The mutational specificity of DNA polymerases-alpha and -gamma during in vitro DNA synthesis

Low fidelity mutants in the O-helix of Thermus aquaticus DNA polymerase I

We screened 67 mutants in the O-helix of Thermus aquaticus (Taq) DNA polymerase I (pol I) for altered fidelity of DNA synthesis. These mutants were obtained (Suzuki, M., Baskin, D., Hood, L., and Loeb, L. A. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 9670-9675) by substituting an oligonucleotide containing random sequences for codons 659-671, and selecting for complementation of a growth defect in Escherichia coli caused by temperature-sensitive host pol I. Thirteen mutants decreased fidelity in a screen that employed primer extension reactions lacking one of four complementary deoxynucleoside triphosphates (dNTPs). Three mutants were purified and exhibited 29-68% of wild-type specific activity. Homogeneous polymerases A661E, A661P, and T664R extended primers further than the wild-type, synthesizing past template nucleotides for which the complementary dNTP was absent. The data indicate that both misinsertion of incorrect nucleotides and extension of mispaired primer termini were increased. In a lacZalpha forward mutation assay, A661E and T664R yielded mutation frequencies at least 7- and 25-fold greater, respectively, than that of the wild-type polymerase. These findings emphasize the importance of the O-helix in substrate recognition and are compatible with a role for pyrophosphate release in enhancing fidelity of DNA synthesis.

Incorporation of the guanosine triphosphate analogs 8-oxo-dGTP and 8-NH2-dGTP by reverse transcriptases and mammalian DNA polymerases

We have measured the efficiencies of utilization of 8-oxo-dGTP and 8-NH2-dGTP by human immunodeficiency virus type 1 and murine leukemia virus reverse transcriptases and compared them to those of DNA polymerases alpha and beta. Initially, we carried out primer extension reactions in the presence of dGTP or a dGTP analog and the remaining three dNTPs using synthetic DNA and RNA templates. These assays revealed that, in general, 8-NH2-dGTP is incorporated and extended more efficiently than 8-oxo-dGTP by all enzymes tested. Second, we determined rate constants for the incorporation of each analog opposite a template cytidine residue using steady state single nucleotide extension kinetics. Our results demonstrated the following. 1) Both reverse transcriptases incorporate the nucleotide analogs; discrimination against their incorporation is a function primarily of Km or Vmax depending on the analog and the enzyme. 2) Discrimination against the analogs is more stringent with the DNA template than with a homologous RNA template. 3) Polymerase alpha exhibits a mixed kinetic phenotype, with a large discrimination against 8-oxo-dGTP but a comparatively higher preference for 8-NH2-dGTP. 4) Polymerase beta incorporates both analogs efficiently; there is no discrimination with respect to Km and a significantly lower discrimination with respect to Vmax when compared with the other polymerases.

Mitochondrial DNA maintenance in vertebrates

The discovery that mutations in mitochondrial DNA (mtDNA) can be pathogenic in humans has increased interest in understanding mtDNA maintenance. The functional state of mtDNA requires a great number of factors for gene expression, DNA replication, and DNA repair. These processes are ultimately controlled by the cell nucleus, because the requisite proteins are all encoded by nuclear genes and imported into the mitochondrion. DNA replication and transcription are linked in vertebrate mitochondria because RNA transcripts initiated at the light-strand promoter are the primers for mtDNA replication at the heavy-strand origin. Study of this transcription-primed DNA replication mechanism has led to isolation of key factors involved in mtDNA replication and transcription and to elucidation of unique nucleic acid structures formed at this origin. Because features of a transcription-primed mechanism appear to be conserved in vertebrates, a general model for initiation of vertebrate heavy-strand DNA synthesis is proposed. In many organisms, mtDNA maintenance requires not only faithful mtDNA replication, but also mtDNA repair and recombination. The extent to which these latter two processes are involved in mtDNA maintenance in vertebrates is also appraised.

