Exonucleolytic proofreading enhances the fidelity of DNA synthesis by chick embryo DNA polymerase-gamma

Structural basis for DNA proofreading

DNA polymerase (DNAP) can correct errors in DNA during replication by proofreading, a process critical for cell viability. However, the mechanism by which an erroneously incorporated base translocates from the polymerase to the exonuclease site and the corrected DNA terminus returns has remained elusive. Here, we present an ensemble of nine high-resolution structures representing human mitochondrial DNA polymerase Gamma, Polγ, captured during consecutive proofreading steps. The structures reveal key events, including mismatched base recognition, its dissociation from the polymerase site, forward translocation of DNAP, alterations in DNA trajectory, repositioning and refolding of elements for primer separation, DNAP backtracking, and displacement of the mismatched base into the exonuclease site. Altogether, our findings suggest a conserved 'bolt-action' mechanism of proofreading based on iterative cycles of DNAP translocation without dissociation from the DNA, facilitating primer transfer between catalytic sites. Functional assays and mutagenesis corroborate this mechanism, connecting pathogenic mutations to crucial structural elements in proofreading steps.

Saccharomyces cerevisiae as a Tool for Studying Mutations in Nuclear Genes Involved in Diseases Caused by Mitochondrial DNA Instability

Mitochondrial DNA (mtDNA) maintenance is critical for oxidative phosphorylation (OXPHOS) since some subunits of the respiratory chain complexes are mitochondrially encoded. Pathological mutations in nuclear genes involved in the mtDNA metabolism may result in a quantitative decrease in mtDNA levels, referred to as mtDNA depletion, or in qualitative defects in mtDNA, especially in multiple deletions. Since, in the last decade, most of the novel mutations have been identified through whole-exome sequencing, it is crucial to confirm the pathogenicity by functional analysis in the appropriate model systems. Among these, the yeast Saccharomyces cerevisiae has proved to be a good model for studying mutations associated with mtDNA instability. This review focuses on the use of yeast for evaluating the pathogenicity of mutations in six genes, MPV17/SYM1, MRM2/MRM2, OPA1/MGM1, POLG/MIP1, RRM2B/RNR2, and SLC25A4/AAC2, all associated with mtDNA depletion or multiple deletions. We highlight the techniques used to construct a specific model and to measure the mtDNA instability as well as the main results obtained. We then report the contribution that yeast has given in understanding the pathogenic mechanisms of the mutant variants, in finding the genetic suppressors of the mitochondrial defects and in the discovery of molecules able to improve the mtDNA stability.

Dinucleotide Degradation by REXO2 Maintains Promoter Specificity in Mammalian Mitochondria

Oligoribonucleases are conserved enzymes that degrade short RNA molecules of up to 5 nt in length and are assumed to constitute the final stage of RNA turnover. Here we demonstrate that REXO2 is a specialized dinucleotide-degrading enzyme that shows no preference between RNA and DNA dinucleotide substrates. A heart- and skeletal-muscle-specific knockout mouse displays elevated dinucleotide levels and alterations in gene expression patterns indicative of aberrant dinucleotide-primed transcription initiation. We find that dinucleotides act as potent stimulators of mitochondrial transcription initiation in vitro. Our data demonstrate that increased levels of dinucleotides can be used to initiate transcription, leading to an increase in transcription levels from both mitochondrial promoters and other, nonspecific sequence elements in mitochondrial DNA. Efficient RNA turnover by REXO2 is thus required to maintain promoter specificity and proper regulation of transcription in mammalian mitochondria.

Single-sperm sequencing reveals the accelerated mitochondrial mutation rate in male Daphnia pulex (Crustacea, Cladocera)

Mutation rate in the nuclear genome differs between sexes, with males contributing more mutations than females to their offspring. The male-biased mutation rates in the nuclear genome is most likely to be driven by a higher number of cell divisions in spermatogenesis than in oogenesis, generating more opportunities for DNA replication errors. However, it remains unknown whether male-biased mutation rates are present in mitochondrial DNA (mtDNA). Although mtDNA is maternally inherited and male mtDNA mutation typically does not contribute to genetic variation in offspring, male mtDNA mutations are critical for male reproductive health. In this study, we measured male mtDNA mutation rate using publicly available whole-genome sequences of single sperm of the freshwater microcrustacean Daphnia pulex Using a stringent mutation detection pipeline, we found that the male mtDNA mutation rate is 3.32 × 10^-6 per site per generation. All the detected mutations are heteroplasmic base substitutions, with 57% of mutations converting G/C to A/T nucleotides. Consistent with the male-biased mutation in the nuclear genome, the male mtDNA mutation rate in D. pulex is approximately 20 times higher than the female rate per generation. We propose that the elevated mutation rate per generation in male mtDNA is consistent with an increased number of cell divisions during male gametogenesis.

Origins of mtDNA mutations in ageing

MtDNA mutations are one of the hallmarks of ageing and age-related diseases. It is well established that somatic point mutations accumulate in mtDNA of multiple organs and tissues with increasing age and heteroplasmy is universal in mammals. However, the origin of these mutations remains controversial. The long-lasting hypothesis stating that mtDNA mutations emanate from oxidative damage via a self-perpetuating mechanism has been extensively challenged in recent years. Contrary to this initial ascertainment, mtDNA appears to be well protected from action of reactive oxygen species (ROS) through robust protein coating and endomitochondrial microcompartmentalization. Extensive development of scrupulous high-throughput DNA sequencing methods suggests that an imperfect replication process, rather than oxidative lesions are the main sources of mtDNA point mutations, indicating that mtDNA polymerase γ (POLG) might be responsible for the majority of mtDNA mutagenic events. Here, we summarize the recent knowledge in prevention and defence of mtDNA oxidative lesions and discuss the plausible mechanisms of mtDNA point mutation generation and fixation.

p53 in the mitochondria, as a trans-acting protein, provides error-correction activities during the incorporation of non-canonical dUTP into DNA

Mutations in mitochondrial DNA is an outcome of errors produced by DNA polymerase γ during replication and failure of the repair mechanism. Misincorporation of non-canonical dUTP leads to mutagenesis or apoptosis, and may contribute to the cytotoxic effects of 5'-fluorouracil chemotherapy. Tumor suppressor p53 protein in the mitochondria displays physical and functional interactions with mitochondrial DNA and polymerase γ, and by its intrinsic 3'→5' exonuclease activity can diminish the polymerization errors. Here we demonstrate the impact of p53 on incorporation of uracil into DNA examined with mitochondrial fractions, as the source of polymerase γ. p53 in mitochondria facilitates DNA damage repair functions resulting from uracil-DNA misincorporation. Our biochemical studies revealed that the procession of U:A and mismatched U:G lesions enhances in the presence of recombinant or endogenous cytoplasmic p53. p53 in mitochondria can function as an exonuclease/proofreader for polymerase γ by either decreasing the incorporation of non-canonical dUTP into DNA or by promoting the excision of incorporated nucleotide from nascent DNA, thus expanding the spectrum of DNA damage sites exploited for proofreading as a trans-acting protein. The data suggest that p53 may contribute to defense of the cells from consequences of dUTP misincorporation in both normal and tumor cells.

