The in vitro fidelity of yeast DNA polymerase δ and polymerase ε holoenzymes during dinucleotide microsatellite DNA synthesis

Elucidating the sources of genetic variation within microsatellite alleles has important implications for understanding the etiology of human diseases. Mismatch repair is a well described pathway for the suppression of microsatellite instability. However, the cellular polymerases responsible for generating microsatellite errors have not been fully described. We address this gap in knowledge by measuring the fidelity of recombinant yeast polymerase δ (Pol δ) and ? (Pol ?) holoenzymes during synthesis of a [GT/CA] microsatellite. The in vitro HSV-tk forward assay was used to measure DNA polymerase errors generated during gap-filling of complementary GT(10) and CA(10)-containing substrates and ～90 nucleotides of HSV-tk coding sequence surrounding the microsatellites. The observed mutant frequencies within the microsatellites were 4 to 30-fold higher than the observed mutant frequencies within the coding sequence. More specifically, the rate of Pol δ and Pol ? misalignment-based insertion/deletion errors within the microsatellites was ～1000-fold higher than the rate of insertion/deletion errors within the HSV-tk gene. Although the most common microsatellite error was the deletion of a single repeat unit, ～ 20% of errors were deletions of two or more units for both polymerases. The differences in fidelity for wild type enzymes and their exonuclease-deficient derivatives were ～2-fold for unit-based microsatellite insertion/deletion errors. Interestingly, the exonucleases preferentially removed potentially stabilizing interruption errors within the microsatellites. Since Pol δ and Pol ? perform not only the bulk of DNA replication in eukaryotic cells but also are implicated in performing DNA synthesis associated with repair and recombination, these results indicate that microsatellite errors may be introduced into the genome during multiple DNA metabolic pathways.     

Biochemical properties of the stimulatory activity of DNA polymerase α by the hyper-phosphorylated retinoblastoma protein

Previously, my colleagues and I have reported that the immunopurified hyper-phosphorylated retinoblastoma protein (ppRb) stimulates the activity of DNA polymerase α. I describe here the biochemical characteristics of this stimulatory activity. DNA polymerase α-stimulatory activity of ppRb was most remarkable when using activated DNA as a template-primer, rather than using poly(dT)-(rA)₁₀, poly(dA)-(dT)_12–18, and so on. Kinetic analysis showed that there was no significant difference in K_m value for deoxyribonucleotides of DNA polymerase α in the presence of ppRb. Adding ppRb resulted in the overcoming pause site on the template, but did not affect the rate of misincorporation of incorrect deoxyribonucleotides. By adding ppRb, the optimal concentration of template-primer was shifted to a higher region, but not using M13 singly primed DNA. The ppRb seemed to assist the process that DNA polymerase α changed its conformation resulting in appropriate enzyme activity. These results suggest that ppRb affects both template-primer and DNA polymerase α and makes appropriate circumstances for the enzyme reaction.     

Inhibition of DNA polymerase α by gossypol

Our earlier studies have shown that gossypol is a specific inhibitor of DNA synthesis in cultured cells at low doses. In an attempt to determine the mechanism for the inhibition of DNA synthesis by gossypol we observed that gossypol does not interact with DNA per se but may affect some of the enzymes involved in DNA replication. These studies indicated that gossypol inhibits both in vivo and in vitro the activity of DNA polymerase α (EC 2.7.7.7), a major enzyme involved in DNA replication, in a time- and dose-dependent manner. Kinetic analysis revealed that gossypol acts as a noncompetitive inhibitor of DNA polymerase α with respect to all four deoxynucleotide triphosphates and to the activated DNA template. Inhibition of DNA polymerase α does not appear to be due to either metal chelation or reduction of sulfhydryl groups on the enzyme. Gossypol also inhibited HeLa DNA polymerase β in a dose-dependent manner, but had no effect on DNA polymerase γ. These results suggest that inhibition of DNA polymerase α may account in part for the inhibition of DNA synthesis and the S-phase block caused by gossypol. The data also raise the possibility that gossypol may interfere with DNA repair processes as well.     