Catalytic subunit of mitochondrial DNA polymerase from Drosophila embryos. Cloning, bacterial overexpression, and biochemical characterization

A full-length cDNA of the catalytic subunit of mitochondrial DNA polymerase from Drosophila embryos has been obtained, and its nucleotide sequence was determined. The cDNA clone encodes a polypeptide with a deduced amino acid sequence of 1145 residues and a predicted molecular mass of 129.9 kDa. Amino-terminal sequence analysis of the mature catalytic subunit of the heterodimeric mitochondrial enzyme from Drosophila embryos identified the amino-terminal amino acid at position +10 in the deduced amino acid sequence, indicating a mitochondrial presequence peptide of only nine amino acids. Alignment of the catalytic subunit sequence with that of Escherichia coli DNA polymerase I Klenow fragment indicated a high degree of amino acid sequence conservation in each of the three DNA polymerase and three 3' --> 5' exonuclease domains identified by biochemical studies in the latter enzyme. Bacterial overexpression, purification, and biochemical analysis demonstrated both 5' --> 3' DNA polymerase and 3' --> 5' exonuclease in the recombinant polypeptide. This represents the first demonstration of 3' --> 5' exonuclease activity in the polymerase catalytic subunit of animal mitochondrial DNA polymerase.

Fidelity and error specificity of the alpha catalytic subunit of Escherichia coli DNA polymerase III

Escherichia coli DNA polymerase III holoenzyme is the replicative enzyme primarily responsible for the duplication of the E. coli chromosome. This process occurs with high accuracy, less than 10(-9) to 10(-10) errors being committed per base pair per round of replication. As a first step in understanding the mechanisms responsible for the high fidelity of this process, we have purified the polymerase III alpha catalytic subunit, free of exonuclease activity, and analyzed its fidelity in vitro. We employed a newly developed gap-filling assay using the N-terminal 250 bases of the lacI gene as a forward mutational target. When synthesizing across this target, alpha subunit produced mutations at a frequency of 0.6%. DNA sequencing revealed that the mutants created in vitro consisted mostly of frameshift mutations, although some base substitutions were also observed. The frameshifts, occurring at more than 120-fold above the background, consisted largely of -1 deletions. Among them, about 80% were the deletion of a purine template base with a pyrimidine 5'-neighbor. These results suggest that the alpha subunit (i) has a relatively low ability to extend from misincorporated bases, accounting for the low level of observed base substitutions, and (ii) has a relatively high capability of extension after misalignment of a misincorporated base on the next (complementary) template base, accounting for the high level of frameshift mutations. This model is supported by an experiment in which alpha subunit was required to initiate DNA synthesis from a terminal mispair in a sequence context that allowed slippage on the next template base. Among the products of this reaction, frameshifts outnumbered base pair substitutions by greater than 70-fold. A comparison to in vivo mutational spectra suggests that the pol III accessory factors may play a major role in modulating the fidelity of DNA synthesis.

In vitro bypass replication of the cisplatin-d(GpG) lesion by calf thymus DNA polymerase beta and human immunodeficiency virus type I reverse transcriptase is highly mutagenic

Eukaryotic DNA polymerase beta and the reverse transcriptases are the most inaccurate of the known DNA polymerases. We report here mutagenic replication in vitro past intrastrand N(7)G-N(7)G chelates of the cis-diamminedichloroplatinum(II), the major DNA adduct of the antitumor agent cisplatin by calf thymus DNA polymerase beta and human immunodeficiency virus type I reverse transcriptase (42% and 26% mutations, respectively). The most frequent modifications generated by both enzymes were one-base frameshift deletions. Only one mutational hot spot opposite the platinated guanines was observed with human immunodeficiency virus type I reverse transcriptase, while two hot spots were generated by DNA polymerase beta, one at the base situated 5' to the lesion and the other situated 4-6 nucleotides 5' to the adduct. An unusual mutagenic event, tandem replication of a 12-base pair sequence, was observed with DNA polymerase beta. The mutational spectra of the two DNA polymerases suggest that template slippage occurred with higher frequency in the presence of the more distributive DNA polymerase beta.

