An aerobic recA-, umuC-dependent pathway of spontaneous base-pair substitution mutagenesis in Escherichia coli.

Antimutator alleles indentify genes whose normal products are involved in spontaneous mutagenesis pathways. Mutant alleles of the recA and umuC genes of Escherichia coli, whose wild-type alleles are components of the inducible SOS response, were shown to cause a decrease in the level of spontaneous mutagenesis. Using a series of chromosomal mutant trp alleles, which detect point mutations, as a reversion assay, it was shown that the reduction in mutagenesis is limited to base-pair substitutions. Within the limited number of sites than could be examined, transversions at AT sites were the favored substitutions. Frameshift mutagenesis was slightly enhanced by a mutant recA allele and unchanged by a mutant umuC allele. The wild-type recA and umuC genes are involved in the same mutagenic base-pair substitution pathway, designated "SOS-dependent spontaneous mutagenesis" (SDSM), since a recAumuC strain showed the same degree and specificity of antimutator activity as either single mutant strain. The SDSM pathway is active only in the presence of oxygen, since wild-type, recA, and umuC strains all show the same levels of reduced spontaneous mutagenesis anaerobically. The SDSM pathway can function in starving/stationary cells and may, or may not, be operative in actively dividing cultures. We suggest that, in wild-type cells, SDSM results from basal levels of SOS activity during DNA synthesis. Mutations may result from synthesis past cryptic DNA lesions (targeted mutagenesis) and/or from mispairings during synthesis with a normal DNA template (untargeted mutagenesis). Since it occurs in chromosomal genes of wild-type cells, SDSM may be biologically significant for isolates of natural enteric bacterial populations where extended starvation is often a common mode of existence.

The role of the mutT gene of Escherichia coli in maintaining replication fidelity.

Spontaneous mutation levels are kept low in most organisms by a variety of error-reducing mechanisms, some of which ensure a high level of fidelity during DNA replication. The mutT gene of Escherichia coli is an important participant in avoiding such replication mistakes. An inactive mutT allele is a strong mutator with strict mutational specificity: only A.T-->C.G transversions are enhanced. The biological role of the MutT protein is thought to be the prevention of A.G mispairs during replication, specifically the mispair involving a template A and an oxidized form of guanine, 8-oxoguanine, which results when the oxidized form of dGTP, 8-oxodGTP, is available as a polymerase substrate. MutT is part of an elaborate defense system that protects against the mutagenic effects of oxidized guanine as a part of substrate dGTP and chromosomal DNA. The A.G mispairings prevented by MutT are not well-recognized and/or repaired by other fidelity mechanisms such as proofreading and mismatch repair, accounting in part for the high mutator activity of mutT. MutT is a nucleoside triphosphatase with a preference for the syn form of dGTP, hydrolyzing it to dGMP and pyrophosphate. 8-oxodGTP is hydrolyzed 10 times faster than dGTP, making it a likely biological substrate for MutT. MutT is assumed to hydrolyze 8-oxodGTP in the nucleotide pool before it can be misincorporated. While the broad role of MutT in error avoidance seems resolved, important details that are still unclear are pointed out in this review.

The ultraviolet-sensitizing function of plasmid R391 interferes with a late step of postreplication repair in Escherichia coli.

The conjugative plasmid R391 increases the UV radiation sensitivity of wild-type, uvrA, and lexA cells of Escherichia coli, but not recA strains. To investigate the UV-sensitizing function of R391, we examined the effect of R391 on the repair of DNA daughter-strand gaps and on the UV radiation sensitivities of various repair and/or recombination-deficient mutants. The presence of R391 did not significantly inhibit the repair of DNA daughter-strand gaps in uvrB cells. The presence of R391 increased the UV radiation sensitivity of uvrA, uvrA recF, uvrB, uvrB recF, uvrB recB, and uvrB ssb-113 cells to UV irradiation, but did not significantly increase the UV radiation sensitivity of uvrA ruvA and uvrA ruvC strains. Based on these results, we propose that the UV-sensitizing activity of R391 acts by inhibiting or interfering with the ruvABC-mediated postsynapsis step of recombinational repair.

