Reduced levels of DNA polymerase delta induce chromosome fragile site instability in yeast

Specific regions of genomes (fragile sites) are hot spots for the chromosome rearrangements that are associated with many types of cancer cells. Understanding the molecular mechanisms regulating the stability of chromosome fragile sites, therefore, has important implications in cancer biology. We previously identified two chromosome fragile sites in Saccharomyces cerevisiae that were induced in response to the reduced expression of Pol1p, the catalytic subunit of DNA polymerase α. In the study presented here, we show that reduced levels of Pol3p, the catalytic subunit of DNA polymerase δ, induce instability at these same sites and lead to the generation of a variety of chromosomal aberrations. These findings demonstrate that a change in the stoichiometry of replicative DNA polymerases results in recombinogenic DNA lesions, presumably double-strand DNA breaks.     

Disruption of murine Mus81 increases genomic instability and DNA damage sensitivity but does not promote tumorigenesis

The Mus81-Eme1 endonuclease is implicated in the efficient rescue of broken replication forks in Saccharomyces cerevisiae and Schizosaccharomyces pombe. We have used gene targeting to study the function of the Mus81-Eme1 endonuclease in mammalian cells. Mus81-deficient mice develop normally and are fertile. Surprisingly, embryonic fibroblasts from Mus81(-/-) animals fail to proliferate in vitro. This proliferation defect can be rescued by expression of the papillomavirus E6 protein that promotes degradation of p53. When grown in culture, Mus81(-/-) cells have elevated levels of DNA damage, acquire chromosomal aberrations, and are hypersensitive to agents that generate DNA cross-links. In contrast to the situation in yeast, murine Mus81 is not required for replication restart following camptothecin treatment. Mus81(-/-) mice and cells are hypersensitive to DNA cross-linking agents. Cross-link-induced double-strand break formation is normal in Mus81(-/-) cells, but the resolution of repair intermediates is not. The persistence of Rad51 foci in Mus81(-/-) cells suggests that Mus81 acts at a late step in the repair of cross-link-induced lesions. Despite these defects, Mus81(-/-) mice do not show increased predisposition to lymphoma or any other malignancy in the first year of life.     

Pheasant virus DNA polymerase is related to avian leukosis virus DNA polymerase at the active site.

The DNA polymerase from Amherst pheasant virus (APV), a member of the pheasant virus species of retroviruses, was compared to the DNA polymerases of avian leukosis viruses (ALV) and a reticuloendotheliosis virus (spleen necrosis virus (SNV)). Immunoglobulin inhibition tests and competition immunoassays showed that APV and ALV DNA polymerases are closely related at their active sites. The determinants common to their active sites are not shared by SNV DNA polymerase. Bu using a species-specific radioimmunoassay, it was shown that both APV and SNV DNA polymerases are grossly different from ALV DNA polymerase. The specificity of the relationship of the active sites of APV and ALV DNA polymerases was confirmed by a heterologous radioimmunoassay. Our data indicate that pheasant viruses are evolutionarily linked to ALV.     

DNA polymerase proofreading: active site switching catalyzed by the bacteriophage T4 DNA polymerase

DNA polymerases achieve high-fidelity DNA replication in part by checking the accuracy of each nucleotide that is incorporated and, if a mistake is made, the incorrect nucleotide is removed before further primer extension takes place. In order to proofread, the primer-end must be separated from the template strand and transferred from the polymerase to the exonuclease active center where the excision reaction takes place; then the trimmed primer-end is returned to the polymerase active center. Thus, proofreading requires polymerase-to-exonuclease and exonuclease-to-polymerase active site switching. We have used a fluorescence assay that uses differences in the fluorescence intensity of 2-aminopurine (2AP) to measure the rates of active site switching for the bacteriophage T4 DNA polymerase. There are three findings: (i) the rate of return of the trimmed primer-end from the exonuclease to the polymerase active center is rapid, >500 s⁻¹; (ii) T4 DNA polymerase can remove two incorrect nucleotides under single turnover conditions, which includes presumed exonuclease-to-polymerase and polymerase-to-exonuclease active site switching steps and (iii) proofreading reactions that initiate in the polymerase active center are not intrinsically processive.     

