Project description:DNA damage blocks DNA polymerase progression and increases miscoding. In this study, we assessed the effects of specific lesions on Taq DNA polymerase fidelity and amplification efficiency. In the presence of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG), Taq DNA polymerase inserted dCMP and to a lesser extent dAMP. 8-Oxo-7,8-dihydro-2'-deoxyadenosine (8-oxodA) instructed the incorporation of dTMP and caused a pronounced n-1 deletion not observed in other systems. The presence of an abasic lesion led to dAMP incorporation and n-1 deletions. In addition, we introduce the mean modified efficiency (MME) as a more precise method for determining PCR amplification efficiency of damaged templates. Using this method, we were able to quantify reductions in amplification efficiency of templates containing 8-oxodG (single or multiple), 8-oxodA, or abasic sites. Because the MME method can detect small reductions in amplification efficiency, it may be useful in comparing the extent of damage in environmentally degraded or archival DNA specimens.

Project description:DNA polymerase catalyzes the accurate transfer of genetic information from one generation to the next, and thus it is vitally important for replication to be faithful. DNA polymerase fulfills the strict requirements for fidelity by a combination of mechanisms: 1) high selectivity for correct nucleotide incorporation, 2) a slowing down of the replication rate after misincorporation, and 3) proofreading by excision of misincorporated bases. To elucidate the kinetic interplay between replication and proofreading, we used high-resolution optical tweezers to probe how DNA-duplex stability affects replication by bacteriophage T7 DNA polymerase. Our data show highly irregular replication dynamics, with frequent pauses and direction reversals as the polymerase cycles through the states that govern the mechanochemistry behind high-fidelity T7 DNA replication. We constructed a kinetic model that incorporates both existing biochemical data and the, to our knowledge, novel states we observed. We fit the model directly to the acquired pause-time and run-time distributions. Our findings indicate that the main pathway for error correction is DNA polymerase dissociation-mediated DNA transfer, followed by biased binding into the exonuclease active site. The number of bases removed by this proofreading mechanism is much larger than the number of erroneous bases that would be expected to be incorporated, ensuring a high-fidelity replication of the bacteriophage T7 genome.

Project description:In the family-B DNA polymerase of bacteriophage RB69, the conserved aromatic palm-subdomain residues Tyr391 and Tyr619 interact with the last primer-template base-pair. Tyr619 interacts via a water-mediated hydrogen bond with the phosphate of the terminal primer nucleotide. The main-chain amide of Tyr391 interacts with the corresponding template nucleotide. A hydrogen bond has been postulated between Tyr391 and the hydroxyl group of Tyr567, a residue that plays a key role in base discrimination. This hydrogen bond may be crucial for forcing an infrequent Tyr567 rotamer conformation and, when the bond is removed, may influence fidelity. We investigated the roles of these residues in replication fidelity in vivo employing phage T4 rII reversion assays and an rI forward assay. Tyr391 was replaced by Phe, Met and Ala, and Tyr619 by Phe. The Y391A mutant, reported previously to decrease polymerase affinity for incoming nucleotides, was unable to support DNA replication in vivo, so we used an in vitro fidelity assay. Tyr391F/M replacements affect fidelity only slightly, implying that the bond with Tyr567 is not essential for fidelity. The Y391A enzyme has no mutator phenotype in vitro. The Y619F mutant displays a complex profile of impacts on fidelity but has almost the same mutational spectrum as the parental enzyme. The Y619F mutant displays reduced DNA binding, processivity, and exonuclease activity on single-stranded DNA and double-stranded DNA substrates. The Y619F substitution would disrupt the hydrogen bond network at the primer terminus and may affect the alignment of the 3' primer terminus at the polymerase active site, slowing chemistry and overall DNA synthesis.

