Kinetics of base misinsertion by DNA polymerase I of Escherichia coli

Fidelity, mismatch extension, and proofreading activity of the Plasmodium falciparum apicoplast DNA polymerase

Plasmodium falciparum, a parasitic organism and one of the causative agents of malaria, contains an unusual organelle called the apicoplast. The apicoplast is a nonphotosynthetic plastid responsible for supplying the parasite with isoprenoid units and is therefore indispensable. Like mitochondria and the chloroplast, the apicoplast contains its own genome and harbors the enzymes responsible for its replication. In this report, we determine the relative probabilities of nucleotide misincorporation by the apicoplast polymerase (apPOL), examine the kinetics and sequence dependence of mismatch extension, and determine the rates of mismatch removal by the 3' to 5' proofreading activity of the DNA polymerase. While the intrinsic polymerase fidelity varies by >50-fold for the 12 possible nucleotide misincorporations, the most dominant selection step for overall polymerase fidelity is conducted at the level of mismatch extension, which varies by >350-fold. The efficiency of mismatch extension depends on both the nature of the DNA mismatch and the templating base. The proofreading activity of the 12 possible mismatches varies <3-fold. The data for these three determinants of polymerase-induced mutations indicate that the overall mutation frequency of apPOL is highly dependent on both the intrinsic fidelity of the polymerase and the identity of the template surrounding the potential mismatch.

The effect of tautomeric constant on the specificity of nucleotide incorporation during DNA replication: support for the rare tautomer hypothesis of substitution mutagenesis

The nucleoside analogue dP (6-(2-deoxy-beta-D-ribofuranosyl)-3,4-dihydro-6H,8H-pyrimido[4,5-c][1,2]oxazin-2-one) displays ambivalent hydrogen bonding characteristics whereby the imino tautomer of P can base-pair with adenine and its amino tautomer can base-pair with guanine. Fixed imino and amino tautomers of 6-methyl-3,4-dihydro-6H,8H-pyrimido[4,5-c][1,2]oxazin-2-one (N-methyl P) have been synthesised and their structures obtained by X-ray crystallography. The tautomeric constant of N-methyl P has been calculated from pK(a) values of the fixed tautomers and the kinetic parameters for the incorporation of its 5'-triphosphate (dPTP) by exonuclease-free Klenow fragment of DNA polymerase I have been determined. A strong correlation between the tautomeric constant and the incorporation specificity of dPTP is found. These results lend support to the proposal that the minor tautomeric forms of the natural bases may play an important role in substitution mutagenesis during DNA replication. Furthermore, they imply that DNA polymerases impose specific steric requirements on the base-pair during nucleotide incorporation.

Base mismatches and mutagenesis: how important is tautomerism?

Tautomerism of nucleotides is an attractive model to explain transitional mutations; the structure of the mismatched base pairs in their enol or imino forms do not distort the DNA double helix. However recent structural data suggest that the mismatched nucleotides are in their normal keto and amino forms. 'Wobble' and other base pairings (for transversions) have C1'-C1' distances close to those found in the classical Watson-Crick base pairs. Kinetic studies show substrates are in their major tautomeric forms in their transition states. This suggests tautomerism may not be important for substitution mutations.

Purification and properties of DNA polymerase from Bacillus caldotenax

A thermostable DNA polymerase was prepared from Bacillus caldotenax by using a four-step chromatography procedure. The protein exists as a monomer of M(r) 94,000, has a pI of 4.9 and has no associated 3'-5' or 5'-3'-exonuclease activities or endonuclease activity. The temperature optimum of the enzyme was about 70 degrees C and the pH for maximum activity was about 7.5. The enzyme has an absolute requirement for a bivalent cation, and maximum activity was obtained at the unusually high concentration of 70 mM-MgCl2. Mg2+ could be replaced by MnCl2 or CoCl2, with decreased activity, at the lower optimal concentrations of 1 mM and 2.5 mM respectively. Enzyme activity was inhibited in the presence of 2',3'-dideoxy-TTP, arabinosyl-CTP and aphidicolin. Enzyme activity was stimulated with KCl concentrations of about 100 mM, and concentrations of univalent salts above about 150 mM inhibited activity. The enzyme could use activated calf thymus DNA, poly(dA).p(dT)10 or primed single-stranded phage M13 DNA as a template and maximum activity was obtained with poly(dA).p(dT)10. The enzyme was inactive on unprimed single-stranded DNA, double-stranded DNA and polyribonucleotide template/primer. The apparent Km values for individual dNTPs, determined with the other dNTPs at saturating concentrations, were 5.7 microM (dCTP), 6.3 microM (dATP, dGTP) and 6.4 microM (dTTP). The Km value for the overall incorporation of each dNTP from an equimolar mixture of all four dNTPs was 24.7 microM. The kcat. value was about 1.05 s-1. The kcat./Km value was 0.16-0.18 M-1.s-1 for individual dNTPs and 0.04 for the incorporation of an equimolar mixture of all four dNTPs. Some of the properties of the enzyme show it may be classified as an alpha-Type DNA polymerase.

