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.     

Leucine regulation of the ilvGEDA operon of Serratia marcescens by attenuation is modulated by a single leucine codon.

The effect of leucine limitation and of restricted leucine tRNA charging on the expression of the ilvGEDA operon of Serratia marcescens was examined. In this organism, the ilv leader region specifies a putative peptide containing only a single leucine codon that could be involved in leucine-mediated control by attenuation (E. Harms, J.-H. Hsu, C. S. Subrahmanyam, and H. E. Umbarger, J. Bacteriol. 164:207-216, 1985). A plasmid (pPU134) containing the DNA of the S. marcescens ilv control region and three of the associated structural genes was studied as a single chromosomal copy in an Escherichia coli strain auxotrophic for all three branched-chain amino acids. The S. marcescens ilv genes responded to a multivalent control similar to that found in other enteric organisms. Furthermore, the S. marcescens ilv genes were derepressed when the charging of leucine tRNA was restricted in a leuS derivative of E. coli that had been transformed with pPU134. It was concluded that ribosome stalling leading to deattenuation is not dependent on either tandem or a consecutive series of codons for the regulatory amino acid. However, the fact that the single leucine codon is a less frequently used codon (CUA) may be important. The procedure for obtaining the cloned ilv genes in single chromosomal copy exploited the dependence of ColE1 replicons on the polA gene. The cloning experiments also revealed a branched-chain amino acid-glutamate transaminase in S. marcescens that is different from transaminase B.     

Evolutionary divergence of the Citrobacter freundii tryptophan operon regulatory region: comparison with other enteric bacteria

The regulatory region of the trp operon of Citrobacter freundii was sequenced and compared with the corresponding regions of other enteric bacteria. Significant differences were noted in the promoter region. These differences are presumably responsible for the weak expression of the cloned trp operon in Escherichia coli. The presumed operator region, although nonfunctional in E. coli, has dyad symmetry, but the sequence of the symmetrical region differs appreciably from those of operators that can be regulated by the E. coli trp repressor. The sequence of the trp leader region of C. freundii resembles that of other enteric bacteria, suggesting that the C. freundii operon is also regulated by attenuation. Comparison of the sequence of the initial portion of trpE with the homologous regions of E. coli and Salmonella typhimurium indicates that the three organisms probably are evolutionary equidistant.     

Genetic Fine Structure of the Leucine Operon of Escherichia coli K-12

The order of mutational sites in 10 independently isolated leucine auxotrophys of Escherichia coli K-12 was determined by three-point reciprocal transductions. The sites of mutation mapped in linear sequence in a cluster; all leucine auxotrophic mutations were cotransducible with mutations in the arabinose operon. The mutations were assigned to four complementation groups by abortive transduction tests, designated D, C, B, and A, reading in a clockwise direction from the arabinose operon. Enzyme analyses showed that strains with a mutation in gene A lacked alpha-isopropylmalate synthetase activity (EC 4.1.3), and those with a mutation in gene B lacked beta-isopropylmalate dehydrogenase activity (EC 1.1.1). It is concluded that the gross structure of the leucine operon in E. coli is closely similar to, if not identical with, the gross structure of the leucine operon in Salmonella typhimurium.     

Molecular cloning and physical and functional characterization of the Salmonella typhimurium and Salmonella typhi galactose utilization operons.

The chromosomally encoded galactose utilization (gal) operons of Salmonella typhimurium and S. typhi were each cloned on similar 5.5-kilobase HindIII fragments into pBR322 and were identified by complementation of Gal- Escherichia coli strains. Restriction endonuclease analyses indicated that these Salmonellae operons share considerable homology, but some heterogeneities in restriction sites were observed. Subcloning and exonuclease mapping experiments showed that both operons have the same genetic organization as that established for the E. coli gal operon (i.e., 5' end, promoter, epimerase, transferase, kinase, and 3' end). Two gal operator regions (oE and oI) of S. typhimurium, identified by repressor titration in an E. coli superrepressor [galR(Sup)] mutant, were sequenced and found to flank the promoter region. This promoter region is identical to the -10 and -35 regions of the E. coli gal operon. Minicell studies demonstrated that the three gal structural genes of S. typhimurium encode separate polypeptides of 39 kilodaltons (kDa) (epimerase, 337 amino acids [aa's]), 41 kDa (transferase, 348 aa's), and 43 kDa (kinase, 380 aa's). Despite functional and organizational similarities, DNA sequence analysis revealed that the S. typhimurium gal genes show less than 70% homology to the E. coli gal operon. Because of codon degeneracy, the deduced amino acid sequences of these polypeptides are highly conserved (greater than 90% homology) as compared with those of the E. coli gal enzymes. These studies have defined basic genetic parameters of the gal genes of two medically important Salmonella species, and our findings support the hypothesized divergent evolution of E. coli and Salmonella spp. from a common ancestral parent bacterium.     

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.     

Molecular cloning and characterization of supQ/newD, a gene substitution system for the leuD gene of Salmonella typhimurium.

The isopropylmalate isomerase of Salmonella typhimurium and Escherichia coli is a complex of the leuC and leuD gene products. The supQ/new D gene substitution system in S. typhimurium restores leucine prototrophy to leuD mutants of S. typhimurium. Previous genetic evidence supports a model that indicates the replacement of the missing LeuD polypeptide by the newD gene product. This model proposed that this gene substitution is possible when a mutation at the supQ locus (near newD) liberates unaltered newD polypeptide from its normal complex with the supQ protein product. In this study, recombinant plasmids carrying newD, supQ, or both were transformed into E. coli and S. typhimurium strains deleted for the leuD and supQ genes to test the supQ/newD gene substitution model for suppression of leucine auxotrophy. It was determined that the newD gene encodes a 22-kilodalton polypeptide which can restore leucine prototrophy to leuD deletion strains and that a functional supQ gene prevents this suppression. It was also determined that the supQ and newD genes are separated by a gene encoding a 50-kilodalton protein, pB. While there is extensive DNA sequence homology between the leucine operons of S. typhimurium and E. coli, DNA hybridization experiments did not indicate substantial homology between the newD and leuD genes. These data, taken together with previously obtained genetic data, eliminate the possibility that supQ and newD are recently translocated segments of the leucine operon.