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.     

Role of the intercistronic region in post-transcriptional control of gene expression in the histidine transport operon of Salmonella typhimurium: involvement of REP sequences

The high-affinity histidine permease of Salmonella typhimurium is encoded by a four-gene operon containing a large intercistronic region located between the first gene (hisJ) and the three distal genes (hisQ, hisM, hisP). The level of expression of hisJ is 30-fold greater than that of hisP. In order to investigate the role of the intercistronic region in intra-operonic control of gene expression, we have isolated MudII-mediated lacZ gene fusions to hisQ, hisM and hisP. We have used these fusions to isolate and analyse mutants that have altered levels of expression of the hisQ gene, the first gene downstream from the intercistronic region. The results indicate that intra-operonic regulation is due to a combination of factors including efficiency of translational initiation, mRNA degradation, and retroregulation of hisJ expression. They also suggest that the REP (Repetitive Extragenic Palindromic) sequences, which are located in the hisJ-hisQ intercistronic region, may interfere with translation of the hisQ gene and affect upstream messenger RNA stability by protecting it from 3' to 5' nuclease degradation (in agreement with data presented by Newbury et al., 1987).     

Delineation of the transcriptional boundaries of the lux operon of Vibrio harveyi demonstrates the presence of two new lux genes

The 5' and 3' ends of the lux mRNA of Vibrio harveyi, which extends over 8 kilobases, have been mapped, and two new genes, luxG and luxH, were identified at the 3' end of the lux operon. Both S1 nuclease and primer extension mapping demonstrated that the start site for the lux mRNA was 26 bases before the initiation codon of the first gene, luxC. The promoter region contained a typical -10 but not a recognizable -35 consensus sequence. By using S1 nuclease mapping the mRNA was found to be induced in a cell density- and arginine-dependent manner. The DNA downstream of the five known V. harveyi lux genes, luxCDABE, was sequenced and found to contain coding regions for two new genes, designated luxG and luxH, followed by a classical rho-independent termination signal for RNA polymerase. luxG codes for a protein of 233 amino acids with a molecular weight of 26,108, and luxH codes for a protein of 230 amino acids with a molecular weight of 25,326. The termination signal is active in vivo as demonstrated by 3' S1 nuclease mapping, confirming that the two genes are part of the V. harveyi lux operon. Comparison of the luxG amino acid sequence with coding regions immediately downstream from luxE in other luminescent bacteria has demonstrated that this gene may be a common component of the luminescent systems in different marine bacteria.     

Genetic complementation of the Saccharomyces cerevisiae leu2 gene by the Escherichia coli leuB gene.

The leucine operon of Escherichia coli was cloned on a plasmid possessing both E. coli and Saccharomyces cerevisiae replication origins. This plasmid, pEH25, transformed leuA, leuB, and leuD auxotrophs of E. coli to prototrophy; it also transformed leu2 auxotrophs of S. cerevisiae to prototrophy. beta-Isopropylmalate dehydrogenase was encoded by the leuB gene of E. coli and the leu2 gene of yeast. Verification that the leuB gene present on pEH26 was responsible for complementing yeast leu2 was obtained by isolating in E. coli several leuB mutations that resided on the plasmid. These mutant leuB- plasmids were no longer capable of complementing leu2 in S. cerevisiae. We conclude that S. cerevisiae is capable of transcribing at least a portion of the polycistronic leu operon of E. coli and can translate a functional protein from at least the second gene of this operon. The yeast Leu+ transformants obtained with pEH25, when cultured in minimal medium lacking leucine, grew with a doubling time three to four times longer than when cultured in medium supplemented with leucine.     

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.