Somatic mutations in the brain: relationship to aging?

Genetic instability is generally thought to underlie the process of aging and is predominantly associated with meiosis and mitosis. This review will discuss DNA damage and repair, somatic mutations and somatic recombination events in non-dividing neurons in relation to aging. In general it can be concluded that mutagenesis operates at high frequency in the brain. Present data do not provide clear evidence for accumulating DNA damage or a change in DNA repair activity in the brain with age. However, a linear age-related increase in frameshift mutations has been shown to occur in vasopressin neurons of the rat, revealing a novel post-mitotic mechanism.

Deletion mapping of highly conserved transcribed sequence downstream from APRT locus

To investigate the nature of DNA sequence rearrangements occurring in a highly malignant human colorectal carcinoma cell line (SW620) exhibiting a high level of chromosome instability, we characterized the molecular basis of deletions eliminating APRT. Deletions in SW620 resembled those in a variety of cell lines. They were joined at regions of little similarity through mono-, di-, or trinucleotide repeats. Breakpoint regions were rich in di- and trinucleotide repeats that might constitute pause sites for the replication complex. Deletions ranged in size from 1.8 to approximately 70 kb and were "directional" in that they eliminated sequences upstream of APRT but not downstream. Analysis of downstream sequences suggested that this pattern of deletion was due to the presence of another gene. Transcripts from these two genes converged but did not overlap. Given that this gene was not deleted in any hamster or human mutants, it appears essential for cell viability. This organization has important consequences for the pattern of mutation and repair of this region.

Mutagenesis by metal-induced oxygen radicals

To assess the contribution of reactive oxygen species (ROS) to metal-induced mutagenesis, we have determined the spectrum of mutations in the lacZ alpha gene after exposure of M13mp2 DNA to Fe2+, Cu2+, and Ni2+. With iron and copper ions, mutations are clustered and are predominantly single-base substitutions. Fe, Cu, and phorbol ester-stimulated neutrophils also produced tandem double CC-->TT mutations. This mutation may provide a marker for the role of oxidative damage in carcinogenesis. Mutagenesis by Ni2+ required the complexing of the metal to a tripeptide and the addition of H2O2. To assess the contribution of ROS in mammalian cells, we determined the spectrum of mutations produced when purified DNA polymerases-alpha and -beta synthesized DNA using a template that had been damaged by ROS. The mutation spectra produced by the two polymerases indicates that these enzymes substitute different nucleotides opposite the same lesions.

High rates of frameshift mutations within homo-oligomeric runs during a single cycle of retroviral replication

Homo-oligomeric runs were inserted into a spleen necrosis virus-based retrovirus vector to determine the nature and rate of mutations within runs of 10 to 12 identical nucleotides during a single replication cycle. Clones of helper cells containing integrated copies of retroviral vectors were used to produce virus for infection of target (nonhelper) cells. Proviral sequences from target cell clones were compared with proviral sequences from helper cell clones to study mutations that occurred during a single cycle of replication. In addition to the internal region spanning the homo-oligomeric inserts, a naturally occurring run of 10 T's in the long terminal repeat (LTR) also was sequenced. Rates of mutation ranged from < 0.01 to 0.38 frameshift mutations per run per cycle for different nucleotide runs. Frameshift mutations ranged from deletions of 2 bases to additions of 5 bases; the most common mutations were +1 and -1. Frameshift mutation rates did not increase as the run length increased from 10 to 12 bases. Rates of frameshift mutation for runs of T's and A's were significantly higher than rates for runs of C's and G's, and rates for runs of pyrimidines were significantly higher than those for runs of purines. Interestingly, the vast majority of frameshift mutations in the internal region (95%) were positive, suggesting that the primer strand tends to slip backward on the template in this region. LTR runs had a significantly lower number of positive frameshift mutations than the internal runs. By analyzing the types of frameshift mutations within runs and by comparing the patterns of frameshift mutations in the 5' and 3' LTRs of individual proviruses, we conclude that the majority of mutations observed in our system occurred during minus-strand DNA synthesis of reverse transcription.

