36 research outputs found
Purification and partial characterization of the OmpA family of proteins of Pasteurella haemolytica
This study was conducted to partially characterize and identify the purity of two major outer membrane proteins (OMPs) (with molecular weights of 32,000 and 35,000 [32K and 35K, respectively]) of Pasteurella haemolytica. The 35K and 32K major OMPs, designated Pasteurella outer membrane proteins A and B (PomA and PomB, respectively), were extracted from P. haemolytica by solubilization in N-octyl polyoxyl ethylene. The P. haemolytica strain used was a mutant serotype A1 from which the genes expressing the 30-kDa lipoproteins had been deleted. PomA and PomB were separated and partially purified by anion-exchange chromatography. PomA but not PomB was heat modifiable. The N-terminal amino acid sequences of the two proteins were determined and compared with reported sequences of other known proteins. PomA had significant N-terminal sequence homology with the OmpA protein of Escherichia coli and related proteins from other gram-negative bacteria. Moreover, polyclonal antiserum raised against the E. coli OmpA protein reacted with this protein. PomA was surface exposed, was conserved among P. haemolytica biotype A serotypes, and had porin activity in planar bilayers. No homology between the N-terminal amino acid sequence of PomB and those of other known bacterial proteins was found. Cattle vaccinated with live P. haemolytica developed a significant increase in serum antibodies to partially purified PomA, as shown by enzyme-linked immunosorbent assays, and to purified PomA and PomB, as detected on Western blots and by densitometry.Peer reviewedAnatomy, Pathology and PharmacologyInfectious Disease and Physiolog
Cloning of the Pseudomonas aeruginosa outer membrane porin protein P gene: evidence for a linked region of DNA homology.
The gene encoding the outer membrane phosphate-selective porin protein P from Pseudomonas aeruginosa was cloned into Escherichia coli. The protein product was expressed and transported to the outer membrane of an E. coli phoE mutant and assembled into functional trimers. Expression of a product of the correct molecular weight was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot (immunoblot) analysis, using polyclonal antibodies to protein P monomer and trimer forms. Protein P trimers were partially purified from the E. coli clone and shown to form channels with the same conductance as those formed by protein P from P. aeruginosa. The location and orientation of the protein P-encoding (oprP) gene on the cloned DNA was identified by three methods: (i) mapping the insertion point of transposon Tn501 in a previously isolated P. aeruginosa protein P-deficient mutant; (ii) hybridization of restriction fragments from the cloned DNA to an oligonucleotide pool synthesized on the basis of the amino-terminal protein sequence of protein P; and (iii) fusion of a PstI fragment of the cloned DNA to the amino terminus of the beta-galactosidase gene of pUC8, producing a fusion protein that contained protein P-antigenic epitopes. Structural analysis of the cloned DNA and P. aeruginosa chromosomal DNA revealed the presence of two adjacent PstI fragments which cross-hybridized, suggesting a possible gene duplication. The P-related (PR) region hybridized to the oligonucleotide pool described above. When the PstI fragment which contained the PR region was fused to the beta-galactosidase gene of pUC8, a fusion protein was produced which reacted with a protein P-specific antiserum. However, the restriction endonuclease patterns of the PR region and the oprP gene differed significantly beyond the amino-terminal one-third of the two genes
Overexpression in Escherichia coli and functional analysis of a novel PPi-selective porin, oprO, from Pseudomonas aeruginosa.
