Purification and properties of wild-type and exonuclease-deficient DNA polymerase II from Escherichia coli

Wild-type DNA polymerase II (pol II) and an exonuclease-deficient pol II mutant (D155A/E157A) have been overexpressed and purified in high yield from Escherichia coli. Wild-type pol II exhibits a high proofreading 3'-exonuclease to polymerase ratio, similar in magnitude to that observed for bacteriophage T4 DNA polymerase. While copying a 250-nucleotide region of the lacZ alpha gene, the fidelity of wild-type pol II is high, with error rates for single-base substitution and frameshift errors being < or = 10(-6). In contrast, the pol II exonuclease-deficient mutant generated a variety of base substitution and single base frameshift errors, as well as deletions between both perfect and imperfect directly repeated sequences separated by a few to hundreds of nucleotides. Error rates for the pol II exonuclease-deficient mutant were from > or = 13- to > or = 240-fold higher than for wild-type pol II, depending on the type of error considered. These data suggest that from 90 to > 99% of base substitutions, frameshifts, and large deletions are efficiently proofread by the enzyme. The results of these experiments together with recent in vivo studies suggest an important role for pol II in the fidelity of DNA synthesis in cells.

Gel kinetic analysis of DNA polymerase fidelity in the presence of proofreading using bacteriophage T4 DNA polymerase

A gel fidelity assay, previously used in the analysis of DNA polymerases having no associated 3' to 5' exonuclease activity, has been generalized for use with polymerases that contain exonucleolytic proofreading. The main purpose of this study was the development of a general analysis, using a standard Markov model, to convert experimentally observed DNA primer gel bands arising from insertion and proofreading of right and wrong deoxyribonucleotides, into nucleotide incorporation velocities and, most importantly, fidelities. The model has been applied primarily to an analysis of polymerase kinetics and fidelity in the presence of a next correct rescue dNTP, but the model can be conveniently modified to investigate other experimental designs. In the presence of rescue dNTP, direct competition occurs between excision or extension of a mismatch. At concentrations of rescue dNTP sufficient to suppress the gel band intensity at the mismatch target site, nucleotide incorporation and misincorporation rates can be obtained from the ratios of gel band intensities 3' (downstream) and 5' (upstream) to the target site, measured as a function dNTP concentration for "wrong" and "right" dNTP substrates. The polymerase misincorporation efficiency, in the presence of proofreading, is given by the ratio of wrong to right incorporation efficiencies, Vmax/Km, obtained from the gel band ratios. The bacteriophage T4 polymerase with a highly active 3'-exonuclease activity was used to illustrate the assay. Nucleotide misincorporation efficiencies measured at several template sites were dCMP.A approximately equal to 10(-6), dGMP.A approximately equal to 10(-5), dTMP.T approximately equal to 2 x 10(-4), and dAMP.A < 10(-7). Proofreading of the dGMP.A mispair was suppressed by about 3-fold in the presence of high concentrations of next correct "rescue" dNTP causing a concomitant reduction in the fidelity of dGMP.A to about 3 x 10(-5).

Enthalpy-entropy compensation in DNA melting thermodynamics

We investigate enthalpy-entropy compensation for melting of nearest-neighbor doublets in DNA. Based on data for 10 normal doublets and for doublets containing a mispaired or analog base, the correlation of delta Szero with delta Hzero follows a rectangular hyperbola. Doublet melting temperature relates linearly to delta Hzero by Tm = T(o) + delta Hzero/a, where T(o) = 273 K and a = 80 cal/mol-K. Thus Tm is proportional to delta Hzero + aTo rather than to delta Hzero alone as previously thought by assuming delta Szero to be constant. The term aTo = 21.8 kcal/mol may reflect a constant enthalpy change in solvent accompanying the DNA enthalpy change for doublet melting and is roughly equivalent to breaking four H-bonds between water molecules for each melted doublet. The solvent entropy change (aTo/Tm) declines with increasing Tm, while the DNA entropy change (delta Hzero/Tm) rises, so the combined DNA + solvent entropy change stays constant at 80 cal/K/mol of doublet. If such constancy in DNA + solvent entropy changes also holds for enzyme clefts as "solvent," then free energy differences for competing correct and incorrect base pairs in polymerase clefts may be as large as enthalpy differences and possibly sufficient to account for DNA polymerase accuracy. The hyperbolic relationship between delta Szero and delta Hzero observed in 1 M salt can be used to evaluate delta Hzero and delta Szero from Tm at lower, physiologically relevant, salt concentrations.

