Molecular cloning of gltS and gltP, which encode glutamate carriers of Escherichia coli B.

Two genes encoding distinct glutamate carrier proteins of Escherichia coli B were cloned into an E. coli K-12 strain by using a cosmid vector, pHC79. One of them was the gltS gene coding for a glutamate carrier of an Na+-dependent, binding protein-independent, and glutamate-specific transport system. The content of the glutamate carrier was amplified about 25-fold in the cytoplasmic membranes from a gltS-amplified strain. The gltS gene was located in a 3.2-kilobase EcoRI-MluI fragment, and the gene product was identified as a membrane protein with an apparent Mr of 35,000 in a minicell system. A gene designated gltP was also cloned. The transport activity of the gltP system in cytoplasmic membrane vesicles from a gltP-amplified strain was driven by respiratory substrates and was independent of the concentrations of Na+, K+, and Li+. An uncoupler, carbonylcyanide m-chlorophenylhydrazone, completely inhibited the transport activities of both systems, whereas an ionophore, monensin, inhibited only that of the gltS system. The Kt value for glutamate was 11 microM in the gltP system and 3.5 microM in the gltS system. L-Aspartate inhibited the glutamate transport of the gltP system but not that of the gltS system. Aspartate was taken up actively by membrane vesicles from the gltP-amplified strain, although no aspartate uptake activity was detected in membrane vesicles from a wild-type E. coli strain. These results suggest that gltP is a structural gene for a carrier protein of an Na+-independent, binding protein-independent glutamate-aspartate transport system.     

Effect of growth conditions on glutamate transport in the wild-type strain and glutamate-utilizing mutants of Escherichia coli.

The effects of growth conditions on the glutamate transport activity of intact cells and membrane vesicles and on the levels of glutamate-binding protein in wild-type Escherichia coli K-12 CS101 and in two glutamate-utilizing mutants, CS7 and CS2TC, were studied. Growth of CS101 on aspartate as the sole source of carbon or nitrogen resulted in a severalfold increase in glutamate transport activity of intact cells and membrane preparations to levels characteristic of the operator-constitutive mutant CS7. The high glutamate transport activity of mutant CS7 was not depressed further by growth on aspartate. Synthesis of glutamate-binding protein was not enhanced by aspartate in either strain. Mutant CS2TC produces a heat-labile repressor of glutamate permease synthesis and is therefore able to grow on glutamate at 42 C but not at 30 C. CS2TC cells grown in a glycerol-minimal medium at the restrictive temperature (30 C) exhibit low glutamate transport activity. Growth on aspartate at 30 C results in derepressed synthesis of glutamate permease. Cells grown on glycerol at 42 C have high glutamate transport activity. No further derepression is obtained upon growth on aspartate. Growth of CS101 and CS7 in "rich broth" greatly reduces the levels of glutamate-binding protein but does not appreciably affect glutamate transport by whole cells or membrane preparations. The identity of the carrier and the role of the binding protein in glutamate transport are discussed in the light of these findings.     

Characterization of the specific pyruvate transport system in Escherichia coli K-12.

A mutant of Escherichia coli K-12 lacking pyruvate dehydrogenase and phosphoenolpyruvate synthase was used to study the transport of pyruvate by whole cells. Uptake of pyruvate was maximal in mid-log phase cells, with a Michaelis constant for transport of 20 microM. Pretreatment of the cells with respiratory chain poisons or uncouplers, except for arsenate, inhibited transport up to 95%. Lactate and alanine were competitive inhibitors, but at nonphysiological concentrations. The synthetic analogs 3-bromopyruvate and pyruvic acid methyl ester inhibited competitively. The uptake of pyruvate was also characterized in membrane vesicles from wild-type E. coli K-12. Transport required an artificial electron donor system, phenazine methosulfate and sodium ascorbate. Pyruvate was concentrated in vesicles 7- to 10-fold over the external concentration, with a Michaelis constant of 15 microM. Energy poisons, except arsenate, inhibited the transport of pyruvate. Synthetic analogs such as 3-bromopyruvate were competitive inhibitors of transport. Lactate initially appeared to be a competitive inhibitor of pyruvate transport in vesicles, but this was a result of oxidation of lactate to pyruvate. The results indicate that uptake of pyruvate in E. coli is via a specific active transport system.     