DNA replication fidelity with 8-oxodeoxyguanosine triphosphate

Oxidative metabolism is known to generate mutagenic compounds within cells, among which is 8-oxodeoxyguanosine. Here the mutagenic potential of the triphosphate form of this base analog (8-O-dGTP) is investigated during replication in vitro of the lacZ alpha-complementation sequence in M13mp2 DNA. Adding 8-O-dGTP at equimolar concentration with the normal dNTPs to polymerization reactions decreases the fidelity of DNA synthesis by exonuclease-deficient Klenow, T4, and Thermus thermophilus DNA polymerases. Sequence analysis of mutants suggests that 8-O-dGMP is misincorporated opposite template adenines, yielding A-->C transversions. The degree of polymerase selectivity against this error is enzyme-dependent, with rates varying by > 25-fold. To determine if the A.8-O-dGMP mispair is proofread, a direct comparison of the fidelity of proofreading-proficient and proofreading-deficient Klenow and T4 DNA polymerases was made. Although the exonuclease activity of Klenow polymerase did not substantially reduce overall misincorporation of 8-O-dGMP, misincorporation was lower for the proofreading-proficient T4 enzyme as compared to its proofreading-deficient derivative. These data suggest that the A.8-O-dGMP mispair can be proofread. The mutagenic potential of 8-O-dGTP with eukaryotic systems was also examined. Misincorporation of 8-O-dGTP opposite adenine was observed during SV40 origin-dependent replication of double-stranded DNA in HeLa cell extracts. When present during replication at a concentration equal to the four normal dNTPs, 8-O-dGTP was at least 13-fold more mutagenic for A.T-->C.G transversions than was a 100-fold excess of normal dGTP.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxygen radical induced mutagenesis is DNA polymerase specific

Oxygen free radicals are produced in large amounts by normal cellular processes. Damage to DNA by these reactive species has been implicated in mutagenesis and may be important in the etiology of a variety of human diseases. In this study we investigate the types of mutations produced in vitro as a result of DNA damage by oxygen free radicals. We used a lacZ alpha forward mutation assay in which M13 viral DNA is damaged in vitro, replicated with purified DNA polymerase alpha or beta, transfected into E. coli, and screened for mutations by reduced alpha-complementation of beta-galactosidase activity. By determining the effects of damaged templates on the fidelity of individual DNA polymerases involved in replication and repair, we address the role of specific DNA polymerases in mutagenesis induced by reactive oxygen species. Aerobic incubation of DNA with 100 microM CuCl, 10 microM H2O2 and 100 microM ascorbic acid results in a 3.3-fold and a 3.6-fold elevation in mutation frequency for polymerases alpha and beta, respectively. The specificity and location of the induced mutations, however, are entirely different. For polymerase alpha, A to C, and C to A transversions and deletions of C are each elevated more than 10-fold over their frequencies on undamaged template. For polymerase beta, A to T, C to T, C to A, G to C, and G to T substitutions, and deletions of G are elevated by damage. The frequency of mutants containing two or more closely spaced substitutions is also markedly increased by template damage although the types of mutations and their positions are again specific to each DNA polymerase. We conclude that, for oxidative lesions, the frequency and the types of mutations are determined in part by the DNA polymerase that encounters the site of damage.

International Commission for Protection Against Environmental Mutagens and Carcinogens. Working paper no. 5. Impact of the molecular spectrum of mutational lesions on estimates of germinal gene-mutation rates