Analysis of mutational changes at the HLA locus in single human sperm

Using a simple and efficient single sperm PCR and direct sequencing method, we screened for HLA-DPB1 gene mutations that may give rise to new alleles at this highly polymorphic locus. More than 800 single sperm were studied from a heterozygous individual whose two alleles carried 16 nucleotide sequence differences clustered in six polymorphic regions. A potential microgene conversion event was detected. Unrepaired heteroduplex DNA similar to that which gives rise to postmeiotic segregation events in yeast was observed in three cases. Control experiments also revealed unusual sperm from DPB1 homozygous individuals. The data may help explain allelic diversity in the MHC and suggest that a possible source of human mosaicism may be incomplete DNA mismatch repair during gametogenesis.

Involvement of Escherichia coli DNA polymerase II in response to oxidative damage and adaptive mutation

DNA polymerase II (Pol II) is regulated as part of the SOS response to DNA damage in Escherichia coli. We examined the participation of Pol II in the response to oxidative damage, adaptive mutation, and recombination. Cells lacking Pol II activity (polB delta 1 mutants) exhibited 5- to 10-fold-greater sensitivity to mode 1 killing by H2O2 compared with isogenic polB+ cells. Survival decreased by about 15-fold when polB mutants containing defective superoxide dismutase genes, sodA and sodB, were compared with polB+ sodA sodB mutants. Resistance to peroxide killing was restored following P1 transduction of polB cells to polB+ or by conjugation of polB cells with an F' plasmid carrying a copy of polB+. The rate at which Lac+ mutations arose in Lac- cells subjected to selection for lactose utilization, a phenomenon known as adaptive mutation, was increased threefold in polB backgrounds and returned to wild-type rates when polB cells were transduced to polB+. Following multiple passages of polB cells or prolonged starvation, a progressive loss of sensitivity to killing by peroxide was observed, suggesting that second-site suppressor mutations may be occurring with relatively high frequencies. The presence of suppressor mutations may account for the apparent lack of a mutant phenotype in earlier studies. A well-established polB strain, a dinA Mu d(Apr lac) fusion (GW1010), exhibited wild-type (Pol II+) sensitivity to killing by peroxide, consistent with the accumulation of second-site suppressor mutations. A high titer anti-Pol II polyclonal antibody was used to screen for the presence of Pol II in other bacteria and in the yeast Saccharomyces cerevisiae. Cross-reacting material was found in all gram-negative strains tested but was not detected in gram-positive strains or in S. cerevisiae. Induction of Pol II by nalidixic acid was observed in E. coli K-12, B, and C, in Shigella flexneri, and in Salmonella typhimurium.

Sequential folding of UmuC by the Hsp70 and Hsp60 chaperone complexes of Escherichia coli

Replication-blocking lesions generate a signal in Escherichia coli that leads to the induction of the multigene SOS response. Among the SOS-induced genes are umuD and umuC, whose products are necessary for the increased mutation rate in induced bacteria. The mutations are likely to result from replication across the DNA lesion, and such a bypass event has been reconstituted in vitro (Rajagopalan, M., L, C., Woodgate, R., O'Donnel, M., Goodman, M. F., Echols, H. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 10777-10781). In this work, we show that the chaperone proteins promote the proper folding of UmuC protein in vitro. We treated purified and inactive UmuC with Hsp70 and Hsp60. After Hsp70 treatment, the DNA binding activity of UmuC was recovered, but the ability to promote replication across DNA lesions was not. However, lesion bypass activity was recovered upon further treatment with Hsp60. The biological significance of such a folding pathway for UmuC protein is strengthened by in vivo evidence for a role of DnaK in UV-induced mutagenesis.

