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.     

Efficient and erroneous incorporation of oxidized DNA precursors by human DNA polymerase eta

Altered oxidative metabolism is a property of many tumor cells. Oxidation of DNA precursors, i.e., dNTP pool, as well as DNA is a major source of mutagenesis and carcinogenesis. Here, we report the remarkable nature of human DNA polymerase eta that incorporates oxidized dNTPs into a nascent DNA strand in an efficient and erroneous manner. The polymerase almost exclusively incorporated 8-hydroxy-dGTP (8-OH-dGTP) opposite template adenine (A) at 60% efficiency of normal dTTP incorporation, and incorporated 2-hydroxy-dATP (2-OH-dATP) opposite template thymine (T), guanine (G), or cytosine (C) at substantial rates. The synthetic primers having 8-hydroxy-G paired with template A or 2-hydroxy-A paired with template T, G, or C at the termini were efficiently extended. In contrast, human DNA polymerase iota incorporated 8-OH-dGTP opposite template A with much lower efficiency and did not incorporate 2-OH-dATP opposite any of the template bases. It did not extend the primers having the oxidized bases at the termini either. We propose that human DNA polymerase eta may participate in oxidative mutagenesis through the efficient and erroneous incorporation of oxidized dNTPs during DNA synthesis.     

Specificity of mutations induced by incorporation of oxidized dNTPs into DNA by human DNA polymerase eta

Aberrant oxidation is a property of many tumor cells. Oxidation of DNA precursors, i.e., deoxynucleotide triphosphates (dNTPs), as well as DNA is a major cause of genome instability. Here, we report that human DNA polymerase eta (h Poleta) incorporates oxidized dNTPs, i.e., 2-hydroxy-2'-deoxyadenosine 5'-triphosphate (2-OH-dATP) and 8-hydroxy-2'-deoxyguanosine 5'-triphosphate (8-OH-dGTP), into DNA in an erroneous and efficient manner, thereby inducing various types of mutations during in vitro gap-filling DNA synthesis. When 2-OH-dATP was present at a concentration equal to those of the four normal dNTPs in the reaction mixture, DNA synthesis by h Poleta enhanced the frequency of G-to-T transversions eight-fold higher than that of the transversions in control where only the normal dNTPs were present. When 8-OH-dGTP was present at an equimolar concentration to the normal dNTPs, it enhanced the frequency of A-to-C transversions 17-fold higher than the control. It also increased the frequency of C-to-A transversions about two-fold. These results suggest that h Poleta incorporates 2-OH-dATP opposite template G and incorporates 8-OH-dGTP opposite template A and slightly opposite template C during DNA synthesis. Besides base substitutions, h Poleta enhanced the frequency of single-base frameshifts and deletions with the size of more than 100 base pairs when 8-OH-dGTP was present in the reaction mixture. Since h Poleta is present in replication foci even without exogenous DNA damage, we suggest that h Poleta may be involved in induction of various types of mutations through the erroneous and efficient incorporation of oxidized dNTPs into DNA in human cells.     

Toxicity of antiviral nucleoside analogs and the human mitochondrial DNA polymerase

To examine the role of the mitochondrial polymerase (Pol gamma) in clinically observed toxicity of nucleoside analogs used to treat AIDS, we examined the kinetics of incorporation catalyzed by Pol gamma for each Food and Drug Administration-approved analog plus 1-(2-deoxy-2-fluoro-beta-D-arabinofuranosyl)-5-iodouracil (FIAU), beta-L-(-)-2',3'-dideoxy-3'-thiacytidine (-)3TC, and (R)-9-(2-phosphonylmethoxypropyl)adenine (PMPA). We used recombinant exonuclease-deficient (E200A), reconstituted human Pol gamma holoenzyme in single turnover kinetic studies to measure K(d) (K(m)) and k(pol) (k(cat)) to estimate the specificity constant (k(cat)/K(m)) for each nucleoside analog triphosphate. The specificity constants vary more than 500,000-fold for the series ddC > ddA (ddI) > 2',3'-didehydro-2',3'-dideoxythymidine (d4T) > (+)3TC > (-)3TC > PMPA > azidothymidine (AZT) > Carbovir (CBV). Abacavir (prodrug of CBV) and PMPA are two new drugs that are expected to be least toxic. Notably, the higher toxicities of d4T, ddC, and ddA arose from their 13-36-fold tighter binding relative to the normal dNTP even though their rates of incorporation were comparable with PMPA and AZT. We also examined the rate of exonuclease removal of each analog after incorporation. The rates varied from 0.06 to 0.0004 s(-1) for the series FIAU > (+)3TC approximately equal to (-)3TC > CBV > AZT > PMPA approximately equal to d4T > ddA (ddI) > ddC. Removal of ddC was too slow to measure (<0.00002 s(-1)). The high toxicity of dideoxy compounds, ddC and ddI (metabolized to ddA), may be a combination of high rates of incorporation and ineffective exonuclease removal. Conversely, the more effective excision of (-)3TC, CBV, and AZT may contribute to lower toxicity. FIAU is readily extended by the next correct base pair (0.13 s(-1)) faster than it is removed (0.06 s(-1)) and, therefore, is stably incorporated and highly mutagenic. We define a toxicity index for chain terminators to account for relative rates of incorporation versus removal. These results provide a method to rapidly screen new analogs for potential toxicity.     