Review of the molecular characteristics of the variants identified at a series of disease loci suggests significant differences among loci in the relative frequency of nucleotide substitutions versus more complex events such as deletions. Some common features are repeatedly observed in each class of variant. For example, a high proportion of the nucleotide substitutions involve transitions of deoxycytidine and are suggested to result from deamination of cytosine at 5-methyl-CpG sites. Similarly, deletions of three or fewer nucleotides are relatively common in the non-nucleotide substitution class and these deletions are often associated with a seven-nucleotide core sequence. A significant fraction of the larger deletions and rearrangements may be associated with repetitive elements. Many of the deletion events do not appear to involve a chromosomal recombination mechanism. Mechanisms involving transcription slippage and chromatid exchange have been suggested as possible alternative mechanisms for generating deletion events. The spectrum of mutational events identified, e.g. nucleotide substitutions versus deletions, differs between loci and is probably a reflection of both the gene structure and the selective pressure to generate a disease phenotype. This locus specificity (at both the biological and molecular level) would appear to have significant potential to compromise estimates of increases in the gene germinal mutation rate following exposure to mutagenic agents.

Multi-stage proofreading in DNA replication

The mechanisms by which DNA polymerases achieve their remarkable fidelity, including base selection and proofreading, are briefly reviewed. Nine proofreading models from the current literature are evaluated in the light of steady-state and transient kinetic studies of E. coli DNA polymerase I, the best-studied DNA polymerase. One model is demonstrated to predict quantitatively the response of DNA polymerase I to three mutagenic probes of proofreading: exogenous pyrophosphate, deoxynucleoside monophosphates, and the next correct deoxynucleoside triphosphate substrate, as well as the response to combinations of these probes. The theoretical analysis allows elimination of many possible proofreading mechanisms based on the kinetic data. A structural hypothesis links the kinetic analysis with crystallographic, NMR and genetic studies. It would appear that DNA polymerase I proofreads each potential error twice, at the same time undergoing two conformational changes within a catalytic cycle. Multi-stage proofreading is more efficient, and may be utilized in other biological systems as well. In fact, recent evidence suggests that fidelity of transfer RNA charging may be ensured by a similar mechanism.

Echinomycin, a bis-intercalating agent, induces C-->T mutations via cytosine deamination

Echinomycin, a bis-intercalating, antitumor drug, has been studied for its ability to induce the deamination of cytosine to uracil (C-->U) in double-stranded DNA. We have employed a sensitive lacZ alpha-complementation reversion assay to detect G.C-->A.T mutations at a number of sites in M13mp2 DNA to determine the extent to which distortions of DNA structure induced by echinomycin may affect C-->U rates. When double-stranded M13mp2 DNA with a 12-base target containing a CpG site was incubated at 37 degrees C, the reversion frequency of the echinomycin-treated DNA increased linearly over time, with a rate constant 3-fold greater than DNA incubated without echinomycin. Of the 11 ways that blue pseudo-revertants can occur in the target, 96% of the observed revertants arose from C-->T and tandem CC-->TT transitions, with 78% attributable to single-base C-->T changes at three sites. Transfection into ung+ cells decreased the reversion frequencies by 85% to near background levels, indicating that the increase in C-->T mutations was due to deamination of C to U. The cytosine deamination rate constants for the entire target at pH 6.0 and 37 degrees C were 1.2 x 10(-11) sec-1 for untreated DNA and 3.5 x 10(-11) sec-1 for echinomycin-treated DNA. The increase in C-->T mutation rates occurred at cytosines both proximal and distal to a CpG echinomycin-binding site. We hypothesize that this increase in deamination rate is due to a more open or single-stranded DNA structure caused by the echinomycin: DNA interaction.

Nucleotide sequence analysis of human hypoxanthine phosphoribosyltransferase (HPRT) gene deletions

We have determined the nucleotide sequences of 10 intragenic human HPRT gene deletion junctions isolated from thioguanine-resistant PSV811 Werner syndrome fibroblasts or from HL60 myeloid leukemia cells. Deletion junctions were located by fine structure blot hybridization mapping and then amplified with flanking oligonucleotide primer pairs for DNA sequence analysis. The junction region sequences from these 10 HPRT mutants contained 13 deletions ranging in size from 57 bp to 19.3 kb. Three DNA inversions of 711, 368, and 20 bp were associated with tandem deletions in two mutants. Each mutant contained the deletion of one or more HPRT exon, thus explaining the thioguanine-resistant cellular phenotype. Deletion junction and donor nucleotide sequence alignments suggest that all of these HPRT gene rearrangements were generated by the nonhomologous recombination of donor DNA duplexes that share little nucleotide sequence identity. This result is surprising, given the potential for homologous recombination between copies of repeated DNA sequences that constitute approximately a third of the human HPRT locus. No difference in deletion structure or complexity was observed between deletions isolated from Werner syndrome or from HL60 mutants. This suggests that the Werner syndrome deletion mutator uses deletion mutagenesis pathway(s) that are similar or identical to those used in other human somatic cells.

