Mutagenic Specificity of a Novel T4 DNA Polymerase Mutant

The in vivo mutational specificity of a novel T4 DNA polymerase mutator mutant, tsM19, was determined. Two genetic tester systems were used to characterize the mutant. Results of our studies indicate that tsM19 promotes transition and transversion mutagenesis and, possibly, frameshift mutagenesis. Central G:C base pairs in runs of three or more consecutive G:C base pairs may be target sites for tsM19-induced transitions.     

Effect of amino acid substitutions in the polypeptide chain of DNA-polymerase on manifestation of the mutator effect]

Thin map of gene 43, controlling the synthesis of T4 DNA polymerase, is obtained by mapping experiments performed with 39 amber mutants, and is used for analysis of the sites of DNA polymerase gene from the point of view of displaying the mutator effect. The mutant sites studied possessed different reaction on amino acid substitutions in the polypeptide chain of the enzyme. Most of sites of the DNA polymerase gene, with the exception of two "supersensitive", responsed only on the apparent type of the amino acid substitutions: the mutator effect of amber mutations, which are located at these sites, was exhibited only in the case of insertion of the definite amino acid in the respective point of polypeptide chain. The proposed system of amber mutations for studying the mutator effect, allowed the authors to obtain the data on the effect of concrete alterations in the polypeptide chain of the enzyme on the development of its mutator properties.     

Studeis on the biochemical basis of mutation. IV. Effect of amino acid substitution on the enzymatic and biological properties of bacteriophage T4 DNA polymerase

The effects of substituting specific amino acids at specified loci in the bacterio-phage T4 DNA polymerase molecule have been studied. Gene 43 (DNA polymerase) amber mutants grown on suppressor strains which substitute serine, glutamine, or tyrosine at specific sites in the polymerase molecule, produce enzymes with substantially different physical, enzymatic and biological properties when compared to wild type. When amB22, a gene 43 mutant which makes a DNA polymerase fragment with only 3′-exonuclease activity, was grown in Escherichia coli B40(sup⁺1), -(sup⁺ 2) or -(sup⁺3), enzymes with different temperature sensitivities and nuclease to polymerase ratios were produced. Measurements of spontaneous mutation rates in these suppressed strains indicated that the two with higher than normal exonuclease activity were antimutators, and the one with a slightly lower exonuclease activity was a mutator. The substituted amino acids at the amB22 site perturbed the 3′-exonuclease activity creating either antimutator or mutator phenotypes. Thus, the B22 enzymes provide additional biochemical evidence to support the hypothesis that the exonuclease to polymerase ratio may influence the spontaneous mutation rate in phage T4.     

A strong mutator effect caused by an amino acid change in the alpha subunit of DNA polymerase III of Escherichia coli

Most potent mutators heretofore detected in Escherichia coli are associated with defects in epsilon subunit of DNA polymerase III, encoded by the dnaQ gene. To elucidate the role of the alpha subunit, the catalytic subunit of the polymerase, in maintaining the high fidelity of DNA replication, we isolated a mutator mutant, the mutation (dnaE173) of which resides on the dnaE gene, encoding the alpha subunit. The dnaE173 mutant was unable to grow in salt-free L broth at temperatures exceeding 44.5 degrees C and exhibited an increased frequency of spontaneous mutations, 1,000 to 10,000-fold the wild type level, at permissive temperatures. The mutator effect of dnaE173 mutation is dominant over the wild type allele. These phenotypes are caused by a single base substitution, resulting in one amino acid change, Glu612 (GAA)----Lys(AAA), in the alpha subunit molecule. DNA polymerase III purified from the dnaE173 mutant contained both alpha and epsilon subunits, in a normal molar ratio. We found no differences between wild type and mutant polymerases in the Vmax, thermolabilities, and salt sensitivities. However, the apparent Km for the substrate nucleotide of the mutant polymerase was 1/6 of that determined with the wild type polymerase. Although the mutant polymerase retained a normal level of 3'----5' exonuclease activity, the proofreading capacity determined by "turnover assay" was significantly lower in the mutant polymerase, as compared with findings in the normal enzyme. It seems likely that the enhanced mutability in the dnaE173 strain results from, at least in part, a defect in the editing function of DNA polymerase III, and further suggests that a portion of the alpha subunit in which the amino acid change resides may be important for the proper setting of the two subunits at the replication fork so as to facilitate efficient editing during the DNA replication.     

