Requirements for osmosensing and osmotic activation of transporter ProP from Escherichia coli.

Transporter ProP of Escherichia coli, a solute-H+ symporter, can sense and respond to osmotic upshifts imposed on cells, on membrane vesicles, or on proteoliposomes that incorporate purified ProP-(His)6. In this study, proline uptake catalyzed by ProP was used as a measure of its osmotic activation, and the requirements for osmosensing were defined using the proteoliposome system. The initial rate of proline uptake increased with decreasing external pH and increasing DeltaPsi, lumen negative. Osmotic upshifts increased DeltaPsi by concentrating lumenal K+, but osmotic activation of ProP could be distinguished from this effect. Osmotic activation of ProP resulted from changes in Vmax, though osmotic shifts also increased the KM for proline. Osmotic activation could be described as a reversible, osmotic upshift-dependent transition linking (at least) two transporter protein conformations. No correlation was observed between ProP activation and the position of the anions of activating sodium salts within the Hofmeister series of solutes. Both the magnitude of the osmotic upshift required to activate ProP and the ProP activity attained were similar for membrane-impermeant osmolytes, including NaCl, glucose, and PEG 600. The membrane-permeant osmolytes glycerol, urea, PEG 62, and PEG 106 failed to activate ProP. Two poly(ethylene glycol)s, PEG 150 and PEG 200, were membrane-permeant and did not cause liposome shrinkage, but they did partially activate ProP-(His)6.

An Escherichia coli reference collection group B2- and uropathogen-associated polymorphism in the rpoS-mutS region of the E. coli chromosome.

Chromosomal DNAs of enterohemorrhagic, uropathogenic, and laboratory attenuated Escherichia coli strains differ in the rpoS-mutS region. Many uropathogens lack a deletion and an insertion characteristic of enterohemorrhagic strains. At the same chromosomal position, they harbor a 2.1-kb insertion of unknown origin with a base composition suggestive of horizontal gene transfer. Unlike virulence determinants associated with urinary tract infection and/or neonatal meningitis (pap or prs, sfa, kps, and hly), the 2.1-kb insertion is shared by all group B2 strains of the E. coli Reference Collection.

The role of the carboxyl terminal alpha-helical coiled-coil domain in osmosensing by transporter ProP of Escherichia coli.

Concentrative uptake of osmoprotectants via transporter ProP contributes to the rehydration of Escherichia coli cells that encounter high osmolality media. A member of the major facilitator superfamily, ProP is activated by osmotic upshifts in whole bacteria, in cytoplasmic membrane vesicles and in proteoliposomes prepared with the purified protein. Soluble protein ProQ is also required for full osmotic activation of ProP in vivo. ProP is differentiated from structural and functional homologues by its osmotic activation and its C-terminal extension, which is predicted to form an alpha-helical coiled-coil. A synthetic polypeptide corresponding to the C-terminus of ProP (ProP-p) formed a dimeric alpha-helical coiled-coil. A derivative of transporter ProP lacking 26 C-terminal amino acids was expressed but inactive. A derivative harbouring amino acid changes K460I, Y467I and H495I (each at the core, coiled-coil 'a' position) required a larger osmotic upshift for activation than did the wild type transporter. The same changes extended, stabilized and altered the oligomeric state of the coiled-coil formed by ProP-p. Amino acid change R488I (also at the 'a' position) further increased the magnitude of the osmotic upshift required to activate ProP, reduced the activity attained and rendered ProP activation transient. Unexpectedly, replacement R488I destabilized the coiled-coil formed by ProP-p. The activity and osmotic activation of ProP were even more strongly attenuated by helix-destabilizing change I474P. These data demonstrate that the carboxyl terminal domain of ProP can form a homodimeric alpha-helical coiled-coil with unusual properties. They implicate the C-terminal domain in the osmotic activation of ProP.

The ion coupling and organic substrate specificities of osmoregulatory transporter ProP in Escherichia coli.

Transporter ProP of Escherichia coli, a member of the major facilitator superfamily, mediates osmoprotective proline or glycine betaine accumulation by bacteria exposed to high osmolality environments. Morpholinopropane sulfonic acid, a common constituent of microbiological media, accumulates in osmoadapting E. coli cells but it is not osmoprotective and it did not influence proP transcription or ProP activity. The apparent K(m) for proline uptake via ProP increased with decreasing pH in the range 7.5-4. ProP-dependent proline uptake by de-energized bacteria was associated with alkalinization of the external medium. Thus ProP mediates cotransport of H(+) and zwitterionic proline and a transporter functional group with a pK(a) of 5-6 is implicated in catalysis. Exogenous proline or glycine betaine elicits K(+) release from osmoadapting E. coli cells and ProP activity is stimulated by exogenous K(+). However, uptake of proline or glycine betaine stimulated K(+) efflux from K(+)-loaded bacteria which expressed either ProP or alternative, osmoregulatory transporter ProU. This indicated that ProP was unlikely to mediate K(+) efflux. Zwitterions ectoine, pipecolate, proline betaine, N,N-dimethylglycine, carnitine and 1-carboxymethylpyridinium were identified as alternative ProP substrates. Choline, a cation and a structural analogue of glycine betaine, was a low affinity inhibitor but not a substrate of ProP.