Project description:DNA polymerase ? (pol ?) synthesizes across from damaged DNA templates in order to prevent deleterious consequences like replication fork collapse and double-strand breaks. This process, termed translesion synthesis (TLS), is an overall positive for the cell, as cells deficient in pol ? display higher mutation rates. This outcome occurs despite the fact that the in vitro fidelity of bypass by pol ? alone is moderate to low, depending on the lesion being copied. One possible means of increasing the fidelity of pol ? is interaction with replication accessory proteins present at the replication fork. We have previously utilized a bacteriophage based screening system to measure the fidelity of bypass using purified proteins. Here we report on the fidelity effects of a single stranded binding protein, replication protein A (RPA), when copying the oxidative lesion 7,8-dihydro-8-oxo-guanine(8-oxoG) and the UV-induced cis-syn thymine-thymine cyclobutane pyrimidine dimer (T-T CPD). We observed no change in fidelity dependent on RPA when copying these damaged templates. This result is consistent in multiple position contexts. We previously identified single amino acid substitution mutants of pol ? that have specific effects on fidelity when copying both damaged and undamaged templates. In order to confirm our results, we examined the Q38A and Y52E mutants in the same full-length construct. We again observed no difference when RPA was added to the bypass reaction, with the mutant forms of pol ? displaying similar fidelity regardless of RPA status. We do, however, observe some slight effects when copying undamaged DNA, similar to those we have described previously. Our results indicate that RPA by itself does not affect pol ? dependent lesion bypass fidelity when copying either 8-oxoG or T-T CPD lesions.

Project description:Oxidative stress is capable of causing damage to various cellular constituents, including DNA. There is however limited knowledge on how oxidative stress influences mitochondrial DNA and its replication. Here, we have used purified mtDNA replication proteins, i.e. DNA polymerase ? holoenzyme, the mitochondrial single-stranded DNA binding protein mtSSB, the replicative helicase Twinkle and the proposed mitochondrial translesion synthesis polymerase PrimPol to study lesion bypass synthesis on oxidative damage-containing DNA templates. Our studies were carried out at dNTP levels representative of those prevailing either in cycling or in non-dividing cells. At dNTP concentrations that mimic those in cycling cells, the replication machinery showed substantial stalling at sites of damage, and these problems were further exacerbated at the lower dNTP concentrations present in resting cells. PrimPol, the translesion synthesis polymerase identified inside mammalian mitochondria, did not promote mtDNA replication fork bypass of the damage. This argues against a conventional role for PrimPol as a mitochondrial translesion synthesis DNA polymerase for oxidative DNA damage; however, we show that Twinkle, the mtDNA replicative helicase, is able to stimulate PrimPol DNA synthesis in vitro, suggestive of an as yet unidentified role of PrimPol in mtDNA metabolism.

Project description:DNA polymerase γ (pol γ), encoded by POLG, is responsible for replicating human mitochondrial DNA. About 150 mutations in the human POLG have been identified in patients with mitochondrial diseases such as Alpers syndrome, progressive external ophthalmoplegia, and ataxia-neuropathy syndromes. Because many of the mutations are described in single citations with no genotypic family history, it is important to ascertain which mutations cause or contribute to mitochondrial disease. The vast majority of data about POLG mutations has been generated from biochemical characterizations of recombinant pol γ. However, recently, the study of mitochondrial dysfunction in Saccharomyces cerevisiae and mouse models provides important in vivo evidence for the role of POLG mutations in disease. Also, the published 3D-structure of the human pol γ assists in explaining some of the biochemical and genetic properties of the mutants. This review summarizes the current evidence that identifies and explains disease-causing POLG mutations.

