A Constitutively Expressed, Truncated umuDC Operon Regulates the recA-Dependent DNA Damage Induction of a Gene in Acinetobacter baylyi Strain ADP1

In response to environmentally caused DNA damage, SOS genes are up-regulated due to RecA-mediated relief of LexA repression. In Escherichia coli, the SOS umuDC operon is required for DNA damage checkpoint functions and for replicating damaged DNA in the error-prone process called SOS mutagenesis. In the model soil bacterium Acinetobacter baylyi strain ADP1, however, the content, regulation, and function of the umuDC operon are unusual. The umuC gene is incomplete, and a remnant of an ISEhe3-like transposase has replaced the middle 57% of the umuC coding region. The umuD open reading frame is intact, but it is 1.5 times the size of other umuD genes and has an extra 5′ region that lacks homology to known umuD genes. Analysis of a umuD::lacZ fusion showed that umuD was expressed at very high levels in both the absence and presence of mitomycin C and that this expression was not affected in a recA-deficient background. The umuD mutation did not affect the growth rate or survival after UV-induced DNA damage. However, the UmuD-like protein found in ADP1 (UmuDAb) was required for induction of an adjacent DNA damage-inducible gene, ddrR. The umuD mutation specifically reduced the DNA damage induction of the RecA-dependent DNA damage-inducible ddrR locus by 83% (from 12.9-fold to 2.3-fold induction), but it did not affect the 33.9-fold induction of benA, an unrelated benzoate degradation gene. These data suggest that the response of the ADP1 umuDC operon to DNA damage is unusual and that UmuDAb specifically regulates the expression of at least one DNA damage-inducible gene.     

Sequence analysis and mapping of the Salmonella typhimurium LT2 umuDC operon.

In Escherichia coli, efficient mutagenesis by UV requires the umuDC operon. A deficiency in umuDC activity is believed to be responsible for the relatively weak UV mutability of Salmonella typhimurium LT2 compared with that of E. coli. To begin evaluating this hypothesis and the evolutionary relationships among umuDC-related sequences, we cloned and sequenced the S. typhimurium umuDC operon. S. typhimurium umuDC restored mutability to umuD and umuC mutants of E. coli. DNA sequence analysis of 2,497 base pairs (bp) identified two nonoverlapping open reading frames spanning 1,691 bp that were were 67 and 72% identical at the nucleotide sequence level to the umuD and umuC sequences, respectively, from E. coli. The sequences encoded proteins whose deduced primary structures were 73 and 84% identical to the E. coli umuD and umuC gene products, respectively. The two bacterial umuDC sequences were more similar to each other than to mucAB, a plasmid-borne umuDC homolog. The umuD product retained the Cys-24--Gly-25, Ser-60, and Lys-97 amino acid residues believed to be critical for RecA-mediated proteolytic activation of UmuD. The presence of a LexA box 17 bp upstream from the UmuD initiation codon suggests that this operon is a member of an SOS regulon. Mu d-P22 inserts were used to locate the S. typhimurium umuDC operon to a region between 35.9 and 40 min on the S. typhimurium chromosome. In E. coli, umuDC is located at 26 min. The umuDC locus in S. typhimurium thus appears to be near one end of a chromosomal inversion that distinguishes gene order in the 25- to 35-min regions of the E. coli and S. typhimurium chromosomes. It is likely, therefore, that the umuDC operon was present in a common ancestor before S. typhimurium and E. coli diverged approximately 150 million years ago. These results provide new information for investigating the structure, function, and evolutionary origins of umuDC and for exploring the genetic basis for the mutability differences between S. typhimurium and E. coli.     

Identification of a umuDC locus in Salmonella typhimurium LT2.

The umuDC operon of Escherichia coli is required for efficient mutagenesis by UV light and many other DNA-damaging agents. The existence of a umuDC analog in Salmonella typhimurium has been questioned. With DNA probes to the E. coli umuD and umuC genes, we detected, by Southern blot hybridization, sequences similar to both of these genes in S. typhimurium LT2. We also confirmed that the presence of cloned E. coli umuD enhances the UV mutability and resistance of S. typhimurium. Our data strongly suggest that S. typhimurium contains a functional umuDC operon.     

Cloning of Salmonella typhimurium DNA encoding mutagenic DNA repair.

Mutagenic DNA repair in Escherichia coli is encoded by the umuDC operon. Salmonella typhimurium DNA which has homology with E. coli umuC and is able to complement E. coli umuC122::Tn5 and umuC36 mutations has been cloned. Complementation of umuD44 mutants and hybridization with E. coli umuD also occurred, but these activities were much weaker than with umuC. Restriction enzyme mapping indicated that the composition of the cloned fragment is different from the E. coli umuDC operon. Therefore, a umu-like function of S. typhimurium has been found; the phenotype of this function is weaker than that of its E. coli counterpart, which is consistent with the weak mutagenic response of S. typhimurium to UV compared with the response in E. coli.     

