Two proline porters in Escherichia coli K-12

Escherichia coli mutants defective at putP and putA lack proline transport via proline porter I and proline dehydrogenase activity, respectively. They retain a proline uptake system (proline porter II) that is induced during tryptophan-limited growth and are sensitive to the toxic L-proline analog, 3,4-dehydroproline. 3,4-Dehydroproline-resistant mutants derived from a putP putA mutant lack proline porter II. Auxotrophic derivatives derived from putP+ or putP bacteria can grow if provided with proline at low concentration (25 microM); those derived from the 3,4-dehydroproline-resistant mutants require high proline for growth (2.5 mM). We conclude that E. coli, like Salmonella typhimurium, possesses a second proline porter that is inactivated by mutations at the proP locus.     

Isolation and characterization of monoclonal antibodies to proline dehydrogenase from Escherichia coli K-12

The PutA protein of Escherichia coli K-12 serves as both proline dehydrogenase and the repressor controlling the expression of genes putP and putA. Thirty-eight hybridoma cell lines were isolated using mice immunized with proline dehydrogenase purified from a bacterial membrane extract. The monoclonal antibodies secreted by those cells showed varying affinities for proline dehydrogenase by enzyme-linked immunosorbent assay (ELISA). Nine antibodies labelled the PutA protein in Western blots after sodium dodecyl sulfate--polyacrylamide gel electrophoresis and two of the five tested also labelled the undenatured PutA protein. Three antibodies bound proteins present in a peripheral membrane protein fraction from both putA+ bacteria and a putA::Tn5 mutant strain. Urea denaturation eliminated the proline:2,6-dichloroindophenol (DCIP) oxidoreductase activity, but did not alter the immunoreactivity of the PutA protein. Tween 20, which caused 1.8-fold increases in Km (proline) and Vmax for proline:DCIP oxidoreductase, increased the avidity of the antibody from hybridoma line 2.1C10.3 fivefold. The antibodies from hybridoma lines 2.1C10.2, 1.2C10.3, and 1.1B07.1 were shown by electron microscopy of immunogold-labelled preparations or by ELISA to bind the membrane-associated PutA protein, whereas those from hybridoma lines 2.1A08.2 and 1.4C09.1 failed to recognize that antigen form. These antibodies will serve as probes of the relationships among protein domain, conformation, and function for the PutA protein.     

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.     

Proline catabolism by Pseudomonas putida: cloning, characterization, and expression of the put genes in the presence of root exudates

Pseudomonas putida KT2442 is a root-colonizing strain which can use proline, one of the major components in root exudates, as its sole carbon and nitrogen source. A P. putida mutant unable to grow with proline as the sole carbon and nitrogen source was isolated after random mini-Tn5-Km mutagenesis. The mini-Tn5 insertion was located at the putA gene, which is adjacent to and divergent from the putP gene. The putA gene codes for a protein of 1,315 amino acid residues which is homologous to the PutA protein of Escherichia coli, Salmonella enterica serovar Typhimurium, Rhodobacter capsulatus, and several Rhizobium strains. The central part of P. putida PutA showed homology to the proline dehydrogenase of Saccharomyces cerevisiae and Drosophila melanogaster, whereas the C-terminal end was homologous to the pyrroline-5-carboxylate dehydrogenase of S. cerevisiae and a number of aldehyde dehydrogenases. This suggests that in P. putida, both enzymatic steps for proline conversion to glutamic acid are catalyzed by a single polypeptide. The putP gene was homologous to the putP genes of several prokaryotic microorganisms, and its gene product is an integral inner-membrane protein involved in the uptake of proline. The expression of both genes was induced by proline added in the culture medium and was regulated by PutA. In a P. putida putA-deficient background, expression of both putA and putP genes was maximal and proline independent. Corn root exudates collected during 7 days also strongly induced the P. putida put genes, as determined by using fusions of the put promoters to 'lacZ. The induction ratio for the putA promoter (about 20-fold) was 6-fold higher than the induction ratio for the putP promoter.     

Proline carrier mutant of Escherichia coli K-12 with altered cation sensitivity of substrate-binding activity: cloning, biochemical characterization, and identification of the mutation.