Different Divalent Cations Alter the Kinetics and Fidelity of DNA Polymerases

Divalent metal ions are essential components of DNA polymerases both for catalysis of the nucleotidyl transfer reaction and for base excision. They occupy two sites, A and B, for DNA synthesis. Recently, a third metal ion was shown to be essential for phosphoryl transfer reaction. The metal ion in the A site is coordinated by the carboxylate of two highly conserved acidic residues, water molecules, and the 3'-hydroxyl group of the primer so that the A metal is in an octahedral complex. Its catalytic function is to lower the pK_a of the hydroxyl group, making it a highly effective nucleophile that can attack the α phosphorous atom of the incoming dNTP. The metal ion in the B site is coordinated by the same two carboxylates that are affixed to the A metal ion as well as the non-bridging oxygen atoms of the incoming dNTP. The carboxyl oxygen of an adjacent peptide bond serves as the sixth ligand that completes the octahedral coordination geometry of the B metal ion. Similarly, two metal ions are required for proofreading; one helps to lower the pK_a of the attacking water molecule, and the other helps to stabilize the transition state for nucleotide excision. The role of different divalent cations are discussed in relation to these two activities as well as their influence on base selectivity and misincorporation by DNA polymerases. Some, but not all, of the effects of these different metal ions can be rationalized based on their intrinsic properties, which are tabulated in this review.

Validation of Next-Generation Sequencing of Entire Mitochondrial Genomes and the Diversity of Mitochondrial DNA Mutations in Oral Squamous Cell Carcinoma

BACKGROUND

Oral squamous cell carcinoma (OSCC) is mainly caused by smoking and alcohol abuse and shows a five-year survival rate of ~50%. We aimed to explore the variation of somatic mitochondrial DNA (mtDNA) mutations in primary oral tumors, recurrences and metastases.

METHODS

We performed an in-depth validation of mtDNA next-generation sequencing (NGS) on an Illumina HiSeq 2500 platform for its application to cancer tissues, with the goal to detect low-level heteroplasmies and to avoid artifacts. Therefore we genotyped the mitochondrial genome (16.6 kb) from 85 tissue samples (tumors, recurrences, resection edges, metastases and blood) collected from 28 prospectively recruited OSCC patients applying both Sanger sequencing and high-coverage NGS (~35,000 reads per base).

RESULTS

We observed a strong correlation between Sanger sequencing and NGS in estimating the mixture ratio of heteroplasmies (r = 0.99; p<0.001). Non-synonymous heteroplasmic variants were enriched among cancerous tissues. The proportions of somatic and inherited variants in a given gene region were strongly correlated (r = 0.85; p<0.001). Half of the patients shared mutations between benign and cancerous tissue samples. Low level heteroplasmies (<10%) were more frequent in benign samples compared to tumor samples, where heteroplasmies >10% were predominant. Four out of six patients who developed a local tumor recurrence showed mutations in the recurrence that had also been observed in the primary tumor. Three out of five patients, who had tumor metastases in the lymph nodes of their necks, shared mtDNA mutations between primary tumors and lymph node metastases. The percentage of mutation heteroplasmy increased from the primary tumor to lymph node metastases.

CONCLUSIONS

We conclude that Sanger sequencing is valid for heteroplasmy quantification for heteroplasmies ≥10% and that NGS is capable of reliably detecting and quantifying heteroplasmies down to the 1%-level. The finding of shared mutations between primary tumors, recurrences and metastasis indicates a clonal origin of malignant cells in oral cancer.

Kinetic analysis of the unique error signature of human DNA polymerase ν

The fidelity of DNA synthesis by A-family DNA polymerases ranges from very accurate for bacterial, bacteriophage, and mitochondrial family members to very low for certain eukaryotic homologues. The latter include DNA polymerase ν (Pol ν) which, among all A-family polymerases, is uniquely prone to misincorporating dTTP opposite template G in a highly sequence-dependent manner. Here we present a kinetic analysis of this unusual error specificity, in four different sequence contexts and in comparison to Pol ν's more accurate A-family homologue, the Klenow fragment of Escherichia coli DNA polymerase I. The kinetic data strongly correlate with rates of stable misincorporation during gap-filling DNA synthesis. The lower fidelity of Pol ν compared to that of Klenow fragment can be attributed primarily to a much lower catalytic efficiency for correct dNTP incorporation, whereas both enzymes have similar kinetic parameters for G-dTTP misinsertion. The major contributor to sequence-dependent differences in Pol ν error rates is the reaction rate, k(pol). In the sequence context where fidelity is highest, k(pol) for correct G-dCTP incorporation by Pol ν is ~15-fold faster than k(pol) for G-dTTP misinsertion. However, in sequence contexts where the error rate is higher, k(pol) is the same for both correct and mismatched dNTPs, implying that the transition state does not provide additional discrimination against misinsertion. The results suggest that Pol ν may be fine-tuned to function when high enzyme activity is not a priority and may even be disadvantageous and that the relaxed active-site specificity toward the G-dTTP mispair may be associated with its cellular function(s).

Animal models of mitochondrial DNA transactions in disease and ageing

Mitochondrial DNA (mtDNA) transactions, processes that include mtDNA replication, repair, recombination and transcription constitute the initial stages of mitochondrial biogenesis, and are at the core of understanding mitochondrial biology and medicine. All of the protein players are encoded in nuclear genes: some are proteins with well-known functions in the nucleus, others are well-known mitochondrial proteins now ascribed new functions, and still others are newly discovered factors. In this article we review recent advances in the field of mtDNA transactions with a special focus on physiological studies. In particular, we consider the expression of variant proteins, or altered expression of factors involved in these processes in powerful model organisms, such as Drosophila melanogaster and the mouse, which have promoted recognition of the broad relevance of oxidative phosphorylation defects resulting from improper maintenance of mtDNA. Furthermore, the animal models recapitulate many phenotypes related to human ageing and a variety of different diseases, a feature that has enhanced our understanding of, and inspired theories about, the molecular mechanisms of such biological processes.