Nucleotide insertion and primer extension at abasic template sites in different sequence contexts

Efficiencies of insertion and extension at a single site-directed abasic lesion, X, were measured while varying 5'- and 3'-template bases adjacent to X. The preference for insertion was found to be A > G > T approximately C, with the "upstream" (3'-neighboring) template base perturbing insertion efficiencies by an order of magnitude or more. Efficiencies of synthesis past the abasic lesion depended strongly on the "downstream" (5'-neighboring) template base and on the properties of the polymerase. HIV-1 RT favored "direct" extension of X.A > X.G > X.T > X.C, by addition of the next correct nucleotide. However, it was found that X.C, least favored for direct extension, was most favored for "misalignment" extension, occurring when the DNA structure in the vicinity of the lesion collapsed to realign a primer 3'-C terminus opposite a downstream template G site. Polymerase properties have an important role in copying abasic lesions. Drosophila DNA polymerase alpha, HIV-1, and AMV reverse transcriptases had "little" difficulty inserting opposite abasic lesions, with efficiencies comparable to misinsertions opposite normal template bases. However, AMV RT did not extent past the lesion using direct or misalignment mechanisms. Wild-type and mutant T4 DNA polymerases were used to show that although exonucleolytic proofreading inhibits lesion bypass, the presence of a highly active proofreading exonuclease is not sufficient to prevent bypass.

Pre-steady-state kinetic analysis of sequence-dependent nucleotide excision by the 3'-exonuclease activity of bacteriophage T4 DNA polymerase

The effects of local DNA sequence on the proofreading efficiency of wild-type T4 DNA polymerase were examined by measuring the kinetics of removal of the fluorescent nucleotide analog 2-aminopurine deoxynucleoside monophosphate (dAPMP) from primer/templates of defined sequences. The effects of (1) interactions with the 5'-neighboring bases, (2) base pair stability, and (3) G.C content of the surrounding sequences on the pre-steady-state kinetics of dAPMP excision were measured. Rates of excision dAPMP from a primer 3'-terminus located opposite a template T (AP.T base pair) increased, over a 3-fold range, with the 5'-neighbor to AP in the order C < G < T < A. Rates of removal of dAPMP from AP.X base pairs located in the same surrounding sequence increased as AP.T < AP.A < AP.C < AP.G, which correlates with the decrease in the stabilities of these base pairs predicted by Tm measurements. A key finding was that AP was excised at a slower rate when mispaired opposite C located next to four G.C base pairs than when correctly paired opposite T next to four A.T base pairs, suggesting that exonuclease mismatch removal specificities may be enhanced to a much greater extent by instabilities of local primer termini than by specific recognition of incorrect base pairs. In polymerase-initiated reactions, biphasic reaction kinetics were observed for the excision of AP within most but not all sequence contexts. Rates of the rapid phases (30-40 s-1) were relatively insensitive to sequence context. Rapid-phase rates reflect the rate constants for exonucleolytic excision of dAPMP from melted primer termini for both correct and incorrect base pairs and were roughly comparable to rates of removal of dAPMP from single-stranded DNA (65-80 s-1). Rates of the slow phases (3-13 s-1) were dependent on sequence context; the slow phase may reflect the rate of switching from the polymerase to the exonuclease active site, or perhaps the conversion of a primer/template terminus from an annealed to a melted state in the exonuclease active site. These data, using wild-type T4 DNA polymerase and two exonuclease-deficient T4 polymerases, support a model in which exonuclease excision occurs on melted primer 3'-termini for both mismatched and correctly matched primer termini, and where specificity favoring removal of terminally mismatched base pairs is determined by the much larger fraction of melted-out primer 3'-termini for mispairs compared to that for correct pairs.

Crystallization of DNA polymerase II from Escherichia coli

DNA polymerase II of Escherichia coli, an alpha-like or group B polymerase, has been crystallized. The crystals are orthorhombic, space group P2(1)2(1)2, with cell dimensions a = 94.4 A, b = 118.2 A, c = 84.2 A and diffract to at least 3.0 A resolution. This is the first example of a group B polymerase to be crystallized.

