Duplications of histidine transport genes in Salmonella typhimurium and their use for the selection of deletion mutants.

We demonstrate that tandem duplications of the histidine transport operon can be selected by requesting elevated levels of transport activity to be present. Several strains were constructed which contain duplications heterozygotic for either hisJ, hisQ, or hisP. The size of one duplication which was analyzed in detail is about 16 genes, with one end close to the promoter site (dhuA) of the histidine transport operon and, therefore, enclosing about 12 more genes counterclockwise to this operon. Duplication-carrying strains could be utilized for the selection of deletion mutations by requiring both copies of the operon to be rendered defective simultaneously and, therefore, unable to transport into the cell an inhibitory histidine analog, alpha-hydrazino imidazole propionic acid. Over 60% (probably as high as 100%) of the alpha-hydrazino imidazole propionic acid-resistant strains arising in the selection are deletion mutants. The principle of our selection method is generally applicable and will be useful in the accumulation of deletions for mapping and fusing of genes and other purposes.     

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).     

Isolation of F' plasmids carrying a portion of the Salmonella typhimurium histidine transport operon.

The transposable drug resistance element Tn10 was employed as a region of homology to direct the insertion of Tn10-containing derivatives of F'ts114 lac into the chromosome of a Salmonella typhimurium strain that carries a Tn10 insertion in the histidine transport operon. Based on the direction of transfer of the resulting Hfr strains, the chromosomal Tn10 insertion was determined to be in orientation "A." New F' plasmids were selectively generated from one of the Hfr strains. The F' factors carry an intact dhuA hisJ portion of the histidine transport operon. A Southern hybridization revealed that one of the F' plasmids was formed by a type II excision event.     

Mutants of Salmonella typhimurium able to utilize D-histidine as a source of L-histidine

Secondary mutants able to utilize d-histidine, dhu, were isolated in histidine auxotrophs of Salmonella typhimurium. Mutations of one class (dhuA) are closely linked with the hisP locus which codes for a component of histidine permease. The specific activity of l-histidine permeation was estimated as increased two- to seven-fold in dhuA mutants. The dhuB mutants which have not been mapped also had elevated specific activity of l-histidine permeation. The uptake of d-histidine, barely detectable in the parental strains, was prominent in dhuA mutants and showed an apparent Michaelis constant about 1,000-fold higher than that observed with l-histidine. No change was detected in the kinetics of l-histidine permeation. d- and l-histidine competed in the uptake process. Tertiary mutants which lost the ability to grow on d-histidine were isolated by ampicillin counter-selection in dhuA his(-) strains. All of them mapped in the dhuA hisP region. Most of them had all known properties of hisP mutants. It is inferred from these data that the dhuA mutations increase synthesis of components critical to d- and l-histidine permeation.     

Histidine and Aromatic Permeases of Salmonella typhimurim

Mutants defective either in the histidine permease (hisP) or in the aromatic permease (aroP) were isolated in Salmonella typhimurium and were characterized. The hisP locus had a 49% linkage to purF by phage transduction. The aroP locus was close to proA. Merozygotes diploid for the hisP gene were constructed by episomal transfer, and hisP(+) was dominant over hisP. The properties of merozygotes are described and discussed. A method for the selection of revertants of hisP mutants was devised. By this method, one of the hisP mutants was characterized as an amber mutant. The specificity of the aromatic permease was investigated by using as substrates analogues of the aromatic amino acids and of histidine.     

Isolation and Characterization of acetate kinase and phosphotransacetylase mutants of Escherichia coli and Salmonella typhimurium.

Mutations in the ack (acetate kinase) and pta (phosphotransacetylase) genes in Salmonella typhimurium were characterized and determined to be analogous to those of previously described Escherichia coli mutants. We established that in both bacterial species these genes were cotransducible with the neighboring histidine transport operon and were distally located relative to purF. pta mutants were sensitive to the dye alizarin yellow and were unable to grow on medium containing inositol as a carbon source. We selected mutants of both species with deletions covering both the ack and the pta genes; some deletions extended into the histidine transport operon.     