Lack of umuDC gene functions in Vibrio cholerae cells

Attempts to identify an umuDC analog, using interspecific complementation of Escherichia coli mutants with plasmids containing a gene bank of Vibrio cholerae, were not successful. The DNA from none of the vibrio species examined including marine vibrios hybridized to E. coli umuC and umuD gene sequences. These cells are not mutable by ultraviolet (UV) light and cannot Weigle-reactivate UV-irradiated choleraphages, suggesting that vibrios are deficient in the umuDC operon. This possibility is supported by the fact that when the plasmid pKM101 carrying the mucAB genes is introduced into V. cholerae cells, they acquire the UV-mutable phenotype and UV-irradiated choleraphages can be Weigle-reactivated.     

Substitution of UmuD' for UmuD does not affect SOS mutagenesis

In order to study the role of UmuDC proteins in SOS mutagenesis, we have constructed new Escherichia coli K-12 strains to avoid i) over-production of Umu proteins, ii) the formation of unwanted mixed plasmid and chromosomal Umu proteins upon complementation. We inserted a mini-kan transposon into the umuD gene carried on a plasmid. The insertion at codon 24 ends protein translation and has a polar effect on the expression of the downstream umuC gene. We transferred umuD24 mutation to the E coli chromosome. In parallel, we subcloned umuD+ umuC+ or umuD' umuC+ genes into pSC101, a low copy number plasmid. In a host with the chromosomal umuD24 mutation, plasmids umuD+ umuC+ or umuD' umuC+ produced elevated resistance to UV light and increased SOS mutagenesis related to a gene dosage of about 3. UV mutagenesis was as high in umuD' umuC+ hosts devoid of UmuD+ protein as in umuD+ umuC+ hosts. UmuD' protein, the maturated form of UmuD, can substitute for UmuD in SOS mutagenesis.     

Structural characterization of the Salmonella typhimurium LT2 umu operon.

The umuDC operon of Escherichia coli encodes functions required for mutagenesis induced by radiation and a wide variety of chemicals. The closely related organism Salmonella typhimurium is markedly less mutable than E. coli, but a umu homolog has recently been identified and cloned from the LT2 subline. In this study the nucleotide sequence and structure of the S. typhimurium LT2 umu operon have been determined and its gene products have been identified so that the molecular basis of umu activity might be understood more fully. S. typhimurium LT2 umu consists of a smaller 417-base-pair (bp) umuD gene ending 2 bp upstream of a larger 1,266-bp umuC gene. The only apparent structural difference between the two operons is the lack of gene overlap. An SOS box identical to that found in E. coli is present in the promoter region upstream of umuD. The calculated molecular masses of the umuD and umuC gene products were 15.3 and 47.8 kilodaltons, respectively, which agree with figures determined by transpositional disruption and maxicell analysis. The S. typhimurium and E. coli umuD sequences were 68% homologous and encoded products with 71% amino acid identity; the umuC sequences were 71% homologous and encoded products with 83% amino acid identity. Furthermore, the potential UmuD cleavage site and associated catalytic sites could be identified. Thus the very different mutagenic responses of S. typhimurium LT2 and E. coli cannot be accounted for by gross differences in operon structure or gene products. Rather, the ability of the cloned S. typhimurium umuD gene to give stronger complementation of E. coli umuD77 mutants in the absence of a functional umuC gene suggests that Salmonella UmuC protein normally constrains UmuD protein activity.     

umuDC-mediated cold sensitivity is a manifestation of functions of the UmuD(2)C complex involved in a DNA damage checkpoint control

The umuDC genes are part of the Escherichia coli SOS response, and their expression is induced as a consequence of DNA damage. After induction, they help to promote cell survival via two temporally separate pathways. First, UmuD and UmuC together participate in a cell cycle checkpoint control; second, UmuD'(2)C enables translesion DNA replication over any remaining unrepaired or irreparable lesions in the DNA. Furthermore, elevated expression of the umuDC gene products leads to a cold-sensitive growth phenotype that correlates with a rapid inhibition of DNA synthesis. Here, using two mutant umuC alleles, one that encodes a UmuC derivative that lacks a detectable DNA polymerase activity (umuC104; D101N) and another that encodes a derivative that is unable to confer cold sensitivity but is proficient for SOS mutagenesis (umuC125; A39V), we show that umuDC-mediated cold sensitivity can be genetically separated from the role of UmuD'(2)C in SOS mutagenesis. Our genetic and biochemical characterizations of UmuC derivatives bearing nested deletions of C-terminal sequences indicate that umuDC-mediated cold sensitivity is not due solely to the single-stranded DNA binding activity of UmuC. Taken together, our analyses suggest that umuDC-mediated cold sensitivity is conferred by an activity of the UmuD(2)C complex and not by the separate actions of the UmuD and UmuC proteins. Finally, we present evidence for structural differences between UmuD and UmuD' in solution, consistent with the notion that these differences are important for the temporal regulation of the two separate physiological roles of the umuDC gene products.     

