Structures of mismatch replication errors observed in a DNA polymerase

Accurate DNA replication is essential for genomic stability. One mechanism by which high-fidelity DNA polymerases maintain replication accuracy involves stalling of the polymerase in response to covalent incorporation of mismatched base pairs, thereby favoring subsequent mismatch excision. Some polymerases retain a "short-term memory" of replication errors, responding to mismatches up to four base pairs in from the primer terminus. Here we a present a structural characterization of all 12 possible mismatches captured at the growing primer terminus in the active site of a polymerase. Our observations suggest four mechanisms that lead to mismatch-induced stalling of the polymerase. Furthermore, we have observed the effects of extending a mismatch up to six base pairs from the primer terminus and find that long-range distortions in the DNA transmit the presence of the mismatch back to the enzyme active site, suggesting the structural basis for the short-term memory of replication errors.     

Proofreading dynamics of a processive DNA polymerase

Replicative DNA polymerases present an intrinsic proofreading activity during which the DNA primer chain is transferred between the polymerization and exonuclease sites of the protein. The dynamics of this primer transfer reaction during active polymerization remain poorly understood. Here we describe a single‐molecule mechanical method to investigate the conformational dynamics of the intramolecular DNA primer transfer during the processive replicative activity of the Φ29 DNA polymerase and two of its mutants. We find that mechanical tension applied to a single polymerase–DNA complex promotes the intramolecular transfer of the primer in a similar way to the incorporation of a mismatched nucleotide. The primer transfer is achieved through two novel intermediates, one a tension‐sensitive and functional polymerization conformation and a second non‐active state that may work as a fidelity check point for the proofreading reaction.     

An analysis of replication errors made by a defective T4 DNA polymerase

Summary An amber mutant in the head protein of bacteriophage T4D, amH36 has been induced to revert by a mutator, tsL56 in gene 43 (the structural gene for DNA polymerase, de Waard, Paul and Lehman, 1965) which is known to cause errors in replication. As a consequence the known am base triplet is converted to other triplets which assign certain amino acids. The nature of the replication errors has been analyzed by looking at the insertion of amino acids in a peptide from the head protein of 60 independent am ⁺ revertants. Of these, 38 had incorporated tyrosine (like spontaneous revertants also do) while in 21 cases glutamine was inserted and in one case glutamic acid. With the help of the codon catalogue it could be shown that the L56 polymerase promotes an A:TG:C transition as well as more than one type of transversion. The single revertant which had incorporated glutamic acid clearly represents an A:TC:G transversion. The other transversions leading to the insertion of tyrosine indicate that a C:G pair has been converted. In this case the degeneracy of the code does not allow to differentiate between the transversion C:GG:C and C:GA:T. These findings and the absence of certain amino acids as permissible substituents are discussed with regard to the specificity of the errors in replication made by L56 polymerase.     

Evidence that errors made by DNA polymerase alpha are corrected by DNA polymerase delta

Eukaryotic replication begins at origins and on the lagging strand with RNA-primed DNA synthesis of a few nucleotides by polymerase alpha, which lacks proofreading activity. A polymerase switch then allows chain elongation by proofreading-proficient pol delta and pol epsilon. Pol delta and pol epsilon are essential, but their roles in replication are not yet completely defined . Here, we investigate their roles by using yeast pol alpha with a Leu868Met substitution . L868M pol alpha copies DNA in vitro with normal activity and processivity but with reduced fidelity. In vivo, the pol1-L868M allele confers a mutator phenotype. This mutator phenotype is strongly increased upon inactivation of the 3' exonuclease of pol delta but not that of pol epsilon. Several nonexclusive explanations are considered, including the hypothesis that the 3' exonuclease of pol delta proofreads errors generated by pol alpha during initiation of Okazaki fragments. Given that eukaryotes encode specialized, proofreading-deficient polymerases with even lower fidelity than pol alpha, such intermolecular proofreading could be relevant to several DNA transactions that control genome stability.     