Isolation of thermotolerant mutants by using proofreading-deficient DNA polymerase delta as an effective mutator in Saccharomyces cerevisiae

Eukaryotic DNA polymerases delta and epsilon, both of which are required for chromosomal DNA replication, contain proofreading 3'-->5'exonuclease activity. DNA polymerases lacking proofreading activity act as strong mutators. Here we report isolation of thermotolerant mutants by using a proofreading-deficient DNA polymerase delta variant encoded by pol3-01 in the yeast Saccharomyces cerevisiae. The parental pol3-01 strain grew only poorly at temperatures higher than 38 degrees C. By stepwise elevation of the incubation temperature, thermotolerant mutants that could proliferate at 40 degrees C were successfully obtained; however, no such mutants were isolated with the isogenic POL3 strain. The recessive hot1-1 mutation was defined by genetic analysis of a weak thermotolerant mutant. Strong thermotolerance to 40 degrees C was attained by multiple mutations, at least one of which was recessive. These results indicate that a proofreading-deficient DNA delta polymerase variant is an effective mutator for obtaining yeast mutants that have gained useful characteristics, such as the ability to proliferate in harsh environments.     

A Major Role for Bacteriophage T4 DNA Polymerase in Frameshift Mutagenesis

T4 DNA polymerase strongly influences the frequency and specificity of frameshift mutagenesis. Fifteen of 19 temperature-sensitive alleles of the DNA polymerase gene substantially influenced the reversion frequencies of frameshift mutations measured in the T4 rII genes. Most polymerase mutants increased frameshift frequencies, but a few alleles (previously noted as antimutators for base substitution mutations) decreased the frequencies of certain frameshifts while increasing the frequencies of others. The various patterns of enhanced or decreased frameshift mutation frequencies suggest that T4 DNA polymerase is likely to play a variety of roles in the metabolic events leading to frameshift mutation. A detailed genetic study of the specificity of the mutator properties of three DNA polymerase alleles (tsL56, tsL98 and tsL88) demonstrated that each produces a distinctive frameshift spectrum. Differences in frameshift frequencies at similar DNA sequences within the rII genes, the influence of mutant polymerase alleles on these frequencies, and the presence or absence of the dinucleotide sequence associated with initiation of Okazaki pieces at the frameshift site has led us to suggest that the discontinuities associated with discontinuous DNA replication may contribute to spontaneous frameshift mutation frequencies in T4.     

Suppression of dnaE nonsense mutations by pcbA1.

DNA polymerase III has been recognized as the required replication enzyme in Escherichia coli. The synthesis subunit of DNA polymerase III holoenzyme (alpha subunit) is encoded by the dnaE gene. We have reported that E. coli cells can survive and grow in the absence of a functional dnaE gene product if DNA polymerase I and the pcbA1 mutation are present. Existing mutations in the dnaE gene have been conditionally defective thermolabile mutations. We report here construction of nonsense mutations in the dnaE gene by use of a temperature-sensitive suppressor mutation to permit survival at the permissive temperature (32 degrees C). Introduction of the pcbA1 mutation eliminated the temperature-sensitive phenotype. We confirmed by immunoblotting the lack of detectable alpha subunit at 43 degrees C.     

Suppression of temperature-sensitive chromosome replication of an Escherichia coli dnaX(Ts) mutant by reduction of initiation efficiency