Amino acid similarities to other proteins offer insights into roles of UmuD and UmuC in mutagenesis

The products of the umuD and umuC genes are required for most uv and chemical mutagenesis in Escherichia coli. The genes are organized in an operon that is repressed by LexA and regulated as part of the SOS response. The umuD protein shares homology with the carboxyl-terminal domain of LexA. Genetic evidence now indicates that RecA-mediated cleavage activates UmuD for its role in mutagenesis. The COOH-terminal fragment of UmuD is both necessary and sufficient for this role. Similarities of UmuD to gene 45 protein of bacteriophage T4 and of UmuC to gene 44 protein and gene 62 protein suggest possible roles for UmuD and UmuC in mutagenesis that are supported by preliminary evidence.     

Different mechanisms for SOS induced alleviation of DNA restriction in Escherichia coli.

The alleviation of DNA restriction during the SOS response in Escherichia coli has been further investigated. With the EcoK DNA restriction system UV irradiated wild-type cells show a 10(4)-fold increase in ability to plate non-modified lambda phage and a 3-4 fold increase in transformation by non-modified plasmid DNA. A role for the umuDC genes of E coli in the process of SOS-induced restriction alleviation was identified by showing that a umuC122::Tn5 mutant could alleviate EcoK restriction to only 5% that of wild-type levels. Although umuDC are better characterized for their pivotal role in SOS induced mutagenesis, it is demonstrated here that umu-dependent alleviation of EcoK restriction is a transient process in which umu-dependent mutagenesis plays little part. A second form of SOS induced alleviation of DNA restriction is described in this paper involving the McrA restriction system. The mcrA gene is shown to be encoded within a defective prophage called e14 situated at the 25 min region on the Escherichia coli genetic map. e14 is known to abortively excise from the chromosome after SOS induction and it is demonstrated in this report that mcrA is lost from the genome after SOS induction as part of e14. This results in co-ordinate decrease in the level of McrA restriction within a population of cells.     

Mechanism of SOS-induced targeted and untargeted mutagenesis in E. coli

This paper retraces the evolution of hypotheses concerning mechanisms of SOS induced mutagenesis. Moreover, it reports some recent data which support a new model for the mechanism of targeted and untargeted mutagenesis in E. coli. In summary, the SOS mutator effect, which is responsible for untargeted mutagenesis and perhaps for the misincorporation step in targeted mutagenesis, is believed to involve a fidelity function associated with DNA polymerase III and does not require the umuC gene product. umuC and umuD gene products are probably required specifically for elongation of DNA synthesis past blocking lesions, i.e. to allow mutagenic replication of damaged DNA.     

UV mutagenesis in Salmonella typhimurium is umuDC dependent despite the presence of samAB.

We investigated the role of the umuDC and samAB operons in the UV mutability of Salmonella typhimurium. umuDC is located on the chromosome, whereas samAB resides on the virulence plasmid pSLT. Using allele replacement and plasmid curing techniques, we found that UV mutability was eliminated when any of three different umuDC alleles (umuD1, umuC1, or umuD1 umuC1) were on the chromosome even when samAB was present. We conclude that samAB normally does not complement umuDC function in S. typhimurium.     

A role for the umuDC gene products of Escherichia coli in increasing resistance to DNA damage in stationary phase by inhibiting the transition to exponential growth

The umuDC gene products, whose expression is induced by DNA-damaging treatments, have been extensively characterized for their role in SOS mutagenesis. We have recently presented evidence that supports a role for the umuDC gene products in the regulation of growth after DNA damage in exponentially growing cells, analogous to a prokaryotic DNA damage checkpoint. Our further characterization of the growth inhibition at 30 degrees C associated with constitutive expression of the umuDC gene products from a multicopy plasmid has shown that the umuDC gene products specifically inhibit the transition from stationary phase to exponential growth at the restrictive temperature of 30 degrees C and that this is correlated with a rapid inhibition of DNA synthesis. These observations led to the finding that physiologically relevant levels of the umuDC gene products, expressed from a single, SOS-regulated chromosomal copy of the operon, modulate the transition to rapid growth in E. coli cells that have experienced DNA damage while in stationary phase. This activity of the umuDC gene products is correlated with an increase in survival after UV irradiation. In a distinction from SOS mutagenesis, uncleaved UmuD together with UmuC is responsible for this activity. The umuDC-dependent increase in resistance in UV-irradiated stationary-phase cells appears to involve, at least in part, counteracting a Fis-dependent activity and thereby regulating the transition to rapid growth in cells that have experienced DNA damage. Thus, the umuDC gene products appear to increase DNA damage tolerance at least partially by regulating growth after DNA damage in both exponentially growing and stationary-phase cells.     