Functional human mitochondrial DNA polymerase gamma forms a heterotrimer

Mitochondrial DNA polymerase gamma (pol gamma) is responsible for replication and repair of mtDNA and is mutated in individuals with genetic disorders such as chronic external ophthalmoplegia and Alpers syndrome. pol gamma is also an adventitious target for toxic side effects of several antiviral compounds, and mutation of its proofreading exonuclease leads to accelerated aging in mouse models. We have used a variety of physical and functional approaches to study the interaction of the human pol gamma catalytic subunit with both the wild-type accessory factor, pol gammaB, and a deletion derivative that is unable to dimerize and consequently is impaired in its ability to stimulate processive DNA synthesis. Our studies clearly showed that the functional human holoenzyme contains two subunits of the processivity factor and one catalytic subunit, thereby forming a heterotrimer. The structure of pol gamma seems to be variable, ranging from a single catalytic subunit in yeast to a heterodimer in Drosophila and a heterotrimer in mammals.     

Preferential incorporation of G opposite template T by the low-fidelity human DNA polymerase iota

DNA polymerase activity is essential for replication, recombination, repair, and mutagenesis. All DNA polymerases studied so far from any biological source synthesize DNA by the Watson-Crick base-pairing rule, incorporating A, G, C, and T opposite the templates T, C, G, and A, respectively. Non-Watson-Crick base pairs would lead to mutations. In this report, we describe the ninth human DNA polymerase, Pol(iota), encoded by the RAD30B gene. We show that human Pol(iota) violates the Watson-Crick base-pairing rule opposite template T. During base selection, human Pol(iota) preferred T-G base pairing, leading to G incorporation opposite template T. The resulting T-G base pair was less efficiently extended by human Pol(iota) compared to the Watson-Crick base pairs. Consequently, DNA synthesis frequently aborted opposite template T, a property we designated the T stop. This T stop restricted human Pol(iota) to a very short stretch of DNA synthesis. Furthermore, kinetic analyses show that human Pol(iota) copies template C with extraordinarily low fidelity, misincorporating T, A, and C with unprecedented frequencies of 1/9, 1/10, and 1/11, respectively. Human Pol(iota) incorporated one nucleotide opposite a template abasic site more efficiently than opposite a template T, suggesting a role for human Pol(iota) in DNA lesion bypass. The unique features of preferential G incorporation opposite template T and T stop suggest that DNA Pol(iota) may additionally play a specialized function in human biology.     

An autoradiographic demonstration of nuclear DNA replication by DNA polymerase alpha and of mitochondrial DNA synthesis by DNA polymerase gamma.

The incorporation of thymidine into the DNA of eukaryotic cells is markedly depressed, but not completely inhibited, by aphidicolin, a highly specific inhibitor of DNA polymerase alpha. An electron microscope autoradiographic analysis of the synthesis of nuclear and mitochondrial DNA in vivo in Concanavalin A stimulated rabbit spleen lymphocytes and in Hamster cell cultures, in the absence and in the presence of aphidicolin, revealed that aphidicolin inhibits the nuclear but not the mitochondrial DNA replication. We therefore conclude that DNA polymerase alpha performs the synchronous bidirectional replication of nuclear DNA and that DNA polymerase gamma, the only DNA polymerase present in the mitochondria, performs the "strand displacement" DNA synthesis of these organelles.     