RNA virus populations as quasispecies

RNA virus mutation frequencies generally approach maximum tolerable levels, and create complex indeterminate quasispecies populations in infected hosts. This usually favors extreme rates of evolution, although periods of relative stasis or equilibrium, punctuated by rapid change may also occur (as for other life forms). Because complex quasispecies populations of RNA viruses arise probabilistically and differentially in every host, their compositions and exact roles in disease pathogenesis are indeterminate and their directions of evolution, and the nature and timing of "new" virus outbreaks are unpredictable.

Mechanisms of spontaneous mutation in DNA repair-proficient Escherichia coli

This paper describes the DNA sequence analysis of 729 independent spontaneous lacI- mutations. This total is comprised of 478 novel mutations and 251 previously described events, and therefore should allow a more comprehensive view of spontaneous mutation in Escherichia coli. The spectrum is dominated by a hotspot (71% of all events). Mutations at this site consist of related addition and deletion events involving a number of repetitive sequences. Here we discuss how the frequency and proportion of these events vary in different DNA repair-deficient genetic backgrounds. The distribution of non-hotspot events includes base substitutions (38%), deletions (35%), frameshifts (14%), duplications (4%) and insertion elements (4%). G:C----A:T events dominate among base substitutions, while G:C----C:G events are the least common; the remaining types of base substitution are equally represented. Among deletions, a significant number do not display repeated sequences at their endpoints (26/72). However, almost all multiply recovered events (15/17) possess repeated sequences capable of accounting for the deletion endpoints. Similarly, over half of all duplications recovered (5/7) display repeated endpoints. Single-base frameshifts are equally divided between A:T and G:C sites, in each case (-) 1 events occur 3-fold more frequently that (+) 1 events. A comparative analysis of each mutational class recovered to lacI- spectra available in a variety of DNA repair/metabolism-deficient strains is presented here in an attempt to assess possible contributions from chemical, physical and enzymic sources of damage.

Why do O6-alkylguanine and O4-alkylthymine miscode? The relationship between the structure of DNA containing O6-alkylguanine and O4-alkylthymine and the mutagenic properties of these bases

The carcinogenic and mutagenic N-nitroso compounds produce GC to AT and TA to GC transition mutations because they alkylate O6 of guanine and O4 of thymine. It has been generally assumed that these mutations occur because O6-alkylguanine forms a stable mispair with thymine and O4-alkylthymine forms a mispair with guanine. Recent studies have shown that this view is mistaken and that the alkylG.T and alkylT.G mispairs are not more stable than their alkylG.C or alkylT.A counterparts. Two possible explanations based on recent structural studies are put forward to account for the miscoding. The first possibility is that the DNA polymerase might mistake O6-alkylguanine for adenine, and O4-alkylthymine for cytosine, because of the physical similarity of these bases. O6-Methylguanine and adenine are similarly lipophilic and X-ray crystallography of the nucleosides has shown a close similarity in bond angles and lengths between O6-methylguanine and adenine, and between O4-methylthymine and cytosine. The second possible explanation is that the important factor in the miscoding is that the alkylG.T and alkylT.G mispairs retain the Watson-Crick alignment with N1 of the purine juxtaposed to N3 of the pyrimidine while the alkylG.C and alkylT.A pairs adopt a wobble conformation. 31P NMR of DNA duplexes show that the phosphodiester links both 3' and 5' to the C have to be distorted to accommodate the O6-ethylguanine:C pair, whereas there is less distortion of the phosphodiesters 3' and 5' to the T in an ethylG.T pair. Recent kinetic measurements show that the essential aspect of base selection in DNA synthesis is the ease of formation of the phosphodiester links on both the 3' and 5' side of the incoming base. The Watson-Crick alignment of the alkylG.T and alkylT.G mispairs may facilitate formation of these phosphodiester links, and this alignment rather than the strength of the base pairs and the extent of hydrogen bonding between them may be the crucial factor in the miscoding. If either hypothesis is correct it suggests that previously too much emphasis has been placed on the stability of the normal pairs in the replication of DNA.