Glutamate transport in wild-type and mutant strains of Escherichia coli

Halpern, Yeheskel S. (Hebrew University-Hadassah Medical School, Jerusalem, Israel), and Meir Lupo. Glutamate transport in wild-type and mutant strains of Escherichia coli. J. Bacteriol. 90:1288-1295. 1965.-Mutants of Escherichia coli able to grow on glutamate as their source of carbon showed glutamate dehydrogenase and glutamate-oxaloacetate transaminase activities similar to those possessed by the parent strain. The mutants took up glutamate at a much faster rate and showed a several-fold greater capacity for concentrating the amino acid than did the corresponding parent strains. Curvilinear double reciprocal plots of velocity of uptake versus glutamate concentration were obtained with the E. coli H strains. A break in the curve of glutamate uptake was observed with the E. coli K-12 strains when incubated in a glucose medium. It is suggested that these findings may be due to allosteric activation of glutamate permease by its substrate.     

Evidence that the wzxE gene of Escherichia coli K-12 encodes a protein involved in the transbilayer movement of a trisaccharide-lipid intermediate in the assembly of enterobacterial common antigen

The assembly of many bacterial cell surface polysaccharides requires the transbilayer movement of polyisoprenoid-linked saccharide intermediates across the cytoplasmic membrane. It is generally believed that transverse diffusion of glycolipid intermediates is mediated by integral membrane proteins called translocases or "flippases." The bacterial genes proposed to encode these translocases have been collectively designated wzx genes. The wzxE gene of Escherichia coli K-12 has been implicated in the transbilayer movement of Fuc4NAc-ManNAcA-GlcNAc-P-P-undecaprenol (lipid III), the donor of the trisaccharide repeat unit in the biosynthesis of enterobacterial common antigen (ECA). Previous studies (Feldman, M. F., Marolda, C. L., Monteiro, M. A., Perry, M. B., Parodi, A. J., and Valvano, M. (1999) J. Biol. Chem. 274, 35129-35138) provided indirect evidence that the wzx(016) gene product of E. coli K-12 encoded a translocase capable of mediating the transbilayer movement of N-acetylglucosaminylpyrophosphorylundecaprenol (GlcNAc-P-P-Und), an early intermediate in the synthesis of ECA and many lipopolysaccharide O antigens. Therefore, genetic and biochemical studies were conducted to determine if the putative Wzx(O16) translocase was capable of mediating the transport of N-acetylglucosaminylpyrophosphorylnerol (GlcNAc-P-P-Ner), a water-soluble analogue of GlcNAc-P-P-Und. [(3)H]GlcNAc-P-P-Ner was transported into sealed, everted cytoplasmic membrane vesicles of E. coli K-12 as well as a deletion mutant lacking both the wzx(016) and wzxC genes. In contrast, [(3)H]GlcNAc-P-P-Ner was not transported into membrane vesicles prepared from a wzxE-null mutant, and metabolic radiolabeling experiments revealed the accumulation of lipid III in this mutant. The WzxE transport system exhibited substrate specificity by recognizing both a pyrophosphoryl-linked saccharide and an unsaturated alpha-isoprene unit in the carrier lipid. These results support the conclusion that the wzxE gene encodes a membrane protein involved in the transbilayer movement of lipid III in E. coli.     

Characterization and functional expression in Escherichia coli of the sodium/proton/glutamate symport proteins of Bacillus stearothermophilus and Bacillus caldotenax

The genes encoding the Na+/H+/L-glutamate symport proteins of the thermophilic organisms Bacillus stearothermophilus (gltTBs) and Bacillus caldotenax (gltTBc) were cloned by complementation of Escherichia coli JC5412 for growth on glutamate as sole source of carbon, energy and nitrogen. The nucleotide sequences of the gltTBs and gltTBc genes were determined. In both cases the translated sequences corresponded with proteins of 421 amino acid residues (96.7% amino acid identity between GltTBs and GltTBc). Putative promoter, terminator and ribosome-binding-site sequences were found in the flanking regions. These expression signals were functional in E. coli. The hydropathy profiles indicate that the proteins are hydrophobic and could form 12 membrane-spanning regions. The Na+/H+ coupled L-glutamate symport proteins GltTBs and GltTBc are homologous to the strictly H+ coupled L-glutamate transport protein of E. coli K-12 (overall 57.2% identity). Functional expression of glutamate transport activity was demonstrated by uptake of glutamate in whole cells and membrane vesicles. In accordance with previous observations (de Vrij et al., 1989; Heyne et al., 1991), glutamate uptake was driven by the electrochemical gradients of sodium ions and protons.     