Proofreading activity of DNA polymerase III responds like elongation activity to auxiliary subunits

A comparison of the 3'----5' proofreading properties between Escherichia coli DNA polymerase III holoenzyme and DNA polymerase III' was conducted. This study indicated that the influence of the holoenzyme auxiliary subunits on the proofreading exonuclease parallels their effect on the elongation reaction. At physiological ionic strengths the auxiliary subunits markedly stimulated the exonuclease rate in an ATP-dependent reaction, while the exonuclease rate of DNA polymerase III' was not affected by ATP. E. coli single-stranded DNA binding protein stimulated the 3'----5' exonuclease activity of holoenzyme and inhibited DNA polymerase III'. Similarly, the auxiliary subunits and ATP converted the proofreading activity to a highly processive exonuclease. Our observation, that the exonuclease activity of the DNA polymerase III holoenzyme responded to ATP, salt, and E. coli single-stranded DNA-binding protein like the elongation activity, is consistent with the polymerase and exonuclease subunits acting within the same complex in a coordinated reaction.     

DNA polymerase beta can substitute for DNA polymerase I in the initiation of plasmid DNA replication.

We previously demonstrated that mammalian DNA polymerase beta can substitute for DNA polymerase I of Escherichia coli in DNA replication and in base excision repair. We have now obtained genetic evidence suggesting that DNA polymerase beta can substitute for E. coli DNA polymerase I in the initiation of replication of a plasmid containing a pMB1 origin of DNA replication. Specifically, we demonstrate that a plasmid with a pMB1 origin of replication can be maintained in an E. coli polA mutant in the presence of mammalian DNA polymerase beta. Our results suggest that mammalian DNA polymerase beta can substitute for E. coli DNA polymerase I by initiating DNA replication of this plasmid from the 3' OH terminus of the RNA-DNA hybrid at the origin of replication.     

Involvement of DNA polymerase beta in DNA replication and mutagenic consequences

Overexpression in mammalian cells of the error-prone DNA polymerase beta (Pol beta) has been found to increase the spontaneous mutagenesis. Here, we investigated a possible mechanism used by Pol beta to be a genetic instability enhancer: its interference in replicative DNA synthesis, which is normally catalysed by the DNA polymerases alpha, delta and epsilon. By taking advantage of the ability to incorporate efficiently into DNA the chain terminator ddCTP as well as the oxidised nucleotide 8-oxo-dGTP, we show here that purified Pol beta can compete with the replicative DNA polymerases during replication in vitro of duplex DNA when added to human cell extracts. We found that involvement of Pol beta lowers replication fidelity and results in a modified error-specificity. Furthermore, we demonstrated that involvement of Pol beta occurred during synthesis of the lagging strand. These in vitro data provide one possible explanation of how overexpression of the enzyme could perturb the genetic instability in mammalian cells. We discuss these findings within the scope of the up-regulation of Pol beta in many cancer cells.     

Identification of DNA polymerase delta in CV-1 cells: studies implicating both DNA polymerase delta and DNA polymerase alpha in DNA replication

DNA polymerases delta and alpha were purified from CV-1 cells, and their sensitivities to the inhibitors aphidicolin, (p-n-butylphenyl)deoxyguanosine triphosphate (BuPdGTP), and monoclonal antibodies directed against DNA polymerase alpha were determined. The effects of these inhibitors on DNA replication in permeabilized CV-1 cells were studied to investigate the potential roles of polymerases delta and alpha in DNA replication. Aphidicolin was shown to be a more potent inhibitor of DNA replication than of DNA polymerase alpha or delta activity. Inhibition of DNA replication by various concentrations of BuPdGTP was intermediate between inhibition of purified polymerase alpha or delta activity. Concentrations of BuPdGTP which totally abolished DNA polymerase alpha activity were much less effective in reducing DNA replication, as well as the activity of DNA polymerase delta. Monoclonal antibodies which specifically inhibited polymerase alpha activity reduced, but did not abolish, DNA replication in permeable cells. BuPdGTP, as well as anti-polymerase alpha antibodies, inhibited DNA replication in a nonlinear manner as a function of time. Depending upon the initial or final rates of inhibition of replication by BuPdGTP and anti-alpha antibodies, as little as 50%, or as much as 80%, of the replication activity can be attributed to polymerase alpha. The remaining replication activity (20-50%) is tentatively attributed to polymerase delta, because it was aphidicolin sensitive and resistant to both anti-polymerase alpha antibodies and low concentrations of BuPdGTP. A concentration of BuPdGTP which abolished polymerase alpha activity reduced, but did not abolish, both the synthesis and maturation of nascent DNA fragments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mammalian DNA polymerase beta can substitute for DNA polymerase I during DNA replication in Escherichia coli.