Kinetics of deoxyribonucleotide insertion and extension at abasic template lesions in different sequence contexts using HIV-1 reverse transcriptase

Deoxyribonucleotide insertion efficiencies were measured opposite site-directed abasic template lesions using human immunodeficiency virus 1 reverse transcriptase (HIV-1RT), and the efficiencies to continue primer synthesis beyond the lesion, by addition of the "next correct" deoxynucleotide, were measured as a function of sequence context. Insertion of purines was favored over pyrimidines, A > G > T approximately C. Primer extension past the lesion occurred by two distinct mechanisms, either by direct or by misalignment extension. An "A-rule" appeared to hold for the case of direct extension, where the abasic template moiety is intrahelical, aligned opposite the primer 3'-terminus. In misalignment extension, the primer terminus is realigned from a site directly opposite the lesion to a new position opposite a neighboring template base 5' to the lesion. Direct extension efficiencies were measured in 16 different configurations, by varying 4 bases at the primer 3'-termini and 4 at the 5'-side (downstream) of the lesion. The predominant order of direct extension was A > G > T approximately C, similar to that observed for insertion. Reduced primer extension rates were not caused by a reduction in HIV-1 RT-DNA binding. Primers terminating in C showed inefficient direct extension, but were readily extended via misaligned configurations. The ratios of direct-to-misalignment extension efficiencies were 27:1, 2.5:1, and 1:25 for A, G, and C opposite the lesion, respectively. For the case of primers terminating in T, misalignment extension was not observed. A striking result was that while primers were extended past an abasic lesion by HIV-1 RT in both direct and misalignment modes, avian myeloblastosis virus RT failed to catalyze significant extension by either mode.

Influence of 5'-nearest neighbors on the insertion kinetics of the fluorescent nucleotide analog 2-aminopurine by Klenow fragment

The effects of nearest neighbor interactions between a nucleotide base at the primer 3'-terminus and an incoming deoxyribonucleoside triphosphate on DNA polymerase catalyzed insertion were examined. Kinetics of inserting the fluorescent nucleotide analog 2-aminopurine deoxyribonucleotide (dAPMP) and dAMP opposite a template T by 3'-->5' exonuclease-deficient mutants of Klenow fragment (KF-) were measured on primer/templates of identical sequence except for the base pair at the 3'-primer terminus. In addition to its fluorescence properties, 2-aminopurine (AP) is an attractive probe because it is misinserted opposite T by polymerases at much higher frequencies than natural nucleotides. Misinsertion frequencies for AP are on the same order of magnitude as variations in misinsertion frequencies due to changes in local DNA sequence, which makes the statistical significance of these variations easier to document. We have established that changes in the fluorescence of AP can be used to follow the insertion of dAPMP on both steady-state and pre-steady-state time scales. Rates of insertion of dAPMP measured by fluorescence and by a polyacrylamide gel assay were similar and are sensitive to the identity of the base at the 3'-primer twice as fast as insertion following a primer terminus T. The difference in rates arises primarily from differences in kcat values, which were fastest next to G and slowest next to T, while apparent Km values were similar next to each of the 4 different nearest neighbors. The gel assay was used to measure AP misinsertion efficiencies by two methods: (1) by having dAPTP and dATP directly compete for insertion opposite T in the same reaction and (2) by measuring Vmax/Km values for each substrate in separate reactions. The results from the direct competition and separate kinetics measurements are similar. The misinsertion efficiency of dAPMP relative to dAMP opposite a template T was significantly higher next to a 3'-primer terminus G (f(ins) = 0.31 +/- 0.06) than next to T (f(ins) = 0.15 +/- 0.03) for the KF- single mutant (D42A). The corresponding misinsertion efficiencies next to a 3'-primer terminus G and T were 0.20 +/- 0.02 and 0.16, respectively, for the KF- double mutant (D355A, E357A). Relative rates of insertion of dAPMP and dAMP correlate with melting temperatures calculated for nearest neighbor doublets which reflect the relative base-stacking energies. In addition to changes in insertion kinetics, polymerase-DNA dissociation rates varied with the identity of the 3'-primer terminus, differing by as much as 7-20-fold depending on the polymerase and the primer/template.