Inhibitors of HIV-1 reverse transcriptase and fidelity of in vitro DNA replication

Mechanisms of the effects of the dTTP analogues 3'-azido-3'-deoxythymidine 5'-triphosphate (AZTTP) and 3'-amino-3'-deoxythymidine 5'-triphosphate (NH2 TTP) upon the HIV-1 reverse transcriptase (RT) are discussed. These compounds block the RT in vitro and do so by different kinetic mechanisms. Infidelity of replication is a hallmark of the HIV-1 RT, and replication errors by the enzyme on RNA and DNA templates are discussed. The enzyme's infidelity has ramifications for inhibition: On the one hand, the propensity to produce mutations enhances the ability of the virus to escape inhibitors whereas on the other hand, the infidelity of the reverse transcriptase may allow the development of imaginative inhibitor strategies.

Influence of neighboring base sequence on mutagenesis induced by in vitro misincorporation in the lacI gene of Escherichia coli

Genetic and electrophoretic assays of misincorporation were used to assess the effect of DNA sequence on mutagenesis arising from in vitro DNA synthesis within the lacI gene of Escherichia coli. The viral strand of a derivative of phage M13 containing the entire lacI gene was annealed with a series of synthetic oligonucleotides complementary to the N-terminal region of the lacI gene. Each primer-template was incubated with E. coli DNA polymerase I (Klenow fragment) under conditions favoring misincorporation, wherein one of the 4 dNTPs was lacking ('minus' reaction) or present at very low concentration ('micro' reaction). The extent of elongation of each primer was assessed by gel electrophoresis, and lacI mutants arising during the misincorporation reactions were detected by a transfection assay in which i- base substitutions within the in vitro synthesized strand were selectively recovered by the use of uracil-containing templates. Direct dideoxy sequencing of the '-A' reaction products and sequence analysis of i- mutant progeny revealed a vast predominance of single and non-tandem multiple base transitions. The addition of small quantities of dATP to a '-A' reaction increased the mutation yield and broadened the distribution of base substitutions along the template. We detected a general bias towards increased base substitution at template positions flanked by G.C base pairs or 5'-pyrimidine, 3'-purine nearest neighbors, although considerable site-to-site variation in the occurrence of base substitutions was seen, even within identical nearest neighbor contexts.

Genetic assay of misincorporation

A system to characterize mutations arising from in vitro nucleotide misincorporation, which avoids the effects of in vivo mismatch repair on recovery of mutants, was constructed and evaluated. The lacI gene of Escherichia coli was inserted into phage M13 and the M13-lacI recombinant was introduced into a strain of E. coli lacking a resident lacI gene. In this system the function of the M13-bearing lacI gene can be detected by plaque color. Mutants in the 5'-region of the lacI gene (encoding operator-binding domain) are seen as blue plaques when the host strain is grown in the presence of chromogenic substrate, X-gal, in the absence of inducer. The use of uracil-containing single stranded DNA from M13-lacI as template for DNA synthesis avoids the contribution of mismatch repair (in transfection recipients) on the recovery of mutants. To demonstrate the usefulness of the M13-lacI system we produced nucleotide misincorporations by in vitro DNA synthesis in the N-terminal region of the lacI template in the presence of only 3 deoxynucleoside triphosphates (dNTPs). Such mutagenic reactions were conducted in the absence of dATP with 4 different primers and in the absence of dGTP with 2 primers. The type of mutants produced by these reactions were identified through sequencing of DNA from progeny phage after screening for i- (blue plaque) phenotype. Mutations recovered in this system consisted of single and multiple base substitutions in the region of the template near the 3'-terminus of the primer. Nearly all of the mutants induced by '-A' conditions were T----C base substitutions, and those induced by '-G' conditions were C----T transitions. In general, the results were consistent with the spectrum of spontaneous mutants produced in strains deficient in mismatch repair, although some differences were noted. Several new base substitutions within the lacI gene (producing i- phenotype and unobserved by others) were isolated by the procedures described in this paper.