Long sequence duplications, repeats, and palindromes in HIV-1 gp120: length variation in V4 as the product of misalignment mechanism

We have shown that indels in gp120 V4 are associated to the presence of duplicated and palindromic sequences, suggesting that they may be produced by strand-slippage misalignment mechanism. Indels in V4 involved region-specific duplications 9 to 15 bp long, and repeats of various lengths, associated to trinucleotides AAT. No duplications were found in V3 and C3. The frequency of palindromic sequences in individual genes was found to be significantly higher in gp120 (p < or = 3.00E-7), and significantly lower in Tat (p < or = 9.00E-7) than the average frequency calculated over the full genome. The finding of elements of misalignment in association with indels in V4 suggests that these mutations may occur in proviral DNA after integration of HIV into the host genome. It also implies that occurrence of large indels in gp120 is not random but is directed by the presence and distribution of elements of misalignment in the HIV genome.

A mechanistic view of human mitochondrial DNA polymerase gamma: providing insight into drug toxicity and mitochondrial disease

Mitochondrial DNA polymerase gamma (Pol gamma) is the sole polymerase responsible for replication of the mitochondrial genome. The study of human Pol gamma is of key importance to clinically relevant issues such as nucleoside analog toxicity and mitochondrial disorders such as progressive external ophthalmoplegia. The development of a recombinant form of the human Pol gamma holoenzyme provided an essential tool in understanding the mechanism of these clinically relevant phenomena using kinetic methodologies. This review will provide a brief history on the discovery and characterization of human mitochondrial DNA polymerase gamma, focusing on kinetic analyses of the polymerase and mechanistic data illustrating structure-function relationships to explain drug toxicity and mitochondrial disease.

Excision of nucleoside analogs in mitochondria by p53 protein

OBJECTIVE

Nucleoside analogs, used against HIV, can be incorporated into a mitochondrial DNA by DNA polymerase gamma. Both the decrease in mitochondrial DNA and increased mutations of mitochondrial DNA may lead to mitochondrial diseases. The tumor suppressor protein p53 exhibits 3' --> 5' exonuclease activity and can provide a proofreading function for DNA polymerases. In the present study, we investigated the ability of p53 to excise incorporated nucleoside analogs from DNA in mitochondria.

DESIGN

The functional interaction of p53 and DNA polymerase gamma during the incorporation of nucleoside analog was examined in mitochondrial fractions of p53-null H1299 cells, as the source of DNA polymerase gamma.

METHODS

Primer extension reactions were carried out to elucidate the incorporation and removal of nucleoside analogs.

RESULTS

The results demonstrate that the excision of incorporated nucleoside analogs in mitochondrial fractions of H1299 cells increased in the presence of purified recombinant p53, or cytoplasmic extracts of large cell carcinoma 2 cells expressing endogenous wild-type p53 (but not specifically predepleted extracts) or cytoplasmic extracts of H1299 cells overexpressing wild-type p53, but not exonuclease-deficient mutant p53-R175H. The amount of nucleoside analogs incorporated into the elongated DNA with mitochondrial fractions of human colon carcinoma 116 (HCT116)(p53+/+) cells was lower than that of HCT116(p53-/-) cells. Furthermore, mitochondrion-localized elevation of p53 in HCT116(p53+/+) cells, following the irradiation-stress stimuli, correlates with the reduction in incorporation of nucleoside analogs and wrong nucleotides.

CONCLUSION

p53 in mitochondria may functionally interact with DNA polymerase gamma, thus providing a proofreading function during mitochondrial DNA replication for excision of nucleoside analogs and polymerization errors.

Number matters: control of mammalian mitochondrial DNA copy number

Regulation of mitochondrial biogenesis is essential for proper cellular functioning. Mitochondrial DNA (mtDNA) depletion and the resulting mitochondrial malfunction have been implicated in cancer, neurodegeneration, diabetes, aging, and many other human diseases. Although it is known that the dynamics of the mammalian mitochondrial genome are not linked with that of the nuclear genome, very little is known about the mechanism of mtDNA propagation. Nevertheless, our understanding of the mode of mtDNA replication has advanced in recent years, though not without some controversies. This review summarizes our current knowledge of mtDNA copy number control in mammalian cells, while focusing on both mtDNA replication and turnover. Although mtDNA copy number is seemingly in excess, we reason that mtDNA copy number control is an important aspect of mitochondrial genetics and biogenesis and is essential for normal cellular function.

Molecular detection of Mycoplasma haemofelis and 'Candidatus Mycoplasma haemominutum' Infection in cats by direct PCR using whole blood without DNA extraction

Detection of hemotropic Mycoplasma spp. infection was attempted in cats by PCR using whole blood without DNA extraction. A total 46 of 54 (85%) cats with suspected Mycoplasma spp. infection showed a positive reaction, corresponding completely with the results of standard PCR testing. The direct PCR assay was sensitive enough to detect more than 0.0061% parasitemia for ;C. M. haemominutum' and 0.0075% parasitemia for M. haemofelis. These data indicate that the direct PCR assay might be sufficient for use as a tool in clinical examinations.

p53 in mitochondria enhances the accuracy of DNA synthesis

Mitochondrial localization of p53 was observed in stressed and unstressed cells. p53 is involved in DNA repair and apoptosis. It exerts physical and functional interactions with mitochondrial DNA and DNA polymerase gamma (pol gamma). The functional cooperation of p53 and pol gamma during DNA synthesis was examined in the mitochondrial fraction of p53-null H1299 cells, as the source of pol gamma. The results show that p53 may affect the accuracy of DNA synthesis in mitochondria: (1) the excision of a misincorporated nucleotide increases in the presence of (a) recombinant wild-type p53 (wtp53); (b) cytoplasmic fraction of LCC2 cells expressing endogenous wtp53 (but not specifically pre-depleted fraction); (c) cytoplasmic extract of H1299 cells overexpressing wtp53, but not exonuclease-deficient mutant p53-R175H. (2) Mitochondrial extracts of HCT116(p53+/+) cells display higher exonuclease activity compared with that of HCT116(p53-/-) cells. Addition of exogenous p53 complements the HCT116(p53-/-) mitochondrial extract mispair excision. Furthermore, the misincorporation was lower in the mitochondrial fraction of HCT116(p53+/+) cells as compared with that of HCT116(p53-/-) cells. (3) Irradiation-induced mitochondrial translocation of endogenous p53 in HCT116(p53+/+) cells correlates with the enhancement of error-correction activities. Taken together, the data suggest that p53 in mitochondria may be a component of an error-repair pathway and serve as guardian of the mitochondrial genome. The function of p53 in DNA repair and apoptosis is discussed.