Effect of a template-located 2',2'-difluorodeoxycytidine on the kinetics and fidelity of base insertion by Klenow (3'-->5'exonuclease-) fragment

Gemcitabine [2',2'-difluorodeoxycytidine (dFdCyd)], a potent antitumor agent, inhibits DNA synthesis and is incorporated internally into DNA. The effect of a template-incorporated dFdCyd molecule (dFdCyd-) on DNA polymerase function was examined. Two 25-base deoxyoligonucleotides were synthesized with either a single dFdCyd- or template-incorporated deoxycytidine molecule (dCyd-) at the same position. Each was annealed separately to an identical complementary 5'-32P-labeled primer and extended by the Klenow fragment (3'-->5' exo-) of DNA polymerase I. "Correct" insertion of dGMP was 80-fold less efficient opposite dFdCyd- than dCyd-. A comparison of misinsertion efficiencies opposite template dFdCyd gave values of 2.7 x 10(-2) for dAMP insertion, 1.1 x 10(-3) for dTMP insertion, and 5.9 x 10(-4) for dCMP insertion. A similar measurement opposite template dC gave values of 1.8 x 10(-4), 1.7 x 10(-4), and 2.9 x 10(-6) for dAMP, dTMP, and dCMP insertion, respectively. Thus, the presence of dFdCyd on the template strand inhibited "normal" DNA synthesis and increased deoxyribonucleotide misinsertion frequencies. Pausing during DNA synthesis occurred directly opposite template dFdCyd suggesting that dFdC.dG base pairs might be less stable than normal dC.dG pairs, resulting in a decreased rate of primer extension beyond this site. Consistent with kinetic data, thermal denaturation measurements using comparable surrounding sequences showed that dFdC.dG "correct" pairs were less stable than dC.dG base pairs. Measurements on base mispairs showed that dFdC.dC was more stable than dC.dC, while no measurable Tm differences were found between polymers containing dFdC.dA and dC.dA or dFdC.dT, and dC.dT.

Ionization of bromouracil and fluorouracil stimulates base mispairing frequencies with guanine

To test whether ionized base pairs influence polymerase-catalyzed misinsertion rates, we measured the efficiency of forming 5-bromouracil (B), 5-fluorouracil (F), and thymine base pairs with guanine and adenine as a function of pH using avian myeloblastosis reverse transcriptase. When B, F, and T were present as dNTP substrates, misincorporation efficiencies opposite G, normalized to incorporation of C opposite G, increased by about 20-, 13-, and 7-fold, respectively, as reaction pH increased from 7.0 to 9.5. Incorporation efficiencies to form the correct base pairs, B.A and F.A, normalized to T.A, decreased by 4- and 8-fold, respectively, with increasing pH. The effects of pH on misincorporation efficiencies were about 10-fold greater when B, F, and T were present as template bases. The relative misincorporation efficiencies of G opposite template B, F, and T, normalized to incorporation of A opposite B, F, and T, increased by about 430-, 370-, and 70-fold, respectively, as pH was increased from 6.5 to 9.5, while correct incorporation of A opposite template B and F decreased about 10-fold over the same pH range. Plots depicting incorrect and correct incorporation efficiencies versus pH were fit to a pH titration equation giving the fraction of ionized base as a function of pH. We conclude that avian myeloblastosis reverse transcriptase forms B.G and F.G mispairs in an ionized Watson-Crick conformation in preference to a neutral wobble structure containing favored keto tautomers of B or F. Although participation of disfavored enol tautomers in enzyme-catalyzed base mispair formation cannot be ruled out, the results are inconsistent with the "standard" disfavored tautomer model of mutagenesis. Instead, the data support a model in which ionization of halouracil bases is primarily responsible for B- and F-induced mutagenesis.