A.T----C.G transversions and their prevention by the Escherichia coli mutT and mutHLS pathways

Escherichia coli mutT strains are strong mutators yielding only A.T----C.G transversion mutations. These are thought to result from uncorrected (or unprevented) A.G mispairings during DNA replication. We have investigated the interaction of mutT-induced replication errors with the mutHLS-encoded postreplicative mismatch repair system. By measuring mutation frequencies in both forward and reversion systems, we have demonstrated that mutTmutL and mutTmutS double mutators produce no more mutants than expected from simple additivity of the frequencies in the single mutators. We conclude that mutT-induced A.G replication errors are not recognized by the MutHLS system. On the other hand, direct measurements of mismatch repair by transfection of bacteriophage M13mp2 heteroduplex DNA as well as mutational data from strains other than muT, indicate that the MutHLS system can repair at least certain A.G mispairs. We suggest that A.G mispairs may exist in several different conformations, some of which are recognized by the MutHLS system. However, the A.G mispairs normally prevented by the mutT function are refractory to mismatch repair, indicating that they may represent a structurally distinct class.

Mispair formation in DNA can involve rare tautomeric forms in the template

The formation of pyridine-pyrimidine- and pyrimidine-pyrimidine base pairs after in vitro DNA replication with the large fragment of Escherichia coli DNA polymerase I indicates that Watson-Crick-like base pairing between pyrimidine bases can occur in the enzyme due to the presence of the rare tautomers of deoxycytidylate and thymidylate in the template strand. The implications to mispair formation in DNA, such as the difference between the structures of the mispairs during and after replication, are discussed and the possible action of mutagenic DNA protonating and deprotonating agents in vivo is considered.

Ribosomal binding and dipeptide formation by misacylated tRNA(Phe),S

Eight structurally modified peptidyl-tRNA(Phe),s were employed to study P-site binding and peptide bond formation in a cell-free system involving Escherichia coli ribosomes programmed with poly(uridylic acid). It was found that the two analogues (N-acetyl-D-phenylalanyl-tRNA(Phe) and N-acetyl-D-tyrosyl-tRNA(Phe] containing D-amino acids functioned poorly as donors in the peptidyltransferase reaction and that two N-acetyl-L-phenylalanyl-tRNA(Phe)'s differing from the prototype substrate in that they contained 2'- or 3'-deoxyadenosine at the 3'-terminus failed to form dipeptide at all when L-phenylalanyl-tRNA(Phe) was the acceptor tRNA. Interestingly, all four of these peptidyl-tRNA's bound to ribosomes to about the same extent as tRNA's that functioned normally as donors in the peptidyltransferase reaction, at least in the absence of competing peptidyl-tRNA species. Two peptidyl-tRNA's lacking an amino group were also tested. In comparison with N-acetyl-L-phenylalanyl-tRNA(Phe) it was found that trans-cinnamyl-tRNA(Phe) and 3-phenylpropionyl-tRNA(Phe)'s formed dipeptides to the extent of 53 and 80%, respectively, when L-phenylalanyl-tRNA(Phe)was used as the acceptor tRNA. N-Acetyl-beta-phenylalanyl-tRNA(Phe) was found to be the most efficient donor substrate studied. Both isomers transferred N-acetyl-beta-phenylalanine to L-phenylalanyl-tRNA(Phe); the nature of the dipeptides formed in each case was verified by HPLC in comparison with authentic synthetic samples. Further, the rate and extent of peptide bond formation in each case exceeded that observed with the control tRNA, N-acetyl-L-phenylalanyl-tRNA(Phe).