Enhanced discrimination of single nucleotide polymorphism in genotyping by phosphorothioate proofreading allele-specific amplification

There is a significant demand for sensitive, inexpensive, and flexible genotyping techniques that can be accomplished with reasonable throughput. Allele-specific amplification (ASA) has the advantage of combining the amplification and discrimination steps into a single reaction. However, mismatch amplification that occurs during traditional ASA limits its application for genotyping. Here, a modified ASA termed phosphorothioate proofreading allele-specific amplification (PP-ASA) is developed, for single nucleotide polymorphism (SNP) genotyping analysis. Using both 3' end phosphorothioate modification of primers and DNA polymerase with proofreading activity completely eliminated mismatch amplifications, therefore enhancing discrimination between alleles for genotyping. The conditions for PP-ASA were optimized for template concentration and amplification cycle number as both were found to be critical for accurate genotyping. The utility of PP-ASA was assessed using both plasmid and genomic DNAs as templates and validated by polymerase chain reaction (PCR)-restriction fragment length polymorphism analysis of 60 human DNA samples for two distinct SNPs. PP-ASA represents a reliable, flexible, and inexpensive assay for SNP genotyping; it could be integrated to chip- or PCR-array-based assays to improve the throughput and reduce the cost for SNP analyses.

A dideoxynucleotide-sensitive DNA polymerase activity characterized from endoreduplicating cells of mungbean (Vigna radiata L.) during ontogeny of cotyledons

Within this work we describe the purification and biochemical characterization of a ddNTP-sensitive DNA polymerase purified from mungbean (Vigna radiata cv B1, L.) seeds at 18 days after fertilization, when > 70% of the nuclei are reported to be in the endoreduplicated state. The purified enzyme is a single polypeptide of 62 kDa and many of its physicochemical properties are similar to those of mammalian DNA polymerase beta. Similar to the other X-family DNA polymerases, it lacks 3'-5' exonuclease activity and has short gap-filling and strand-displacement activity. The enzyme shows moderately processive DNA synthesis on a single-strand template. The determined N-terminal heptapeptide sequence of the enzyme showed clear homology with helix 1 of the N-terminal single strand DNA-binding domain (residues 32-41) of rat and human DNA polymerase beta. These results represent the first evidence for the identification and characterization of a ddNTP-sensitive DNA polymerase expressed during the endoreduplication cycle that shares biochemical and immunological similarity with mammalian DNA polymerase beta.

Mitochondrial DNA polymerase-gamma and human disease

The maintenance of mitochondrial DNA (mtDNA) is critically dependent upon polymerase-gamma (pol-gamma), encoded by the nuclear gene POLG. Over the last 5 years, it has become clear that mutations of POLG are a major cause of human disease. Secondary mtDNA defects characterize these disorders, with mtDNA depletion, multiple mtDNA deletions or multiple point mutations of mtDNA in clinically affected tissues. The secondary mtDNA defects cause cell and tissue-specific deficiencies of mitochondrial oxidative phosphorylation, leading to organ dysfunction and human disease. Functional genetic variants of POLG are present in up to approximately 0.5% of the general population, and pathogenic mutations have been described in most exons of the gene. Clinically, POLG mutations can present from early neonatal life to late middle age, with a spectrum of phenotypes that includes common neurological disorders such as migraine, epilepsy and Parkinsonism. Transgenic mice and biochemical studies of recombinant mutated proteins are helping to unravel mechanisms of pathogenesis, and patterns are beginning to emerge relating genotype to phenotype.

Fidelity of the human mitochondrial DNA polymerase

We have quantified the fidelity of polymerization of DNA by human mitochondrial DNA polymerase using synthetic DNA oligonucleotides and recombinant holoenzyme and examining each of the possible 16-base pair combinations. Although the kinetics of incorporation for all correct nucleotides are similar, with an average Kd of 0.8 microM and an average k(pol) of 37 s(-1), the kinetics of misincorporation vary widely. The ground state binding Kd of incorrect bases ranges from a low of 25 microM for a dATP:A mispair to a high of 360 microM for a dCTP:T mispair. Similarly, the rates of incorporation of incorrect bases vary from 0.0031 s(-1) for a dCTP:C mispair to 1.16 s(-1) for a dGTP:T mispair. Due to the variability in the kinetic parameters for misincorporation, the estimates of fidelity range from 1 error in 3563 nucleotides for dGTP:T to 1 error in 2.3 x 10(6) nucleotides for dCTP:C. Interestingly, the discrimination against a dGTP:T mismatch is 16.5 times lower than that of a dTTP:G mismatch due to a tighter Kd for ground state binding and a faster rate of incorporation of the dGTP:T mismatch relative to the dTTP:G mismatch. We calculate an average fidelity of 1 error in 440,000 nucleotides.

Antiretroviral nucleosides, deoxynucleotide carrier and mitochondrial DNA: evidence supporting the DNA pol gamma hypothesis

DESIGN

Nucleoside reverse transcriptase inhibitors (NRTIs) exhibit mitochondrial toxicity. The mitochondrial deoxynucleotide carrier (DNC) transports nucleotide precursors (or phosphorylated NRTIs) into mitochondria for mitochondrial (mt)DNA replication or inhibition of mtDNA replication by NRTIs. Transgenic mice (TG) expressing human DNC targeted to murine myocardium served to define mitochondrial events from NRTIs in vivo and findings were corroborated by biochemical events in vitro.

METHODS

Zidovudine (3'-azido-2',3'-deoxythymidine; ZDV), stavudine (2', 3'-didehydro-2', 3'-deoxythymidine; d4T), or lamivudine ((-)-2'-deoxy-3'-thiacytidine; 3TC) were administered individually to TGs and wild-type (WT) littermates (35 days) at human doses with drug-free vehicle as control. Left ventricle (LV) mass was defined echocardiographically, mitochondrial ultrastructural defects were identified by electron microscopy, the abundance of cardiac mtDNA was quantified by real time polymerase chain reaction, and mtDNA-encoded polypeptides were quantified.

RESULTS

Untreated TGs exhibited normal LV mass with minor mitochondrial damage. NRTI monotherapy (either d4T or ZDV) increased LV mass in TGs and caused significant mitochondrial destruction. Cardiac mtDNA was depleted in ZDV and d4T-treated TG hearts and mtDNA-encoded polypeptides decreased. Changes were absent in 3TC-treated cohorts. In supportive structural observations from molecular modeling, ZDV demonstrated close contacts with K947 and Y951 in the DNA pol gamma active site that were absent in the HIV reverse transcriptase active site.

CONCLUSIONS

NRTIs deplete mtDNA and polypeptides, cause mitochondrial structural and functional defects in vivo, follow inhibition kinetics with DNA pol gamma in vitro, and are corroborated by molecular models. Disrupted pools of nucleotide precursors and inhibition of DNA pol gamma by specific NRTIs are mechanistically important in mitochondrial toxicity.