The spectrum of spontaneous mutations in a Saccharomyces cerevisiae uracil-DNA-glycosylase mutant limits the function of this enzyme to cytosine deamination repair

Uracil-DNA-glycosylase has been proposed to function as the first enzyme in strand-directed mismatch repair in eukaryotic organisms, through removal of uracil from dUMP residues periodically inserted into the DNA during DNA replication (Aprelikova, O. N., V. M. Golubovskaya, T. A. Kusmin, and N. V. Tomilin, Mutat. Res. 213:135-140, 1989). This hypothesis was investigated with Saccharomyces cerevisiae. Mutation frequencies and spectra were determined for an ung1 deletion strain in the target SUP4-o tRNA gene by using a forward selection scheme. Mutation frequencies in the SUP4-o gene increased about 20-fold relative to an isogenic wild-type S. cerevisiae strain, and the mutator effect was completely suppressed in the ung1 deletion strain carrying the wild-type UNG1 gene on a multicopy plasmid. Sixty-nine independently derived mutations in the SUP4-o gene were sequenced. All but five of these were due to GC----AT transitions. From this analysis, we conclude that the mutator phenotype of the ung1 deletion strain is the result of a failure to repair spontaneous cytosine deamination events occurring frequently in S. cerevisiae and that the UNG1 gene is not required for strand-specific mismatch repair in S. cerevisiae.

Strand-specific nucleotide composition bias in echinoderm and vertebrate mitochondrial genomes

The gene organization of starfish mitochondrial DNA is identical with that of the sea urchin counterpart except for a reported inversion of an approximately 4.6-kb segment containing two structural genes for NADH dehydrogenase subunits 1 and 2 (ND 1 and ND 2). When the codon usage of each structural gene in starfish, sea urchin, and vertebrate mitochondrial DNAs is examined, it is striking that codons ending in T and G are preferentially used more for heavy strand-encoded genes, including starfish ND 1 and ND 2, than for light strand-encoded genes, including sea urchin ND 1 and ND 2. On the contrary, codons ending in A and C are preferentially used for the light strand-encoded genes rather than for the heavy strand-encoded ones. Moreover, G-U base pairs are more frequently found in the possible secondary structures of heavy strand-encoded tRNAs than in those of light strand-encoded tRNAs. These observations suggest the existence of a certain constraint operating on mitochondrial genomes from various animal phyla, which results in the accumulation of G and T on one strand, and A and C on the other.

Effect of activators and inhibitors on the activity of mitochondrial DNA polymerase

At a concentration of 0.5 to 3 mmol/l, ATP stimulates the activity of mitochondrial DNA polymerase of Neurospora crassa under the optimum reaction conditions; at higher concentrations, an inhibitory effect is observed. 4-Chloromercuribenzoate (1 mmol/L), a thiol inhibitor, decreases the enzyme activity two-fold, while N-ethylmalcimide (2 mmol/L) has no effect. Ethidium bromide (up to 10 mumol/L) and heparin (up to 0.4 micrograms/mL) reduce the activity by 60%. ddTTP does not affect the DNA polymerase reaction. The best in vitro template is the activated calf-thymus DNA.