The fidelity of base selection by the polymerase subunit of DNA polymerase III holoenzyme

In common with other DNA polymerases, DNA polymerase III holoenzyme of E. coli selects the biologically correct base pair with remarkable accuracy. DNA polymerase III is particularly useful for mechanistic studies because the polymerase and editing activities reside on separate subunits. To investigate the biochemical mechanism for base insertion fidelity, we have used a gel electrophoresis assay to measure kinetic parameters for the incorporation of correct and incorrect nucleotides by the polymerase (alpha) subunit of DNA polymerase III. As judged by this assay, base selection contributes a factor of roughly 10(4)-10(5) to the overall fidelity of genome duplication. The accuracy of base selection is determined mainly by the differential KM of the enzyme for correct vs. incorrect deoxynucleoside triphosphate. The misinsertion of G opposite template A is relatively efficient, comparable to that found for G opposite T. Based on a variety of other work, the G:A pair may require a special correction mechanism, possibly because of a syn-anti pairing approximating Watson-Crick geometry. We suggest that precise recognition of the equivalent geometry of the Watson-Crick base pairs may be the most critical feature for base selection.

Influence of divalent metal activator on the specificity of misincorporation during DNA synthesis catalyzed by DNA polymerase I of Escherichia coli

To test whether the identity of divalent metal activator affects the specificity of misincorporation during polymerization catalyzed by E. coli DNA polymerase I, we carried out the following procedure. A series of oligonucleotide primers, annealed at different positions along the lacZ region of bacteriophage M13mp9 DNA, were elongated in the presence of 3 of the 4 deoxynucleoside 5'-triphosphates (dNTPs) until one or a few misincorporations occurred in each elongated primer. The elongated primers (containing deoxynucleotide residues that had been misincorporated in the presence of either Mg2+ or Mn2+) were then isolated and sequenced by the 'dideoxy' chain termination method to determine the identity of deoxynucleoside monophosphates (dNMPs) that had been misincorporated at different template positions during the original 'minus' reactions, activated by Mg2+ or Mn2+. The results obtained by this approach revealed that both the type of misincorporation and the effect of substituting Mn2+ for Mg2+ depended on the nucleotide sequence of the template. At 40% of the template positions at which misincorporation was compared with both metal ions (8 out of 20), the identity of mispairs differed significantly for synthesis activated by Mn2+ versus Mg2+. Of these 8 sites, 4 exhibited increased transversions in the presence of Mn2+, while 4 exhibited decreased transversions with Mn2+.

Mechanism of DNA polymerase I: exonuclease/polymerase activity switch and DNA sequence dependence of pyrophosphorolysis and misincorporation reactions

Mechanistic features of several processes involved in the idling-turnover reaction catalyzed by the large (Klenow) fragment of Escherichia coli DNA polymerase I have been established. The exonuclease----polymerase activity switch involved in the excision/incorporation mode of idling-turnover occurs without an intervening dissociation of the enzyme from its DNA substrate. Comparative studies on the pyrophosphorolysis kinetics of related DNA substrates indicate a significant dependence of the reaction rate upon the DNA sequence within the duplex region upstream of the primer-template junction. Finally, a gel electrophoretic analysis of the products of the idling-turnover reaction has provided direct evidence for an alternative DNA sequence-dependent misincorporation/excision pathway.

Mnemonic aspects of Escherichia coli DNA polymerase I. Interaction with one template influences the next interaction with another template

When Escherichia coli DNA polymerase I (Pol I) replicates a homopolymer, the excision/polymerization (exo/pol) ratio varies with enzyme and initiator concentration. The study of this effect in the case of poly(dA).oligo(dT) replication led us to propose a mnemonic model for Pol I, in which the 3' to 5' excision activity warms up when the enzyme is actively polymerizing, and cools down when it dissociates from the template. The model predicts that the exo/pol ratio must increase with processivity length and initiator concentration and decrease with enzyme concentration. It predicts also that contact of the enzyme with one template alters its excision efficiency towards another template. The exo/pol ratio and processivities of Pol I and its Klenow fragment were studied on four templates: poly(dA).(dT)10, poly(dT).(dA)10, poly(dC).(dG)10 and poly(dI).(dC)10. We show that the Klenow fragment is usually much less processive than Pol I and when this is the case it has a much lower exo/pol ratio. At equal processivity, the exo/pol ratios are nearly equal. Furthermore, many factors that influence processivity length (e.g. manganese versus magnesium, inorganic pyrophosphate, ionic strength) influence the exo/pol ratio in the same direction. The study of deaminated poly(dC) replication, where we followed incorporation and excision of both G and A residues, allowed us to assign the origin of the dNMP variations to changes in the 3' to 5' proof-reading activity of Pol I. Similarly, the lower dNMP turnover of the Klenow fragment observed with deaminated poly(dC) was specifically assigned to a decreased 3' to 5' exonuclease activity. The exo/pol ratio generally increased with initiator and decreased with enzyme concentration, in agreement with the model, except for poly(dI).oligo(dC), where it decreased with initiator concentration. However, by terminating chain elongation with dideoxy CTP, we showed directly that, even in this system, excision is relatively inefficient at the beginning of synthesis. Interaction of Pol I with poly(dA).(dT) or with poly(dC).(dG) modifies its exo/pol characteristics in the replication of poly(dI).(dC) and poly(dA).(dT), respectively. The Klenow enzyme is not sensitive to such influences and this correlates with its reduced processivity on the influencing templates. Our results reveal the existence of differences between Pol I and its Klenow fragment that are more profound than has been thought previously.(ABSTRACT TRUNCATED AT 400 WORDS)