Translesion synthesis past acrolein-derived DNA adduct,gamma -hydroxypropanodeoxyguanosine,by yeast and human DNA polymerase eta

gamma-Hydroxy-1,N(2)-propano-2'deoxyguanosine (gamma-HOPdG) is a major deoxyguanosine adduct derived from acrolein, a known mutagen. In vitro, this adduct has previously been shown to pose a severe block to translesion synthesis by a number of polymerases (pol). Here we show that both yeast and human pol eta can incorporate a C opposite gamma-HOPdG at approximately 190- and approximately 100-fold lower efficiency relative to the control deoxyguanosine and extend from a C paired with the adduct at approximately 8- and approximately 19-fold lower efficiency. Although DNA synthesis past gamma-HOPdG by yeast pol eta was relatively accurate, the human enzyme misincorporated nucleotides opposite the lesion with frequencies of approximately 10(-1) to 10(-2). Because gamma-HOPdG can adopt both ring closed and ring opened conformations, comparative replicative bypass studies were also performed with two model adducts, propanodeoxyguanosine and reduced gamma-HOPdG. For both yeast and human pol eta, the ring open reduced gamma-HOPdG adduct was less blocking than gamma-HOPdG, whereas the ring closed propanodeoxyguanosine adduct was a very strong block. Replication of DNAs containing gamma-HOPdG in wild type and xeroderma pigmentosum variant cells revealed a somewhat decreased mutation frequency in xeroderma pigmentosum variant cells. Collectively, the data suggest that pol eta might potentially contribute to both error-free and mutagenic bypass of gamma-HOPdG.     

Kinetic analysis of nucleotide incorporation by mammalian DNA polymerase delta

The kinetics of nucleotide incorporation into 24/36-mer primer/template DNA by purified fetal calf thymus DNA polymerase (pol) delta was examined using steady-state and pre-steady-state kinetics. The role of the pol delta accessory protein, proliferating cell nuclear antigen (PCNA), on DNA replication by pol delta was also examined by kinetic analysis. The steady-state parameter k(cat) was similar for pol delta in the presence and absence of PCNA (0.36 and 0.30 min(-1), respectively); however, the K(m) for dNTP was 20-fold higher in the absence of PCNA (0.067 versus 1.2 microm), decreasing the efficiency of nucleotide insertion. Pre-steady-state bursts of nucleotide incorporation were observed for pol delta in the presence and absence of PCNA (rates of polymerization (k(pol)) of 1260 and 400 min(-1), respectively). The reduction in polymerization rate in the absence of PCNA was also accompanied by a 2-fold decrease in burst amplitude. The steady-state exonuclease rate of pol delta was 0.56 min(-1) (no burst, 10(3)-fold lower than the rate of polymerization). The small phosphorothioate effect of 2 for correct nucleotide incorporation into DNA by pol delta.PCNA indicated that the rate-limiting step in the polymerization cycle occurs prior to phosphodiester bond formation. A K(d)(dNTP) value of 0.93 microm for poldelta.dNTP binding was determined by pre-steady-state kinetics. A 5-fold increase in K(d)(DNA) for the pol delta.DNA complex was measured in the absence of PCNA. We conclude that the major replicative mammalian polymerase, pol delta, exhibits kinetic behavior generally similar to that observed for several prokaryotic model polymerases, particularly a rate-limiting step following product formation in the steady state (dissociation of oligonucleotides) and a rate-limiting step (probably conformational change) preceding phosphodiester bond formation. PCNA appears to affect pol delta replication in this model mainly by decreasing the dissociation of the polymerase from the DNA.     

Exonuclease of human DNA polymerase gamma disengages its strand displacement function

Pol γ, the only DNA polymerase found in human mitochondria, functions in both mtDNA repair and replication. During mtDNA base-excision repair, gaps are created after damaged base excision. Here we show that Pol γ efficiently gap-fills except when the gap is only a single nucleotide. Although wild-type Pol γ has very limited ability for strand displacement DNA synthesis, exo^? (3′–5′ exonuclease-deficient) Pol γ has significantly high activity and rapidly unwinds downstream DNA, synthesizing DNA at a rate comparable to that of the wild-type enzyme on a primer-template. The catalytic subunit Pol γA alone, even when exo^?, is unable to synthesize by strand displacement, making this the only known reaction of Pol γ holoenzyme that has an absolute requirement for the accessory subunit Pol γB.     