Temperature sensitivity of DNA polymerization and growth of a dnaX(Ts) mutant is suppressible at 39 to 40 degrees C by mutations in the initiator gene, dnaA. These suppressor mutations concomitantly cause initiation inhibition at 20 degrees C and have been designated Cs,Sx to indicate both phenotypic characteristics of cold-sensitive initiation and suppression of dnaX(Ts). One dnaA(Cs,Sx) mutant, A213D, has reduced affinity for ATP, and two mutants, R432L and T435K, have eliminated detectable DnaA box binding in vitro. Two models have explained dnaA(Cs,Sx) suppression of dnaX, which codes for both the tau and gamma subunits of DNA polymerase III. The initiation deficiency model assumes that reducing initiation efficiency allows survival of the dnaX(Ts) mutant at the somewhat intermediate temperature of 39 to 40 degrees C by reducing chromosome content per cell, thus allowing partially active DNA polymerase III to complete replication of enough chromosomes for the organism to survive. The stabilization model is based on the idea that DnaA interacts, directly or indirectly, with polymerization factors during replication. We present five lines of evidence consistent with the initiation deficiency model. First, a dnaA(Cs,Sx) mutation reduced initiation frequency and chromosome content (measured by flow cytometry) and origin/terminus ratios (measured by real-time PCR) in both wild-type and dnaX(Ts) strains growing at 39 and 34 degrees C. These effects were shown to result specifically from the Cs,Sx mutations, because the dnaX(Ts) mutant is not defective in initiation. Second, reduction of the number of origins and chromosome content per cell was common to all three known suppressor mutations. Third, growing the dnaA(Cs,Sx) dnaX(Ts) strain on glycerol-containing medium reduced its chromosome content to one per cell and eliminated suppression at 39 degrees C, as would be expected if the combination of poor carbon source, the Cs,Sx mutation, the Ts mutation, and the 39 degrees C incubation reduced replication to the point that growth (and, therefore, suppression) was not possible. However, suppression was possible on glycerol medium at 38 degrees C. Fourth, the dnaX(Ts) mutation can be suppressed also by introduction of oriC mutations, which reduced initiation efficiency and chromosome number per cell, and the degree of suppression was proportional to the level of initiation defect. Fifth, introducing a dnaA(Cos) allele, which causes overinitiation, into the dnaX(Ts) mutant exacerbated its temperature sensitivity.     

Isolation of an Escherichia coli K-12 dnaE mutation as a mutator.

Using a papillation method, a large number of Escherichia coli K-12 mutator mutations have been isolated. Only one of these (out of 1,250) mutator mutations has proved to be conditionally lethal at high temperatures. In vivo complementation tests indicated that this mutation, dnaE9, lies in dnaE, the structural gene for DNA polymerase III. The dnaE9 polymerase was not thermolabile in vitro; however, it showed a slow decline in specific activity in vivo at the nonpermissive temperature. Cultures of this mutant exhibited a comparably slow shutoff of DNA synthesis on shift to a nonpermissive temperature. dnaE9 showed temperature-sensitive mutator activity, which is not dependent on recA.     

Isolation and characterization of mutants with deletions in dnaQ, the gene for the editing subunit of DNA polymerase III in Salmonella typhimurium.

dnaQ (mutD) encodes the editing exonuclease subunit (epsilon) of DNA polymerase III. Previously described mutations in dnaQ include dominant and recessive mutator alleles as well as leaky temperature-sensitive alleles. We describe the properties of strains bearing null mutations (deletion-substitution alleles) of this gene. Null mutants exhibited a growth defect as well as elevated spontaneous mutation. As a consequence of the poor growth of dnaQ mutants and their high mutation rate, these strains were replaced within single colonies by derivatives carrying an extragenic suppressor mutation that compensated the growth defect but apparently not the mutator effect. Sixteen independently derived suppressors mapped in the vicinity of dnaE, the gene for the polymerization subunit (alpha) of DNA polymerase III, and one suppressor that was sequenced encoded an altered alpha polypeptide. Partially purified DNA polymerase III containing this altered alpha subunit was active in polymerization assays. In addition to their dependence on a suppressor mutation affecting alpha, dnaQ mutants strictly required DNA polymerase I for viability. We argue from these data that in the absence of epsilon, DNA replication falters unless secondary mechanisms, including genetically coded alteration in the intrinsic replication capacity of alpha and increased use of DNA polymerase I, come into play. Thus, epsilon plays a role in DNA replication distinct from its known role in controlling spontaneous mutation frequency.     

Increased rates of genomic deletions generated by mutations in the yeast gene encoding DNA polymerase delta or by decreases in the cellular levels of DNA polymerase delta

In Saccharomyces cerevisiae, POL3 encodes the catalytic subunit of DNA polymerase delta. While yeast POL3 mutant strains that lack the proofreading exonuclease activity of the polymerase have a strong mutator phenotype, little is known regarding the role of other Pol3p domains in mutation avoidance. We identified a number of pol3 mutations in regions outside of the exonuclease domain that have a mutator phenotype, substantially elevating the frequency of deletions. These deletions appear to reflect an increased frequency of DNA polymerase slippage. In addition, we demonstrate that reduction in the level of wild-type DNA polymerase results in a similar mutator phenotype. Lowered levels of DNA polymerase also result in increased sensitivity to the DNA-damaging agent methyl methane sulfonate. We conclude that both the quantity and the quality of DNA polymerase delta is important in ensuring genome stability.     