Genetic and biochemical studies of transport systems for branched-chain amino acids in Escherichia coli.

Mutants of Escherichia coli K-12 requiring high concentrations of branched-chain amino acids for growth were isolated. One of the mutants was shown to be defective in transport activity for branched-chain amino acids. The locus of the mutation (hrbA) was mapped at 8.9 min on the E. coli genetic map by conjugational and transductional crosses. The gene order of this region is proC-hrbA-tsx. The hrbA system was responsible for the uptake activity of cytoplasmic membrane vesicles. It was not repressed by leucine. The substrate specificities and kinetics of the uptake activities were studied using cytoplasmic membrane vesicles and intact cells of the mutants grown in the presence or absence of leucine. Results showed that there are three transport systems for branched-chain amino acids, LIV-1, -2, and -3. The LIV-2 and -3 transport systems are low-affinity systems, the activities of which are detectable in cytoplasmic membrane vesicles. The systems are inhibited by norleucine but not by threonine. The LIV-2 system is also repressed by leucine. The LIV-1 transport system is a high-affinity system that is sensitive to osmotic shock. When the leucine-isoleucine-valine-threonine-binding protein is derepressed, the high-affinity system can be inhibited by threonine.     

Iron uptake in colicin B-resistant mutants of Escherichia coli K-12.

Four classes of colicin B-resistant mutants of Escherichia coli K-12 were examined for defects in iron uptake. All four mutant classes (cbt, exbC, exbB, and tonB) were defective in the uptake of ferri-ennterochelin. The tonB mutant was also defective in citrate-, ferrichrome-, and rhodoturulic acid-mediated iron uptake. The defects in iron transport were reflected in increased sensitivity to iron chelators and to chromium and aluminium salts, and in hypersecretion of enterochelin. One of the mutants (cbt) was apparently defective in outer membrane ferri-enterochelin receptor activity. aroE derivatives (unable to synthesize enterochelin) of the four mutant classes and the parent strain produced increased amounts of two outer membranes polypeptides when grown under iron stress. These polypeptides are implicated in ferri-enterochelin receptor activity.     

Defective transport and other phenotypes of a periplasmic "leaky" mutant of Escherichia coli K-12.

A mutant of Escherichia coli K-12 deficient in high-affinity leucine transport and related binding proteins was obtained by selecting for azaleucine resistance after bacteriophage Mu mutagenesis. We determined that the cause was a generalized loss of periplasmic binding proteins and a sharp decrease in the activity of transport systems requiring them. Other transport systems resistant to osmotic shock and present in membrane vesicles, were affected to a lesser degree or not at all. The mutation, designated lky::Mucts, was shown to be a pleiotropic envelope mutation, rendering the mutant sensitive to ionic and nonionic detergents, antibiotics, and ethylenediaminetetraacetic acid: the strain had also acquired tolerance to colicins E1, E2, and E3, while remaining normally sensitive to a variety of bacteriophages. An analysis of the lipopolysaccharide of parent and mutant strains revealed a twofold reduction in the neutral sugar content of the core oligosaccharide of the lky strain, but no change in sensitivities to phages which utilize lipopolysaccharide or outer membrane proteins for absorption. The lky::Mucts locus was mapped by transduction and found to be located near, or in, the tolPAB gene cluster linked to gal. Secondary mutations suppressing the detergent sensitivity of lky arose at a frequency of 10(-7), yielding a variety of new phenotypes. The lky::Mucts mutation did not give rise to obvious alterations in the gross morphology of the cell or in cell division.     

Purification and properties of glutamate binding protein from the periplasmic space of Escherichia coli K-12.

