-dG adduct. Combining Rev1 and Polzeta, however, led to a synergistic effect on translesion synthesis. Rev1 protein enhanced Polzeta-catalyzed nucleotide insertion opposite the AAF-dG adduct and strongly stimulated Polzeta-catalyzed extension from opposite the lesion. Rev1 also stimulated the deficient synthesis by Polzeta at the very end of undamaged DNA templates. Deleting the C-terminal 205 aa of Rev1 did not affect its dCMP transferase activity, but abolished its stimulatory activity on Polzeta-catalyzed extension from opposite the AAF-dG adduct. These results suggest that translesion synthesis of AAF-dG adducts by Polzeta is stimulated by Rev1 protein in yeast. Consistent with the in vitro results, both Polzeta and Rev1 were found to be equally important for error-prone translesion synthesis across from AAF-dG DNA adducts in yeast cells.

Mutagenesis of benzo[a]pyrene diol epoxide in yeast: requirement for DNA polymerase zeta and involvement of DNA polymerase eta

Benzo[a]pyrene is a potent environmental carcinogen, which can be metabolized in cells to the DNA damaging agent anti-benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide (anti-BPDE). We hypothesize that mutations induced by BPDE DNA adducts are mainly generated through an error-prone translesion synthesis that requires a specialized DNA polymerase (Pol). Using an in vivo mutagenesis assay in the yeast model system, we have examined the potential roles of Pol(zeta) and Pol(eta) in (+/-)-anti-BPDE-induced mutagenesis. In cells proficient in mutagenesis, (+/-)-anti-BPDE induced 85% base substitutions with predominant G --> C followed by G --> T transversions, 9% deletions of 1-3 nucleotides, and 6% insertions of 1-3 nucleotides. In rad30 mutant cells lacking Pol(eta), (+/-)-anti-BPDE-induced mutagenesis was reduced and accompanied by a moderate decrease in base substitutions and more significant decrease in deletions and insertions of 1-3 nucleotides. In rev3 mutant cells lacking Pol(zeta), (+/-)-anti-BPDE-induced mutagenesis was mostly abolished, leading to a great decrease in both base substitutions and deletions/insertions of 1-3 nucleotides. In contrast, large deletions/insertions were significantly increased in cells lacking Pol(zeta). Consistent with the in vivo results, purified yeast Pol(zeta) performed limited translesion synthesis opposite (+)- and (-)-trans-anti-BPDE-N(2)-dG DNA adducts with predominant G incorporation opposite the lesion. These results show that (+/-)-anti-BPDE-induced mutagenesis in yeast requires Pol(zeta) and partially involves Pol(eta) and suggest that Pol(zeta) directly participates in nucleotide insertions opposite the lesion, while Pol(eta) significantly contributes to deletions and insertions of 1-3 nucleotides.

Sequence context-dependent replication of DNA templates containing UV-induced lesions by human DNA polymerase iota

Humans possess four Y-family polymerases: pols eta, iota, kappa and the Rev1 protein. The pivotal role that pol eta plays in protecting us from UV-induced skin cancers is unquestioned given that mutations in the POLH gene (encoding pol eta), lead to the sunlight-sensitive and cancer-prone xeroderma pigmentosum variant phenotype. The roles that pols iota, kappa and Rev1 play in the tolerance of UV-induced DNA damage is, however, much less clear. For example, in vitro studies in which the ability of pol iota to bypass UV-induced cyclobutane pyrimidine dimers (CPDs) or 6-4 pyrimidine-pyrimidone (6-4PP) lesions has been assayed, are somewhat varied with results ranging from limited misinsertion opposite CPDs to complete lesion bypass. We have tested the hypothesis that such discrepancies might have arisen from different assay conditions and local sequence contexts surrounding each UV-photoproduct and find that pol iota can facilitate significant levels of unassisted highly error-prone bypass of a T-T CPD, particularly when the lesion is located in a 3'-A[T-T]A-5' template sequence context and the reaction buffer contains no KCl. When encountering a T-T 6-4PP dimer under the same assay conditions, pol iota efficiently and accurately inserts the correct base, A, opposite the 3'T of the 6-4PP by factors of approximately 10(2) over the incorporation of incorrect nucleotides, while incorporation opposite the 5'T is highly mutagenic. Pol kappa has been proposed to function in the bypass of UV-induced lesions by helping extend primers terminated opposite CPDs. However, we find no evidence that the combined actions of pol iota and pol kappa result in a significant increase in bypass of T-T CPDs when compared to pol iota alone. Our data suggest that under certain conditions and sequence contexts, pol iota can bypass T-T CPDs unassisted and can efficiently incorporate one or more bases opposite a T-T 6-4PP. Such biochemical activities may, therefore, be of biological significance especially in XP-V cells lacking the primary T-T CPD bypassing enzyme, pol eta.