Nucleotide-induced DNA polymerase active site motions accommodating a mutagenic DNA intermediate

DNA polymerases occasionally insert the wrong nucleotide. For this error to become a mutation, the mispair must be extended. We report a structure of DNA polymerase beta (pol beta) with a DNA mismatch at the boundary of the polymerase active site. The structure of this complex indicates that the templating adenine of the mispair stacks with the primer terminus adenine while the templating (coding) cytosine is flipped out of the DNA helix. Soaking the crystals of the binary complex with dGTP resulted in crystals of a ternary substrate complex. In this case, the templating cytosine is observed within the DNA helix and forms Watson-Crick hydrogen bonds with the incoming dGTP. The adenine at the primer terminus has rotated into a syn-conformation to interact with the opposite adenine in a planar configuration. Yet, the 3'-hydroxyl on the primer terminus is out of position for efficient nucleotide insertion.     

Overexpression of DNA polymerase beta: a genomic instability enhancer process.

DNA polymerase beta (Pol beta) is the most inaccurate of the six DNA polymerases found in mammalian cells. In a normal situation, it is expressed at a constant low level and its role is believed to be restricted to repair synthesis in the base excision repair pathway participating to the genome stability. However, excess of Pol beta, found in some human tumors, could confer an increase in spontaneous mutagenesis and result in a highly mutagenic tolerance phenotype toward bifunctional DNA cross-linking anticancer drugs. Here, we present a hypothesis on the mechanisms used by Pol beta to be a genetic instability enhancer through its overexpression. We hypothesize that an excess of Pol beta perturbs the well-defined specific functions of DNA polymerases developed by the cell and propose Pol beta-mediated gap fillings during DNA transactions like repair, replication, or recombination pathways as key processes to introduce illegitimate deoxyribonucleotides or mutagenic base analogs like those produced by intracellular oxidative processes. These mechanisms may predominate during cellular nonproliferative phases in the absence of DNA replication.     

Minor groove interactions at the DNA polymerase beta active site modulate single-base deletion error rates

The structures of open and closed conformations of DNA polymerase beta (pol beta) suggests that the rate of single-nucleotide deletions during synthesis may be modulated by interactions in the DNA minor groove that align the templating base with the incoming dNTP. To test this hypothesis, we measured the single-base deletion error rates of wild-type pol beta and lysine and alanine mutants of Arg(283), whose side chain interacts with the minor groove edge of the templating nucleotide at the active site. The error rates of both mutant enzymes are increased >100-fold relative to wild-type pol beta. Template engineering experiments performed to distinguish among three possible models for deletion formation suggest that most deletions in repetitive sequences by pol beta initiate by strand slippage. However, pol beta also generates deletions by a different mechanism that is strongly enhanced by the substitutions at Arg(283). Analysis of error specificity suggests that this mechanism involves nucleotide misinsertion followed by primer relocation, creating a misaligned intermediate. The structure of pol beta bound to non-gapped DNA also indicates that the templating nucleotide and its downstream neighbor are out of register in the open conformation and this could facilitate misalignment (dNTP or primer terminus) with the next template base.     

Increased rates of genomic deletions generated by mutations in the yeast gene encoding DNA polymerase delta or by decreases in the cellular levels of DNA polymerase delta

In Saccharomyces cerevisiae, POL3 encodes the catalytic subunit of DNA polymerase delta. While yeast POL3 mutant strains that lack the proofreading exonuclease activity of the polymerase have a strong mutator phenotype, little is known regarding the role of other Pol3p domains in mutation avoidance. We identified a number of pol3 mutations in regions outside of the exonuclease domain that have a mutator phenotype, substantially elevating the frequency of deletions. These deletions appear to reflect an increased frequency of DNA polymerase slippage. In addition, we demonstrate that reduction in the level of wild-type DNA polymerase results in a similar mutator phenotype. Lowered levels of DNA polymerase also result in increased sensitivity to the DNA-damaging agent methyl methane sulfonate. We conclude that both the quantity and the quality of DNA polymerase delta is important in ensuring genome stability.     