Two putP mutants of Escherichia coli K-12 that were defective in proline transport but retained the binding activities of the major proline carrier were isolated (T. Mogi, H. Yamamoto, T. Nakao, I. Yamato, and Y. Anraku, Mol. Gen. Genet. 202:35-41, 1986). One of these mutations and three null-type mutations (K. Motojima, I. Yamato, and Y. Anraku, J. Bacteriol. 136:5-9, 1978) were cloned into a pBR322 putP+ hybrid plasmid (pTMP5) by in vivo recombination. Cytoplasmic membrane vesicles were prepared from the mutant strains and strains harboring pTMP5 putP plasmids, and the properties of the proline-binding reaction of the mutant putP carriers in membranes were examined under nonenergized conditions. The putP19, putP21, and putP22 mutations, which were mapped in the same DNA segment of the putP gene (Mogi et al., Mol. Gen. Genet. 202:35-41, 1986), caused the complete loss of proline carrier activity. The proline carriers encoded by the mutant putP genes, putP9 and putP32, and putP32 in pTMP5-32, which was derived from in vivo recombination with the putP32 mutation, had altered sodium ion and proton dependence of binding affinities for proline and were resistant to N-ethylmaleimide inactivation without changes in the specificities for substrates and alkaline metal cations. The nucleotide sequence of the putP32 lesion located on the 0.35-megadalton RsaI-PvuII fragment in the putP gene in pTMP5-32 was determined; the mutation changed a cytosine at position 1001 to a thymine, causing the alteration of arginine to cysteine at amino acid position 257 in the primary structure of the proline carrier. It was shown that this one point mutation was enough to produce the phenotype of pTMP5-32 by in vitro DNA replacement of the AcyI-PvuII fragment of the wild-type putP gene with the DNA fragment containing the mutated nucleotide sequence.     

Cluster of genes controlling proline degradation in Salmonella typhimurium.

A cluster of genes essential for degradation of proline to glutamate (put) is located between the pyrC and pyrD loci at min 22 of the Salmonella chromosome. A series of 25 deletion mutants of this region have been isolated and used to construct a fine-structure map of the put genes. The map includes mutations affecting the proline degradative activities, proline oxidase and pyrroline-5-carboxylic dehydrogenase. Also included are mutations affecting the major proline permease and a regulatory mutation that affects both enzyme and permease production. The two enzymatic activities appear to be encoded by a single gene (putA). The regulatory mutation maps between the putA gene and the proline permease gene (putP).     

Characterization of an inducible porter required for L-proline catabolism by Escherichia coli K12.

L-Proline can serve as sole source of carbon and nitrogen for the growth of Escherichia coli K12 and other Enterobacteria. L-Proline uptake and L-proline oxidase are subject both to catabolite repression and to specific induction by L-proline or glycyl-L-proline, although their regulation is not strictly coordinate. A strain defective for L-proline uptake due to a lesion at the locus putP does not show elevated uptake activity either on relief of catabolite repression or when grown on glycyl-L-proline as nitrogen source. The apparent Km for L-proline uptake decreases up to 14-fold as uptake Vm increases when cells are induced for both L-proline uptake and L-proline oxidase; cells with increased uptake activity, alone, do not show an altered Km. Although L-proline is metabolized during the uptake measurements, uptake is always active. The observed variations in uptake Km are unlikely to result from the escape of radioactive L-proline metabolites or from reversal of the transport reaction during the uptake measurements. We conclude that the L-proline porter encoded in putP is responsible for 80 to 90% of the constitutive and for the inducible L-proline uptake activity of wild-type bacteria. Although this porter is amplified in cells induced for L-proline catabolism, the observed values for uptake Vm may not be taken as a direct indicator of porter concentration.     

Oxidation of 3,4-dehydro-D-proline and other D-amino acid analogues by D-alanine dehydrogenase from Escherichia coli

