Leucine binding protein and regulation of transport in E. coli

Engineering a periplasmic binding protein for amino acid sensors with improved binding properties

Periplasmic binding proteins (PBPs) are members of a widely distributed protein superfamily found in bacteria and archaea, and are involved in the cellular uptake of solutes. In this report, a leucine-binding PBP was engineered to detect l-Leu based on a fluorescence resonance energy transfer (FRET) change upon ligand binding. A fluorescent unnatural amino acid, l-(7-hydroxycoumarin-4-yl)ethylglycine (CouA), was genetically incorporated into the protein as a FRET donor, and a yellow fluorescent protein (YFP) was fused with its N-terminus as a FRET acceptor. When CouA was incorporated into position 178, the sensor protein showed a 2.5-fold increase in the FRET ratio. Protein engineering significantly improved its substrate specificity, showing minimal changes in the FRET ratio with the other 19 natural amino acids and d-Leu. Further modification increased the sensitivity of the sensor protein (14-fold) towards l-Leu, and it recognized l-Met as well with moderate binding affinity. Selected mutant sensors were used to measure concentrations of l-Leu in a biological sample (fetal bovine serum) and to determine the optical purity of Leu and Met. This FRET-based sensor design strategy allowed us to easily manipulate the natural receptor to improve its binding affinity and specificity and to recognize other natural molecules, which are not recognized by the wild-type receptor. The design strategy can be applied to other natural receptors, enabling engineering receptors that sense biochemically interesting molecules.

Cloning and characterization of livH, the structural gene encoding a component of the leucine transport system in Escherichia coli

The physical location of the genetically defined livH gene was mapped in the 17-kilobase plasmid pOX1 by using transposon Tn5 inactivation mapping and further confirmed by subcloning and complementation analysis. These results indicated that the livH gene maps 3' to livK, the gene encoding the leucine-specific binding protein. Moreover, the nucleotide sequence of the livH gene and its flanking regions was determined. The livH gene is encoded starting 47 base pairs downstream from the livK gene, and it is transcribed in the same direction as the livK gene. The livK-livH intergenic region lacks promoter sequences and contains a GC-rich sequence that could lead to the formation of a stable stem loop structure. The coding sequence of the livH gene, which is 924 base pairs, specifies a very hydrophobic protein of 308 amino acid residues. Expression of livH-containing plasmids in minicells suggested that a poorly expressed protein with an Mr of 30,000 could be the livH gene product.

Regulation of peptide transport in Escherichia coli: induction of the trp-linked operon encoding the oligopeptide permease

Growth of Escherichia coli in medium containing leucine results in increased entry of exogenously supplied tripeptides into the bacterial cell. This leucine-mediated elevation of peptide transport required expression of the trp-linked opp operon and was accompanied by increased sensitivity to toxic tripeptides, by an enhanced capacity to utilize nutritional peptides, and by an increase in both the velocity and apparent steady-state level of L-[U-14C]alanyl-L-alanyl-L-alanine accumulation for E. coli grown in leucine-containing medium relative to these parameters of peptide transport measured with bacteria grown in media lacking leucine. Direct measurement of opp operon expression by pulse-labeling experiments demonstrated that growth of E. coli in the presence of leucine resulted in increased synthesis of the oppA-encoded periplasmic binding protein.

Identification of livG, a membrane-associated component of the branched-chain amino acid transport in Escherichia coli

Branched-chain amino acids are transported into Escherichia coli by two osmotic shock-sensitive systems (leucine-isoleucine-valine and leucine-specific transport systems). These high-affinity systems consist of separate periplasmic binding protein components and at least three common membrane-bound components. In this study, one of the membrane-bound components, livG, was identified. A toxic analog of leucine, azaleucine, was used to isolate a large number of azaleucine-resistant mutants which were defective in branched-chain amino acid transport. Genetic complementation studies established that two classes of transport mutants with similar phenotypes, livH and livG, were obtained which were defective in one of the membrane-associated transport components. Since the previously cloned plasmid, pOX1, genetically complemented both livH and livG mutants, we were able to verify the physical location of the livG gene on this plasmid. Recombinant plasmids which carried different portions of the pOX1 plasmid were constructed and subjected to complementation analysis. These results established that livG was located downstream from livH with about 1 kilobase of DNA in between. The expression of these plasmids was studied in minicells; these studies indicate that livG appears to be membrane bound and to have a molecular weight of 22,000. These results establish that livG is a membrane-associated component of the branched-chain amino acid transport system in E. coli.

Regulation of aromatic amino acid transport by tRNA: role of 2-methylthio-N6-(delta2-isopentenyl)-adenosine

E. coli growing rapidly in media where ferric iron is not freely available contain a population of specifically undermodified tRNAs. These tRNAs contain isopentenyl adenosine instead of the usual methylthioisopentenyl adenosine adjacent to the 3' end of the anticodon. Iron restricted E. coli also show an enhanced capacity to transport aromatic amino acids into the cell. Our work shows that undermodified tRNAs for phe, tyr and trp can function as positive regulatory elements of the aromatic amino acid transport system in E. coli. This iron related metabolic control, mediated through a specific post-transcriptional modification of the tRNAs, may be an important mechanism for adapting E. coli for growth in an iron restricted environment.

tonB-independent ferrichrome-mediated iron transport in Escherichia coli spheroplasts

Although a functional tonB gene product was required for ferrichrome-mediated iron transport in whole cells of Escherichia coli K-12, such transport did not require the tonB+ function in spheroplasts. We suggest that in spheroplasts ferrichrome has direct access to the cytoplasmic membrane and that this is reflected in tonB-independent accumulation of ferrichrome iron. Therefore, the tonB gene product does not function in the translocation of ferrichrome iron across the inner membrane.

