Mistranslation induced by streptomycin provokes a RecABC/RuvABC-dependent mutator phenotype in Escherichia coli cells.

Translational stress-induced mutagenesis (TSM) refers to the mutator phenotype observed in Escherichia coli cells expressing a mutant allele (mutA or mutC) of the glycine tRNA gene glyV (or glyW). Because of an anticodon mutation, expression of the mutA allele results in low levels of Asp-->Gly mistranslation. The mutA phenotype does not require lexA-regulated SOS mutagenesis functions, and appears to be suppressed in cells defective for RecABC-dependent homologous recombination functions. To test the hypothesis that the TSM response is mediated by non-specific mistranslation rather than specific Asp-->Gly misreading, we asked if streptomycin (Str), an aminoglycoside antibiotic known to promote mistranslation, can provoke a mutator phenotype. We report that Str induces a strong mutator phenotype in cells bearing certain alleles of rpsL, the gene encoding S12, an essential component of the ribosomal 30 S subunit. The phenotype is strikingly similar to that observed in mutA cells in its mutational specificity, as well as in its requirement for RecABC-mediated homologous recombination functions. Expression of Str-inducible mutator phenotype correlates with mistranslation efficiency in response to Str. Thus, mistranslation in general is able to induce the TSM response. The Str-inducible mutator phenotype described here defines a new functional class of rpsL alleles, and raises interesting questions on the mechanism of action of Str, and on bacterial response to antibiotic stress.     

Dominant negative mutator mutations in the mutL gene of Escherichia coli.

The mutL gene product is part of the dam-directed mismatch repair system of Escherichia coli but has no known enzymatic function. It forms a complex on heteroduplex DNA with the mismatch recognition MutS protein and with MutH, which has latent endonuclease activity. An N-terminal hexahistidine-tagged MutL was constructed which was active in vivo. As a first stop to determine the functional domains of MutL, we have isolated 72 hydroxylamine-induced plasmid-borne mutations which impart a dominant-negative phenotype to the wild-type strain for increased spontaneous mutagenesis. None of the mutations complement a mutL deletion mutant, indicating that the mutant proteins by themselves are inactive. All the dominant mutations but one could be complemented by the wild-type mutL at about the same gene dosage. DNA sequencing indicated that the mutations affected 22 amino acid residues located between positions 16 and 549 of the 615 amino acid protein. In the N-terminal half of the protein, 12 out of 15 amino acid replacements occur at positions conserved in various eukaryotic MutL homologs. All but one of the sequence changes affecting the C-terminal end of the protein are nonsense mutations.     

Dominant negative mutator mutations in the mutS gene of Escherichia coli.

The MutS protein of Escherichia coli is part of the dam-directed MutHLS mismatch repair pathway which rectifies replication errors and which prevents recombination between related sequences. In order to more fully understand the role of MutS in these processes, dominant negative mutS mutations on a multicopy plasmid were isolated by screening transformed wild-type cells for a mutator phenotype, using a Lac+ papillation assay. Thirty-eight hydroxylamine- and 22 N-methyl-N'-nitro-N-nitrosoguanidine-induced dominant mutations were isolated. Nine of these mutations altered the P-loop motif of the ATP-binding site, resulting in four amino acid substitutions. With one exception, the remaining sequenced mutations all caused substitution of amino acids conserved during evolution. The dominant mutations in the P-loop consensus caused severely reduced repair of heteroduplex DNA in vivo in a mutS mutant host strain. In a wild-type strain, the level of repair was decreased by the dominant mutations to between 12 to 90% of the control value, which is consistent with interference of wild-type MutS function by the mutant proteins. Increasing the wild-type mutS gene dosage resulted in a reversal of the mutator phenotype in about 60% of the mutant strains, indicating that the mutant and wild-type proteins compete. In addition, 20 mutant isolates showed phenotypic reversal by increasing the gene copies of either mutL or mutH. There was a direct correlation between the levels of recombination and mutagenesis in the mutant strains, suggesting that these phenotypes are due to the same function of MutS.     