Glutamate binding protein released from the periplasmic space of Escherichia coli K-12 by lysozyme-EDTA treatment was purified to homogeneity and its physical and chemical properties were studied. It is a basic protein with a pI of 9.1. Its molecular weight, determined in an analytical ultracentrifuge, and by gel filtration on Sephadex G-100 and dodecylsulphate acrylamide is 29 700, 27 800 and 32 000, respectively. The KD value for glutamate was 6.7 - 10- minus 6 M. L-Aspartate, reduced glutathione, G-glutamate-gamma-benzylester and L-glutamate-gamma-ethylester competitively inhibited glutamate binding with K-i; values of 7.8 - 10- minus 5, 1.1 - 10- minus 5, 1.0 - 10- minus 5 and 1.0 - 10- minus 5 M, respectively. Spheroplasts retained 40% of glutamate transport as compared to intact cells. The glutamate binding activity of a glutamate-utilizing strain (CS7), was 1.6 times as high as that of the glutamate non-utilizing parent strain (CS101). Similarly, the glutamate binding activity of a temperature conditional glutamate-utilizing mutant (CS2-TC) was 1.9 times higher when grown at the permissive temperature (42 degrees C) than when grown at the restrictive temperature (30 degrees C).     

Valinomycin-induced cation transport in vesicles does not reflect the activity of K+ transport systems in Escherichia coli.

Transport systems for K+ in Escherichia coli are not detectable in membrane vesicles, but vesicles will take up K+ (and Rb+) in the presence of valinomycin. It is generally believed that valinomycin acts as a lipid-soluble cation carrier and that it does not interact with or activate cation transport systems. This view is challenged by Bhattacharyya et al. (Proc. Natl. Acad. Sci. USA 68:1448-1492, 1971), who reported reduced uptake in vesicles from E. coli mutants with K+ transport defects. We reexamined this question with some of the same mutants and were unable to confirm a correlation of valinomycin-induced vesicle transport with transport properties in intact cells. We found great variability in transport activity of vesicles from these E. coli K-12 strains and believe such variability as well as possible contamination with intact cells accounts for the earlier report. Our data do not support the idea that valinomycin-mediated transport in vesicles is related to physiological K+ transport systems.     

Genetic and biochemical studies of transport systems for branched-chain amino acids in Escherichia coli K-12: isolation and properties of mutants defective in leucine-repressible transport activities.

The characteristics of a mutant (hrbA) of Escherichia coli K-12 that is defective in a leucine-nonrepressible transport system, the LIV-3 system, for branched-chain amino acids were described previously (I. Yamato et al., J. Bacteriol 138:24-32, 1979). New mutants requiring a high concentration of isoleucine for growth were isolated from strain B763 (hrbA ileA) after mutagenesis with ethyl methane sulfonate. These mutants had a defect of the leucine-repressible transport activities for branched-chain amino acids of the parental strain. One of these mutants, strain B7634, had defects of two independent genetic loci (hrbBC and hrbD). The genes hrbBC were mapped at min 76 near malT, and the gene hrbD mapped at min 77 near xyl on the E. coli genetic map. The substrate specificity, kinetic properties, and source of coupling energy of the transport system coded for by each of these genes were studied using cytoplasmic membrane vesicles and intact cells. The results identified three transport systems with characteristic features other than the LIV-3 system. The hrbB and hrbC systems are responsible for the uptake activites of the LIV-2 system, with a high Km value, and the LIV-1 system, with a low Km value, respectively. Both activities are repressed by leucine and inhibited by threonine and the b(--) isomer of 2-aminobicycloheptyl-2-carboxylic acid. They both utilize adenosine 5'-triphosphate as coupling energy and are not detected in cytoplasmic membrane vesicles. The hrbD system is responsible for the LIV-4 system, with a high Km value. Its activity is repressed by leucine and partially inhibited by threonine. It is detected in cytoplasmic membrane vesicles with a proton motive force as the driving energy.     

Glutamate transport driven by an electrochemical gradient of sodium ions in Escherichia coli.