Physical map of the Salmonella typhimurium histidine transport operon: correlation with the genetic map.

A detailed restriction map of a 12.4-kilobase EcoRI fragment of Salmonella typhimurium deoxyribonucleic acid (DNA) containing the entire histidine transport operon and the argT gene is presented. Subclones of specific regions of the transport operon of S. typhimurium were constructed in plasmid vectors. An accurate correlation between the restriction map and the location of genetically defined deletions was obtained by hybridizing restriction digests of chromosomal DNA from strains carrying each deletion with cloned transport operon DNA as a probe. These data were used to position the histidine transport genes on the cloned 12.4-kilobase fragment of DNA.     

Analysis of promoter mutations in the histidine transport operon of Salmonella typhimurium: use of hybrid M13 bacteriophages for cloning, transformation, and sequencing.

Mutations that cause an increased level of expression of the histidine transport operon were isolated and characterized genetically. Five independently isolated promoter-up mutations were transferred to an M13 hybrid phage that carries the histidine transport operon, and their nucleotide sequences were determined. For all five mutations, the change was the same as the one previously determined for promoter-up mutation dhuA1: a C-to-T change in the Pribnow box rendered this region more homologous to the consensus sequence. Methods for enabling Salmonella typhimurium to support growth of M13 phage effectively and for easy transfer of chromosomal mutations onto the hybrid phage are presented.     

Nitrogen control of Salmonella typhimurium: co-regulation of synthesis of glutamine synthetase and amino acid transport systems.

Nitrogen control in Salmonella typhimurium is not limited to glutamine synthetase but affects, in addition, transport systems for histidine, glutamine, lysine-arginine-ornithine, and glutamate-aspartate. Synthesis of both glutamine synthetase and transport proteins is elevated by limitation of nitrogen in the growth medium or as a result of nitrogen (N)-regulatory mutations. Increases in the amounts of these proteins were demonstrated by direct measurements of their activities, by immunological techniques, and by visual inspection of cell fractions after gel electrophoresis. The N-regulatory mutations are closely linked on the chromosome to the structural gene for glutamine synthetase, glnA: we discuss the possibility that they lie in a regulatory gene, glnR, which is distinct from glnA. Increases in amino acid transport in N-regulatory mutant strains were indicated by increased activity in direct transport assays, improved growth on substrates of the transport systems, and increased sensitivity to inhibitory analogs that are trnasported by these systems. Mutations to loss of function of individual transport components (hisJ, hisP, glnH, argT) were introduced into N-regulatory mutant strains to determine the roles of these components in the phenotype and transport behavior of the strains. The structural gene for the periplasmic glutamine-binding protein, glnH, was identified, as was a gene argT that probably encodes the structure of the lysine-arginine-ornithine-binding protein. Genes encoding the structures of the histidine- and glutamine-binding proteins are not linked to glnA or to each other by P22-mediated transduction; thus, nitrogen control is exerted on several unlinked genes.     

Isolation of mutants with impaired retroinhibition of histidine biosynthesis

The Escherichia coli, strain possessing purF, deoD and add mutations converts exogenous adenine into guanine nucleotides exclusively by the pathway coupled with histidine biosynthesis. When grown on adenine, this strain demonstrated sensitivity to histidine, thus making it possible to select histidine-resistant hisGR mutants with ATP-phosphoribosyltransferase desensibilized for histidine. The hisGR mutations were obtained in two his operons introduced into the his operon-sensitive E. coli strain: his operon of Salmonella typhimurium incorporated in DNA and his operon of E. coli on the F'episome. In both cases, the hisGR mutants obtained were shown to excrete histidine.     