Mammalian DNA polymerase beta is the smallest known eukaryotic polymerase and is expressed as an active protein in Escherichia coli harboring a plasmid containing its cDNA. Since some catalytic functions of DNA polymerase beta and E. coli DNA polymerase I are similar, we wished to determine if DNA polymerase beta could substitute for DNA polymerase I in bacteria. We found that the expression of mammalian DNA polymerase beta in E. coli restored growth in a DNA polymerase I-defective bacterial mutant. Sucrose density gradient analysis revealed that DNA polymerase beta complements the replication defect in the mutant by increasing the rate of joining of Okazaki fragments. These findings demonstrate that DNA polymerase beta, believed to function in DNA repair in mammalian cells, can also function in DNA replication. Moreover, this complementation system will permit study of the in vivo function of altered species of DNA polymerase beta, an analysis currently precluded by the difficulty in isolating mutants in mammalian cells.     

Role of Escherichia coli DNA polymerase I in chromosomal DNA replication fidelity

We have investigated the possible role of Escherichia coli DNA polymerase (Pol) I in chromosomal replication fidelity. This was done by substituting the chromosomal polA gene by the polAexo variant containing an inactivated 3′→5′ exonuclease, which serves as a proofreader for this enzyme's misinsertion errors. Using this strain, activities of Pol I during DNA replication might be detectable as increases in the bacterial mutation rate. Using a series of defined lacZ reversion alleles in two orientations on the chromosome as markers for mutagenesis, 1.5‐ to 4‐fold increases in mutant frequencies were observed. In general, these increases were largest for lac orientations favouring events during lagging strand DNA replication. Further analysis of these effects in strains affected in other E. coli DNA replication functions indicated that this polAexo mutator effect is best explained by an effect that is additive compared with other error‐producing events at the replication fork. No evidence was found that Pol I participates in the polymerase switching between Pol II, III and IV at the fork. Instead, our data suggest that the additional errors produced by polAexo are created during the maturation of Okazaki fragments in the lagging strand.     

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.     

DNA polymerase requirements for parvovirus H-1 DNA replication in vitro.

An in vitro system using nuclei from parvovirus H-1-infected cells was used to characterize the influence of inhibitors of mammalian DNA polymerases on viral DNA synthesis. The experiments tested the effects of aphidicolin, which is highly specific for DNA polymerase alpha, and 2',3'-dideoxythymidine-5'-triphosphate (ddTTP), which inhibits cellular DNA polymerases in the order gamma greater than beta greater than alpha. Both aphidicolin and ddTTP were inhibitory, indicating that both polymerase alpha and a ddttp-sensitive enzyme are required for viral DNA synthesis. This was seen more clearly in kinetic measurements, which indicated an initial period of rapid DNA synthesis with the participation of polymerase alpha, followed by a period of less rapid, but more sustained, rate of DNA synthesis carried out by a ddTTP-sensitive enzyme, probably polymerase gamma. One interpretation of the results is that polymerase alpha functions in a strand displacement stage of the viral DNA replication mechanism, whereas polymerase gamma serves to convert the displaced single strands back to double-strand replicative form.     

DNA polymerase I in constitutive stable DNA replication in Escherichia coli.