XRCC1 and DNA polymerase β in cellular protection against cytotoxic DNA single-strand breaks

Single-strand breaks （SSBs） can occur in cells either directly, or indirectly following initiation of base excision repair （BER）. SSBs generally have blocked termini lacking the conventional 5＇-phosphate and 3＇-hydroxyl groups and require further processing prior to DNA synthesis and ligation. XRCC1 is devoid of any known enzymatic activity, but it can physically interact with other proteins involved in all stages of the overlapping SSB repair and BER pathways, including those that conduct the rate-limiting end-tailoring, and in many cases can stimulate their enzymatic activities. XRCC1^-/- mouse fibroblasts are most hypersensitive to agents that produce DNA lesions repaired by monofunctional glycosylase-initiated BER and that result in formation of indirect SSBs. A requirement for the deoxyribose phosphate lyase activity of DNA polymerase β （pol β） is specific to this pathway, whereas pol β is implicated in gap-filling during repair of many types of SSBs. Elevated levels of strand breaks, and diminished repair, have been demonstrated in MMS- treated XRCC1^-/-, and to a lesser extent in pol β^-/- cell lines, compared with wild-type cells. Thus a strong correlation is observed between cellular sensitivity to MMS and the ability of cells to repair MMS-induced damage. Exposure of wild-type and polβ^-/- cells to an inhibitor of PARP activity dramatically potentiates MMS-induced cytotoxicity. XRCC1^-/- cells are also sensitized by PARP inhibition demonstrating that PARP-mediated poly（ADP-ribosyl）ation plays a role in modulation of cytotoxicity beyond recruitment of XRCC 1 to sites of DNA damage.     

Cooperation of terminal deoxynucleotidyl transferase with DNA polymerase α in the replication of ultraviolet-irradiated DNA

The amount of DNA synthesis in vitro with the ultraviolet-irradiated poly-(dT) · oligo(rA) template initiators catalysed by DNA polymerase α (Masaki, S. and Yoshida, S., Biochim. Biophys. Acta 521, 74–88) decreased with the dose of ultraviolet-irradiation. The ultraviolet irradiation to the template, however, did not affect the rate of incorporation of incorrect deoxynycleotides into the newly synthesized poly(dA). The addition of terminal deoxynucleotidyl transferase to this system enhanced the DNA synthesis to a level which is comparable to that of the control and it concomitantly increased the incorporation of the mismatched deoxynucleotide into the newly synthesized poly(dA) strands. On the other hand, with an unirradiated template initiator, the misincorporation was only slightly enhanced by the addition of terminal deoxynucleotidyl transferase. The sizes of newly synthesized DNA measured by the sedimentation velocities were found to be smaller with the ultraviolet-irradiated templates but they increased to the control level with the addition of terminal deoxynucleotidyl transferase to the systems. These results suggest that terminal deoxynucleotidyl transferase can help DNA polymerase α to ‘bypass’ thymine dimers in vitro by the formation of mismatched regions at the positions opposite to pyrimidine dimers on the template.     

Intracellular localization and metabolism of DNA polymerase α in human cells visualized with monoclonal antibody

Indirect immunofluorescence microscopy with monoclonal antibody against DNA polymerase α revealed the intranuclear localization of DNA polymerase α in G1, S, and G2 phases of transformed human cells, and dispersed cytoplasmic distribution during mitosis. In the quiescent, G0 phase of normal human skin fibroblasts or lymphocytes, the α-enzyme was barely detectable by either immunofluorescence or enzyme activity. By exposing cells to proliferation stimuli, however, DNA polymerase a appeared in the nuclei just prior to onset of DNA synthesis, increased rapidly during S phase, reached the maximum level at late S and G2 phases, and was then redistributed to the daughter cells through mitosis. It was also found that the increase in the amount of DNA polymerase a by proliferation stimuli was not affected by inhibition of DNA synthesis with aphidicolin or hydroxyurea.     