Project description:Local conformational changes in primer-template (P/T) DNA are involved in the selective incorporation of dNTP by DNA polymerases (DNAP). Here we use near UV CD and fluorescence spectra of pairs of base analogue probes, substituted either at the primer terminus or in the coding region of the template strand, to monitor and interpret conformational changes at and near the coding base of the template in P/T DNA complexes with Klenow fragment (KF) DNAP as the polymerase moves through the nucleotide addition cycle. Incoming dNTPs and rNTPs encounter binary complexes in which the 3'-end of the primer shuttles between the polymerization (pol) and exonuclease (exo) sites of DNAPs, even for perfectly complementary P/T DNA sequences. We have used spectral changes of probes inserted in both strands to monitor this two-state distribution and determine how it depends on the formation of ternary complexes with both complementary ("correct") and noncomplementary ("incorrect") NTPs and on the local sequence of the P/T DNA. The results show that the relative occupancy of the exo and pol sites is coupled to conformational changes in the P/T DNA of the complex that are partially regulated by the incoming NTP. We find that the coding base on the template strand is unperturbed by the binding of incorrect dNTPs, while binding of complementary rNTPs induces a novel template conformation. We conclude that, in addition to its editing function, primer strand occupancy of the 3'-exo site may also serve as a regulatory checkpoint for accurate dNTP selection in DNA synthesis.

Project description:The four B-family DNA polymerases α, δ, ϵ and ζ cooperate to accurately replicate the eukaryotic nuclear genome. Here, we report that a Saccharomyces cerevisiae strain encoding the pol2-16 mutation that lacks Pol ϵ's polymerase and exonuclease activities has increased dNTP concentrations and an increased mutation rate at the CAN1 locus compared to wild type yeast. About half of this mutagenesis disappears upon deleting the REV3 gene encoding the catalytic subunit of Pol ζ. The remaining, still strong, mutator phenotype is synergistically elevated in an msh6Δ strain and has a mutation spectrum characteristic of mistakes made by Pol δ. The results support a model wherein slow-moving replication forks caused by the lack of Pol ϵ's catalytic domains result in greater involvement of mutagenic DNA synthesis by Pol ζ as well as diminished proofreading by Pol δ during replication.

Project description:Mutations in the human mitochondrial polymerase (polymerase-? (Pol-?)) are associated with various mitochondrial disorders, including mitochondrial DNA (mtDNA) depletion syndrome, Alpers syndrome, and progressive external opthamalplegia. To correlate biochemically quantifiable defects resulting from point mutations in Pol-? with their physiological consequences, we created "humanized" yeast, replacing the yeast mtDNA polymerase (MIP1) with human Pol-?. Despite differences in the replication and repair mechanism, we show that the human polymerase efficiently complements the yeast mip1 knockouts, suggesting common fundamental mechanisms of replication and conserved interactions between the human polymerase and other components of the replisome. We also examined the effects of four disease-related point mutations (S305R, H932Y, Y951N, and Y955C) and an exonuclease-deficient mutant (D198A/E200A). In haploid cells, each mutant results in rapid mtDNA depletion, increased mutation frequency, and mitochondrial dysfunction. Mutation frequencies measured in vivo equal those measured with purified enzyme in vitro. In heterozygous diploid cells, wild-type Pol-? suppresses mutation-associated growth defects, but continuous growth eventually leads to aerobic respiration defects, reduced mtDNA content, and depolarized mitochondrial membranes. The severity of the Pol-? mutant phenotype in heterozygous diploid humanized yeast correlates with the approximate age of disease onset and the severity of symptoms observed in humans.

Project description:Mitochondrial DNA is prone to damage by various intrinsic as well as environmental stressors. DNA damage can in turn cause problems for replication, resulting in replication stalling and double-strand breaks, which are suspected to be the leading cause of pathological mtDNA rearrangements. In this study, we exposed cells to subtle levels of oxidative stress or UV radiation and followed their effects on mtDNA maintenance. Although the damage did not influence mtDNA copy number, we detected a massive accumulation of RNA:DNA hybrid-containing replication intermediates, followed by an increase in cruciform DNA molecules, as well as in bidirectional replication initiation outside of the main replication origin, OH. Our results suggest that mitochondria maintain two different types of replication as an adaptation to different cellular environments; the RNA:DNA hybrid-involving replication mode maintains mtDNA integrity in tissues with low oxidative stress, and the potentially more error tolerant conventional strand-coupled replication operates when stress is high.