Amino-terminal sequence and processing of the precursor of the leucine-specific binding protein, and evidence for conformational differences between the precursor and the mature form

A 2.1-kilobase Bgl II DNA fragment from Escherichia coli containing livK, the gene coding for the leucine-specific binding protein, has been cloned into the BamHI site of the plasmid vector pBR322. The DNA sequence of segments of the resulting plasmid, pOX7, established the location of the livK gene and the direction of its transcription. In vitro protein synthesis directed by pOX7DNA yielded the Mr 42,000 precursor of the leucine-specific binding protein and a small amount of the Mr 39,000 mature protein. Continued incubation of the in vitro reaction mixture after DNase and RNase treatment resulted in additional processing. The DNA sequence of the beginning of livK suggested that 23 additional amino acid residues are present as an extension of the NH2 terminus of the mature protein. Amino acid sequence analysis established that the precursor has the predicted 23-residue extension. Proteolytic digestion studies with the precursor and mature forms of the leucine-specific binding protein indicate that there are conformational differences between the two. This suggests a possible role for the signal sequence in determining the conformation of the binding protein precursor that is recognized by the membrane.

Structural and functional analysis of cloned DNA containing genes responsible for branched-chain amino acid transport in Escherichia coli

The four genes encoding the components of the high-affinity branched-chain amino acid transport systems in Escherichia coli (livH, livG, livJ, and livK) have been cloned into lambda phage and subsequently into the plasmid vector pACYC184. The presence of the four structural genes and their accompanying regulatory regions on the resultant plasmid, pOXI, was confirmed by genetic complementation and analysis and by transport studies carried out on the appropriate transformed mutant strains. When pOX1 DNA was used to direct an in vitro transcription/translation system, four major polypeptide products were produced. Immunoprecipitation with antibody directed against the LIV-binding protein identified the two leucine-binding proteins as products of in vitro synthesis. The binding proteins were produced in precursor forms and had molecular weights approximately 2500 higher than the processed, mature forms. A minicell-producing strain transformed with plasmid pOX1 produced the binding proteins in the processed form.

Regulation of high-affinity leucine transport in Escherichia coli

Leucine is transported into E coli by two osmotic shock-sensitive, high-affinity systems (LIV-I and leucine-specific systems) and one membrane bound, low-affinity system (LIV-II). Expression of the high-affinity transport systems is altered by mutations in livR and 1stR, genes for negatively acting regulatory elements, and by mutations in rho, the gene for transcription termination. All four genes for high-affinity leucine transport (livJ, livK, livH, and livG) are closely linked and have been cloned on a plasmid vector, pOX1. Several subcloned fragments of this plasmid have been prepared and used in complementation and regulation studies. The results of these studies suggest that livJ and livK are separated by approximately one kilobase and give a gene order of livJ-livK-livH. livJ and livK appear to be regulated in an interdependent fashion; livK is expressed maximally when the livJ gene is activated by mutation or deletion. The results support the existence of separate promotors for the livJ and livK genes. The effects of mutations in the rho and livR genes are additive on one another and therefore appear to be involved in independent regulatory mechanisms. Mutations in the rho gene affect both the LIV-I and leucine-specific transport systems by increasing the expression of livJ and livK, genes for the LIV-specific and leucine-specific binding proteins, respectively.

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.

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.

Mechanism of folate transport in Lactobacillus casei: evidence for a component shared with the thiamine and biotin transport systems

Lactobacillus casei cells have been shown previously to utilize two separate binding proteins for the transport of folate and thiamine. Folate transport, however, was found to be strongly inhibited by thiamine in spite of the fact that the folate-binding protein has no measurable affinity for thiamine. This inhibition, which did not fluctuate with intracellular adenosine triphosphate levels, occurred only in cells containing functional transport systems for both vitamins and was noncompetitive with folate but competitive with respect to the level of folate-binding protein. Folate uptake in cells containing optimally induced transport systems for both vitamins was inhibited by thiamine (1 to 10 muM) to a maximum of 45%; the latter value increased to 77% in cells that contained a progressively diminished folate transport system and a normal thiamine system. Cells preloaded with thiamine could transport folate at a normal rate, indicating that the inhibition resulted from the entry of thiamine rather than from its presence in the cell. In a similar fashion, folate (1 to 10 muM) did not interfere with the binding of thiamine to its transport protein, but inhibited thiamine transport (to a maximum of 25%). Competition also extended to biotin, whose transport was strongly inhibited (58% and 73%, respectively) by the simultaneous uptake of either folate or thiamine; biotin, however, had only a minimal effect on either folate or thiamine transport. The nicotinate transport system was unaffected by co-transport with folate, thiamine, or biotin. These results are consistent with the hypothesis that the folate, thiamine, and biotin transport systems of L. casei each function via a specific binding protein, and that they require, in addition, a common component present in limiting amounts per cell. The latter may be a protein required for the coupling of energy to these transport processes.

The relA locus specifies a positive effector in branched-chain amino acid transport regulation

The regulation of branched-chain amino acid transport and periplasmic binding proteins was studied in Escherichia coli strains which were isogenic except for the relA locus, the gene for the "stringent factor," which is responsible for guanosine tetraphosphate synthesis. The strain containing the relA mutation could not be derepressed for the synthesis of leucine transport or binding proteins when shifted from a medium containing all 20 amino acids in excess to one in which leucine was limiting. The relA+ strain showed normal derepression under these conditions.