Mutations induced by DNA polymerase alpha upon in vitro replication of M13mp8(+) DNA

The forward mutation of the lacZ part of the bacteriophage M13mp8 has been used to study the fidelity of the 9S DNA polymerase alpha from calf thymus during in vitro replication of single-stranded DNA. Errors leading to a loss of alpha-complementation were identified by DNA sequencing. The overall mutation rate of the lacZ target sequence was in the range of 1:300-1:1000 which is more than one order of magnitude higher than the spontaneous mutation rate. In a mutL host the mutation rate was nearly threefold higher as compared to the wildtype host. Base substitutions comprise 86% of the errors whereas base deletions amount to 12%. The addition of a base was detected only in one mutant out of 71 sequenced ones. The frameshift mutations occurred predominantly in runs of the same base. The frequencies of individual base substitution are in the order of 2 X 10(-4)-4 X 10(-4) for most of the mismatches. Mutations involving dCTP:T and dGTP:T mismatches are observed with a lower frequency, those involving dTTP:C mismatches with a higher frequency.

Mechanism of the idling-turnover reaction of the large (Klenow) fragment of Escherichia coli DNA polymerase I

The mechanism of the idling-turnover reaction catalyzed by the large (Klenow) fragment of Escherichia coli DNA polymerase I has been investigated. The reaction cycle involved is one of excision/incorporation, in which the 3' deoxynucleotide residue of the primer DNA strand is partitioned into its 5'-mono- and 5'-triphosphate derivatives, respectively. Mechanistic studies suggest the 5'-monophosphate product is formed in the first step by simple 3'----5' exonucleolytic cleavage. Rapid polymerization follows with the concomitant release of inorganic pyrophosphate. In the second step, the 5'-triphosphate product is generated by a pyrophosphorolysis reaction, which, despite the low concentration of pyrophosphate that has accumulated, occurs at a rate that is comparable with that of the parallel 3'----5' hydrolysis reaction.

G . T base-pairs in a DNA helix: the crystal structure of d(G-G-G-G-T-C-C-C)

The synthetic deoxyoctanucleotide d(G-G-G-G-T-C-C-C) crystallizes as an A-type DNA double helix containing two adjacent G . T base-pair mismatches. The structure has been refined to an R-factor of 14% at 2.1 A resolution with 104 solvent molecules located. The two G . T mismatches adopt the "wobble" form of base-pairing. The mismatched bases are linked by a network of water molecules interacting with the exposed functional groups in both the major and minor grooves. The presence of two mispaired bases in the octamer has surprisingly little effect on the global structure of the helix or the backbone and glycosidic torsional angles. Base stacking around the mismatch is perturbed, but the central G-T step shows particularly good base overlap, which may contribute to the relatively high stability of this oligomer.