Structural analysis of strand misalignment during DNA synthesis by a human DNA polymerase

Insertions and deletions in coding sequences can alter the reading frame of genes and have profound biological consequences. In 1966, Streisinger proposed that these mutations result from strand slippage, which in repetitive sequences generates misaligned intermediates stabilized by correct base pairing that support polymerization. We report here crystal structures of human DNA polymerase lambda, which frequently generates deletion mutations, bound to such intermediates. Each contains an extrahelical template nucleotide upstream of the active site. Surprisingly, the extra nucleotide, even when combined with an adjacent mismatch, does not perturb polymerase active site geometry, which is indistinguishable from that for correctly aligned strands. These structures reveal how pol lambda can polymerize on substrates with minimal homology during repair of double-strand breaks and represent strand-slippage intermediates consistent with Streisinger's classical hypothesis. They are thus relevant to the origin of single-base deletions, a class of mutations that can confer strong biological phenotypes.

DNA precursor asymmetries in mammalian tissue mitochondria and possible contribution to mutagenesis through reduced replication fidelity

The mutation rate of the mammalian mitochondrial genome is higher than that of the nuclear genome. Because mitochondrial and nuclear deoxyribonucleoside triphosphate (dNTP) pools are physically distinct and because dNTP concentrations influence replication fidelity, we asked whether mitochondrial dNTP pools are asymmetric with respect to each other. We report here that the concentrations of the four dNTPs are not equal in mitochondria isolated from several tissues of both young and old rats. In particular, in most tissues examined, mitochondrial dGTP concentrations are high relative to the other dNTPs. Moreover, in the presence of the biased dNTP concentrations measured in heart and skeletal muscle, the fidelity of DNA synthesis in vitro by normally highly accurate mtDNA polymerase gamma is reduced, with error frequencies increased by as much as 3-fold, due to increased formation of template T.dGTP mismatches that are inefficiently corrected by proofreading. These data, plus some published data on specific mitochondrial mutations seen in human diseases, are consistent with the hypothesis that normal intramitochondrial dNTP pool asymmetries may contribute to spontaneous mutagenesis in the mammalian mitochondrial genome.

DNA polymerase gamma, the mitochondrial replicase

DNA polymerase (pol) gamma is the sole DNA polymerase in animal mitochondria. Biochemical and genetic evidence document a key role for pol gamma in mitochondrial DNA replication, and whereas DNA repair and recombination were thought to be limited or absent in animal mitochondria, both have been demonstrated in recent years. Thus, the mitochondrial replicase is also apparently responsible for the relevant DNA synthetic reactions in these processes. Pol gamma comprises a catalytic core in a heterodimeric complex with an accessory subunit. The two-subunit holoenzyme is an efficient and processive polymerase, which exhibits high fidelity in nucleotide selection and incorporation while proofreading errors with its intrinsic 3' 5' exonuclease. Incorporation of nucleotide analogs followed by proofreading failure leads to mitochondrial toxicity in antiviral therapy, and misincorporation during DNA replication leads to mitochondrial mutagenesis and dysfunction. This review describes our current understanding of pol gamma biochemistry and biology, and it introduces other key proteins that function at the mitochondrial DNA replication fork.

Mitochondrial toxicity of NRTI antiviral drugs: an integrated cellular perspective

Highly active antiretroviral therapy (HAART) regimes based on nucleoside reverse transcriptase inhibitors (NRTIs) have revolutionized the treatment of AIDS in recent years. Although HAART can successfully suppress viral replication in the long term, it is not without significant toxicity, which can seriously compromise treatment effectiveness. A major toxicity that has been recognized for more than a decade is NRTI-related mitochondrial toxicity, which manifests as serious side effects such as hepatic failure and lactic acidosis. However, a lack of understanding of the mechanisms underlying mitochondrial toxicity has hampered efforts to develop novel drugs with better side-effect profiles. This review characterizes the pharmacological mechanisms and pathways that are involved in mitochondrial dysfunction caused by NRTIs, and suggests opportunities for future pharmacological research.

Structural determinants in human DNA polymerase gamma account for mitochondrial toxicity from nucleoside analogs

Although antiviral nucleoside analog therapy successfully delays progression of HIV infection to AIDS, these drugs cause unwelcome side-effects by inducing mitochondrial toxicity. We and others have demonstrated that the mitochondrial polymerase, DNA polymerase gamma (pol gamma), participates in mitochondrial toxicity by incorporating these chain-terminating antiviral nucleotide analogs into DNA. Here, we explore the role of three highly conserved amino acid residues in the active site of human pol gamma that modulate selection of nucleotide analogs as substrates for incorporation. Sequence alignments, crystal structures and mutagenesis studies of family A DNA polymerases led us to change Tyr951 and Tyr955 in polymerase motif B to Phe and Ala, and Glu895 in polymerase motif A was changed to Ala. The mutant polymerases were tested for their ability to incorporate natural nucleotides and the five antiviral nucleoside analogs currently approved for antiviral therapy: AZT, ddC, D4T, 3TC and carbovir. Steady-state kinetic analysis of the pol gamma derivatives with the normal and antiviral nucleotides demonstrated that Tyr951 is largely responsible for the ability of pol gamma to incorporate dideoxynucleotides and D4T-MP. Mutation of Tyr951 to Phe renders the enzyme resistant to dideoxynucleotides and D4T-TP without compromising the activity of the polymerase. Alteration of Glu895 and Tyr955 to Ala had the largest effect on overall polymerase activity with normal nucleotides, producing dramatic increases in K(m(dNTP)) and large decreases in k(cat). Mutation of Tyr955 in pol gamma causes the degenerative disease progressive external ophthalmoplegia in humans, and we show that this residue partially accounts for the ability of pol gamma to incorporate D4T-MP and carbovir. Alteration of Glu895 to Ala slightly increased discrimination against dideoxynucleotides and D4T-TP. The mechanisms by which pol gamma selects certain nucleotide analogs are discussed.

Mitochondrial DNA replication, nucleoside reverse-transcriptase inhibitors, and AIDS cardiomyopathy

Nucleoside reverse-transcriptase inhibitors (NRTIs) in combination with other antiretrovirals (HAART) are the cornerstones of current AIDS therapy, but extensive use brought mitochondrial side effects to light. Clinical experience, pharmacological, cell, and molecular biological evidence links altered mitochondrial (mt-) DNA replication to the toxicity of NRTIs in many tissues, and conversely, mtDNA replication defects and mtDNA depletion in target tissues are observed. Organ-specific pathological changes or diverse systemic effects result from and are frequently attributed to HAART in which NRTIs are included. The shared features of mtDNA depletion and energy depletion became key observations and related the clinical and in vivo experimental findings to inhibition of mtDNA replication by NRTI triphosphates in vitro. Subsequent to those findings, other observations suggested that mitochondrial energy deprivation is concomitant with or the result of mitochondrial oxidative stress in AIDS (from HIV, for example) or from NRTI therapy itself.