Biochemical basis of DNA replication fidelity

DNA polymerase is the critical enzyme maintaining genetic integrity during DNA replication. Individual steps in the replication process that contribute to DNA synthesis fidelity include nucleotide insertion, exonucleolytic proofreading, and binding to and elongation of matched and mismatched primer termini. Each process has been investigated using polyacrylamide gel electrophoresis (PAGE) to resolve 32P-labeled primer molecules extended by polymerase. We describe how integrated gel band intensities can be used to obtain site-specific velocities for addition of correct and incorrect nucleotides, extending mismatched compared to correctly matched primer termini and measuring polymerase dissociation rates and equilibrium DNA binding constants. The analysis is based on steady-state "single completed hit conditions", where polymerases encounter many DNA molecules but where each DNA encounters an enzyme at most once. Specific topics addressed include nucleotide misinsertion, mismatch extension, exonucleolytic proofreading, single nucleotide discrimination using PCR, promiscuous mismatch extension by HIV-1 and AMV reverse transcriptases, sequence context effects on fidelity and polymerase dissociation, structural and kinetic properties of mispairs relating to fidelity, error avoidance mechanisms, kinetics of copying template lesions, the "A-rule" for insertion at abasic template lesions, an interesting exception to the "A-rule", thermodynamic and kinetic determinants of base pair discrimination by polymerases.

Absence of a role for DNA polymerase II in SOS-induced translesion bypass of phi X174

In order to examine the possible role of Escherichia coli DNA polymerase II in SOS-induced translesion bypass, Weigle reactivation and mutation induction were measured with single-stranded phi X174 transfecting DNA containing individual lesions. No decrease in bypass of thymine glycol or cyclobutane pyrimidine dimers in the absence of DNA polymerase II was observed. Furthermore, DNA polymerase II did not affect bypass of abasic sites when either survival or mutagenesis was the endpoint. Lastly, repair of gapped DNA molecules, intermediates in methyl-directed mismatch repair, was also unaffected by the presence or absence of DNA polymerase II.

Activity of the purified mutagenesis proteins UmuC, UmuD', and RecA in replicative bypass of an abasic DNA lesion by DNA polymerase III

The introduction of a replication-inhibiting lesion into the DNA of Escherichia coli generates the induced, multigene SOS response. One component of the SOS response is a marked increase in mutation rate, dependent on RecA protein and the induced mutagenesis proteins UmuC and UmuD. A variety of previous indirect approaches have indicated that SOS mutagenesis results from replicative bypass of the DNA lesion by DNA polymerase III (pol III) holoenzyme in a reaction mediated by RecA, UmuC, and a processed form of UmuD termed UmuD'. To study the biochemistry of SOS mutagenesis, we have reconstituted replicative bypass with a defined in vitro system containing purified protein and a DNA substrate with a single abasic DNA lesion. The replicative bypass reaction requires pol III, UmuC, UmuD', and RecA. The nonprocessed UmuD protein does not replace UmuD' but inhibits the bypass activity of UmuD', perhaps by sequestering UmuD' in a heterodimer. Our experiments demonstrate directly that the UmuC-UmuD' complex and RecA act to rescue an otherwise stalled pol III holoenzyme at a replication-blocking DNA lesion.

A comparison of the fidelity of copying 5-methylcytosine and cytosine at a defined DNA template site

5-Methylcytosine has been postulated to be an endogenous mutagen in procaryotes and eucaryotes leading to base substitution hot spots, C-->T transitions, resulting from spontaneous deamination of mC to T. The possibility remains, however, that a second mechanism involving mispairing of mC with A might also contribute to base substitution mutagenesis via G-->A transitions. Stimulation of the G-->A mutational pathway could involve preferential misincorporation of dAMP opposite template mC compared to C. To investigate this possibility, we synthesized a sequence containing mC at a defined template location. We compared the fidelity of copying mC versus C and the efficiency of extending mismatched base pairs at the mC position using three DNA polymerases, AMV reverse transcriptase, Drosophila DNA polymerase alpha, and mutant Escherichia coli Klenow fragment containing no proofreading exonuclease activity. Significant differences in misinsertion and mismatch extension efficiencies were observed only for the case of AMV reverse transcriptase. AMV reverse transcriptase was observed to incorporate dAMP 4 to 5-fold more efficiently opposite mC than C. Favored extension of a 5-MeC.A over C.A mispair was also observed with a difference of about 3-fold. In contrast to AMV reverse transcriptase, Klenow fragment showed no significant difference when copying either mC or C sites or when extending mispairs involving mC and C. Incorporation of dAMP opposite either C or mC was barely detectable using pol alpha, although pol alpha has been observed to form A.C mismatches in other sequences. While we cannot completely exclude the possibility that dAMP might be incorporated opposite mC in preference to C, our results suggest that contributions of the G-->A pathway to mC mutagenic hot spots are likely to be minor, lending additional support to the model invoking deamination of mC.