Proofreading of ribonucleotides inserted into DNA by yeast DNA polymerase ɛ

We have investigated the ability of the 3′ exonuclease activity of Saccharomyces cerevisiae DNA polymerase ? (Pol ?) to proofread newly inserted ribonucleotides (rNMPs). During DNA synthesis in vitro, Pol ? proofreads ribonucleotides with apparent efficiencies that vary from none at some locations to more than 90% at others, with rA and rU being more efficiently proofread than rC and rG. Previous studies show that failure to repair ribonucleotides in the genome of rnh201Δ strains that lack RNase H2 activity elevates the rate of short deletions in tandem repeat sequences. Here we show that this rate is increased by 2–4-fold in pol2-4 rnh201Δ strains that are also defective in Pol ? proofreading. In comparison, defective proofreading in these same strains increases the rate of base substitutions by more than 100-fold. Collectively, the results indicate that although proofreading of an ‘incorrect’ sugar is less efficient than is proofreading of an incorrect base, Pol ? does proofread newly inserted rNMPs to enhance genome stability.     

Mismatch repair-independent increase in spontaneous mutagenesis in yeast lacking non-essential subunits of DNA polymerase ε

Yeast DNA polymerase ε (Pol ε) is a highly accurate and processive enzyme that participates in nuclear DNA replication of the leading strand template. In addition to a large subunit (Pol2) harboring the polymerase and proofreading exonuclease active sites, Pol ε also has one essential subunit (Dpb2) and two smaller, non-essential subunits (Dpb3 and Dpb4) whose functions are not fully understood. To probe the functions of Dpb3 and Dpb4, here we investigate the consequences of their absence on the biochemical properties of Pol ε in vitro and on genome stability in vivo. The fidelity of DNA synthesis in vitro by purified Pol2/Dpb2, i.e. lacking Dpb3 and Dpb4, is comparable to the four-subunit Pol ε holoenzyme. Nonetheless, deletion of DPB3 and DPB4 elevates spontaneous frameshift and base substitution rates in vivo, to the same extent as the loss of Pol ε proofreading activity in a pol2-4 strain. In contrast to pol2-4, however, the dpb3Δdpb4Δ does not lead to a synergistic increase of mutation rates with defects in DNA mismatch repair. The increased mutation rate in dpb3Δdpb4Δ strains is partly dependent on REV3, as well as the proofreading capacity of Pol δ. Finally, biochemical studies demonstrate that the absence of Dpb3 and Dpb4 destabilizes the interaction between Pol ε and the template DNA during processive DNA synthesis and during processive 3' to 5'exonucleolytic degradation of DNA. Collectively, these data suggest a model wherein Dpb3 and Dpb4 do not directly influence replication fidelity per se, but rather contribute to normal replication fork progression. In their absence, a defective replisome may more frequently leave gaps on the leading strand that are eventually filled by Pol ζ or Pol δ, in a post-replication process that generates errors not corrected by the DNA mismatch repair system.     

Induction of alkaline phosphatase and the glycoprotein hormone α subunit in HeLa cells by inhibitors of DNA polymerase

Levels of the glycoprotein hormone α subunit and alkaline phosphatase activity were increased in cultures of HeLa S₃ cells exposed to aphidicolin (0.2–10 μg/ml) or phosphonoformic acid (0.1–3 mm), inhibitors of DNA polymerase α. Induction was dependent on both the concentration and duration of exposure to the inhibitors and was prevented by cycloheximide and actinomycin D. Limited characterization of the induced α subunit and alkaline phosphatase activity suggest that they are similar to the uninduced proteins expressed by this cell line. Induction of both proteins by aphidicolin and phosphonoformic acid was enhanced by the simultaneous addition of 3 mm sodium butyrate but was depressed by 1 mm hydroxy urea. In contrast, both butyrate and hydroxy urea cause induction of these proteins when added alone to HeLa cultures. It is unlikely that a direct relationship exists between protein induction and the inhibition of DNA synthesis produced by aphidicolin and phosphonoformic acid since the concentrations required to produce half-maximal induction are 5 to 10 times greater than those needed to inhibit replication by 50%.     