On the fidelity of DNA replication: manganese mutagenesis in vitro

Manganese is mutagenic in vivo and in vitro in studies with a variety of enzymes and templates. Using Escherichia coli DNA polymerase I with poly[d(A-T)] and phi X174 DNA templates, we analyzed the mechanism of manganese mutagenesis by determining the dependence of error rate on free Mn2+ concentration and comparing this to measured dissociation constants of Mn2+ from enzyme, template, and deoxynucleoside triphosphate substrates. This comparison suggests several conclusions: (1) At very low Mn2+ concentrations, the enzyme is activated at high fidelity. Thus, it is unlikely that activation with manganese per se significantly alters the conformation of the enzyme so as to affect nucleotide selection. (2) At low free Mn2+ concentrations (less than 100 microM), manganese causes errors in incorporation via its interaction with the DNA template. The concentration dependence of mutagenesis is determined by the strength of binding Mn2+ to the particular DNA template used. The data do not allow one to rule out the possibility that Mn2+-deoxynucleoside triphosphate interactions contribute to mutagenesis in selected situations. This range of free Mn2+ concentrations is the one of greatest relevance for in vivo mutagenesis. (3) At higher concentrations (between 500 microM and 1.5 mM), further mutagenesis by Mn2+ occurs. This mutagenesis probably is due either to binding of manganese to single-stranded regions within the DNA or to weak accessory sites on the enzyme.

Structural studies of DNA fragments: the G.T wobble base pair in A, B and Z DNA; the G.A base pair in B-DNA

The crystal structures of five double helical DNA fragments containing non-Watson-Crick complementary base pairs are reviewed. They comprise four fragments containing G.T base pairs: two deoxyoctamers d(GGGGCTCC) and d(GGGGTCCC) which crystallise as A type helices; a deoxydodecamer d(CGCGAATTTGCG) which crystallises in the B-DNA conformation; and the deoxyhexamer d(TGCGCG), which crystallises as a Z-DNA helix. In all four duplexes the G and T bases form wobble base pairs, with bases in the major tautomer forms and hydrogen bonds linking N1 of G with O2 of T and O6 of G with N3 of T. The X-ray analyses establish that the G.T wobble base pair can be accommodated in the A, B or Z double helix with minimal distortion of the global conformation. There are, however, changes in base stacking in the neighbourhood of the mismatched bases. The fifth structure, d(CGCGAATTAGCG), contains the purine purine mismatch G.A where G is in the anti and A in the syn conformation. The results represent the first direct structure determinations of base pair mismatches in DNA fragments and are discussed in relation to the fidelity of replication and mismatch recognition.

On the fidelity of DNA polymerase alpha: the influence of alpha-thio dNTPs, Mn2+ and mismatch repair

The phi X174am16 revertant system has been used to investigate the influence of alpha-thio-dNTPs and of Mn2+ on the fidelity of the 9S DNA polymerase alpha from calf thymus. Upon substituting dGTP by alpha-thio-dGTP during the in vitro replication, a nearly tenfold decrease in the frequency of G:G and G:T mispairs is observed. The formation of all other mispairs is not changed in the presence of the corresponding alpha-thio-dNTP. Mn2+ at concentrations of 0.5 mM does not influence the frequencies of the mispairs. The expression rate of errors formed during in vitro replication in the (-) strand has been determined for all mispairs detectable in the phi Xam16 system. The (-) strand expression of G:T, T:T and C:T mismatches is about 50%, whereas for A:G, G:G and C:A mismatches it is clearly below 50%. We conclude that the different base-base mismatches are repaired with different efficiencies.

Abasic sites from cytosine as termination signals for DNA synthesis

DNA with abasic sites has been prepared by deamination of cytosine followed by treatment of the product with uracil N-glycosylase. Termination in vitro on such templates does not occur until treatment with uracil N-glycosylase. DNA terminated one base before abasic sites created from C's has been used as a template in "second stage" reactions. With enzymes devoid or deficient in 3' greater than 5' exonuclease activity purines, particularly adenine, are preferentially added opposite the putative abasic site. 2-Aminopurine behaves more like adenine than like guanine in these experiments. Polymerase beta preferentially incorporates A opposite abasic sites produced from T, and G opposite abasic sites produced from C. We have eliminated an obvious artefact (e.g. strand switching) which might account for this observation.

High-resolution structure of a DNA helix containing mismatched base pairs

The concept of complementary base pairing, integral to the double-helical structure of DNA, provides an effective and elegant mechanism for the faithful transmission of genetic information. Implicit in this model, however, is the potential for incorporating non-complementary base pairs (mismatches) during replication or subsequently, for example, during genetic recombination. As such errors are usually damaging to the organism, they are generally detected and repaired. Occasionally, however, the propagation of erroneous copies of the genome confers a selective advantage, leading to genetic variation and evolutionary change. An understanding of the nature of base-pair mismatches at a molecular level, and the effect of incorporation of such errors on the secondary structure of DNA is thus of fundamental importance. We now report the first single-crystal X-ray analysis of a DNA fragment, d(GGGGCTCC), which contains two non-complementary G X T base pairs, and discuss the implications of the results for the in vivo recognition of base-pair mismatches.