Purification and reconstitution of an osmosensor: transporter ProP of Escherichia coli senses and responds to osmotic shifts.

The ProP protein of Escherichia coli is an osmoregulatory H+-compatible solute cotransporter. ProP is activated by an osmotic upshift in both whole cells and membrane vesicles. We are using biochemical and biophysical techniques to explore the osmosensory and catalytic mechanisms of ProP. We now report the purification and reconstitution of the active transporter. Protein purification was facilitated by the addition of six histidine (His) codons to the 3' end of proP. The recombinant gene was overexpressed from the E. coli galP promoter, and ProP-(His)6 was shown to be functionally equivalent to wild-type ProP by enzymatic assay of whole cells. ProP-(His)6, purified by Ni2+ (NTA) affinity chromatography, cross-reacted with antibodies raised against the ProP protein. ProP-(His)6 was reconstituted into Triton X-100 destabilized liposomes prepared with E. coli phospholipid. The reconstituted transporter mediated proline accumulation only if (1) a membrane potential was generated by valinomycin-mediated K+ efflux and (2) the proteoliposomes were subjected to an osmotic upshift (0.6 M sucrose). Activity was also stimulated by DeltapH. Pure ProP acts, in the proteoliposome environment, as sensor, transducer, and respondent to a hyperosmotic shift. It is the first such osmosensor to be isolated.

Protein ProQ influences osmotic activation of compatible solute transporter ProP in Escherichia coli K-12.

ProP is an osmoregulatory compatible solute transporter in Escherichia coli K-12. Mutation proQ220::Tn5 decreased the rate constant for and the extent of ProP activation by an osmotic upshift but did not alter proP transcription or the ProP protein level. Allele proQ220::Tn5 was isolated, and the proQ sequence was determined. Locus proQ is upstream from prc (tsp) at 41.2 centisomes on the genetic map. The proQ220::Tn5 and prc phenotypes were different, however. Gene proQ is predicted to encode a 232-amino-acid, basic, hydrophilic protein (molecular mass, 25,876 Da; calculated isoelectric point, 9.66; 32% D, E, R, or K; 54.5% polar amino acids). The insertion of PCR-amplified proQ into vector pBAD24 produced a plasmid containing the wild-type proQ open reading frame, the expression of which yielded a soluble protein with an apparent molecular mass of 30 kDa. Antibodies raised against the overexpressed ProQ protein detected cross-reactive material in proQ+ bacteria but not in proQ220::Tn5 bacteria. ProQ may be a structural element that influences the osmotic activation of ProP at a posttranslational level.

Bacterial genetic loci implicated in the Pseudomonas putida GR12-2R3--canola mutualism: identification of an exudate-inducible sugar transporter.

Pseudomonas putida GR12-2R3 promotes the emergence and growth of diverse plant species. Analyses of TnphoA insertion mutations are revealing bacterial characteristics pertinent to the plant-microbe interaction. Pseudomonas putida PG269 is a TnphoA insertion derivative of GR12-2R3 that expresses canola seed exudate-inducible alkaline phosphatase (PhoA) activity. It promoted the growth of canola roots, as well as strain GR12-2R3, and outgrew its parent when they were cocultured in the presence of canola roots or in liquid seed exudate medium. (In contrast, mutant PG126 failed to promote canola root growth and was outgrown by its parent strain.) The PhoA activity of strain PG269 was induced by glucosamine and other sugars; glucosamine inhibited the growth of strain GR12-2R3 and stimulated the growth of strain PG269. Strain PG269 contained two TnphoA insertions: seiA1::TnphoA and seiB1::TnphoA. Strain PG312, which contained only insertion seiA1::TnphoA, shared all aspects of the PG269 phenotype, except the ability to outcompete strain GR12-2R3 during coculture. Insertion seiA1::TnphoA interrupted an open reading frame related in sequence to members of the MalF family of sugar transporter subunits. The PhoA-inducing fraction of canola seed exudate was hydrophilic, low in molecular weight, and heat stable. It cochromatographed with basic amino acids and amino sugars, and was inactivated by strains GR12-2R3 and PG269. Gene seiA may encode a subunit of an ABC transporter with broad specificity for glucose and related sugars whose expression can be induced by exudate sugars.

Genes encoding osmoregulatory proline/glycine betaine transporters and the proline catabolic system are present and expressed in diverse clinical Escherichia coli isolates.