Affinity labeling the DNA polymerase alpha complex. Identification of subunits containing the DNA polymerase active site and an important regulatory nucleotide-binding site

Pyridoxal 5'-phosphate (PLP) inhibits DNA polymerase activity of the intact multifunctional DNA polymerase alpha complex by binding at either of two sites which can be distinguished on the basis of differential substrate protection. One site (PLP site 1) corresponds to an important nucleotide-binding site which is distinct from the DNA polymerase active site and which appears to correspond to the DNA primase active site while the second site (PLP site 2) corresponds to the dNTP binding domain of the DNA polymerase active site. A method for the enzymatic synthesis of high specific activity [32P]PLP is described and this labeled PLP was used to identify the binding sites described above. PLP inhibition of DNA polymerase alpha activity was shown to involve the binding of only a few (one to two) molecules of PLP/molecule of DNA polymerase alpha, and this label is primarily found on the 148- and 46-kDa subunits although the 63-, 58-, and 49-kDa subunits are labeled to a lesser extent. Labeling of the 46-kDa subunit by [32P]PLP is the only labeling on the enzyme which is blocked or even diminished in the presence of nucleotide alone, and, therefore, this 46-kDa subunit contains PLP site 1. Labeling of the 148-kDa subunit is enhanced in the presence of template-primer, suggesting that this subunit undergoes a conformational change upon binding template-primer. Furthermore, labeling of the 148-kDa subunit is the only labeling on the enzyme which can be specifically blocked only by the binding of both template-primer and the correct dNTP in a stable ternary complex. Therefore, the 148-kDa subunit contains PLP site 2, which corresponds to the dNTP binding domain of the DNA polymerase active site.     

Alterations of DNA and chromatin structures at telomeres and genetic instability in mouse cells defective in DNA polymerase alpha

Telomere length is controlled by a homeostatic mechanism that involves telomerase, telomere-associated proteins, and conventional replication machinery. Specifically, the coordinated actions of the lagging strand synthesis and telomerase have been argued. Although DNA polymerase alpha, an enzyme important for the lagging strand synthesis, has been indicated to function in telomere metabolism in yeasts and ciliates, it has not been characterized in higher eukaryotes. Here, we investigated the impact of compromised polymerase alpha activity on telomeres, using tsFT20 mouse mutant cells harboring a temperature-sensitive polymerase alpha mutant allele. When polymerase alpha was temperature-inducibly inactivated, we observed sequential events that included an initial extension of the G-tail followed by a marked increase in the overall telomere length occurring in telomerase-independent and -dependent manners, respectively. These alterations of telomeric DNA were accompanied by alterations of telomeric chromatin structures as revealed by quantitative chromatin immunoprecipitation and immunofluorescence analyses of TRF1 and POT1. Unexpectedly, polymerase alpha inhibition resulted in a significantly high incidence of Robertsonian chromosome fusions without noticeable increases in other types of chromosomal aberrations. These results indicate that although DNA polymerase alpha is essential for genome-wide DNA replication, hypomorphic activity leads to a rather specific spectrum of chromosomal abnormality.     

Reactions at the polymerase active site that contribute to the fidelity of Escherichia coli DNA polymerase I (Klenow fragment).

In order to study the structural principles governing DNA polymerase fidelity we have measured the rates of insertion of incorrect nucleotides and the rates of extension from the resulting mismatched base pairs, catalyzed by the Klenow fragment of DNA polymerase I. Using a combination of semi-quantitative and qualitative approaches, we have studied each of the 12 possible mismatches in a variety of sequence contexts. The results indicate that Klenow fragment discriminates between mismatches largely on the basis of the identity of the mismatch, with the surrounding sequence context playing a significant, but secondary, role. For purine-pyrimidine and pyrimidine-pyrimidine mispairs, the relative ease of mismatch synthesis and extension can be rationalized using a simple geometrical model, with the important criterion being the extent to which the mismatched base pair can conform to normal DNA geometry. Essentially similar conclusions have been reached in studies of other polymerases, suggesting that this aspect of mispair geometry is sensed and responded to in a similar way by all polymerases. Purine-purine mismatches form a less cohesive class, showing more variable behavior from mispair to mispair, and a greater apparent susceptibility to sequence context effects. Comparison of our data with studies of other polymerases also suggests that different polymerases respond to purine-purine mismatches in distinct and characteristic ways. An extensive analysis of each of the four purine-purine mispairs in approximately 100 different sequence contexts suggests that the reaction is influenced both by the local DNA structure and by the ability of the mismatched terminus to undergo slippage.     