Mitochondrial DNA alterations in cancer

A number of studies have demonstrated the presence of mitochondrial DNA (mtDNA) mutations in cancer cells. In this article, we review mitochondrial genomic aberrations reported in solid tumors of the breast, colon, stomach, liver, kidney, bladder, head/neck, and lung. The tantalizing association of tumors with mtDNA mutations implicates these mutations in the process of carcinogenesis. Alterations in expression of mtDNA transcripts in a variety of cancer types are also reviewed. In solid tumors, elevated expression of mtDNA-genes coding for subunits of the mitochondrial electron respiratory chain may reflect mitochondrial adaptation to perturbations in cellular energy requirements. The role of mtDNA mutations and altered expression of mitochondrial genes in carcinogenesis is discussed. Mitochondrial DNA mutations can initiate a cascade of events leading to a continuous increase in the production of reactive oxygen species (persistent oxidative stress), a condition that probably favors tumor development.

Active site mutation in DNA polymerase gamma associated with progressive external ophthalmoplegia causes error-prone DNA synthesis

Progressive external ophthalmoplegia (PEO) is a heritable mitochondrial disorder characterized by the accumulation of multiple point mutations and large deletions in mtDNA. Autosomal dominant PEO was recently shown to co-segregate with a heterozygous Y955C mutation in the human gene encoding the sole mitochondrial DNA polymerase, DNA polymerase gamma (pol gamma). Since Tyr-955 is a highly conserved residue critical for nucleotide recognition among family A DNA polymerases, we analyzed the effects of the Y955C mutation on the kinetics and fidelity of DNA synthesis by the purified human mutant polymerase in complex with its accessory subunit. The Y955C enzyme retains a wild-type catalytic rate (k(cat)) but suffers a 45-fold decrease in apparent binding affinity for the incoming nucleoside triphosphate (K(m)). The Y955C derivative is 2-fold less accurate for base pair substitutions than wild-type pol gamma despite the action of intrinsic exonucleolytic proofreading. The full mutator effect of the Y955C substitution was revealed by genetic inactivation of the exonuclease, and error rates for certain mismatches were elevated by 10-100-fold. The error-prone DNA synthesis observed for the Y955C pol gamma is consistent with the accumulation of mtDNA mutations in patients with PEO.

The fidelity of human DNA polymerase gamma with and without exonucleolytic proofreading and the p55 accessory subunit

Mutations in human mitochondrial DNA influence aging, induce severe neuromuscular pathologies, cause maternally inherited metabolic diseases, and suppress apoptosis. Since the genetic stability of mitochondrial DNA depends on the accuracy of DNA polymerase gamma (pol gamma), we investigated the fidelity of DNA synthesis by human pol gamma. Comparison of the wild-type 140-kDa catalytic subunit to its exonuclease-deficient derivative indicates pol gamma has high base substitution fidelity that results from high nucleotide selectivity and exonucleolytic proofreading. pol gamma is also relatively accurate for single-base additions and deletions in non-iterated and short repetitive sequences. However, when copying homopolymeric sequences longer than four nucleotides, pol gamma has low frameshift fidelity and also generates base substitutions inferred to result from a primer dislocation mechanism. The ability of pol gamma both to make and to proofread dislocation intermediates is the first such evidence for a family A polymerase. Including the p55 accessory subunit, which confers processivity to the pol gamma catalytic subunit, decreases frameshift and base substitution fidelity. Kinetic analyses indicate that p55 promotes extension of mismatched termini to lower the fidelity. These data suggest that homopolymeric runs in mitochondrial DNA may be particularly prone to frameshift mutation in vivo due to replication errors by pol gamma.

Fidelity of nucleotide incorporation by human mitochondrial DNA polymerase

We have examined the fidelity of polymerization catalyzed by the human mitochondrial DNA polymerase using wild-type and exonuclease-deficient (E200A mutation) forms of recombinant, reconstituted holoenzyme. Each of the four nucleotides bind and incorporate with similar kinetics; the average dissociation constant for ground state binding is 0.8 microm, and the average rate of polymerization is 37 x s(-1), defining a specificity constant kcat/Km = 4.6 x 10(7) x m(-1) x s(-1). Mismatched nucleotides show weaker ground-state nucleotide binding affinities ranging from 57 to 364 microm and slower rates of polymerization ranging from 0.013 to 1.16 x s(-1). The kinetic parameters yield fidelity estimates of 1 error out of 260,000 nucleotides for a T:T mismatch, 3563 for G:T, and 570,000 for C:T. The accessory subunit increases fidelity 14-fold by facilitating both ground-state binding and the incorporation rate of the correct A:T base pair compared with a T:T mismatch. Correctly base-paired DNA dissociates from the polymerase at a rate of 0.02 x s(-1) promoting processive polymerization. Thus, the mitochondrial DNA polymerase catalyzed incorporation with an average processivity of 1850, defined by the ratio of polymerization rate to the dissociation rate (37/0.02) and with an average fidelity of one error in 280,000 base pairs.

Exonuclease proofreading by human mitochondrial DNA polymerase

We have examined the ability of the human mitochondrial DNA polymerase to correct errors in DNA sequence using single turnover kinetic methods. The rate of excision of single-stranded DNA ranged from 0.07 to 0.17 x s(-1), depending on the identity of the 3'-base. Excision of the 3'-terminal base from correctly base paired DNA occurred at a rate of 0.05 x s(-1), indicating that the cost of proofreading is minimal, as defined by the ratio of the k(exo) for correctly base-paired DNA divided by the rate of forward polymerization (0.05/37 = 0.14%). Excision of duplex DNA containing 1-7 mismatches was biphasic, and the rate and amplitude of the fast phase increased with the number of mismatches, reaching a maximum of 9 x s(-1). We showed that transfer of DNA from the polymerase to the exonuclease active site and back again occurs through an intramolecular reaction, allowing for a complete cycle of reactions for error correction. For DNA containing a buried mismatch (T:T followed by C:G base pairs), the 3' base was removed at a rate of 3 x s(-1). The addition of nucleotide to the reaction that is identical to the 3' base increased the rate of excision 7-fold to 21 x s(-1). We propose that the free nucleotide enhances the rate of transfer of the DNA to the exonuclease active site by interrupting the correct 3' base pair through interaction with the template base. The exonuclease contribution to fidelity is minimal if the calculation is based on hydrolysis of a single mismatch: (k(exo) + k(pol,over))/(k(pol,over)) = 10, but this value increases to approximately 200 when examining error correction in the presence of nucleotides.