The role of Na+ in glutamate transport was studied in Escherichia coli B, strain 29-78, which possesses a very high activity of glutamate transport (L. Frank and I. Hopkins, J. Bacteriol., 1969). Energy-depleted cells were exposed to radioactive glutamate in the presence of a sodium gradient, a membrane potential, or both. One hundred- to 200-fold accumulation of the amino acid was attained in the presence of both electrical and chemical driving forces for the sodium ion. Somewhat lower accumulation values were obtained when either chemical or electrical driving forces were applied separately. A chemical driving force was produced by the addition of external Na+ to Na+-free cells. A membrane potential was established by a diffusion potential either of H+ in the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone or of SCN-. These results support the hypothesis of a Na+-glutamate cotransport. Na+-driven glutamate transport was also observed in wild-type E. coli B but not in a strain of K-12.     

Proline transport carrier-defective mutants of Escherichia coli K-12: properties and mapping.

A series of mutants of Escherichia coli K-12 requiring a high concentration of L-proline for growth were isolated from a proline auxotroph strain, JE2133. Genetic studies of the mutants, PT19, PT21, and PT22, showed that all the mutations (proT) were point mutations, and these were mapped at 82 min on the E. coli genetic map. Intact cells and cytoplasmic membrane vesicles of these mutants were specifically defective in L-proline transport activity. Strain PT21 had no detectable activity of the L-proline transport carrier at all, and strains PT19 and PT22 had only 1/35 and 1/70, respectively, of the transport activity of the parental strain. The mutants were also shown to have a defect in proline-binding function of the carrier by measuring specific binding of proline to sonically disrupted membranes. These results indicate that the gene proT determines the function of proline carrier in the cytoplasmic membrane.     

Outer Membrane Proteins of Escherichia coli VII. Evidence That Bacteriophage-Directed Protein 2 Functions as a Pore

Protein 1, a major protein of the outer membrane of Escherichia coli, has been shown to be the pore allowing the passage of small hydrophilic solutes across the outer membrane. In E. coli K-12 protein 1 consists of two subspecies, 1a and 1b, whereas in E. coli B it consists of a single species which has an electrophoretic mobility similar to that of 1a. K-12 strains mutant at the ompB locus lack both proteins 1a and 1b and exhibit multiple transport defects, resistance to toxic metal ions, and tolerance to a number of colicins. Mutation at the tolF locus results in the loss of 1a, in less severe transport defects, and more limited colicin tolerance. Mutation at the par locus causes the loss of protein 1b, but no transport defects or colicin tolerance. Lysogeny of E. coli by phage PA-2 results in the production of a new major protein, protein 2. Lysogeny of K-12 ompB mutants resulted in dramatic reversal of the transport defects and restoration of the sensitivity to colicins E2 and E3 but not to other colicins. This was shown to be due to the production of protein 2, since lysogeny by phage mutants lacking the ability to elicit protein 2 production did not show this effect. Thus, protein 2 can function as an effective pore. ompB mutations in E. coli B also resulted in loss of protein 1 and similar multiple transport defects, but these were only partially reversed by phage lysogeny and the resulting production of protein 2. When the ompB region from E. coli B was moved by transduction into an E. coli K-12 background, only small amounts of proteins 1a and 1b were found in the outer membrane. These results indicate that genes governing the synthesis of outer membrane proteins may not function interchangeably between K-12 and B strains, indicating differences in regulation or biosynthesis of these proteins between these strains.     

Mechanism of glutamate transport in Escherichia coli B. 1. Proton-dependent and sodium ion dependent binding of glutamate to a glutamate carrier in the cytoplasmic membrane

Specific binding of glutamate to its carrier was investigated by using cytoplasmic membrane vesicles prepared from Escherichia coli B. The binding activity was specifically affected by the Na+ and H+ concentrations of the medium. Cytoplasmic membrane vesicles from the mutant strain 36-39 that is defective in the Na+-dependent glutamate transport system showed no binding of glutamate. Addition of the protonophore uncoupler 3,5-di-tert-butyl-4-hydroxy-benzylidenemalononitrile or carbonyl cyanide m-chlorophenylhydrazone, or the ionophore monensin or nigericin, did not inhibit the binding, indicating that the binding reaction is not energy dependent. The parameters of binding were determined in reaction media with various combinations of H+ and Na+ concentrations. The maximum number of binding sites was constant and determined to be 70 pmol/mg of membrane protein, irrespective of the concentrations of H+ and Na+ in the medium. The apparent dissociation constant, however, was greatly affected by changes in the concentrations of both H+ and Na+, in such a way that it was expressed by a linear combination of the reciprocals of the H+ and Na+ concentrations. The characteristics of binding can be explained best by supposing that glutamate can bind only to a H+/Na+/carrier complex that is formed by random binding of H+ and Na+ to the unloaded carrier. The physiological role of this elementary binding reaction and of this quaternary complex as an active intermediate in the process of glutamate transport is discussed.     