Allele-specific interactions between the yeast RFC1 and RFC5 genes suggest a basis for RFC subunit-subunit interactions

Replication factor C (RFC) is an essential, multi-subunit ATPase that functions in DNA replication, DNA repair, and DNA metabolism-related checkpoints. In order to investigate how the individual RFC subunits contribute to these functions in vivo, we undertook a genetic analysis of RFC genes from budding yeast. We isolated and characterized mutations in the RFC5 gene that could suppress the cold-sensitive phenotype of rfc1-1 mutants. Analysis of the RFC5 suppressors revealed that they could not suppress the elongated telomere phenotype, the sensitivity to DNA damaging agents, or the mutator phenotype of rfc1-1 mutants. Unlike the checkpoint-defective rfc5-1 mutation, the RFC5 suppressor mutations did not interfere with the methylmethane sulfonate- or hydroxyurea-induced phosphorylation of Rad53p. The Rfc5p suppressor substitutions mapped to amino acid positions in the conserved RFC box motifs IV-VII. Comparisons of the structures of related RFC box-containing proteins suggest that these RFC motifs may function to coordinate interactions between neighboring subunits of multi-subunit ATPases.     

Identification of important amino acid residues that modulate binding of Escherichia coli GroEL to its various cochaperones

Genetic experiments have shown that the GroEL/GroES chaperone machine of Escherichia coli is absolutely essential, not only for bacterial growth but also for the propagation of many bacteriophages including lambda. The virulent bacteriophages T4 and RB49 are independent of the host GroES function, because they encode their own cochaperone proteins, Gp31 and CocO, respectively. E. coli groEL44 mutant bacteria do not form colonies above 42 degrees nor do they propagate bacteriophages lambda, T4, or RB49. We found that the vast majority (40/46) of spontaneous groEL44 temperature-resistant colonies at 43 degrees were due to the presence of an intragenic suppressor mutation. These suppressors define 21 different amino acid substitutions in GroEL, each affecting one of 13 different amino acid residues. All of these amino acid residues are located at or near the hinge, which regulates the large en bloc movements of the GroEL apical domain. All of these intragenic suppressors support bacteriophages lambda, T4, and RB49 growth to various extents in the presence of the groEL44 allele. Since it is known that the GroEL44 mutant protein does not interact effectively with Gp31, the suppressor mutations should enhance cochaperone binding. Analogous intragenic suppressor studies were conducted with the groEL673 temperature-sensitive allele.     

Reversion of Frameshift Mutations Stimulated by Lesions in Early Function Genes of Bacteriophage T4

Temperature-sensitive (ts) mutants representative of a number of genes of phage T4 were crossed with rII mutants to allow isolation of ts, rII double-mutant recombinants. The rII mutations used were characterized as frameshift mutations primarily on the basis of their revertability by proflavine. For each ts, rII double mutant, the effect of the ts mutation on spontaneous reversion of the rII mutation was determined over a range of incubation temperatures. A strong enhancement in reversion of two different rII mutants was detected when they were combined with tsL56, a mutation in gene 43 [deoxyribonucleic acid (DNA) polymerase]. Three other mutants defective in gene 43 enhanced reversion about fourfold. Two mutations in gene 32, which specifies a protein necessary for DNA replication, enhanced reversion about 5-fold and 18-fold, respectively. Two additional mutations in gene 43 and two in gene 32 had no effect. Fivefold and threefold enhancements in reversion were also found with mutations in genes 44 (DNA synthesis) and 47 (deoxyribonuclease), respectively. No significant effect was found with mutations in seven additional genes. The results of other workers suggest that frameshift mutations arise from errors in strand alignment during repair synthesis occurring at chromosome tips. Our results show that such errors can be enhanced by mutations in the DNA polymerase, the gene 32 protein, and the enzymes specified by genes 44 and 47. This implies that these proteins are employed in the repair process occurring at chromosome tips and that mutational errors in these proteins can lead to loss of ability to recognize and reject strand misalignments.     