Differential incorporation and removal of antiviral deoxynucleotides by human DNA polymerase gamma

Mitochondrial toxicity can result from antiviral nucleotide analog therapy used to control human immunodeficiency virus type 1 infection. We evaluated the ability of such analogs to inhibit DNA synthesis by the human mitochondrial DNA polymerase (pol gamma) by comparing the insertion and exonucleolytic removal of six antiviral nucleotide analogs. Apparent steady-state K(m) and k(cat) values for insertion of 2',3'-dideoxy-TTP (ddTTP), 3'-azido-TTP (AZT-TP), 2',3'-dideoxy-CTP (ddCTP), 2',3'-didehydro-TTP (D4T-TP), (-)-2',3'-dideoxy-3'-thiacytidine (3TC-TP), and carbocyclic 2',3'-didehydro-ddGTP (CBV-TP) indicated incorporation of all six analogs, albeit with varying efficiencies. Dideoxynucleotides and D4T-TP were utilized by pol gamma in vitro as efficiently as natural deoxynucleotides, whereas AZT-TP, 3TC-TP, and CBV-TP were only moderate inhibitors of DNA chain elongation. Inefficient excision of dideoxynucleotides, D4T, AZT, and CBV from DNA predicts persistence in vivo following successful incorporation. In contrast, removal of 3'-terminal 3TC residues was 50% as efficient as natural 3' termini. Finally, we observed inhibition of exonuclease activity by concentrations of AZT-monophosphate known to occur in cells. Thus, although their greatest inhibitory effects are through incorporation and chain termination, persistence of these analogs in DNA and inhibition of exonucleolytic proofreading may also contribute to mitochondrial toxicity.

Mitochondrial DNA in human malignancy

Alterations in expression of mitochondrial DNA (mtDNA)-encoded polypeptides required for oxidative phosphorylation and cellular ATP generation may be a general characteristic of cancer cells. Mitochondrial DNA has been proposed to be involved in carcinogenesis because of high susceptibility to mutations and limited repair mechanisms in comparison to nuclear DNA. Since mtDNA lacks introns, it has been suggested that most mutations will occur in coding sequences and subsequent accumulation of mutations may lead to tumor formation. The mitochondrial genome is dependent upon the nuclear genome for transcription, translation, replication and repair, but precise mechanisms for how the two genomes interact and integrate with each other are poorly understood. In solid tumors, elevated expression of mtDNA-encoded subunits of the mitochondrial electron respiratory chain may reflect mitochondrial adaptation to perturbations in cellular energy requirements. In this paper, we review mitochondrial genomic aberrations reported in solid tumors of the breast, colon, stomach, liver, kidney, bladder, head/neck and lung as well as for hematologic diseases such as leukemia, myelodysplastic syndrome and lymphoma. We include data for elevated expression of mtDNA-encoded electron respiratory chain subunits in breast, colon and liver cancers and also the mutations reported in cancers of the colon, stomach, bladder, head/neck and lung. Finally, we examine the role of reactive oxygen species (ROS) generated by mitochondria in the process of carcinogenesis.

Accumulation of adenine DNA glycosylase-sensitive sites in human mitochondrial DNA

The mitochondrial respiratory chain inevitably produces reactive oxygen species as byproducts of aerobic ATP synthesis. Mitochondrial DNA (mtDNA), which is located close to the respiratory chain, is reported to contain much more 8-oxoguanine (8-oxoG), an oxidatively modified guanine base, than nuclear DNA. Despite such a high amount of 8-oxoG in mtDNA (1-2 8-oxoG/10(4) G), mtDNA is barely cleaved by an 8-oxoG DNA glycosylase or MutM, which specifically excises 8-oxoG from a C:8-oxoG pair. We find here that about half of human mtDNA molecules are cleaved by another 8-oxoG-recognizing enzyme, an adenine DNA glycosylase or MutY, which excises adenine from an A:8-oxoG pair. The cleavage sites are mapped to adenines. The calculated number of MutY-sensitive sites in mtDNA is approximately 1.4/10(4) G. This value roughly corresponds with the electrochemically measured amount of 8-oxoG in mtDNA (2.2/10(4) G), raising the possibility that 8-oxoG mainly accumulates as an A:8-oxoG pair.

Mismatch extension by Escherichia coli DNA polymerase III holoenzyme

The in vitro fidelity of Escherichia coli DNA polymerase III holoenzyme (HE) is characterized by an unusual propensity for generating (-1)-frameshift mutations. Here we have examined the capability of HE isolated from both a wild-type and a proofreading-impaired mutD5 strain to polymerize from M13mp2 DNA primer-templates containing a terminal T(template).C mismatch. These substrates contained either an A or a G as the next (5') template base. The assay allows distinction between: (i) direct extension of the terminal C (producing a base substitution), (ii) exonucleolytic removal of the C, or (iii), for the G-containing template, extension after misalignment of the C on the next template G (producing a (-1)-frameshift). On the A-containing substrate, both HEs did not extend the terminal C (<1%); instead, they exonucleolytically removed it (>99%). In contrast, on the G-containing substrate, the MutD5 HE yielded 61% (-1)-frameshifts and 6% base substitutions. The wild-type HE mostly excised the mispaired C from this substrate before extension (98%), but among the 2% mutants, (-1)-frameshifts exceeded base substitutions by 20 to 1. The preference of polymerase III HE for misalignment extension over direct mismatch extension provides a basis for explaining the in vitro (-1)-frameshift specificity of polymerase III HE.

The fidelity of DNA polymerase beta during distributive and processive DNA synthesis

During base excision repair, DNA polymerase beta fills 1-6-nucleotide gaps processively, reflecting a contribution of both its 8- and 31-kDa domains to DNA binding. Here we report the fidelity of pol beta during synthesis to fill gaps of 1, 5, 6, or >300 nucleotides. Error rates during distributive synthesis by recombinant rat and human polymerase (pol) beta with a 390-base gap are similar to each other and to previous values with pol beta purified from tissues. The base substitution fidelity of human pol beta when processively filling a 5-nucleotide gap is similar to that with a 361-nucleotide gap, but "closely-spaced" substitutions are produced at a rate at least 60-fold higher than for distributive synthesis. Base substitution fidelity when filling a 1-nucleotide gap is higher than when filling a 5-nucleotide gap, suggesting a contribution of the 8-kDa domain to the dNTP binding pocket and/or a difference in base stacking or DNA structure imposed by pol beta. Nonetheless, 1-nucleotide gap filling is inaccurate, even generating complex substitution-addition errors. Finally, the single-base deletion error rate during processive synthesis to fill a 6-nucleotide gap is indistinguishable from that of distributive synthesis to fill a 390-nucleotide gap. Thus the mechanism of processivity by pol beta does not allow the enzyme to suppress template misalignments.