Bromouracil mutagenesis and mismatch repair in mutator strains of Escherichia coli.

A screening procedure based on the formation of papillae on individual bacterial colonies was used to isolate mutants of Escherichia coli with high mutation rates in the presence of bromouracil. Most of the mutants obtained had high spontaneous mutation rates and mapped close to the previously known mutators mutT, mutS, mutR, uvrE and mutL. Except for mutants of mutT type, these mutators also showed high mutability by bromouracil. Transfection experiments were performed with heteroduplex lambda DNA to test for mismatch repair. The results suggest a reduced efficiency of repair of mismatched bases in mutators mutS, mutR, uvrE and mutL, whereas mutants mapping as mutT appear normal. The results support a connection between spontaneous and bromouracil-induced mutability and repair of mismatched bases in DNA.     

Mismatch repair in the antimutator Escherichia coli mud

Antimutators are genetic mutants that produce mutations at reduced rates compared to the wild type strain. They are interesting because they may provide insights into the mechanisms by which spontaneous mutations occur. We have investigated a reported antimutator strain of Escherichia coli termed mud for its possible mechanism. The mud strain exhibits a decrease in both spontaneous mutagenesis and mutability with alkylated agents and base analogs. These types of DNA lesions are known to be the substrates for the E. coli methyl-directed mismatch repair encoded by the mutHLSU system. We investigated whether the putative antimutator effect results from the increased expression or activity of the mutHLSU system. To directly measure the mismatch repair capacity of mud cells, we have transfected them with phage lambda heteroduplexes and scored the fraction of mixed (unrepaired) infective centers. This transfection system has been used routinely to assay mismatch repair capacity in E. coli and other organisms. No difference between mud and wild type cells is observed. From the results of the experiments we conclude that the reported antimutator effect of mud does not result from enhanced mismatch repair capacity. This conclusion is consistent with recently published evidence that the mud effect does not represent a real antimutator effect, but is an artifact due to impaired growth of mud cells under certain selective conditions.     

Phasmid vectors for identification of genes by complementation of Escherichia coli mutants.

A bacteriophage lambda cloning vector was designed to facilitate the isolation of genes from procaryotic organisms by complementation of Escherichia coli mutants. This vector, lambda SE4, was constructed by attaching a very-low-copy-number replication system (from the plasmid NR1) and a spectinomycin resistance gene to the left arm of lambda 1059 (Karn et al., Proc. Natl. Acad. Sci. U.S.A. 77:5172-5176, 1980). This phasmid cloning vector is capable of growing lytically as a phage in a nonimmune host or lysogenically as a phasmid in an immune host. This phasmid utilizes the Spi- selection for insertions of DNA into the vector and has the ability to accept 2- to 19-kilobase Sau3A1, BamHI, BglII, BclI, or XhoII fragments; recombinants lysogenize immune hosts as single-copy-number selectable plasmids at 100% frequency. An E. coli library was constructed by using the initial vector lambda SE4, and clones of a number of representative genes were identified. A typical clone, lambda ant+, was shown to be readily mutagenized by a mini-Tn10 transposon. A general method for transferring cloned DNA segments onto bacteriophage lambda was developed. The method involves the use of in vivo recombination with a selection and was used to construct two derivatives of lambda SE4. Possible uses of these vectors and of the method for transferring cloned DNA onto phage lambda are discussed.     

Saturation of mismatch repair in the mutD5 mutator strain of Escherichia coli.

The mutD (dnaQ) gene of Escherichia coli codes for the proofreading activity of DNA polymerase III. The very strong mutator phenotype of mutD5 strains seems to indicate that their postreplicational mismatch repair activity is also impaired. We show that the mismatch repair system of mutD5 strains is functional but saturated, presumably by the excess of DNA replication errors, since it is recovered by inhibiting chromosomal DNA replication. This recovery depends on de novo protein synthesis.     