An analysis of the structure of the product of the rbsA gene of Escherichia coli K12

The predicted amino acid sequence of rbsA, a gene from the high affinity ribose transport operon (rbs) of Escherichia coli K12, is homologous to the products of hisP, malK, and pstB, components of the histidine, maltose, and phosphate high affinity transport operons. The recent finding by Hobson et al. (Hobson, A. C., Weatherwax, R., and Ames, G.F.-L. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 7333-7337) that the hisP and malK products bind ATP suggests that these four gene products may be involved in coupling the energy from ATP to drive the active transport in their respective transport systems. Each gene product contains a sequence of glycine and basic residues which are characteristic of an ATP-binding site (Walker, J.E., Saraste, M., Runswick, M.J., and Gay, N.J. (1982) EMBO J. 1, 945-951). Interestingly the N- and C-terminal halves of rbsA are also homologous, suggesting that a primordial gene duplication and subsequent fusion of the products occurred.     

A chimeric nucleotide-binding protein, encoded by a hisP–malK hybrid gene, is functional in maltose transport in Salmonella typhimurium

We have isolated a hybrid gene, composed of the first 455 nucleotides of hisP and nucleotides 275-1107 of malK, the genes coding for the nucleotide-binding components of the high-affinity transport systems for histidine and maltose in Salmonella typhimurium, respectively. The fusion had occurred by recombination within 11 homologous base pairs located between the two DNA fragments. In the chimeric protein peptidic motifs A and B, proposed to be part of the nucleotide-binding fold, originate from HisP and MalK, respectively. Plasmid pES42-39, harbouring the hybrid gene, was shown to complement only a malK mutation but failed to complement a hisP deletion mutation. The chimeric protein was identified by immunoblotting as a protein with an apparent molecular mass of 49kDa. Removal of the C-terminal 77 amino acid residues from the chimeric protein resulted in the loss of function in transport. In contrast, 51 amino acid residues could be removed from the C-terminus of wild-type MalK without any effect. Upon overproduction the chimeric protein, as wild-type MalK, inhibited expression of the malB regulon. However, both truncated proteins, when overproduced, did not exhibit this activity. Based on these results, a tentative model of the functional domains of MalK is presented.     

Nucleotide binding by membrane components of bacterial periplasmic binding protein-dependent transport systems.

Bacterial periplasmic binding protein-dependent transport systems require the function of a specific substrate-binding protein, located in the periplasm, and several membrane-bound components. We present evidence for a nucleotide-binding site on one of the membrane components from each of three independent transport systems, the hisP, malK and oppD proteins of the histidine, maltose and oligopeptide permeases, respectively. The amino acid sequence of the oppD protein has been determined and this protein is shown to share extensive homology with the hisP and malK proteins. Three lines of evidence lead us to propose the existence of a nucleotide-binding site on each of these proteins. A consensus nucleotide-binding sequence can be identified in the same relative position in each of the three proteins. The oppD protein binds to a Cibacron Blue affinity column and can be eluted by ATP but not by CTP or NADH. The oppD protein is labelled specifically by the nucleotide affinity analogue 5'-p-fluorosulphonylbenzoyladenosine. The identification of a nucleotide-binding site provides strong evidence that transport by periplasmic binding protein-dependent systems is energized directly by the hydrolysis of ATP or a closely related nucleotide. The hisP, malK and oppD proteins are thus responsible for energy-coupling to their respective transport systems.     

Evidence for a common mechanism for the insertion of the Tn10 transposon and for the generation of Tn10-stimulated deletions

Summary Mutations in and near the Salmonella typhimurium histidine transport operon were generated by insertion of the translocatable tetracycline-resistance element Tn10. Deletion mutants affecting histidine transport genes were subsequently isolated in several of the Tn10-containing strains. Tn10 insertions in hisJ occurred preferentially at one site, designated site A. This same site was also the preferential endpoint of deletions originating from Tn10 insertions at two neighboring sites. Thus, Tn10 insertion and Tn10-stimulated deletion formation appear to involve a common DNA-recogition step.