RecA protein of Escherichia coli has a third essential role in SOS mutator activity.

The DNA damage-inducible SOS response of Escherichia coli includes an error-prone translesion DNA replication activity responsible for SOS mutagenesis. In certain recA mutant strains, in which the SOS response is expressed constitutively, SOS mutagenesis is manifested as a mutator activity. Like UV mutagenesis, SOS mutator activity requires the products of the umuDC operon and depends on RecA protein for at least two essential activities: facilitating cleavage of LexA repressor to derepress SOS genes and processing UmuD protein to produce a fragment (UmuD') that is active in mutagenesis. To determine whether RecA has an additional role in SOS mutator activity, spontaneous mutability (tryptophan dependence to independence) was measured in a family of nine lexA-defective strains, each having a different recA allele, transformed or not with a plasmid that overproduces either UmuD' alone or both UmuD' and UmuC. The magnitude of SOS mutator activity in these strains, which require neither of the two known roles of RecA protein, was strongly dependent on the particular recA allele that was present. We conclude that UmuD'C does not determine the mutation rate independently of RecA and that RecA has a third essential role in SOS mutator activity.     

Salmonella typhimurium has two homologous but different umuDC operons: cloning of a new umuDC-like operon (samAB) present in a 60-megadalton cryptic plasmid of S. typhimurium.

Expression of the umuDC operon is required for UV and most chemical mutagenesis in Escherichia coli. The DNA which can restore UV mutability to a umuD44 strain and to a umuC122::Tn5 strain of E. coli has been cloned from Salmonella typhimurium TA1538. DNA sequence analysis indicated that the cloned DNA potentially encoded proteins with calculated molecular weights of 15,523 and 47,726 and was an analog of the E. coli umuDC operon. We have termed this cloned DNA the samAB (for Salmonella mutagenesis) operon and tentatively referred to the umuDC operon of S. typhimurium LT2 (C. M. Smith, W. H. Koch, S. B. Franklin, P. L. Foster, T. A. Cebula, and E. Eisenstadt, J. Bacteriol. 172:4964-4978, 1990; S. M. Thomas, H. M. Crowne, S. C. Pidsley, and S. G. Sedgwick, J. Bacteriol. 172:4979-4987, 1990) as the umuDCST operon. The samAB operon is 40% diverged from the umuDCST operon at the nucleotide level. Among five umuDC-like operons so far sequenced, i.e., the samAB, umuDCST, mucAB, impAB, and E. coli umuDC operons, the samAB operon shows the highest similarity to the impAB operon of TP110 plasmid while the umuDCST operon shows the highest similarity to the E. coli umuDC operon. Southern hybridization experiments indicated that (i) S. typhimurium LT2 and TA1538 had both the samAB and the umuDCST operons and (ii) the samAB operon was located in a 60-MDa cryptic plasmid. The umuDCST operon is present in the chromosome. The presence of the two homologous but different umuDC operons may be involved in the poor mutability of S. typhimurium by UV and chemical mutagens.     

Diesel emissions revisited: is the carcinogenicity due to a genotoxic mechanism?

The induction of recA, umuC and sfiA genes by quercetin was studied in the presence and in the absence of S9 mix. The inducing activity of quercetin is higher for sfiA than for recA and umuC genes in the absence of S9 mix. The putative genotoxic metabolites of quercetin produced by S9 mix display different inducing activities of the three SOS genes as compared to quercetin. The induction of sfiA gene is decreased by the presence of S9 mix, whereas an opposite effect was observed concerning umuC and recA. These data suggest that the error-prone repair pathway participates in mutagenesis by quercetin and its metabolites. Moreover, the type of DNA damage exerted by quercetin seems to be determined by its metabolic fate. The importance of testing for the induction of other SOS genes, together with sfiA, in the study of SOS functions as a genotoxic index is emphasized.     

Identification and cloning of a umu locus in Streptomyces coelicolor A3(2)

The umuDC operon of Escherichia coli is required for efficient mutagenesis by UV and many other DNA-damaging agents. E. coli umu mutants are defective in mutagenesis and slightly more sensitive to DNA-damaging agents. The existence of a umuDC analogue in Streptomyces coelicolor was suggested by data of our previous works. We cloned from Streptomyces coelicolor a fragment of DNA homologous to the E. coli umuDC region that is able to complement the E coli umuC122::Tn5 mutation. Therefore our data suggest that S. coelicolor contains a functional umu-like operon.