Comparative kinetics of nucleotide analog incorporation by vent DNA polymerase

Comparative kinetic and structural analyses of a variety of polymerases have revealed both common and divergent elements of nucleotide discrimination. Although the parameters for dNTP incorporation by the hyperthermophilic archaeal Family B Vent DNA polymerase are similar to those previously derived for Family A and B DNA polymerases, parameters for analog incorporation reveal alternative strategies for discrimination by this enzyme. Discrimination against ribonucleotides was characterized by a decrease in the affinity of NTP binding and a lower rate of phosphoryl transfer, whereas discrimination against ddNTPs was almost exclusively due to a slower rate of phosphodiester bond formation. Unlike Family A DNA polymerases, incorporation of 9-[(2-hydroxyethoxy)methyl]X triphosphates (where X is adenine, cytosine, guanine, or thymine; acyNTPs) by Vent DNA polymerase was enhanced over ddNTPs via a 50-fold increase in phosphoryl transfer rate. Furthermore, a mutant with increased propensity for nucleotide analog incorporation (Vent(A488L) DNA polymerase) had unaltered dNTP incorporation while displaying enhanced nucleotide analog binding affinity and rates of phosphoryl transfer. Based on kinetic data and available structural information from other DNA polymerases, we propose active site models for dNTP, ddNTP, and acyNTP selection by hyperthermophilic archaeal DNA polymerases to rationalize structural and functional differences between polymerases.     

Nucleotide incorporation by human DNA polymerase gamma opposite benzo[a]pyrene and benzo[c]phenanthrene diol epoxide adducts of deoxyguanosine and deoxyadenosine

Mitochondria are major cellular targets of benzo[a]pyrene (BaP), a known carcinogen that also inhibits mitochondrial proliferation. Here, we report for the first time the effect of site-specific N²-deoxyguanosine (dG) and N⁶-deoxyadenosine (dA) adducts derived from BaP 7,8-diol 9,10-epoxide (BaP DE) and dA adducts from benzo[c]phenanthrene 3,4-diol 1,2-epoxide (BcPh DE) on DNA replication by exonuclease-deficient human mitochondrial DNA polymerase (pol γ) with and without the p55 processivity subunit. The catalytic subunit alone primarily misincorporated dAMP and dGMP opposite the BaP DE–dG adducts, and incorporated the correct dTMP as well as the incorrect dAMP opposite the DE–dA adducts derived from both BaP and BcPh. In the presence of p55 the polymerase incorporated all four nucleotides and catalyzed limited translesion synthesis past BaP DE–dG adducts but not past BaP or BcPh DE–dA adducts. Thus, all these adducts cause erroneous purine incorporation and significant blockage of further primer elongation. Purine misincorporation by pol γ opposite the BaP DE–dG adducts resembles that observed with the Y family pol η. Blockage of translesion synthesis by these DE adducts is consistent with known BaP inhibition of mitochondrial (mt)DNA synthesis and suggests that continued exposure to BaP reduces mtDNA copy number, increasing the opportunity for repopulation with pre-existing mutant mtDNA and a resultant risk of mitochondrial genetic diseases.     

Stopped-flow DNA polymerase assay by continuous monitoring of dNTP incorporation by fluorescence

DNA polymerase activity was measured by a stopped-flow assay that monitors polymerase extension using an intercalating dye. Double-stranded DNA formation during extension of a hairpin substrate was monitored at 75 °C for 2 min. Rates were determined in nucleotides per second per molecule of polymerase (nt/s) and were linear with time and polymerase concentration from 1 to 50 nM. The concentrations of 15 available polymerases were quantified and their extension rates determined in 50 mM Tris, pH 8.3, 0.5 mg/ml BSA, 2 mM MgCl₂, and 200 μM each dNTP as well as their commercially recommended buffers. Native Taq polymerases had similar extension rates of 10–45 nt/s. Three alternative polymerases showed faster speeds, including KOD (76 nt/s), Klentaq I (101 nt/s), and KAPA2G (155 nt/s). Fusion polymerases including Herculase II and Phusion were relatively slow (3–13 nt/s). The pH optimum for Klentaq extension was between 8.5 and 8.7 with no effect of Tris concentration. Activity was directly correlated to the MgCl₂ concentration and inversely correlated to the KCl concentration. This continuous assay is relevant to PCR and provides accurate measurement of polymerase activity using a defined template without the need of radiolabeled substrates.     