3,4-Dehydro-DL-proline is a toxic analogue of L-proline which has been useful in studying the uptake and metabolism of this key amino acid. When membrane fractions from Escherichia coli strain UMM5 (putA1::Tn5 proC24) lacking both L-proline dehydrogenase and L-Delta(1)-pyrroline-5-carboxylate reductase were incubated with 3,4-dehydro-DL-proline, pyrrole-2-carboxylate was formed. There was no enzyme activity with 3,4-dehydro-L-proline, but activity was restored after racemization of the substrate. Oxidation of 3,4-dehydro-DL-proline by membrane fractions from strain UMM5 was induced by growth in minimal medium containing D- or L-alanine, had a pH optimum of 9, and was competitively inhibited by D-alanine. An E. coli strain with no D-alanine dehydrogenase activity due to the dadA237 mutation was unable to oxidize either 3,4-dehydro-D-proline or D-alanine, as were spontaneous Dad(-) mutants of E. coli strain UMM5. Membrane fractions containing D-alanine dehydrogenase also catalyzed the oxidation of D-2-aminobutyrate, D-norvaline, D-norleucine, cis-4-hydroxy-D-proline, and DL-ethionine. These results indicate that d-alanine dehydrogenase is responsible for the residual 3,4-dehydro-DL-proline oxidation activity in putA proC mutants of E. coli and provide further evidence that this enzyme plays a general role in the metabolism of D-amino acids and their analogues.     

The γ-Aminobutyrate Permease GabP Serves as the Third Proline Transporter of Bacillus subtilis

PutP and OpuE serve as proline transporters when this imino acid is used by Bacillus subtilis as a nutrient or as an osmostress protectant, respectively. The simultaneous inactivation of the PutP and OpuE systems still allows the utilization of proline as a nutrient. This growth phenotype pointed to the presence of a third proline transport system in B. subtilis. We took advantage of the sensitivity of a putP opuE double mutant to the toxic proline analog 3,4-dehydro-dl-proline (DHP) to identify this additional proline uptake system. DHP-resistant mutants were selected and found to be defective in the use of proline as a nutrient. Whole-genome resequencing of one of these strains provided the lead that the inactivation of the γ-aminobutyrate (GABA) transporter GabP was responsible for these phenotypes. DNA sequencing of the gabP gene in 14 additionally analyzed DHP-resistant strains confirmed this finding. Consistently, each of the DHP-resistant mutants was defective not only in the use of proline as a nutrient but also in the use of GABA as a nitrogen source. The same phenotype resulted from the targeted deletion of the gabP gene in a putP opuE mutant strain. Hence, the GabP carrier not only serves as an uptake system for GABA but also functions as the third proline transporter of B. subtilis. Uptake studies with radiolabeled GABA and proline confirmed this conclusion and provided information on the kinetic parameters of the GabP carrier for both of these substrates.     

Proline transport in Salmonella typhimurium: putP permease mutants with altered substrate specificity.

The putP gene encodes a proline permease required for Salmonella typhimurium LT2 to grow on proline as the sole source of nitrogen. The wild-type strain is sensitive to two toxic proline analogs (azetidine-2-carboxylic acid and 3,4-dehydroproline) also transported by the putP permease. Most mutations in putP prevent transport of all three substrates. Such mutants are unable to grow on proline and are resistant to both of the analogs. To define domains of the putP gene that specify the substrate binding site, we used localized mutagenesis to isolate rare mutants with altered substrate specificity. The position of the mutations in the putP gene was determined by deletion mapping. Most of the mutations are located in three small (approximately 100-base-pair) deletion intervals of the putP gene. The sensitivity of the mutants to the proline analogs was quantitated by radial streaking to determine the affinity of the mutant permeases for the substrates. Some of the mutants showed apparent changes in the kinetics of the substrates transported. These results indicate that the substrate specificity mutations are probably due to amino acid substitutions at or near the active site of proline permease.     

Expression of the putA gene encoding proline dehydrogenase from Rhodobacter capsulatus is independent of NtrC regulation but requires an Lrp-like activator protein.

