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.     

Cloning,expression, and nucleotide sequence of livR,the repressor for high-affinity branched-chain amino acid transport in Escherichia coli

The livR gene encoding the repressor for high-affinity branched-chain amino acid transport in Escherichia coli has been cloned from a library prepared from the episome F106. The inserted DNA fragment from the initial cloned plasmid, pANT1, complemented two independent, spontaneously derived, regulatory mutations. Subcloning as well as the creation of deletions with Bal31 exonuclease revealed that the entire regulatory region is contained within a 1.1-kb RsaI-SalI fragment. Expression of the pANT plasmids in E. coli minicells showed that the regulatory region encodes one detectable protein with an apparent molecular weight of 21,000. DNA sequencing revealed one open reading frame of 501 bp encoding a protein with a calculated MW of 19,155. The potential secondary structure of the regulatory protein has been predicted and it suggests that the carboxy terminus may fold into three consecutive alpha helices. These results suggests that the livR gene encodes a repressor which plays a role in the regulation of expression of the livJ and the livK transport genes.     

Dicarboxylic acid transport in Rhizobium meliloti: isolation of mutants and cloning of dicarboxylic acid transport genes

The role of the dicarboxylic acid transport (dct) system in the Rhizobium meliloti-Alfalfa symbiosis was investigated. Mutants of R. meliloti CM2 unable to grow on medium containing succinate as the sole carbon source were isolated following chemical and transposon mutagenesis. These mutants were also unable to utilize malate or fumarate as the sole source of carbon. Transport studies with ¹⁴C-labelled succinate showed that the mutants were specifically defective in succinate transport. Revertants of both chemical and transposon mutants were obtained at a frequency of 10^-5–10^-6. The R. meliloti dct mutants were able to nodulate Alfalfa plants but the nodules formed were unable to fix nitrogen. Revertants of the mutants were fully effective on plants. The mutants unable to transport succinate were used to isolate dct genes from a R. meliloti gene bank. Two plasmids containing a common 26.5 Mdal insert were found to complement some of the mutants. The presence of this DNA insert in the complementing mutant strains restored their effectivenss of plants. This DNA fragment encoding succinate transport function(s) was used to produce genetically engineered R. meliloti strains with an increased rate of succinate uptake.Abbreviation dct dicarboxylic acid transport     

Characterization of the ugp region containing the genes for the phoB dependent sn-glycerol-3-phosphate transport system of Escherichia coli

Summary The ugp structural genes, coding for the pho regulon dependent sn-glycerol-3-phosphate transport system, were cloned in pBR322 and characterized. The expression of the cloned ugp system was phoB dependent. Cells containing the ugp plasmid overproduced the G3P binding protein upon phosphate starvation. Tn5 mutagenesis of the cloned DNA revealed that the ugp genes are organized in two separate operons which comprise at least four genes: ugpB and ugpD constitute one operon, ugpA and ugpC constitute the other. The structural gene for the G3P binding protein (G3PBP) is ugpB.The ugpC gene product was also synthesized in minicells as a polypeptide, with an apparent molecular weight of 40,000. No gene products could be assigned to the ugpA and ugpD genes. Hybridization experiments allowed the physical characterization of 20 kb of DNA adjacent to the ugp genes on the E. coli chromosome including the liv genes.     