Activity of the Escherichia coli mutT mutator allele in an anaerobic environment.

Mutation frequencies for an Escherichia coli mutT strain were measured in both aerobic and anaerobic environments. When cells were grown in a rich medium (L broth), mutation frequencies were similar in both aerobic and anaerobic conditions. In contrast, when grown in a minimal medium, mutT anaerobic mutation frequencies were reduced dramatically compared with aerobic values, which were similar to L broth frequencies. L broth mutT cultures treated with a commercial enzyme complex that reduces free oxygen in the medium also showed strongly reduced anaerobic mutation frequencies. These results indicate that the biological role of the MutT protein is to prevent oxidative damage from becoming mutagenic.

The high mutator activity of the dnaQ49 allele of Escherichia coli is medium-dependent and results from both defective 3'-->5' proofreading and methyl-directed mismatch repair.

The Escherichia coli dnaQ49 mutator allele maps at the dnaQ locus, the structural gene for the epsilon subunit of the DNA polymerase III holoenzyme. Epsilon, when bound to the alpha subunit, provides the 3'-->5' exonuclease activity (proofreading) that removes 3' mismatched terminal nucleotides from the nascent DNA strand during replication. The temperature sensitive dnaQ49 allele lacks this catalytic activity which results in mutation frequencies 10(4)-10(5)-fold above wild-type values at 37 degrees C. At 30 degrees C dnaQ49 mutation frequencies are much lower but still higher than wild-type levels. We found that dnaQ49, like mutD5, another strong mutator allele of dnaQ, is medium-dependent with mutation frequencies ranging from 12 to nearly 1000-fold higher in rich media (L-broth) than in minimal media. In minimal media dnaQ49 retains modest mutator activity. In addition the base-pair substitution mutational spectrum of dnaQ49 was medium-dependent. Unlike mutD5 the addition of thymidine to minimal medium did not enhance dnaQ49 mutator activity. We also constructed dnaQ49mutL double mutator strains and compared mutator frequencies with single dnaQ49 and mutL strains. The mutL allele results in inactive methyl-directed mismatch repair. Double and single dnaQ49 mutators had similar mutation frequencies at 37 degrees C in L-broth suggesting that dnaQ49 strains are defective in mismatch repair as well as 3'-->5' exonuclease proofreading activity. In contrast in minimal media at 37 degrees C and in L-broth at 30 degrees C dnaQ49 mutL mutation frequencies were much higher than dnaQ49 values indicating the presence of active mismatch-repair activity in the latter strain. In addition at 37 degrees C dnaQ49mutL mutation frequencies were about 100-fold higher in L-broth than in minimal media. We conclude from this result that the rich media effect with dnaQ49 involves an actual increase in replication errors rather than a medium-dependent modulation of mismatch repair activity.

The interaction of the Escherichia coli mutD and mutT pathways in the prevention of A:T-->C:G transversions.

The Escherichia coli mutT mutator allele produces high frequencies of exclusively A:T-->C:G transversions. This is thought to be caused by a failure to prevent or remove A:G mispairs during DNA replication. The mutD5 mutator allele maps to the dnaQ locus which encodes the epsilon subunit of the DNA polymerase III holoenzyme. This subunit provides 3'-->5' exonuclease, proofreading, activity for removing mispaired nucleotides at the 3' end of the newly synthesized DNA strand. mutD5 has an altered epsilon resulting in reduced levels of proofreading and subsequent high mutation frequencies for all base-pair substitutions. We have analyzed the interaction between mutD5 and mutT-induced A:T-->C:G transversions by measuring reversion frequencies in mutD5 and mutT single mutator strains and mutD5mutT double mutator strains using the well-characterized trpA58 and trpA88 alleles. We find that the double mutator strains produce more A:T-->C:G substitutions than would be expected from simple additivity of the single mutator strains. We interpret this to mean that the two systems, at least in part, do act together to prevent the same mutational intermediate from producing A:T-->C:G transversions. It is estimated that over 90% of the mutT-induced A:G mispairs are corrected by proofreading at the trpA58 site while only about 30% are corrected at trpA88. Reversion frequencies in the mutD5mutT double mutator strains indicate A:G misincorporations occur about 100 x more frequently at trpA58 than at the trpA88 site. Using these and other data we also provide estimations of the fidelity contributions for mutT editing, proofreading and methyl-directed mismatch repair at the two trpA sites for both transversions and the transition that could be scored. In the case of A:T-->C:G transversions, both mutT editing and proofreading make major contributions in error reduction with mismatch repair playing a small or no role at all. For the A:T-->G:C transition, proofreading and mismatch repair were both important in preventing mutations while no contribution was observed for mutT editing.