Alteration of the DNA double helix conformation upon incorporation of mispairs as revealed by energy computations and pathways of point mutations

To explain biochemical and genetic data on spontaneous nucleotide replacements in nucleic acid biosynthesis all the 8 mispairs in normal tautomeric forms have been considered. Possible B-conformations of DNA fragments containing each of such mispairs incorporated between Watson-Crick pairs have been found using computations of the energy of non-bonded interactions via classical potential functions. These conformations have no reduced interatomic contacts. The values of each dihedral angle of the sugar-phosphate backbone fall within the limits of those of double-helical fragments of B-DNA in crystals. These values differ from those of the corresponding angles for the low-energy polynucleotide conformations consisting of canonical pairs by no more than 30 degrees (except for the fragment with the U:U pair for which the C4'-C3'-O-P angle differs by about 50 degrees). The difference in experimentally observed frequencies of various nucleotide replacements in DNA biosynthesis correlates with the difference in the energy of non-bonded interactions and with the extent of the sugar-phosphate backbone distortion for the fragments containing the mispairs which serve as intermediates for the replacements.

Molecular mechanisms of manganese mutagenesis

The mechanism by which DNA polymerase discriminates between complementary and noncomplementary nucleotides for insertion into a primer terminus has been investigated. Apparent kinetic constants for the insertion of dGTP and dATP into the hook polymer d(C)194-d(G)12 with Escherichia coli DNA polymerase I (large fragment) were determined. The results suggest that the high specificity of base selection by DNA polymerase I is achieved by utilization of both Km and Vmax differences between complementary and noncomplementary nucleotides. The molecular basis for the increased error frequency observed with DNA polymerase I in the presence of Mn2+ has also been investigated. Our studies demonstrate that when Mn2+ is substituted for Mg2+, there is a higher ratio of insertion of incorrect to correct dNTP by the polymerase activity, accompanied by a decreased hydrolysis of a mismatched dNMP relative to a matched dNMP at the primer terminus by the 3',5' exonuclease activity. Kinetic analysis revealed that in the presence of Mn2+, the kcat for insertion of a complementary dNTP is reduced, whereas the catalytic rate for the insertion of a mismatched nucleotide is increased. The apparent Km values for either complementary or noncomplementary nucleotide substrates are not significantly altered when Mg2+ is replaced by Mn2+. The rate of hydrolysis of a mismatched dNMP at the primer terminus is greater in the presence of Mg2+ vs. Mn2+, whereas the rate of hydrolysis of a properly base-paired terminal nucleotide is greater in Mn2+ vs. Mg2+. These studies demonstrate that both the accuracy of base selection by the polymerase activity and the specificity of hydrolysis by the 3',5' exonuclease activity are altered by the substitution of Mn2+ for Mg2+.

Contribution of 3' leads to 5' exonuclease activity of DNA polymerase III holoenzyme from Escherichia coli to specificity

The effects of deoxynucleoside monophosphates on the 3' leads to 5' exonuclease activity of DNA polymerase III holoenzyme have been correlated with their effects on the fidelity of DNA replication. In particular, dGMP inhibits the proofreading activity of the enzyme and decreases the fidelity in those cases where a "following nucleotide effect" is also noted. This is strong evidence for proofreading. However, the absence of the effects of proofreading inhibitors or following nucleotides need not be evidence against the occurrence of proofreading: a theoretical analysis shows that these effects may not be observed even though there is active proofreading. This is suggested to be the case with the phage T4 enzyme system. The proofreading activity of Pol III appears to be directed primarily towards removing purine x pyrimidine-mediated rather than purine x purine-mediated misincorporations. recA protein inhibits the proofreading activity of Pol III on synthetic templates containing mismatched 3' termini. This is paralleled by a decrease in the fidelity of DNA replication in vitro. The inhibition is increased in the presence of dGMP or dAMP but there is no further increase in the infidelity of replication. The presence of both dNMPs and recA protein does not enable Pol III to copy past pyrimidine photodimers.