The miaA mutator phenotype of Escherichia coli K-12 requires recombination functions

miaA mutants, which contain A-37 instead of the ms(2)i(6)A-37 hypermodification in their tRNA, show a moderate mutator phenotype leading to increased GC-->TA transversion. We show that the miaA mutator phenotype is dependent on recombination functions similar to, but not exactly the same as, those required for translation stress-induced mutagenesis.     

groE genes affect SOS repair in Escherichia coli.

Repair of UV-irradiated bacteriophage in Escherichia coli by Weigle reactivation requires functional recA+ and umuD+C+ genes. When the cells were UV irradiated, the groE heat shock gene products, GroES and GroEL, were needed for at least 50% of the Weigle reactivation of the single-stranded DNA phage S13. Because of repression of the umuDC and recA genes, Weigle reactivation is normally blocked by the lexA3(Ind-) mutation (which creates a noncleavable LexA protein), but it was restored by a combination of a high-copy-number umuD+C+ plasmid and a UV dose that increases groE expression. Maximal reactivation was achieved by elevated amounts of the Umu proteins, which was accomplished in part by UV-induced expression of the groE genes. By increasing the number of copies of the umuD+C+ genes, up to 50% of the normal amount of reactivation of S13 was achieved in an unirradiated recA+ host.     

Nucleotide sequence of the Salmonella typhimurium mutS gene required for mismatch repair: homology of MutS and HexA of Streptococcus pneumoniae.

The mutS gene product of Escherichia coli and Salmonella typhimurium is one of at least four proteins required for methyl-directed mismatch repair in these organisms. A functionally similar repair system in Streptococcus pneumoniae requires the hex genes. We have sequenced the S. typhimurium mutS gene, showing that it encodes a 96-kilodalton protein. Amino-terminal amino acid sequencing of purified S. typhimurium MutS protein confirmed the initial portion of the deduced amino acid sequence. The S. typhimurium MutS protein is homologous to the S. pneumoniae HexA protein, suggesting that they arose from a common ancestor before the gram-negative and gram-positive bacteria diverged. Overall, approximately 36% of the amino acids of the two proteins are identical when the sequences are optimally aligned, including regions of stronger homology which are of particular interest. One such region is close to the amino terminus. Another, located closer to the carboxy terminus, includes homology to a consensus sequence thought to be diagnostic of nucleotide-binding sites. A third one, adjacent to the second, is homologous to the consensus sequence for the helix-turn-helix motif found in many DNA-binding proteins. We found that the S. typhimurium MutS protein can substitute for the E. coli MutS protein in vitro as it can in vivo, but we have not yet been able to demonstrate a similar in vitro complementation by the S. pneumoniae HexA protein.     

Identification of Streptococcus pneumoniae mismatch repair genes by an additive transformation approach

Summary During transformation of Streptococcus pneumoniae, mismatch repair occurs on donor-recipient heteroduplexes harboring some mismatched base pairs. A few mutants defective in mismatch repair have been isolated and termed hex ^-. However, neither the number of genes involved nor their products have yet been identified. In an attempt to characterize such genes we have used an additive transformation approach — that is the inactivation of genes by insertion of chimeric plasmids. Pneumococcal DNA fragments were joined in vitro to a plasmid derivative of pBR325 that carries an erythromycin resistance determinant and does not replicate autonomously in S. pneumoniae. Ery-r transformants obtained with such a ligation mixture arise via homology-dependent integration of the chimeric plasmids into the chromosome. Hex ^- mutants have been selected among the ery-r population. Comparison of these mutants by Southern blot hybridization with a vector probe reveals that at least two genes are involved in mismatch repair.     