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.

Temperature-dependent mutational specificity of an Escherichia coli mutator, dnaQ49, defective in 3'----5' exonuclease (proofreading) activity.

Escherichia coli strains carrying the temperature-dependent dnaQ49 allele are strong mutators at 37 degrees C. Since the dnaQ49 gene encodes the epsilon subunit of DNA polymerase III, it is thought that the large number of errors results in part from impaired proofreading activity during DNA replication. We have examined dnaQ49-induced reversion patterns of defined trpA alleles to determine the kinds of errors produced by dnaQ49 at 30 degrees C and 37 degrees C. We found that at 37 degrees C dnaQ49 produced all types of base-pair substitutions in addition to frameshifts with transitions generally occurring more frequently than transversions. This generalized mutator activity is very similar to that displayed in rich medium by mutD5, another mutator allele at the dnaQ locus. However, when dnaQ49 strains were cultured at 30 degrees C, not only were reversion frequencies much lower than at 37 degrees C, but in addition, the spectrum was altered. Transversions became proportionally more prevalent in the reversion spectra at the lower temperature. We suggest the possibility that at 37 degrees C dnaQ49 results in defective proofreading and methyl-directed postreplicative mismatch repair, while at 30 degrees C mismatch repair is fully and proofreading partially restored.

Characterization of mutational specificity within the lacI gene for a mutD5 mutator strain of Escherichia coli defective in 3'----5' exonuclease (proofreading) activity.

The mutD (dnaQ) gene of Escherichia coli codes for the epsilon subunit of the DNA polymerase III holoenzyme which is involved in 3'----5' exonuclease proofreading activity. We determined the mutational specificity of the mutator allele, mutD5, in the lacI gene of E. coli. The mutD5 mutation preferentially produces single base substitutions as judged from the enhanced fraction of lacI nonsense mutations and the spectrum of sequenced dominant lacI (lacId) and constitutive lacO (lacOc) mutations which were predominantly (69/71) single nucleotide substitutions. The distribution of amber lacI and sequenced lacId mutations revealed that transitions occur more frequently than transversions. A . T----G . C and G . C----A . T transitions were equally frequent and, with one major exception, evenly distributed among numerous sites. Among the transversions, A . T----T . A events were the most common, A . T----C . G substitutions were rare, and G . C----C . G changes were not detected. Transversions were unequally distributed among a limited number of sites with obvious hotspots. All 11 sequenced transversions had a consensus neighboring sequence of 5'-C-C-(mutated G or A)-C-3'. Although no large deletions or complex mutational events were recovered, sequencing revealed that mutD5 induced single nucleotide deletions within consecutive G X C sequences. An extraordinary A . T----G . C transition hotspot occurred at nucleotide position +6 in the lac operator region; the mutD5 mutation frequency of this single base pair was calculated to be 1.2 X 10(-3).

The specificity of base-pair substitution induced by the mutL and mutS mutators in E. coli.

The Escherichia coli mutator alleles, mutL and mutS, produced transversion as well as transition base-pair substitutions with the trpA reversion system. Transversions, however, were generally mutator-induced at a lower level than transitions and the specific type of transversion and its nucleotide position appeared to strongly affect its level of enhancement. These results are interpreted to mean that mutL- and mutS-dependent mismatch correction is generally more effective at correcting transition mispairings than transversion mispairings. Correction of transversion mispairings is probably dependent upon site of occurrence and type of mismatch.

Visible light mutagenesis in Escherichia coli.