Side chains that influence fidelity at the polymerase active site of Escherichia coli DNA polymerase I (Klenow fragment)

To investigate the interactions that determine DNA polymerase accuracy, we have measured the fidelity of 26 mutants with amino acid substitutions in the polymerase domain of a 3'-5'-exonuclease-deficient Klenow fragment. Most of these mutant polymerases synthesized DNA with an apparent fidelity similar to that of the wild-type control, suggesting that fidelity at the polymerase active site depends on highly specific enzyme-substrate interactions and is not easily perturbed. In addition to the previously studied Y766A mutator, four novel base substitution mutators were identified; they are R668A, R682A, E710A, and N845A. Each of these five mutator alleles results from substitution of a highly conserved amino acid side chain located on the exposed surface of the polymerase cleft near the polymerase active site. Analysis of base substitution errors at four template positions indicated that each of the five mutator polymerases has its own characteristic error specificity, suggesting that the Arg-668, Arg-682, Glu-710, Tyr-766, and Asn-845 side chains may contribute to polymerase fidelity in a variety of different ways. We separated the contributions of the nucleotide insertion and mismatch extension steps by using a novel fidelity assay that scores base substitution errors during synthesis to fill a single nucleotide gap (and hence does not require mismatch extension) and by measuring the rates of polymerase-catalyzed mismatch extension reactions. The R682A, E710A, Y766A, and N845A mutations cause decreased fidelity at the nucleotide insertion step, whereas R668A results in lower fidelity in both nucleotide insertion and mismatch extension. Relative to wild type, several Klenow fragment mutants showed substantially more discrimination against extension of a T.G mismatch under the conditions of the fidelity assay, providing one explanation for the anti-mutator phenotypes of mutants such as R754A and Q849A.

The role of 3'-5' exonucleolytic proofreading and mismatch repair in yeast mitochondrial DNA error avoidance

In the D171G/D230A mutant generated at conserved aspartate residues in the Exo1 and Exo2 sites of the 3'-5' exonuclease domain of the yeast mitochondrial DNA (mtDNA) polymerase (pol-gamma), the mitochondrial genome is unstable and the frequency of mtDNA point mutations is 1500 times higher than in the wild-type strain and 10 times higher than in single substitution mutants. The 10(4)-fold decrease in the 3'-5' exonuclease activity of the purified mtDNA polymerase is associated with mismatch extension and high rates of base misincorporation. Processivity of the purified polymerase on primed single-stranded DNA is decreased and the Km for dNTP is increased. The sequencing of mtDNA point mutations in the wild-type strain and in proofreading and mismatch-repair deficient mutants shows that mismatch repair contributes to elimination of the transitions while exonucleolytic proofreading preferentially repairs transversions, and more specifically A to T (or T to A) transversions. However, even in the wild-type strain, A to T (or T to A) transversions are the most frequent substitutions, suggesting that they are imperfectly repaired. The combination of both mismatch repair and proofreading deficiencies elicits a mitochondrial error catastrophe. These data show that the faithful replication of yeast mtDNA requires both exonucleolytic proofreading and mismatch repair.

Impaired mismatch extension by a herpes simplex DNA polymerase mutant with an editing nuclease defect

The D368A mutation within the 3'-5'-exonuclease domain of the herpes simplex type 1 DNA polymerase inactivates this nuclease and severely interferes with virus viability. Compared with the wild type enzyme, the D368A mutant exhibits substantially elevated rates of incorrect nucleotide incorporation, as measured in a LacZ reversion assay. This high rate occurs in the presence of high levels of dNTPs, a condition that forces the enzyme to extend mismatched primers. Hence, the mutant fails to correct many misincorporations that are removed in the wild type. In addition, the mutant shows a much reduced ability to replicate DNA templates primed with a 3'-mismatch as compared with wild type. This extension defect also appears more severe than observed for replicases which naturally lack editing nucleases. Based on these findings, we suggest that the inability of the D368A herpes simplex mutant polymerase to replicate beyond a mismatched base pair severely inhibits viral replication.

The base substitution and frameshift fidelity of Escherichia coli DNA polymerase III holoenzyme in vitro

We have investigated the in vitro fidelity of Escherichia coli DNA polymerase III holoenzyme from a wild-type and a proofreading-impaired mutD5 strain. Exonuclease assays showed the mutD5 holoenzyme to have a 30-50-fold reduced 3'-->5'-exonuclease activity. Fidelity was assayed during gap-filling synthesis across the lacId forward mutational target. The error rate for both enzymes was lowest at low dNTP concentrations (10-50 microM) and highest at high dNTP concentration (1000 microM). The mutD5 proofreading defect increased the error rate by only 3-5-fold. Both enzymes produced a high level of (-1)-frameshift mutations in addition to base substitutions. The base substitutions were mainly C-->T, G-->T, and G-->C, but dNTP pool imbalances suggested that these may reflect misincorporations opposite damaged template bases and that, instead, T-->C, G-->A, and C-->T transitions represent the normal polymerase III-mediated base.base mispairs. The frequent (-1)-frameshift mutations do not result from direct slippage but may be generated via a mechanism involving "misincorporation plus slippage." Measurements of the fidelity of wild-type and mutD5 holoenzyme during M13 in vivo replication revealed significant differences between the in vivo and in vitro fidelity with regard to both the frequency of frameshift errors and the extent of proofreading.

Highly mutagenic bypass synthesis by T7 RNA polymerase of site-specific benzo[a]pyrene diol epoxide-adducted template DNA

We have previously developed an in vitro system that allows quantitative evaluation of the fidelity of transcription during synthesis on a natural template in the presence of all four nucleotides. Here, we have employed this system using a TAA ochre codon reversion assay to examine the fidelity of transcription by T7 RNA polymerase past an adenine residue adducted at the N6-position with (-)-anti-trans- or (+)-anti-trans-benzo[a]pyrene diol epoxide (BPDE). T7 RNAP was capable of transcribing past either BPDE isomer to generate full-length run-off transcripts. The extent of bypass was found to be 32% for the (-)-anti-trans-isomer and 18% for the (+)-anti-trans-isomer. Transcription past both adducts was highly mutagenic. The reversion frequency of bypass synthesis of the (-)-anti-trans-isomer was elevated 11,000-fold and that of the (+)-anti-trans-isomer 6000-fold, relative to the reversion frequency of transcription on unadducted template. Adenine was misinserted preferentially, followed by guanine, opposite the adenine adducted with either BPDE isomer. Although base substitution errors were by far the most frequent mutation on the adducted template, three- and six-base deletions were also observed. These results suggest that transcriptional errors, particularly with regard to damage bypass, may contribute to the mutational burden of the cell.