Identification of DNA polymerase delta in CV-1 cells: studies implicating both DNA polymerase delta and DNA polymerase alpha in DNA replication

DNA polymerases delta and alpha were purified from CV-1 cells, and their sensitivities to the inhibitors aphidicolin, (p-n-butylphenyl)deoxyguanosine triphosphate (BuPdGTP), and monoclonal antibodies directed against DNA polymerase alpha were determined. The effects of these inhibitors on DNA replication in permeabilized CV-1 cells were studied to investigate the potential roles of polymerases delta and alpha in DNA replication. Aphidicolin was shown to be a more potent inhibitor of DNA replication than of DNA polymerase alpha or delta activity. Inhibition of DNA replication by various concentrations of BuPdGTP was intermediate between inhibition of purified polymerase alpha or delta activity. Concentrations of BuPdGTP which totally abolished DNA polymerase alpha activity were much less effective in reducing DNA replication, as well as the activity of DNA polymerase delta. Monoclonal antibodies which specifically inhibited polymerase alpha activity reduced, but did not abolish, DNA replication in permeable cells. BuPdGTP, as well as anti-polymerase alpha antibodies, inhibited DNA replication in a nonlinear manner as a function of time. Depending upon the initial or final rates of inhibition of replication by BuPdGTP and anti-alpha antibodies, as little as 50%, or as much as 80%, of the replication activity can be attributed to polymerase alpha. The remaining replication activity (20-50%) is tentatively attributed to polymerase delta, because it was aphidicolin sensitive and resistant to both anti-polymerase alpha antibodies and low concentrations of BuPdGTP. A concentration of BuPdGTP which abolished polymerase alpha activity reduced, but did not abolish, both the synthesis and maturation of nascent DNA fragments.(ABSTRACT TRUNCATED AT 250 WORDS)     

A genetic look at the active site of RNA polymerase III

rpc160-112, a mutant of the RNA polymerase III active site, is corrected in vivo by six second-site mutants obtained by random mutagenesis. These mutants introduce single-site amino acid replacements at the two large subunits of the enzyme. The mutated motifs are conserved in RNA polymerases I and II and, for some of them, in the bacterial enzyme, thus delineating key elements of the active site in eukaryotic RNA polymerases.     

Telomere dysfunction increases mutation rate and genomic instability

The increased tumor incidence in telomerase null mice suggests that telomere dysfunction induces genetic instability. To test this directly, we examined mutation rate in the absence of telomerase in S. cerevisiae. The mutation rate in the CAN1 gene increased 10- to 100-fold in est1Delta strains as telomeres became dysfunctional. This increased mutation rate resulted from an increased frequency of terminal deletions. Chromosome fusions were recovered from est1Delta strains, suggesting that the terminal deletions may occur by a breakage-fusion-bridge type mechanism. At one locus, chromosomes with terminal deletions gained a new telomere through a Rad52p-dependent, Rad51p-independent process consistent with break-induced replication. At a second locus, more complicated rearrangements involving multiple chromosomes were seen. These data suggest that telomerase can inhibit chromosomal instability.     

Two forms of DNA polymerase delta from mouse cells. Purification and properties

A procedure is described for the purification from cultured mouse cells of two DNA polymerase "delta-like" enzymes, as defined by intrinsic 3'-exonuclease activity, inhibition by aphidicolin, and relative insensitivity to N2-(p-n-butylphenyl)-dGTP. One of the two enzymes has been purified to near homogeneity and, similar to the DNA polymerase delta from calf thymus described by Lee et al. (Lee, M. Y. W. T., Tan, C. K., Downey, K. M., and So, A. G. (1984) Biochemistry 23, 1906-1913), it has a total molecular mass of 178 kDa (from sedimentation velocity of 8.0 S and Stokes radius of 54 A) and is composed of one each of 125- and 50-kDa polypeptides. It also resembles the DNA polymerase delta of Lee et al. in being stimulated by proliferating cell nuclear antigen (PCNA). It is the first clear structural and functional counterpart of the calf thymus enzyme. The major difference between the mouse DNA polymerase delta and the calf thymus enzyme of Lee et al. is that, under specific conditions, the mouse enzyme is active with poly(dA).oligo(dT) in the absence of PCNA, whereas the activity of the calf thymus enzyme with this template is reported to be completely dependent on PCNA. The reason for this difference is not known at this time. The second mouse cell enzyme has a molecular mass of 112 kDa (from sedimentation velocity of 6.3 S and Stokes radius of 43.0 A) and consists of a single polypeptide of 123-125 kDa in denaturing gels (p125). On the basis of its apparent formation by dissociation of DNA polymerase delta, and multiple similarities with DNA polymerase delta in enzymatic properties, the p125 is provisionally identified as the 125-kDa polypeptide of DNA polymerase delta. The p125 does not respond to PCNA, suggesting that the 50-kDa polypeptide is required for the stimulation of DNA polymerase delta by PCNA. The presence of the p125 in cell extracts would explain reports that DNA polymerase delta consists of a single polypeptide of approximately 125 kDa and/or thast it has a smaller molecular mass than DNA polymerase delta of Lee et al. and is not affected by PCNA (this does not apply to PCNA-independent DNA polymerase delta-like enzymes with higher molecular mass than the polymerase delta of Lee et al., which have recently been named DNA polymerases epsilon).     

