Walter H. Koch

Escherichia coli umuDC mutants : DNA sequence alterations and UmuD cleavage

SummaryThe products of the chromosomally encoded umuDC genes are directly required for mutagenesis in Escherichia coli. Strains with either umuD or umuC mutations are rendered phenotypically non-mutable. To ascertain the molecular basis of this non-mutability, we determined the DNA sequence alterations of seven chromosomal umuDC mutants. Six mutants (umuD1, umuD44, umuD77, umuC36, umuC25, and umuC104) were found to be single base-pair substitutions that resulted in missense mutations. The Tn5 transposon insertion mutation (umuC122) resulted in a missense mutation followed immediately by a termination codon, producing a truncated UmuC protein lacking 102 carboxyl-terminal amino acids. All of the mutations were found to reside in regions of the UmuD and UmuC proteins that share high homology with analogous proteins. Chemiluminescent immunoassays revealed that the umuD1, umuD44, and umuD77 mutations all resulted in a non-cleavable UmuD protein. Because UmuD cleavage is a prerequisite for mutagenesis, the lack of UmuD processing appears to be the molecular basis for the non-mutable phenotype in these strains. These studies re-emphasize the critical nature of the RecA-mediated cleavage of UmuD for inducible mutagenesis and provide insights into the functional domains of the UmuC protein.

Induction and cleavage of Salmonella typhimurium UmuD protein

SummarySOS mutagenesis in prokaryotes is dependent upon the inducible activity of the chromosomally encoded UmuDC proteins, or homologous proteins such as MucAB or ImpCAB which are found on naturally occurring plasmids. Relative to Escherichia coli, however, Salmonella typhimurium is much less responsive to the mutagenic effects of DNA-damaging agents, despite the fact that it possesses both chromosomally and plasmid encoded umu-like operons. In E. coli, activation of the UmuD mutagenesis protein to UmuD′ via RecA-mediated proteolysis is a critical step in the mutation fixation pathway. We have used a polyclonal antiserum raised against the E. coli UmuD and UmuD′ proteins to show that S. typhimurium expresses cross-reacting material only after treatment with the DNA-damaging agent mitomycin C. The S. typhimurium umuDC operon, therefore, appears to be regulated by mechanisms similar to the E. coli umuDC operon. After induction, the S. typhimurium UmuD protein was processed to UmuD′ in both S. typhimurium and E. coli. However, the S. typhimurium UmuD protein appears to be cleaved more efficiently than the E. coli UmuD protein under similar conditions. The data suggest that conversion of UmuD to the mutagenically active UmuD′ is not the rate-limiting factor accounting for the weakly mutable phenotype of S. typhimurium.

Identification of mucAB-like homologs on two IncT plasmids, R394 and Rts-1.

Recent phylogenetic analysis of the superfamily of lesion-replicating DNA polymerases suggest that they can be broadly divided into four sub-groups comprised of UmuC-like, DinB-like, Rev1-like and Rad30-like proteins. The UmuC-like sub-family is best characterized at the genetic level and sequence analysis of eleven umu orthologs, residing on bacterial chromosomes or on self-transmissible R-plasmids allows further subdivision into five sub-groups (UmuDC, MucAB, ImpAB, RumAB and RulAB) based on amino acid sequence conservation. Some of these orthologs are apparently inactive in situ, but may promote increased mutagenesis and survival when subcloned and expressed from high-copy number plasmids. We were, therefore, interested in devising an assay that would identify umuC-like genes in situ in the absence of a functional assay. To this end, degenerate primers directed towards conserved amino acid regions within the UmuC-like sub-family of DNA polymerases were designed and used to identify mucAB-like operons on the IncT plasmids, R394 and Rts-1.Interestingly, DNA sequence analysis of an approximately 7kb region of R394 identified two LexA-regulated genes immediately downstream of mucAB((R394)) that are similar to the chromosomally-encoded Escherichia coli tus gene and the IncI plasmid-encoded impC gene, respectively. Analysis of the R394 and Rts-1 mucB genes revealed that both contain insertions which result in the expression of a truncated inactive MucB protein. While R394 was unable to restore mutagenesis functions to a DeltaumuDC E. coli strain, Rts-1 surprisingly promoted significant levels of MMS-induced SOS mutagenesis, raising the possibility that Rts-1 encodes another, yet unidentified, umu-like homolog.

DNA probe for detecting Salmonella enteritidis in food

Salmonellosis is the most frequently reported foodborne illness in the United States, with Salmonella enteritidis being the leading cause of these outbreaks. Nucleotide sequence comparisons of the Salmonella plasmid virulence (spv) genes of S. enteritidis with those of S. typhimurium and S. dublin have revealed that a single base-pair change unique to S. enteritidis is present in the spvA gene. An 18-base synthetic oligonucleotide probe (SE-probe) that is completely homologous to the spvA gene of S. enteritidis but which has one base pair mismatch with other salmonellae was shown to be specific for S. enteritidis. In colony hybridization blots, 129 isolates of S. enteritidis, 29 other species of Salmonella, and 17 non-Salmonella spp. were tested with the SE-probe. The SE-probe hybridized with 96% of the S. enteritidis strains tested but did not react with the other Salmonella or non-Salmonella strains. These data suggest that the SE-probe can be used in a specific and rapid detection assay for S. enteritidis.

Analysis of chimeric UmuC proteins: identification of regions inSalmonella typhimurium UmuC important for mutagenic activity

UnlikeEscherichia coli, the closely related bacteriumSalmonella typhimurium is relatively unresponsive to the mutagenic effects of DNA-damaging agents. Previous experiments have suggested that these phenotypic differences might result from reduced activity of theS. typhimurium UmuC protein. To investigate this possibility, we have taken advantage of the high degree of homology between the UmuC proteins ofE. coli andS. typhimurium and have constructed a series of plasmid-encoded chimeric proteins. The possibility that the phenotypic differences might be due to differential expression of the respective UmuC proteins was eliminated by constructing chimeric proteins that retained the first 25 N-terminal amino acids of either of the UmuC proteins (and presumably the same translational signals), but substituting the remaining 397 C-terminal amino acids with the corresponding segments from the reciprocal operon. Constructs expressing mostlyE. coli UmuC were moderately proficient for mutagenesis whereas those expressing mostlyS. typhimurium UmuC exhibited much lower frequencies of mutation, indicating that the activity of the UmuC protein ofS. typhimurium is indeed curtailed. The regions responsible for this phenotype were more precisely localized by introducing smaller segments of theS. typhimurium UmuC protein into the UmuC protein ofE. coli. While some regions could be interchanged with few or no phenotypic effects, substitution of residues 212–395 and 396–422 ofE. coli UmuC with those fromS. typhimurium resulted in reduced mutability, while substitution of residues 26–59 caused a dramatic loss of activity. We suggest, therefore, that the primary cause for the poor mutability ofS. typhimurium can be attributed to mutations located within residues 26–59 of theS. typhimurium UmuC protein.