Visible light (450 nm) caused base-pair substitution and frameshift mutations in Escherichia coli. Using the defined trpA reversion system, we showed that visible light induced transversions at both A:T and G:C sites although some base-pair substitutions were refractory to light-induced mutagenesis, possibly because of their location. The presence of R plasmid pKM101 caused a greater than additive increase in light-induced base-pair substitutions for some trpA alleles. Visible light mutagenesis was reduced but not abolished in a recA56 background, suggesting that more than one mutational mechanism may be operative.

Mutational specificity of ultraviolet light in Escherichia coli with and without the R plasmid pKM101.

Plasmid pKM101 provides UV protection and increases the frequency of spontaneous and UV-induced mutations in Escherichia coli. By analyzing reversion patterns of defined trpA alleles, we showed that pKM101 altered the mutational specificity of UV-induced mutations. Certain UV-induced base-pair substitutions were strongly enhanced, while others were decreased in frequency in the presence of pKM101. This result suggests an interaction between cellular misrepair and an error-prone repair function(s) provided by pKM101. We have also examined UV mutational specificity in the absence of pKM101 and found the following: (1) UV preferentially enhances missense, as well as nonsense, intergenic suppressor mutations; (2) UV causes all possible base-pair substitutions as well as frameshift mutations; (3) G . C base pairs are more susceptible to UV mutagenesis than a . T base pairs at the same nucleotide positions; and (4) UV-induced mutations can occur at nucleotide positions that are not part of pyrimidine-pyrimidine sequences.

Mutational specificity of the base analogue, 2-aminopurine, in Escherichia coli.

2-Aminopurine (2-AP) is a base analogue of adenine which mispairs with cytosine and causes base-pair substitutions of the transition type. By analyzing the reversion patterns of defined trpA alleles in Escherichia coli we confirm that 2-AP causes both A:T leads to G:C and G:C leads to A:T transitions with the former induced more frequently than the latter. We also find that 2-AP enhances transversions at 3 sites and frameshift mutations at 1 other site. It is unlikely that 2-AP can cause transversions and frameshifts solely by a mispairing mechanism. However, 2-AP-induced transversion and frameshift mutagenesis was not abolished by the presence of an inactive recA allele, indicating this mutagenic activity is not dependent upon recA-directed misrepair.

Spontaneous mutational specificity of drug resistance plasmid pKM101 in Escherichia coli.

Plasmid pKM101 enhances the frequency of spontaneous and ultraviolet light-induced mutations in Escherichia coli and protects the cells against the lethal effects of ultraviolet irradiation. By analyzing reversion patterns of defined trpA alleles, we showed that pKM101 caused all types of spontaneous base-pair substitution mutations with the possible exception of guanine . cytosine leads to adenine. thymine transitions. Neither insertion nor deletion frameshift mutations were enhanced. Transversions were more strongly enhanced than transitions, and adenine . thymine base pairs appeared more susceptible to pKM101 mutator activity than guanine . cytosine base pairs. In addition, there were effects from neighboring base pairs and genetic background that influenced the mutator activity of pKM101.

An altered state of a specific en regulatory element induced in a maize tiller.

There are numerous states of the regulatory element, Enhancer (En). With specific receptor alleles, such as a2m(r-pa-pu) or a2m(r), specific mutability patterns are expressed. One specific derivative En allele, En-v (En-variable), was originally identified with a coarse pattern of mutability with the a2m(r-pa-pu) allele and giving progeny with varied En expression (standard to reduced within an ear progeny). Derivatives of En-v were subsequently found on numerous occasions to give only a very reduced expression (fewer mutant spots) with the a2m(r-pa-pu) allele in the ears derived from the main stalk of the corn plant. When a comparison is made of the effect of this changed En-v state between tiller ears and main stalk ears of the same plant, the tiller ears show an increased level of En-v expression (coarse pattern), while the main-stalk ears continue to show the very reduced level of En-v expression (low frequency of very late variegation). This increased level of mutability of the tiller ears is maintained when transmitted through the main-stalk ear in the subsequent generation. These results indicate that heritable alterations of controlling elements can be produced by endogenous environmental factors present during normal plant development.