Mechanisms of active transport in isolated bacterial membrane vesicles. XII. Active transport by a mutant of Escherichia coli uncoupled for oxidative phosphorylation

Amino acid and β-galactoside transport activity catalyzed by whole cells and membrane vesicles prepared from an Escherichia coli mutant uncoupled for oxidative phosphorylation is comparable to the activity of analogous preparations from the parent strain. Valinomycin-induced rubidium uptake is also similar in membrane vesicles prepared from wild-type and mutant cells. The properties of the transport systems in mutant vesicles are the same as those of wild-type vesicles with respect to electron donors which stimulate transport, and with respect to inhibition by anoxia, cyanide, and 2,4-dinitrophenol.Magnesium ion markedly stimulates the ATPase activity of wild-type membrane vesicles and ethylenediaminetetraacetate markedly inhibits. However, these compounds have relatively slight effects on either the initial rate or extent of transport. Dicyclohexylcarbodiimide does not inhibit respiration-dependent transport despite inhibition of the calcium, magnesium-activated ATPase activity of wild-type vesicles.These results confirm earlier observations indicating that oxidative phosphorylation is not involved in respiration-linked active transport.     

Isolation and properties of Escherichia coli K-12 mutants impaired in the utilization of gamma-aminobutyrate.

We have isolated mutants of Escherichia coli K-12 CS101B that have lost the ability to utilize gamma-aminobutyrate as a source of nitrogen. One class of mutants, which were not affected in the utilization of other nitrogen sources (proline, arginine, glycine), included many isolates with lesions in gamma-aminobutyrate transport or in its transamination and one mutant completely devoid of succinic semialdehyde dehydrogenase activity and exhibiting low gamma-aminobutyrate transport and transamination. gamma-Aminobutyrate-utilizing revertants of the latter recovered full transport and transamination capacities but remained dehydrogenaseless. Another class of mutants showed pleiotropic defects in nitrogen metabolism. One such mutant was lacking glutamate synthase activity. The genes specifying the synthesis of gamma-aminobutyrate permease, gabP, gamma-aminobutyrate transaminase, gabT, and succinic semialdehyde dehydrogenase, gabD, and the control gene, gabC, that coordinately regulates their expression all form a cluster on the E. coli chromosome, linked to the srl and recA loci (at 57.5 min). The mutations with pleiotropic effects on the metabolism of nitrogenous compounds are not linked to the gab cluster.     

Specialized peptide transport system in Escherichia coli.

Trileucine is utilized as a source of leucine for growth of strains of Escherichia coli K-12 that are deficient in the oligopeptide transport system (Opp). Trithreonine is toxic to E. coli K-12. Opp- mutants of E. coli K-12 retain complete sensitivity to this tripeptide. Moreover, E. coli W, which is resistant to trithreonine, can utlize this tripeptide as a threonine source and this capability is fully maintained in E. coli W (Opp-). A spontaneous trithreonine-resistant mutant of E. coli K-12 (Opp-) has been isolated that has an impaired growth response to trileucine and is resistant to trithreonine. Trileucine competes with the uptake of trithreonine as measured by its ability to relieve trithreonine toxicity in E. coli K-12. It is concluded that trileucine as well as trithreonine are transported into E. coli K-12 or W by a common uptake system that is distinct from the Opp system. Trimethionine can act as a competitor of trileucine or trithreonine-supported growth and as an antagonist of trithreonine toxicity in Opp- mutants. It is concluded that trimethionine is recognized by the trileucine-trithreonine transport system. Trithreonine, trimethionine, and trileucine are also transported by the Opp system, as they all relieve triornithine toxicity towards E. coli W and compete with tetralysine utilization as lysine source for growth of a lysine auxotroph of this strain.