Evidence for interplay among yeast replicative DNA polymerases alpha, delta and epsilon from studies of exonuclease and polymerase active site mutations

Background  

DNA polymerase ε (Pol ε) is essential for S-phase replication, DNA damage repair and checkpoint control in yeast. A pol2-Y831A mutation leading to a tyrosine to alanine change in the Pol ε active site does not cause growth defects and confers a mutator phenotype that is normally subtle but strong in a mismatch repair-deficient strain. Here we investigate the mechanism responsible for the mutator effect.     

Binding of substrate at the effector site of pyrophosphatase increases the rate of its hydrolysis at the active site

It is shown that in addition to the active site, each subunit of Escherichia coli inorganic pyrophosphatase (E-PPase) contains an extra binding site for the substrate magnesium pyrophosphate or its non-hydrolyzable analog magnesium methylenediphosphonate. The occupancy of the extra site stimulates the substrate conversion. Binding affinity of this site decreased or disappeared upon the conversion of E-PPase into a trimeric form or introduction of point mutations. However, when the slowly hydrolyzed substrate, lanthanum pyrophosphate (LaPP(i)), is used, the extra site was revealed in all enzyme forms of E-PPase and of Y-PPase (Saccharomyces cerevisiae PPase), resulting in about 100-fold activation of hydrolysis. A hypothesis on the localization of the extra site and the mechanism of its effect in E-PPase is presented.     

Immunochemical studies of DNA polymerase delta: relationships with DNA polymerase alpha

A panel of murine hybridoma cell lines which produce antibodies against polypeptides present in human placental DNA polymerase delta preparations was developed. Eight of these antibodies were characterized by virtue of their ability to inhibit DNA polymerase delta activity and immunoblot the 170-kDa catalytic polypeptide. Six of these eight antibodies inhibit DNA polymerase delta but not DNA polymerase alpha, showing that the two proteins are distinct. However, the other two monoclonal antibodies inhibited both DNA polymerase delta and alpha activities, providing the first evidence that these two proteins have a structural relationship. In addition to antibodies against the catalytic polypeptide we also identified 11 antibodies which recognize 120-, 100-, 88-, 75-, 62-, 36-, and 22-kDa polypeptides in DNA polymerase delta preparations, suggesting that these proteins might be part of a replication complex. The antibody to the 36-kDa polypeptide was shown to be directed against proliferating cell nuclear antigen/cyclin. These antibodies should prove useful for studies aimed at distinguishing between DNA polymerases alpha and delta and for the investigation of the functional roles of DNA polymerase delta polypeptides.     

The miscoding potential of 5-hydroxycytosine arises due to template instability in the replicative polymerase active site

5-Hydroxycytosine (5-OHC) is a stable oxidation product of cytosine associated with an increased frequency of C → T transition mutations. When this lesion escapes recognition by the base excision repair pathway and persists to serve as a templating base during DNA synthesis, replicative DNA polymerases often misincorporate dAMP at the primer terminus, which can lead to fixation of mutations and subsequent disease. To characterize the dynamics of DNA synthesis opposite 5-OHC, we initiated a comparison of unmodified dCMP to 5-OHC, 5-fluorocytosine (5-FC), and 5-methylcytosine (5-MEC) in which these bases act as templates in the active site of RB69 gp43, a high-fidelity DNA polymerase sharing homology with human replicative DNA polymerases. This study presents the first crystal structure of any DNA polymerase binding this physiologically important premutagenic DNA lesion, showing that while dGMP is stabilized by 5-OHC through normal Watson-Crick base pairing, incorporation of dAMP leads to unstacking and instability in the template. Furthermore, the electronegativity of the C5 substituent appears to be important in the miscoding potential of these cytosine-like templates. While dAMP is incorporated opposite 5-OHC ~5 times more efficiently than opposite unmodified dCMP, an elevated level of incorporation is also observed opposite 5-FC but not 5-MEC. Taken together, these data imply that the nonuniform templating by 5-OHC is due to weakened stacking capabilities, which allows dAMP incorporation to proceed in a manner similar to that observed opposite abasic sites.