Structural basis for proficient incorporation of dTTP opposite O6-methylguanine by human DNA polymerase iota

O(6)-methylguanine (O(6)-methylG) is highly mutagenic and is commonly found in DNA exposed to methylating agents, even physiological ones (e.g. S-adenosylmethionine). The efficiency of a truncated, catalytic DNA polymerase ι core enzyme was determined for nucleoside triphosphate incorporation opposite O(6)-methylG, using steady-state kinetic analyses. The results presented here corroborate previous work from this laboratory using full-length pol ι, which showed that dTTP incorporation occurs with high efficiency opposite O(6)-methylG. Misincorporation of dTTP opposite O(6)-methylG occurred with ～6-fold higher efficiency than incorporation of dCTP. Crystal structures of the truncated form of pol ι with O(6)-methylG as the template base and incoming dCTP or dTTP were solved and showed that O(6)-methylG is rotated into the syn conformation in the pol ι active site and that dTTP misincorporation by pol ι is the result of Hoogsteen base pairing with the adduct. Both dCTP and dTTP base paired with the Hoogsteen edge of O(6)-methylG. A single, short hydrogen bond formed between the N3 atom of dTTP and the N7 atom of O(6)-methylG. Protonation of the N3 atom of dCTP and bifurcation of the N3 hydrogen between the N7 and O(6) atoms of O(6)-methylG allow base pairing of the lesion with dCTP. We conclude that differences in the Hoogsteen hydrogen bonding between nucleotides is the main factor in the preferential selectivity of dTTP opposite O(6)-methylG by human pol ι, in contrast to the mispairing modes observed previously for O(6)-methylG in the structures of the model DNA polymerases Sulfolobus solfataricus Dpo4 and Bacillus stearothermophilus DNA polymerase I.     

Mutations in DNA polymerase gamma cause error prone DNA synthesis in human mitochondrial disorders

This paper summarizes recent advances in understanding the links between the cell's ability to maintain integrity of its mitochondrial genome and mitochondrial genetic diseases. Human mitochondrial DNA is replicated by the two-subunit DNA polymerase gamma (polgamma). We investigated the fidelity of DNA replication by polgamma with and without exonucleolytic proofreading and its p55 accessory subunit. Polgamma has high base substitution fidelity due to efficient base selection and exonucleolytic proofreading, but low frameshift fidelity when copying homopolymeric sequences longer than four nucleotides. Progressive external ophthalmoplegia (PEO) is a rare disease characterized by the accumulation of large deletions in mitochondrial DNA. Recently, several mutations in the polymerase and exonuclease domains of the human polgamma have been shown to be associated with PEO. We are analyzing the effect of these mutations on the human polgamma enzyme. In particular, three autosomal dominant mutations alter amino acids located within polymerase motif B of polgamma. These residues are highly conserved among family A DNA polymerases, which include T7 DNA polymerase and E.coli pol I. These PEO mutations have been generated in polgamma to analyze their effects on overall polymerase function as well as the effects on the fidelity of DNA synthesis. One mutation in particular, Y955C, was found in several families throughout Europe, including one Belgian family and five unrelated Italian families. The Y955C mutant polgamma retains a wild-type catalytic rate but suffers a 45-fold decrease in apparent binding affinity for the incoming dNTP. The Y955C derivative is also much less accurate than is wild-type polgamma, with error rates for certain mismatches elevated by 10- to 100-fold. The error prone DNA synthesis observed for the Y955C polgamma is consistent with the accumulation of mtDNA mutations in patients with PEO. The effects of other polgamma mutations associated with PEO are discussed.     

Mechanism of template-independent nucleotide incorporation catalyzed by a template-dependent DNA polymerase

Numerous template-dependent DNA polymerases are capable of catalyzing template-independent nucleotide additions onto blunt-end DNA. Such non-canonical activity has been hypothesized to increase the genomic hypermutability of retroviruses including human immunodeficiency viruses. Here, we employed pre-steady state kinetics and X-ray crystallography to establish a mechanism for blunt-end additions catalyzed by Sulfolobus solfataricus Dpo4. Our kinetic studies indicated that the first blunt-end dATP incorporation was 80-fold more efficient than the second, and among natural deoxynucleotides, dATP was the preferred substrate due to its stronger intrahelical base-stacking ability. Such base-stacking contributions are supported by the 41-fold higher ground-state binding affinity of a nucleotide analog, pyrene nucleoside 5'-triphosphate, which lacks hydrogen bonding ability but possesses four conjugated aromatic rings. A 2.05 A resolution structure of Dpo4*(blunt-end DNA)*ddATP revealed that the base and sugar of the incoming ddATP, respectively, stack against the 5'-base of the opposite strand and the 3'-base of the elongating strand. This unprecedented base-stacking pattern can be applied to subsequent blunt-end additions only if all incorporated dAMPs are extrahelical, leading to predominantly single non-templated dATP incorporation.