DNA polymerase alpha from HeLa cells synthesizes DNA with high fidelity in a reconstituted replication system

To determine the contribution that DNA polymerase alpha makes to the overall DNA replication fidelity in mammalian systems, we measured the fidelity of replication of the SV40-based shuttle vector, pZ189, in a reconstituted in vitro DNA replication system which contained purified HeLa DNA polymerase alpha (in addition to single-stranded DNA binding protein, topoisomerase II, DNA ligase, 5'----3' exonuclease, ribonuclease H, and SV40 T-antigen). We found that DNA polymerase alpha is highly accurate when carrying out bidirectional replication in this system. This high fidelity of replication by DNA polymerase alpha in the reconstituted replication system contrasts with a relatively low fidelity of gap-filling DNA synthesis on the same target gene by purified HeLa cell DNA polymerase alpha in the absence of other replication factors. The fidelity of DNA replication by DNA polymerase alpha, although relatively high in the reconstituted system, is about 4-fold lower than DNA replication in a crude HeLa cell extract which contains additional replication factors including DNA polymerase delta. These results demonstrate that DNA polymerase alpha has the capacity to replicate DNA with high fidelity when carrying out semiconservative DNA replication in a minimal reconstituted replication system, but additional cellular factors not present in the reconstituted system may contribute to the higher replication fidelity of the crude system.

Fidelity of animal cell DNA polymerases alpha and delta and of a human DNA replication complex

We are investigating the mechanisms by which mutations are produced or avoided during DNA synthesis. Using in vitro fidelity assays, we have defined the error frequency and mutational specificity of the replicative animal cell DNA polymerases (alpha and delta). With DNA polymerase alpha or the four-subunit DNA polymerase alpha-DNA primase complex, neither of which contains detectable associated exonuclease activity, the fidelity of the polymerization step is low relative to spontaneous mutation rates in vivo. DNA polymerase delta is much more accurate, partly due to proofreading by the 3'----5' exonuclease activity associated with this polymerase. These fidelity studies have been extended to the replication apparatus present in extracts of human HeLa cells. The replication complex is highly accurate, suggesting that additional fidelity components are operating in the extract during bidirectional, semiconservative replication of double-stranded DNA. Nevertheless, in highly sensitive reversion assays, base substitution errors can be readily detected at frequencies greater than the estimated rate of spontaneous mutation in vivo. This suggests that fidelity components may be missing and/or that human cells depend heavily on postreplicative repair processes to correct replication errors.

Polymerase-specific differences in the DNA intermediates of frameshift mutagenesis. In vitro synthesis errors of Escherichia coli DNA polymerase I and its large fragment derivative

The sequences of more than 600 frameshift mutations produced as a consequence of in vitro DNA replication on an oligonucleotide-primed, single-stranded DNA template by the Escherichia coli polymerase I enzyme (PolI) or its large fragment derivative (PolLF) were compared. Four categories of mutants were found: (1) single-base deletions, (2) base substitutions, (3) multiple-base deletions and (4) complex frameshift mutations that change both the base sequence and the number of bases in a concerted mutational process. The template sequence 5'-Py-T-G-3', previously identified as a PolLF hotspot for single-base deletions opposite G, is also a hotspot for PolI. A PolI-specific warm spot for single-base deletions was identified. Among base substitutions, transitions were more frequent than transversions. Transversions were mediated by (template)G.G, (template)G.A, and (template)C.T mispairs. Multiple-base deletions were found only after PolI replication. Although each of these deletions can be explained by a misalignment mediated by directly repeated DNA sequences, deletion frequencies were often different for repeats of the same length. Both PolI and PolLF produced many complex frameshift mutants. The new sequences at the mutant sites are exactly complementary to nearby DNA sequences in the newly synthesized DNA strand. In each case, palindromic complementarity could mediate the misalignment needed to initiate the mutational process. The misaligned DNA synthesis accounts for the nucleotide changes at the mutant site and for homology that could direct realignment of the DNA onto the template. Most of the complex mutant sequences could be initiated by either intramolecular misalignments involving fold-back structures in newly synthesized DNA or by strand-switching during strand-displacement synthesis. The striking differences between the specificities of complex frameshift mutations and multiple-base deletions by PolI and PolLF identify the existence of polymerase-specific determinants that influence the frequency and specificity of misalignment-mediated frameshifts and deletions.