Protein-protein interaction in transport

The transport of histidine in the gram negative bacterium S. typhimurium has been studied over a number of years and found to occur through five transport systems (Ames, 1972). Of these, the one with the highest affinity has been studied in detail from the genetic, physiological and biochemical point of view. This system, known as the high-affinity histidine permease, is composed of two subsystems, the J-P and K-P systems, which have a component in common, the P protein, presumed to be membrane-bound. The J-P system, moreover, is known to require the presence of a periplasmic histidine-binding protein, the J protein. The J protein is coded for by the hisJ gene and the P protein is coded for by the hisP gene. Both of these genes have been mapped at 75 min on the Salmonella chromosomal map. Adjacent to them is a regulatory gene, the dhuA gene. The periplasmic histidine-binding protein J has been shown to interact directly with the second component of transport, the P protein (Ames and Spudich, 1976). In accordance with this, histidine-binding protein J has been shown to contain, besides the histidine-binding site, a second site, essential for function, the interaction site (Kustu and Ames, 1974). We have recently shown that a mutant J protein with a defective interaction site but an intact histidine-binding site cannot function in histidine transport, unless an appropriate compensating mutation is introduced in the P protein. The interaction between the J and P proteins is an obligatory step in transport. The mutation in the interaction site of the J protein has been shown to map in the hisJ gene, and the compensating supressor mutation in the P protein has been shown to map in the hisP gene. Our contention that the J and P proteins engage in a functional interaction assumes further strength from other studies on protein-protein interaction in bacteriophage development and in ribosomal structure. Among the possible functions of the J-P interaction in histidine transport, a likely one is the transmission of information to the P protein, concerning whether or not the histidine-binding site on the J protein is occupied. Appropriate conformational changes then can occur in either the J or the P protein, or both, such that the histidine is released in the correct location and direction on the inside of the cell. This could occur either by a pore-formation mechanism or by binding-site translocation. Another alternative is that the P protein is part of an energy transducing mechanism in which energy is transmitted to the J protein, through the interaction site, as a prerequisite for the J protein participation in translocation. Among the interesting findings coming out of this work, is also the fact that the P protein performs a central function in transport being involved in the permeation of other substrates besides histidine. It is likely that other binding proteins besides the J protein require the P protein. Thus an interesting question which we are trying to answer at present is whether the P protein has separate interaction sites for each of these other binding proteins requiring its function, or whether they all interact at one common site.     

Molecular cloning and functional characterization of a histidine decarboxylase from Staphylococcus capitis

Aims:  Histamine intoxication is probably the best known toxicological problem of food-borne disease. A histamine-producing Staphylococcus capitis strain has been isolated from a cured meat product. The aim of this study was to gain deeper insights into the genetic determinants for histamine production in Staph. capitis .
Methods and Results:  The nucleotide sequence of a 6446-bp chromosomal DNA fragment containing the hdcA gene encoding histidine decarboxylase (HDC) has been determined in Staph. capitis IFIJ12. This DNA fragment contains five complete and two partial open reading frames. Putative functions have been assigned to gene products by sequence comparison with proteins included in the databases. The hdcA gene has been expressed in Escherichia coli resulting in HDC activity. The presence of a functional promoter (P hdc ) located upstream of hdcA has been demonstrated. Insertion of the histamine biosynthetic locus in Staph. capitis seems to be associated with a noticeable genome reorganization.
Conclusions:  Among the staphylococcal species analysed in this study only Staph. capitis strains produce histamine. The hdcA gene cloned from Staph. capitis encodes a functional HDC that produce histamine from the amino acid histidine.
Significance and Impact of the Study:  The identification of the DNA region involved in histamine production in Staph. capitis will allow further work in order to avoid histamine production in foods.     

Molecular cloning of EcoRII endonuclease and methylase genes

Summary The genes for restriction-modification system EcoRII have been cloned from plasmid N3 DNA using RSF2124 as a vector plasmid. The hybrid plasmids designated pFK321 and pFK322 contained a 5.8 megadaltons EcoRI — fragment derived from N3 DNA including the genes for restriction-modification system EcoRII and a gene for resistance to sulfanilamide.     

Characterization of a two-component signal transduction system involved in the induction of alkaline phosphatase under phosphate-limiting conditions in Synechocystis sp. PCC 6803

The gene products of sll0337 and slr0081 in Synechocystis sp. PCC 6803 have been identified as the homologues of the Escherichia coli phosphate-sensing histidine kinase PhoR and response regulator PhoB, respectively. Interruption of sll0337, the gene encoding the histidine protein kinase, by a spectinomycin-resistance cassette blocked the induction of alkaline phosphatase activity under phosphate-limiting conditions. A similar result was obtained when slr0081, the gene encoding the response regulator, was interrupted with a cassette conferring resistance to kanamycin. In addition, the phosphate-specific transport system was not up-regulated in our mutants when phosphate was limiting. Unlike other genes for bacterial phosphate-sensing two-component systems, sll0337 and slr0081 are not present in the same operon. Although there are three assignments for putative alkaline phosphatase genes in the Synechocystis sp. PCC 6803 genome, only sll0654 expression was detected by northern analysis under phosphate limitation. This gene codes for a 149 kDa protein that is homologous to the cyanobacterial alkaline phosphatase reported in Synechococcus sp. PCC 7942 [Ray, J.M., Bhaya, D., Block, M.A. and Grossman, A.R. (1991) J. Bact. 173: 4297–4309]. An alignment identified a conserved 177 amino acid domain that was found at the N-terminus of the protein encoded by sll0654 but at the C-terminus of the protein in Synechococcus sp. PCC 7942.     