Insights into the cellular role of enigmatic DNA polymerase ι

It has been a decade since the discovery of human DNA polymerase ι (polι). Since that time, the enzyme has been characterized extensively at the biochemical level, but the cellular function of polι remains enigmatic. Recent studies on polι have, however, provided much needed insights into its biological role(s) and suggest that the enzyme plays important functions in protecting humans from the deleterious consequences of exposure to both oxidative- and ultraviolet light-induced DNA damage.     

DNA polymerase III α subunit from Mycobacterium tuberculosis H37Rv: Homology modeling and molecular docking of its inhibitor

The alpha subunit of Mycobacterial DNA polymerase III holo enzyme catalyzes the polymerization of both DNA strands. The present investigation reports three dimensional (3-D) structure model of DNA polymerase III α subunit of Mycobacterium tuberculosis H37Rv (MtbDnaE1) generated using homology modeling with the backbone structure of DNA polymerase III α of Thermus aquaticus as a template. The model was evaluated at various structure verification servers, which assess the stereo chemical parameters of the residues in the model, as well as structural and functional domains. Comparative analysis of MtbDnaE1 structure reveals the structure of its catalytic domain to be unrelated to that of the human. Successful docking of known inhibitor of bacterial DNA polymerases, 251D onto the modeled MtbDnaE1 was also performed. Therefore, the structure model of MtbDnaE1, a potential anti-mycobacterial target, opens a new avenue for structure-based drug designing against the pathogen. ABBREVIATIONS: aa - amino acid(s), PolIIIα - DNA polymerase III alpha subunit, Taq Pol IIIα - Pol IIIα of Thermus aquaticus, MtbDnaE1 - PolIIIα of Mycobacterium tuberculosis.     

Inhibition of calf thymus DNA polymerase α and of normal and cancer cell growth by butylanilinouracil and butylphenylguanine

6-(p-n-Butylanilino)uracil and N²-(p-butylphenyl)guanine inhibited the activity of DNA polymerase α from calf thymus but had no effect on other eukaryotic polymerases (DNA polymerases β and γ) or Escherichia coli DNA polymerase I. Inhibition was competitive with deoxyguanosine 5′-triphosphate and did not occur in the reaction of DNA polymerase α with a template that did not contain cytosine residues. The results support a mechanism which involves hydrogen bonding of inhibitors with cytosines in the DNA template and binding with an inhibitor specific site on the enzyme. A screen of inhibitor effects on normal and cancer cell growth in culture showed that cells were not uniformly sensitive to these compounds, a mouse lymphoma line being least sensitive and a human lung cancer line being most sensitive. It is suggested that these inhibitors may be useful to probe possible structural differences among DNA polymerases α.     

Lack of DNA polymerase μ affects the kinetics of DNA double-strand break repair and impacts on cellular senescence

The specialised DNA polymerase μ (pol μ) affects a sub-class of immunoglobulin genes rearrangements and haematopoietic development in vivo. These effects appear linked to double-strand breaks (DSBs) repair, but it is still unclear how and to what extent pol μ intervenes in this process. Using high-resolution quantitative imaging of DNA damage in irradiated wild-type and pol μ^?/? mouse embryonic fibroblasts (MEFs) we show that lack of pol μ results in delayed DSB repair kinetics and in persistent DNA damage. DNA damage triggers cellular senescence, and this response is thought to suppress cancer. Independent investigations either report or not a proliferative decline for MEFs lacking pol μ. Here we show pronounced senescence in pol μ^?/? MEFs, associated with high levels of the tumor-suppressor p16^INK4A and the DNA damage response kinase CHK2. Importantly, cellular senescence is induced by culture stress and exacerbated by low doses of irradiation in pol μ^?/? MEFs. We also found that low doses of irradiation provoke delayed immortalisation in MEFs lacking pol μ. Pol μ^?/? MEFs thus exhibit a robust anti-proliferative defence in response to irreparable DNA damage. These findings indicate that sub-optimal DSB repair, due to the absence of an auxiliary DNA damage repair factor, can impact on cell fitness and thereby on cell fate.     