Identification of Escherichia coli dnaE (polC) mutants with altered sensitivity to 2',3'-dideoxyadenosine

Bacteria with reduced DNA polymerase I activity have increased sensitivity to killing by chain-terminating nucleotides (S. A. Rashbaum and N. R. Cozzarelli, Nature 264:679-680, 1976). We have used this observation as the basis of a genetic strategy to identify mutations in the dnaE (polC) gene of Escherichia coli that alter sensitivity to 2',3'-dideoxyadenosine (ddA). Two dnaE (polC) mutant strains with increased sensitivity to ddA and one strain with increased resistance were isolated and characterized. The mutant phenotypes are due to single amino acid substitutions in the alpha subunit, the protein product of the dnaE (polC) gene. Increased sensitivity to ddA is produced by the L329F and H417Y substitutions, and increased resistance is produced by the G365S substitution. The L329F and H417Y substitutions also reduce the accuracy of DNA replication (the mutator phenotype), while the G365S substitution increases accuracy (the antimutator phenotype). All of the amino acid substitutions are in conserved regions near essential aspartate residues. These results prove the effectiveness of the genetic strategy in identifying informative dnaE (polC) mutations that can be used to elucidate the molecular basis of nucleotide interactions in the alpha subunit of the DNA polymerase III holoenzyme.     

Mutations in the rpoH (htpR) gene of Escherichia coli K-12 phenotypically suppress a temperature-sensitive mutant defective in the sigma 70 subunit of RNA polymerase.

Escherichia coli K-12 strain 285c contains a mutation in rpoD, the gene encoding the sigma subunit of RNA polymerase. The 70-kilodalton sigma polypeptide encoded by this allele is unstable, and this instability leads to temperature-sensitive growth. We describe the isolation and characterization of four temperature-resistant pseudorevertants of 285c that can grow at high temperature. Each of these revertants increased the stability of the sigma 70 mutant protein. The map position of the suppressor mutations was close to that of the rpoH (htpR) gene. A multicopy plasmid containing the intact rpoH gene restored the temperature-sensitive phenotype. Marker rescue experiments established the positions of three of the alleles within the rpoH gene. One mutation has been sequenced and causes a leucine-to-tryptophan change 7 amino acids from the carboxyl terminus of the rpoH gene product.     

Rates of Spontaneous Mutation in Bacteriophage T4 Are Independent of Host Fidelity Determinants

Bacteriophage T4 encodes most of the genes whose products are required for its DNA metabolism, and host (Escherichia coli) genes can only infrequently complement mutationally inactivated T4 genes. We screened the following host mutator mutations for effects on spontaneous mutation rates in T4: mutT (destruction of aberrant dGTPs), polA, polB and polC (DNA polymerases), dnaQ (exonucleolytic proofreading), mutH, mutS, mutL and uvrD (methyl-directed DNA mismatch repair), mutM and mutY (excision repair of oxygen-damaged DNA), mutA (function unknown), and topB and osmZ (affecting DNA topology). None increased T4 spontaneous mutation rates within a resolving power of about twofold (nor did optA, which is not a mutator but overexpresses a host dGTPase). Previous screens in T4 have revealed strong mutator mutations only in the gene encoding the viral DNA polymerase and proofreading 3'-exonuclease, plus weak mutators in several polymerase accessory proteins or determinants of dNTP pool sizes. T4 maintains a spontaneous mutation rate per base pair about 30-fold greater than that of its host. Thus, the joint high fidelity of insertion by T4 DNA polymerase and proofreading by its associated 3'-exonuclease appear to determine the T4 spontaneous mutation rate, whereas the host requires numerous additional systems to achieve high replication fidelity.     

Genetic evidence for interaction between the a and b subunits of the F0 portion of the Escherichia coli proton translocating ATPase

A mutation of the b subunit of the Escherichia coli proton translocating ATPase was previously described (Porter, A. C. G., Kumamoto, C., Aldape, K., and Simoni, R. D. (1985) J. Biol. Chem. 260, 8182-8187). This mutation, which causes substitution of aspartic acid for glycine at position 9 (basp9), results in loss of function of the ATPase complex. In this paper we describe the isolation and characterization of two mutations that partially suppress the effects of the basp9 alteration. The suppressor mutations cause amino acid substitutions at position 240 of the a subunit. Membranes derived from strains carrying a suppressor mutation and the basp9 mutation exhibited ATP-dependent proton translocating activity.