We examined the effects of mutations in the polA (encoding DNA polymerase I) and polB (DNA polymerase II) genes on inducible and constitutive stable DNA replication (iSDR and cSDR, respectively), the two alternative DNA replication systems of Escherichia coli. The polA25::miniTn10spc mutation severely inactivated cSDR, whereas polA1 mutants exhibited a significant extent of cSDR. cSDR required both the polymerase and 5'-->3' exonuclease activities of DNA polymerase I. A similar requirement for both activities was found in replication of the pBR322 plasmid in vivo. DNA polymerase II was required neither for cSDR nor for iSDR. In addition, we found that the lethal combination of an rnhA (RNase HI) and a polA mutation could be suppressed by the lexA(Def) mutation.     

DNA polymerase I modulates inducible stable DNA replication in Escherichia coli.

Mutants of Escherichia coli lacking RNase HI activity and cells induced for the SOS response express modes of DNA replication independent of protein synthesis, called constitutive and induced stable DNA replication, respectively. We report here that mutants deleted for the polA gene express induced stable DNA replication at approximately 25-fold the rate of wild-type cells, whereas constitutive stable DNA replication is not enhanced.     

Isolation of DNA polymerase gamma from an adenovirus 2 DNA replication complex.

The major DNA polymerase in a nuclear membrane complex that is capable of synthesizing viral DNA sequences in vitro has been purified about 900-fold from adenovirus 2-infected KB cells. The enzyme was characterized as belonging to the class of mammalian DNA polymerases (DNA polymerase gamma) that can utilize poly(A) with oligo(dT) as template primer.     

Origins of human mitochondrial point mutations as DNA polymerase gamma-mediated errors

Mitochondrial mutational spectra in human cells, tissues and derived tumors for bp 10,030-10,130 are essentially identical, suggesting a predominant mutagenic role for endogenous processes. We hypothesized that errors mediated by mitochondrial DNA polymerase gamma were the primary sources of mutations. Point mutations created in this sequence by human DNA pol gamma in vitro were thus compared to the eighteen mutational hotspots, all single base substitutions, previously found in human tissues. The set of concordant hotspots accounted for 83% of these in vivo mutational events. About half of these mutations are insensitive to prolonged heating of DNA during PCR and half increase proportionally with heating time at 98 degrees C. Primary misincorporation errors and miscopying errors past thermal denaturing products such as deaminated cytosines (uracils) thus appear to be of approximately equal importance. For the sequence studied, these data support the conclusion that, endogenous error mediated by DNA pol gamma constitutes the primary source of mitochondrial point mutations in human tissues.     

Processive replication of single-stranded DNA templates by the herpes simplex virus-induced DNA polymerase

The DNA polymerase encoded by herpes simplex virus 1 consists of a single polypeptide of Mr 136,000 that has both DNA polymerase and 3'----5' exonuclease activities; it lacks a 5'----3' exonuclease. The herpes polymerase is exceptionally slow in extending a synthetic DNA primer annealed to circular single-stranded DNA (turnover number approximately 0.25 nucleotide). Nevertheless, it is highly processive because of its extremely tight binding to a primer terminus (Kd less than 1 nM). The single-stranded DNA-binding protein from Escherichia coli greatly stimulates the rate (turnover number approximately 4.5 nucleotides) by facilitating the efficient binding to and extension of the DNA primers. Synchronous replication by the polymerase of primed single-stranded DNA circles coated with the single-stranded DNA-binding protein proceeds to the last nucleotide of available 5.4-kilobase template without dissociation, despite the 20-30 min required to replicate the circle. Upon completion of synthesis, the polymerase is slow in cycling to other primed single-stranded DNA circles. ATP (or dATP) is not required to initiate or sustain highly processive synthesis. The 3'----5' exonuclease associated with the herpes DNA polymerase binds a 3' terminus tightly (Km less than 50 nM) and is as sensitive as the polymerase activity to inhibition by phosphonoacetic acid (Ki approximately 4 microM), suggesting close communication between the polymerase and exonuclease sites.