Development and use of a conditional antisense mutagenesis system in mycobacteria

Expression from a 2.3 kb region upstream of the inducible acetamidase gene from Mycobacterium smegmatis was shown to be upregulated by acetamide. A DNA fragment containing the start of the M. smegmatis hisD gene was cloned in front of the promoter, such that the antisense message was produced. When this construct was induced in vivo, the bacteria became phenotypically histidine auxotrophs; this auxotrophy was restored by histidine supplementation. Auxotrophy was not observed under non-induced conditions. Antisense mutagenesis may be useful for observing the phenotypic inactivation of specific mycobacterial genes, and an inducible system such as that described would allow the study of essential genes.     

The gluEMP operon from Zymomonas mobilis encodes a high-affinity glutamate carrier with similiarity to binding-protein-dependent transport systems

The nucleotide sequence downstream of the grp gene, encoding the glutamate uptake regulatory protein of Zymomonas mobilis, was determined. Three clustered genes (gluE, gluM, and gluP) close to ghe grp gene, but on the opposite strand, were identified. These genes encode a high-affinity transport system for glutamate and aspartate. The gluP gene product is a polypeptide of 25.4 kDa and contains segments with significant similiarity to the ATP-binding proteins of binding-protein-dependent transport systems. The GluM polypeptide (22.9 kDa) is highly hydrophobic and consists of four potential membrane-spanning domains. The hydrophilic gluE gene product, with a molecular mass of 22.1 kDa, contains a region with sequence similiarity to some of the periplasmic binding proteins and a sequence motif of a signal peptide for periplasmic localization. The transport system could not be functionally expressed in Z. mobilis. However, when heterologously expressed in Escherichia coli, it catalyzed uptake of glutamate, which was characterized kinetically. Our results suggest that the glutamate transport system encoded by the gluEMP operon is repressed in Z. mobilis by the regulatory protein Grp. Received: 18 September 1995 / Accepted: 14 February 1996     

Inhibition of growth of bacteriophage BF23 by the ColIb plasmid: Identification of the ibfA and ibfB genes of the ColIb plasmid

Summary A 3.7 Mdal DNA fragment of plasmid ColIb which carried all the genetic information determining the growth inhibition of bacteriophage BF23 (Ibf phenotype) but not for production of colicin Ib protein (Cib) and immunity to colicin Ib (Imm) was cloned in the pBR322 vector. We also cloned the 8.7 Mdal DNA fragment that was responsible for both Cib and Imm but not for Ibf phenotype. Thus, these results clearly showed that the gene(s) determining Ibf are different from those for Cib or Imm. Dissection of the Ibf-DNA revealed that at least two genes, ibfA and ibfB, were involved in the Ibf phenotype. The ibfA gene was mapped within a 1.45 Mdal EcoRI DNA fragment (E-13); mutation of this gene by deletion or by insertion of Tn5, a kanamycin resistance transposon, resulted in the complete loss of Ibf phenotype. The ibfB gene, mapped around a 0.32 Mdal HindIII DNA fragment (H-7), was found to be active in trans to ibfA, and its function seemed to promote ibfA activity. The genetic map of the ibf genes in relation to other ColIb markers was determined as ibfB-ibfA-imm-cib. Attempts to identify the ibfA gene product in the minicell system, however, did not succeed.Preliminary results were presented in the 1980 Annual Meeting of the Japan Molecular Biology Society. (Uemura and Mizobuchi Abst Ann Mol Meet 1980, p 35)     

Self cloning in Micromonospora olivasterospora of fms genes for fortimicin A (astromicin) biosynthesis.