Four Rhodobacter capsulatus mutants unable to grow with proline as the sole nitrogen source were isolated by random Tn5 mutagenesis. The Tn5 insertions were mapped within two adjacent chromosomal EcoRI fragments. DNA sequence analysis of this region revealed three open reading frames designated selD, putR, and putA. The putA gene codes for a protein of 1,127 amino acid residues which is homologous to PutA of Salmonella typhimurium and Escherichia coli. The central part of R. capsulatus PutA showed homology to proline dehydrogenase of Saccharomyces cerevisiae (Put1) and Drosophila melanogaster (SlgA). The C-terminal part of PutA exhibited homology to Put2 (pyrroline-5-carboxylate dehydrogenase) of S. cerevisiae and to aldehyde dehydrogenases from different organisms. Therefore, it seems likely that in R. capsulatus, as in enteric bacteria, both enzymatic steps for proline degradation are catalyzed by a single polypeptide (PutA). The deduced amino acid sequence of PutR (154 amino acid residues) showed homology to the small regulatory proteins Lrp, BkdR, and AsnC. The putR gene, which is divergently transcribed from putA, is essential for proline utilization and codes for an activator of putA expression. The expression of putA was induced by proline and was not affected by ammonia or other amino acids. In addition, putA expression was autoregulated by PutA itself. Mutations in glnB, nifR1 (ntrC), and NifR4 (ntrA encoding sigma 54) had no influence on put gene expression. The open reading frame located downstream of R. capsulatus putR exhibited strong homology to the E. coli selD gene, which is involved in selenium metabolism. R. capsulatus selD mutants exhibited a Put+ phenotype, demonstrating that selD is required neither for viability nor for proline utilization.     

Redesigned purification yields a fully functional PutA protein dimer from Escherichia coli.

Proline utilization by Escherichia coli and Salmonella typhimurium requires expression of genes putP (encoding a proline transporter) and putA. Genetic data indicate that the PutA protein is both put repressor and a respiratory chain-linked dehydrogenase. We report a redesigned purification procedure as well as the physical characteristics and biological activities of the PutA protein purified from E. coli. The purified protein was homogeneous as determined by electrophoresis performed under denaturing and nondenaturing conditions. Its N-terminal sequence corresponded to that predicted by the DNA sequence. We showed copurification of proline and delta 1-pyrroline-5-carboxylate dehydrogenase activities. Purified PutA protein bound put DNA in vitro in an electrophoretic band-shift assay and it could be reconstituted to inverted membrane vesicles, yielding proline dehydrogenase activity. The Stokes radius and Svedberg coefficient of the protein were determined to be 7.1 nm and 9.9 S, respectively. These hydrodynamic data revealed that the protein in our preparation was dimeric with a molecular mass of 293 kDa and that it had an irregular shape indicated by the friction factor (f/f0) of 1.6.     

Solubilization and functional reconstitution of the proline transport system of Escherichia coli

The membrane carrier for L-proline (product of the putP gene) of Escherichia coli K12 was solubilized and functionally reconstituted with E. coli phospholipid by the cholate dilution method. The counterflow activity of the reconstituted system was studied by preloading the proteoliposomes with either L-proline or the proline analogues: L-azetidine-2-carboxylate or 3,4-dehydro-L-proline. The dilution of such preloaded proteoliposomes into a buffer containing [3H]proline resulted in the accumulation of this amino acid against a considerable concentration gradient. A second driving force for proline accumulation was an electrochemical potential difference for Na+ across the membrane. More than a 10-fold accumulation was seen with a sodium electrochemical gradient while no accumulation was found with proton motive force alone. The optimal pH for the L-proline carrier activities for both counterflow and sodium gradient-driven uptake was between pH 6.0 and 7.0. The stoichiometry of the co-transport system was approximately one Na+ for one proline. The effect of different phospholipids on the proline transport activity of the reconstituted carrier was also studied. Both phosphatidylethanolamine and phosphatidylglycerol stimulate the carrier activity while phosphatidylcholine and cardiolipin were almost inactive.     

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.     

Escherichia coli K-12 Mutants Altered in the Transport Systems for Oligo- and Dipeptides

Two mutants of Escherichia coli K-12, defective in the oligopeptide and dipeptide transport system, are described. A mutant defective in the oligopeptide transport system (opp-1) was isolated as resistant to the inhibitory action of triornithine; this mutant is also resistant to glycylglycylvaline and does not concentrate (14)C-glycylglycylglycine, although it is still as sensitive as the parental strain to glycylvaline and valine. Starting from the opp-1 strain, a mutant defective also in the dipeptide transport system (dpp-1) was isolated; this mutant is resistant to the inhibitory action of glycylvaline, valylleucine, and leucylvaline and does not concentrate (14)C-glycylglycine, although it is still as sensitive as the parental strain to valine. The apparent kinetic constants for oligopeptide and dipeptide transport were measured. The opp marker is co-transducible with trp at 27 min on the E. coli genetic map. The dpp locus is separated from opp and is located between proC (10 min) and opp.