Yeast pol eta holds a cis-syn thymine dimer loosely in the active site during elongation opposite the 3'-T of the dimer, but tightly opposite the 5'-T

Polymerase eta is a member of the Y family of DNA polymerases which is able to bypass thymine dimers efficiently and in a relatively error-free manner. To elucidate the mechanism of dimer bypass, the efficiency of dAMP and pyrene nucleotide insertion opposite the thymine dimer and its N3-methyl derivatives was determined. Pol eta inserts pyrene nucleotide with greater efficiency than dAMP opposite the 3'-T of an undimerized or dimerized T and is an effective inhibitor of DNA synthesis by pol eta. Substitution of the N3H of the 3'-T of an undimerized T or a dimerized T with a methyl group has little effect on the insertion efficiency of pyrene nucleotide but greatly inhibits the insertion of dAMP. Together, these results suggest that the error-free insertion of dAMP opposite the 3'-T of the cis-syn thymine dimer happens by way of a loosely held dimer in the active site which can be displaced from the active site by pyrene nucleotide. In contrast, pol eta cannot insert pyrene nucleotide opposite the 5'-T of the dimer, whereas it can insert dAMP with efficiency comparable to that opposite the 3'-T. The inability to insert pyrene nucleotide opposite the 5'-T of the dimer is consistent with the idea that while the polymerase binds loosely to a templating nucleotide, it binds tightly to the nucleotide to its 3'-side. Overall, the results show a marked difference from similar studies on pol I family polymerases, and suggest mechanisms by which this Y family polymerase can process damaged DNA efficiently.

Role of DNA polymerase eta in the UV mutation spectrum in human cells

In humans, inactivation of the DNA polymerase eta gene (pol eta) results in sunlight sensitivity and causes the cancer-prone xeroderma pigmentosum variant syndrome (XP-V). Cells from XP-V individuals have a reduced capacity to replicate UV-damaged DNA and show hypermutability after UV exposure. Biochemical assays have demonstrated the ability of pol eta to bypass cis-syn-cyclobutane thymine dimers, the most common lesion generated in DNA by UV. In most cases, this bypass is error-free. To determine the actual requirement of pol eta in vivo, XP-V cells (XP30RO) were complemented by the wild type pol eta gene. We have used two pol eta-corrected clones to study the in vivo characteristics of mutations produced by DNA polymerases during DNA synthesis of UV-irradiated shuttle vectors transfected into human host cells, which had or had not been exposed previously to UV radiation. The functional complementation of XP-V cells by pol eta reduced the mutation frequencies both at CG and TA base pairs and restored UV mutagenesis to a normal level. UV irradiation of host cells prior to transfection strongly increased the mutation frequency in undamaged vectors and, in addition, especially in the pol eta-deficient XP30RO cells at 5'-TT sites in UV-irradiated plasmids. These results clearly show the protective role of pol eta against UV-induced lesions and the activation by UV of pol eta-independent mutagenic processes.

Erroneous incorporation of oxidized DNA precursors by Y-family DNA polymerases

Deranged oxidative metabolism is a property of many tumour cells. Oxidation of the deoxynucleotide triphosphate (dNTP) pool, as well as DNA, is a major cause of genome instability. Here, we report that two Y-family DNA polymerases of the archaeon Sulfolobus solfataricus strains P1 and P2 incorporate oxidized dNTPs into nascent DNA in an erroneous manner: the polymerases exclusively incorporate 8-OH-dGTP opposite adenine in the template, and incorporate 2-OH-dATP opposite guanine more efficiently than opposite thymine. The rate of extension of the nascent DNA chain following on from these incorporated analogues is only slightly reduced. These DNA polymerases have been shown to bypass a variety of DNA lesions. Thus, our results suggest that the Y-family DNA polymerases promote mutagenesis through the erroneous incorporation of oxidized dNTPs during DNA synthesis, in addition to facilitating translesion DNA synthesis. We also report that human DNA polymerase eta, a human Y-family DNA polymerase, incorporates the oxidized dNTPs in a similar erroneous manner.

Identification of genes that protect the C. elegans genome against mutations by genome-wide RNAi

An RNA interference (RNAi)-based genome-wide screen was performed to detect genes that contribute to genome stability in somatic cells of Caenorhabditis elegans. We identified 61 such genes; these also affect spontaneous mutagenesis in the germ line. Their sequence suggests a role in DNA repair and/or replication, in chromatin remodeling, or in cell cycle control; there are also many novel genes that are highly conserved from yeast to human. Because known mutator genes are causally involved in many hereditary and sporadic human cancers, it is likely that some of these new mutators are equally relevant in cancer etiology.

Mutagenic potentials of damaged nucleic acids produced by reactive oxygen/nitrogen species: approaches using synthetic oligonucleotides and nucleotides: survey and summary

DNA and DNA precursors (deoxyribonucleotides) suffer damage by reactive oxygen/nitrogen species. They are important mutagens for organisms, due to their endogenous formation. Damaged DNA and nucleotides cause alterations of the genetic information by the mispairing properties of the damaged bases, such as 8-hydroxyguanine (7,8-dihydro-8-oxoguanine) and 2-hydroxyadenine. Here, the author reviews the mutagenic potentials of damaged bases in DNA and of damaged DNA precursors formed by reactive oxygen/nitrogen species, focusing on the results obtained with synthetic oligonucleotides and 2'-deoxyribonucleoside 5'-triphosphates.