Sixty-three clinical isolates identified as Escherichia coli, 30 from the human urinary tract and 33 derived from other human origins, were screened for proline/glycine betaine transporters similar to those that support proline catabolism and proline- or glycine betaine-based osmoregulation in E. coli K-12. Both molecular (DNA- and protein-based) analyses and physiological tests were performed. All tests were calibrated with E. coli K-12 derivatives from which genetic loci putP (encoding a proline transporter required for proline catabolism), proP, and (or) proU (loci encoding osmoregulatory proline/glycine betaine transporters) had been deleted. All clinical isolates showed both enhanced sensitivity to the toxic proline analogue azetidine-2-carboxylate on media of high osmolality and growth stimulation by glycine betaine in an artificial urine preparation of high osmolality. DNA sequences similar to the putP, proP, and proU loci of E. coli K-12 were detected by DNA amplification and (or) hybridization and protein specifically reactive with antibodies raised against the ProX protein of E. coli K-12 (a ProU constituent) was detected by western blotting in over 95% of the isolates. Two anomalous isolates were reclassified as non-E. coli on the basis of the API 20E series of tests. A protein immunochemically cross-reactive with the ProP protein of E. coli K-12 was also expressed by the clinical isolates. Since all three transporters were ubiquitous, no particular correlation between clinical origin and PutP, ProP, or ProU activity was observed. These data suggest that the transporters encoded in loci putP, proP, and proU perform housekeeping functions essential for the survival of E. coli cells in diverse habitats.

Isolation and sequencing of Escherichia coli gene proP reveals unusual structural features of the osmoregulatory proline/betaine transporter, ProP.

Transporters encoded in genetic loci putP, proP and proU mediate proline and/or betaine accumulation by Escherichia coli K-12. The ProP and ProU systems are osmoregulatory. Activation of ProP in response to hyperosmotic stress has been demonstrated both in vivo and in vitro. It therefore serves as a model experimental system for the analysis of osmosensory and osmoregulatory mechanisms. We developed methodologies which will facilitate the identification of proline transporter genes by functional complementation of putP proP proU bacteria. E. coli gene proP was isolated and located within a chromosomal DNA fragment. Deletion, complementation and sequence analysis revealed putative promoter and transcription termination signals flanking a 1500 base-pair open reading frame. The predicted 55 kDa ProP protein was hydrophobic. In vitro expression of proP yielded a protein whose apparent molecular mass was determined to be 42 kDa by polyacrylamide gel electrophoresis under denaturing conditions. Database searches and cluster analysis defined relationships among the ProP sequence and those of integral membrane proteins that comprise a transporter superfamily. Members of the superfamily catalyze facilitated diffusion or ion linked transport of organic solutes in prokaryotes and eukaryotes. Multiple alignment revealed particularly close correspondence among the ProP protein, citrate transporters from E. coli and Klebsiella pneumoniae and an alpha-ketoglutarate transporter from E. coli. The predicted ProP sequence differed from those closely similar sequences in possessing an extended central hydrophilic loop and a carboxyl terminal extension. Unlike other protein sequences within the transporter superfamily, the carboxyl terminal extension of ProP was strongly predicted to participate in formation of an alpha-helical coiled coil. These data suggest that the ProP protein catalyzes solute-ion cotransport. Its unusual structural features may be related to osmoregulation of its activity.

Multiple termination sites in an unlinked 5S rRNA operon in the archaebacterium, Thermococcus celer.

The termini of transcripts from an unlinked 5S rRNA operon were analyzed in the archaebacterium, Thermococcus celer. While the sequences of the 5' termini were completely consistent with the presently accepted consensus promoter sequences, putative multiple termination sites were identified which differed significantly from those identified in other organisms, including archaebacteria. Although termination appears to be dependent on a stem/loop structure this structure does not immediately precede a uridylic acid residue cluster. Rather, an adenylic acid residue cluster follows the termination site. The relationship of this termination site structure to those of other archaebacteria is considered.

An unlinked 5 S ribosomal RNA gene in the archaebacterium, Thermococcus celer.

We have determined the nucleotide sequence of an unlinked 5 S rRNA gene region from a thermophilic archaebacterium, Thermococcus celer. This 5 S rRNA gene is flanked by a single tRNA(Asp) sequence and appears to be transcribed as part of a very short operon consisting of only two gene sequences. Comparative studies indicate features in the 5' and 3' flanking sequences, which bear similarity with promoter and termination signals in eubacteria, but also reflect unusual features found in at least some archaebacteria. The evolution of this unlinked operon and the unusual features are discussed.

Effects of ribosome dissociation on the structure of the ribosome-associated 5.8S RNA.

Diethyl pyrocarbonate reactivity and thermal denaturation were used to probe potential ribosomal interactions between tRNA and the small 5.8S and 5S rRNAs. Puromycin, an analogue of the terminal aminoacyl-adenosine portion of aminoacyl-tRNA, was observed to increase the accessibility of the 5.8S rRNA, including the highly conserved GAACp sequences. EDTA which releases both tRNA and the 5S rRNA-protein complex resulted in an even greater accessibility in the 5.8S rRNA. The thermal dissociation of whole ribosomes resulted in the release of all three RNAs, with a striking similarity in the denaturation profiles. These results strongly suggest an interdependence in the ribosome-associated structures of the small rRNAs and provide in situ evidence for the various 5S rRNA, 5.8S rRNA, and tRNA containing ribonucleoprotein complexes previously reconstituted through affinity chromatography.