Suppressors of the temperature sensitivity of DNA polymerase α mutations in Saccharomyces cerevisiae

We have isolated two high copy, allele-specific suppressors of the temperature sensitivity of mutations in POL1, the gene that encodes the catalytic subunit of DNA polymerase α in the yeast Saccharomyces cerevisiae. Both genes, PSP1 and PSP2, also partially suppressed a mutation in POL3 which encodes DNA polymerase δ, and both also affected a mutation in CDC6, which acts in initiation of DNA replication. Suppression was not general, since ts mutations in several genes unrelated to replication were not affected. PSP1 was partially effective on low-copy-number vectors, while PSP2 required high copy numbers. The presence of suppressing plasmids did not alter the steady-state level of Pol1 protein, so suppression does not appear to be due to an increase in production or stability of Pol1p. Deletion of either PSP gene or both in combination resulted in apparently normal viable cells. While neither gene is homologous to genes with known functions, PSP1 and PSP2 both have unusual amino acid compositions: PSP1 is rich in asparagine and glutamine, while PSP2 is rich in asparagine and contains “RGG” motifs that have been associated with RNA-binding proteins. We also describe a transposon-mediated strategy that should be generally effective for rapid characterization of multicopy suppressors. Received: 20 July 1997 / Accepted: 1 October 1997     

Switching between polymerase and exonuclease sites in DNA polymerase ε

The balance between exonuclease and polymerase activities promotes DNA synthesis over degradation when nucleotides are correctly added to the new strand by replicative B-family polymerases. Misincorporations shift the balance toward the exonuclease site, and the balance tips back in favor of DNA synthesis when the incorrect nucleotides have been removed. Most B-family DNA polymerases have an extended β-hairpin loop that appears to be important for switching from the exonuclease site to the polymerase site, a process that affects fidelity of the DNA polymerase. Here, we show that DNA polymerase ε can switch between the polymerase site and exonuclease site in a processive manner despite the absence of an extended β-hairpin loop. K967 and R988 are two conserved amino acids in the palm and thumb domain that interact with bases on the primer strand in the minor groove at positions n−2 and n−4/n−5, respectively. DNA polymerase ε depends on both K967 and R988 to stabilize the 3′-terminus of the DNA within the polymerase site and on R988 to processively switch between the exonuclease and polymerase sites. Based on a structural alignment with DNA polymerase δ, we propose that arginines corresponding to R988 might have a similar function in other B-family polymerases.     

DNA damage in telomeres and mitochondria during cellular senescence: is there a connection?

Cellular senescence is the ultimate and irreversible loss of replicative capacity occurring in primary somatic cell culture. It is triggered as a stereotypic response to unrepaired nuclear DNA damage or to uncapped telomeres. In addition to a direct role of nuclear DNA double-strand breaks as inducer of a DNA damage response, two more subtle types of DNA damage induced by physiological levels of reactive oxygen species (ROS) can have a significant impact on cellular senescence: Firstly, it has been established that telomere shortening, which is the major contributor to telomere uncapping, is stress dependent and largely caused by a telomere-specific DNA single-strand break repair inefficiency. Secondly, mitochondrial DNA (mtDNA) damage is closely interrelated with mitochondrial ROS production, and this might also play a causal role for cellular senescence. Improvement of mitochondrial function results in less telomeric damage and slower telomere shortening, while telomere-dependent growth arrest is associated with increased mitochondrial dysfunction. Moreover, telomerase, the enzyme complex that is known to re-elongate shortened telomeres, also appears to have functions independent of telomeres that protect against oxidative stress. Together, these data suggest a self-amplifying cycle between mitochondrial and telomeric DNA damage during cellular senescence.