Extension of base mispairs by Taq DNA polymerase: implications for single nucleotide discrimination in PCR

Thermus aquaticus (Taq) DNA polymerase was used to measure the extension efficiency for all configurations of matched and mismatched base pairs at template-primer 3'-termini. The transition mispairs, A(primer).C, C.A, G.T, and T.G were extended 10(-3) to 10(-4)-fold less efficiently than their correctly paired counterparts. Relative efficiencies for extending transversion mispairs were 10(-4) to 10(-5) for T.C and T.T, about 10(-6) for A.A, and less than 10(-6) for G.A, A.G, G.G and C.C. The transversion mispair C(primer).T was extended with high efficiency, about 10(-2) compared to a correct A.T basepair. The unexpected ease of extending the C.T mismatch was not likely to have been caused by primer-template misalignment. Taq polymerase was observed to bind with similar affinities to each of the correctly paired and mispaired primer-template 3'-ends. Thus, the failure of Taq polymerase to extend mismatches efficiently appears to be an intrinsic property of the enzyme and not due to an inability to bind to 3'-terminal mispairs. For almost all of the mispairs, C.T being the exception, Taq polymerase exhibits about 100 to 1000-fold greater discrimination against mismatch extension compared to avian myeloblastosis reverse transcriptase and HIV-1 reverse transcriptase which extend most mismatched basepairs permissively. Relative mismatch extension efficiencies for Taq polymerase were measured at 45 degrees C, 55 degrees C and 70 degrees C and found to be independent of temperature. The mispair extension data should be important in designing experiments using PCR to distinguish between sequences that vary by a single nucleotide.

Canine ovulation timing

The key endocrinologic event in the estrous cycle is the luteinizing hormone (LH) peak, which triggers ovulation and thus determines the fertile period. Although LH is impractical to measure directly, a coincidental rise in progesterone also occurs. The recent advent of in-house canine-specific progesterone assays allows accurate identification of the fertile period of the bitch.

Processive DNA synthesis by DNA polymerase II mediated by DNA polymerase III accessory proteins

An interesting property of the Escherichia coli DNA polymerase II is the stimulation in DNA synthesis mediated by the DNA polymerase III accessory proteins beta,gamma complex. In this paper we have studied the basis for the stimulation in pol II activity and have concluded that these accessory proteins stimulate pol II activity by increasing the processivity of the enzyme between 150- and 600-fold. As is the case with pol III, processive synthesis by pol II requires both beta,gamma complex and SSB protein. Whereas the intrinsic velocity of synthesis by pol II is 20-30 nucleotides per s with or without the accessory proteins, the processivity of pol II is increased from approximately five nucleotides to greater than 1600 nucleotides incorporated per template binding event. The effect of the accessory proteins on the rate of replication is far greater on pol III than on pol II; pol III holoenzyme is able to complete replication of circular single-stranded M13 DNA in less than 20 s, whereas pol II in the presence of the gamma complex and beta requires approximately 5 min. We have investigated the effect of beta,gamma complex proteins on bypass of a site-specific abasic lesion by E. coli DNA polymerases I, II, and III. All three polymerases are extremely inefficient at bypass of the abasic lesion. We find limited bypass by pol I with no change upon addition of accessory proteins. pol II also shows limited bypass of the abasic site, dependent on the presence of beta,gamma complex and SSB. pol III shows no significant bypass of the abasic site with or without beta,gamma complex.