Summary We have cloned the seven genes that are responsible for biosynthesis of the antibiotic fortimicin A (FTM A) using a recently developed self-cloning system that employs the plasmid vector pMO116 for Micromonospora olivasterospora. Five chimeric plasmids that restored FTM A production in M. olivasterospora mutants blocked at different biosynthetic steps were isolated by shotgun cloning. Secondary transformation using other non-producing mutants showed that two additional FTM A biosynthetic genes were included on these plasmids, and that at least four of the genes were clustered. Interestingly AN38-1, a non-producing mutant that had a defect in dehydroxylation of a precursor of FTM A, was complemented by the DNA fragment containing a neomycin resistance gene that had been cloned from a neomycin-producing strain (Micromonospora sp. FTM A non-producing strain) in the course of constructing the plasmid vector pM0116. These results clearly show that this novel gene cloning system in Micromonospora is of practical use.     

Genetic aspects of aromatic amino acid biosynthesis in Lactococcus lactic

Polymerase chain reaction (PCR) primers designed from a multiple alignment of predicted amino acid sequences from bacterial aroA genes were used to amplify a fragment of Lactococcus lactis DNA. An 8 kb fragment was then cloned from a lambda library and the DNA sequence of a 4.4 kb region determined. This region was found to contain the genes tyrA, aroA, aroK, and pheA, which are involved in aromatic amino acid biosynthesis and folate metabolism. TyrA has been shown to be secreted and AroK also has a signal sequence, suggesting that these proteins have a secondary function, possibly in the transport of amino acids. The aroA gene from L. lactis has been shown to complement an E. coli mutant strain deficient in this gene. The arrangement of genes involved in aromatic amino acid biosynthesis in L. lactis appears to differ from that in other organisms.The nucleotide sequence data reported in this paper have been submitted to the EMBL, GenBank, and DDBJ Nucleotide Sequence Databanks and have been assigned the accession number X78413     

Towards an understanding of the molecular basis of plants K+ transport: Characterization of cloned K+ transport cDNAs

Recently, two K⁺-transport cDNAs, KAT1 and AKT1, were cloned in Arabidopsis thaliana. These cDNAs had structural similarities to K⁺ channel genes in animals, and also conferred the ability for growth on micromolar levels of K⁺ when expressed in K⁺ transport-defective yeast mutants. In this study, we examined the possibility that KAT1 encodes the high-affinity K⁺ transport system that has been previously characterized in plant roots, by studying the concentration-dependent kinetics of K⁺ transport for KAT1 expressed in Xenopus oocytes and Saccharomyces cerevisiae. In both organisms, the K⁺ transport system encoded by KAT1 yielded Michaelis-Menten kinetics with a high K_m for K⁺ (35 mM in oocytes, 0.6 mM in yeast cells). Furthermore, Northern analysis indicated that KAT1 is expressed primarily in the Arabidopsis shoot. These results strongly suggest that the system encoded by KAT1 is not a root high-affinity K⁺ transporter.     

Sequencing and modification of psbB,the gene encoding the CP-47 protein of Photosystem II,in the cyanobacterium Synechocystis 6803

The Photosystem II protein CP-47 has been hypothesized to be involved in binding the reaction center chlorophyll. The psbB gene, encoding this protein, was cloned from the genome of the cyanobacterium Synechocystis 6803, and sequenced. The DNA sequence is 68% homologous with that of the psbB gene from spinach, whereas the predicted amino acid sequence is 76% homologous. The hydropathy patterns of Synechocystis and spinach CP-47 are almost indistinguishable, indicating the same general CP-47 folding pattern in the thylakoid membrane in the two species. There are five pairs of histidine residues in CP-47 that are spaced by 13 or 14 amino acids and that are located in hydrophobic regions of the protein; these histidine residues may be involved in chlorophyll binding. Interruption of the psbB gene by a DNA fragment carrying a gene conferring kanamycin resistance results in a loss of Photosystem II activity. This indicates that an intact CP-47 is required for a functional Photosystem II complex, but does not necessarily indicate that this protein would house the reaction center.