Mismatch repair and recombination in E. coli

The involvement of the E. coli methyl-directed and very short patch (vsp) mismatch repair systems in bacteriophage lambda recombination has been studied. Genetic crosses and heteroduplex transfection experiments were performed using lambda phages with sequenced mutations in the cl gene. The results indicate that methyl-directed repair does operate during bacteriophage lambda recombination but generally does not contribute to the formation of recombinants involving close markers. Vsp repair apparently acts during bacteriophage lambda recombination to produce recombinants involving close markers because its action does not involve extensive excision tracts. Marker-specific hyperrecombination and the apparent clustering of genetic exchanges in bacteriophage lambda recombination can be accounted for by the action of the vsp repair system.     

Mutator phenotype confers advantage in Escherichia coli chronic urinary tract infection pathogenesis

It has been suggested that mutator phenotype could be associated with an increase in virulence, but to date experimental evidences are lacking. Epidemiological studies have revealed that urinary tract infection isolates encompass the highest proportion of mutator strains within the Escherichia coli species. Using the uropathogenic strain CFT073 and its mutS- mutator mutant, we show that the mutator strain is selected in vitro in urine and in the late stages of infection in a mouse model having urinary tract infection. Thus, we report that, under specific conditions, i.e., urinary tract infection, the mutator phenotype may confer an advantage in pathogenesis.     

Polymer production by Klebsiella pneumoniae 4-hydroxyphenylacetic acid hydroxylase genes cloned in Escherichia coli.

The expression of Klebsiella pneumoniae hpaA and hpaH genes, which code for 4-hydroxyphenylacetic acid hydroxylase in Escherichia coli K-12 derivative strains, is associated with the production of a dark brown pigment in the cultures. This pigment has been identified as a polymer which shows several of the characteristics reported for microbial melanins and results from the oxidative activity of 4-hydroxyphenylacetic acid hydroxylase on some dihydroxylated compounds to form o-quinones. A dibenzoquinone is formed from the oxidation of different mono- or dihydroxylated aromatic compounds by the enzyme prior to polymerization. We report a hydroxylase activity, other than tyrosinase, that is associated with the synthesis of a bacterial melanin.     

Mini-Mu-duction as a test for genetic complementation in Escherichia coli.

In mini-Mu-duction, segments of host DNA bracketed between two copies of an internally deleted Mu phage (a mini-Mu) can be packaged within Mu phage particles. Upon infection of a second host strain, the DNA injected by these particles can insert into the chromosomal DNA in a reaction catalyzed by the phage A gene product (transposase), which is independent of homologous recombination. This results in a partially diploid host strain in which the duplicated host DNA is bracketed by two copies of the mini-Mu phage (Faelen et al., Mol. Gen. Genet. 176:191-197, 1979). The frequency of mini-Mu-duction reported previously was low (10(-8) to 10(-9) per recipient cell) thus limiting its use to rather stable mutational lesions. I have increased the frequency of mini-Mu-duction 10- to 100-fold by use of a helper phage lacking the kil gene and by UV irradiation of the phage stocks. I have also shown that mini-Mu-duction is a reliable complementation assay in rec+ as well as recA recipient strains. This genetic complementation test does not require prior gene localization and (due to the extended host range of phage Mu) should be applicable to many enterobacterial species.     

Further characterization of a non-essential mutator gene in Escherichia coli K-12.

The properties of mutR, a mutator closely linked to thyA, have been further characterized. We have found that the mutator gene is carried on a specialized transducing phage (lambdapcI857 thyA) generated by the excision of lambdacI857 integrated at a secondary attachment site between lysA and thyA. We present three lines of evidence indicating that mutR is a nonessential gene. (i) Deletions of the mutator can be found amoung survivors of heat induction of lambdacI857 when the phage is integrated between lysA and thyA. (ii) Mutations in mutR can be induced with the frameshift mutagen ICR-191. (iii) An amber mutant in mutR has been found. Viable strains could be made by combining the mutator with polB, polA polR, ligts7, and uvrA mutations. The mutator was still able to increase the spontaneous mutation frequency in these genetic backgrounds. When the reversion patterns of a series of well-characterized trpA mutations were analyzed, the results suggested that mutR is more efficient at causing transitions than transversion mutations.