Comparison of HIV-1 and avian myeloblastosis virus reverse transcriptase fidelity on RNA and DNA templates

A comparison of the fidelity of reverse transcriptases (RT) from human immunodeficiency virus (HIV-1) and avian myeloblastosis virus (AMV) is made using RNA and DNA primer-template molecules in vitro. Selected template target sites containing either uracil or thymine are used to measure nucleotide insertion fidelities and to compare the efficiency of extending mismatched nucleotides at primer 3'-termini. HIV-1 reverse transcriptase is observed to incorporate as many as three consecutive mismatches and to continue efficient elongation from mismatched primer 3'-termini without discernible pausing. Nucleotide misinsertion and mispair extension efficiencies are similar for both enzymes on RNA and DNA templates having identical surrounding sequence. HIV-1 and AMV reverse transcriptases form G.T and G.U mismatches most efficiently, between 1.6 x 10(-4) and 7 x 10(-4), and both enzymes extend G.U with exceptionally high efficiencies, 2.7 x 10(-2) for HIV-1 RT and 4.5 x 10(-2) for AMV RT. Extension of the G.T mismatch is similar for AMV RT (5.8 x 10(-2) but 20-fold less efficient for HIV-1 RT. C.U and C.T mismatches are formed by both enzymes in a frequency range of 4.4 x 10(-5)-2.4 x 10(-4). HIV-1 RT extends these mismatches with slightly higher efficiencies (5.5 x 10(-3)-5.9 x 10(-3)) than AMV RT (5.6 x 10(-4)-2.1 x 10(-3)). Insertion of dTMP opposite U and T occur at about 1 x 10(-4)-2 x 10(-4) for HIV-1 RT. For AMV RT, formation of T.U mispairs occurs with an 8-fold lower efficiency, whereas insertion of dTMP opposite T is not detected. This particular DNA template sequence generates a pause site for AMV RT but not HIV-1 RT. HIV-1 RT dissociation rate constants are about 8-fold larger from a DNA primer bound to a DNA template (0.5 s-1), as compared with an RNA template (0.06 s-1) at one site, and are at most 2-fold larger at another site. The equilibrium binding constant for HIV-1 RT bound to DNA primed RNA and DNA templates appears to be similar, KD approximately 2.5 nM. Values of kpol from 0.3 to 1.5 nucleotides/s are obtained for HIV-1 RT at the RNA and DNA template sites used to measure insertion and extension fidelity. The relatively high efficiency of mispair extension catalyzed by reverse transcriptases with both RNA and DNA templates suggests that a significant component of retroviral genetic variability may be related to the ability of reverse transcriptases to continue efficient synthesis of DNA containing mismatches on both RNA and DNA templates.

Base mispair extension kinetics. Binding of avian myeloblastosis reverse transcriptase to matched and mismatched base pair termini

We investigate the enzymatic basis for the inefficient extension of single base mismatches by DNA polymerase compared with the extension of correct base pairs. Inefficient mismatch extension could result from either a reduced binding of the enzyme to mispaired versus correctly paired DNA template-primer termini, or from a lowered intrinsic rate of extension of mispairs by a bound enzyme, or from a combination of both factors. Avian myeloblastosis reverse transcriptase is used to measure the affinities (equilibrium dissociation constants) for the four matched and twelve mismatched base pair configurations situated at a primer 3'-terminus. The binding affinities are analyzed by two different assays employing polyacrylamide gels. The first assay uses steady-state kinetics to measure the efficiency of elongating correct and incorrect base pairs and to evaluate the enzyme's dissociation constants for matched and mismatched termini. The estimated KD values obtained in the steady-state analysis fall within a range of approximately 0.1-20 nM. The efficiencies of extending two of the mispairs, G.G and C.C, are too low to allow a determination of KD by the kinetics method. The second assay uses equilibrium binding to measure the ratio of polymerase bound to matched compared with mismatched termini, KDright/KDwrong. The affinity ratios, including values for G.G and C.C mispairs, are in the range of about 0.4-4.2. While around 1 order of magnitude difference is observed in the relative binding affinities of the polymerase for matched and mismatched primer termini, the relative extension efficiencies vary over more than 5 orders of magnitude. Therefore, it appears that inefficient mismatch extension is caused primarily by a kinetic block inhibiting elongation from mispaired primer 3'-termini rather than to a difference in binding.