Immediately upstream from and adjacent to the oprP gene, which codes for the phosphate-specific porin OprP of Pseudomonas aeruginosa, lies the PR region (oprO), which cross-hybridizes with oprP DNA. To determine the function of this region, the oprO gene was expressed behind the lactose promoter in Escherichia coli, and the resultant OprO protein was purified and reconstituted into planar lipid bilayers. OprO formed sodium dodecyl sulfate-stable trimers, cross-reacted immunologically with OprP, and, like OprP, formed an anion-specific, phosphate-selective porin. However, it demonstrated lower affinity for and higher maximal conductance of both chloride and phosphate than did the OprP channel. Examination by macroscopic conductance inhibition experiments of the affinity of OprO for phosphates of different lengths revealed a preference for PPi and tripolyphosphate over Pi, suggesting that OprO functioned as a PPi-selective polyphosphate channel, in contrast to OprP, which has a marked preference for Pi
Reevaluation, using intact cells, of the exclusion limit and role of porin OprF in Pseudomonas aeruginosa outer membrane permeability.
Earlier studies that used model membrane reconstitution methods have come to different conclusions regarding the exclusion limit of the outer membrane of Pseudomonas aeruginosa and whether OprF is the major channel-forming protein in the outer membrane. In this study, a 6.2-kbp SalI fragment, encoding only two cytoplasmic enzymes, alpha-galactosidase and sucrose hydrolase, and the inner membrane raffinose permease, was cloned behind the m-toluate-inducible tol promoter of vector pNM185 to create plasmid pFB71. P. aeruginosa strains harboring pFB71, when grown with inducer, produced both enzymes encoded by the insert and had acquired the ability to grow on the disaccharide melibiose and the trisaccharide raffinose. The rate of growth was dependent on the concentration and size of the saccharide and was decreased three- to fivefold by the absence of OprF, as examined by measuring the growth on melibiose and raffinose of an isogenic OprF-deficient omega insertion derivative, H636(pFB71). At high concentrations, di-, tri-, and tetrasaccharides could pass across the outer membrane to plasmolyze P. aeruginosa, as measured by light scattering and confirmed by electron microscopy. The initial rate kinetics of light-scattering changes were dependent on the size of the saccharide being used. Furthermore, the rates of change in light scattering due to raffinose and stachyose uptake across the outer membrane for strain H636 were fivefold or more lower than for its OprF-sufficient parent H103. These data are consistent with model membrane studies showing that OprF is the most predominant porin for compounds larger than disaccharides in P. aeruginosa and suggest that the exclusion limit for this porin and the outer membrane is greater than the size of a tetrasaccharide. In addition, these data confirmed the existence of other porins with a predominant function in monosaccharide uptake and a more minor function in the uptake of larger saccharides
Analysis of the Pseudomonas aeruginosa major outer membrane protein OprF by use of truncated OprF derivatives and monoclonal antibodies.
TnphoA mutagenesis of the cloned oprF gene was utilized to generate 16 classes of fusions encoding differing lengths of the amino terminus of OprF fused to either alkaline phosphatase or to peptide tags of 1 to 20 amino acids, depending on the orientation and reading frame into which TnphoA was inserted. Representatives of each of the 16 classes were sequenced to determine the precise fusion joint. Four of these 16 representatives which produced in-frame fusions to alkaline phosphatase and another 8 with fusion joints in the amino-terminal half of OprF failed to react with a panel of 10 specific monoclonal antibodies. In contrast, OprF derivatives with predicted fusion joints at amino acids 180, 204, 289, and 299 reacted with one to five of the monoclonal antibodies. Four other immunoreactive OprF derivatives were created by subcloning and encoded amino acids 1 to 187, 188 to 326, 1 to 273 and 1 to 170 plus 301 to 326. On the basis of reactivity with the TnphoA-truncated derivatives and subclones of oprF, the epitopes for all 10 monoclonal antibodies were localized, in part, to specific regions of OprF. Nnie of the 10 monoclonal antibodies, 8 of which recognize surface-exposed epitopes, mapped within the carboxy-terminal region of OprF that is homologous to the Escherichia coli outer membrane protein OmpA. Thus, we concluded that parts of the carboxy terminus of OprF are exposed on the external face of the outer membrane. In addition, a clone containing only the first two cysteine residues of OprF demonstrated reactivity with monoclonal antibodies MA4-4 and MA7-8 that was destroyed by 2-mercaptoethanol treatment, as was reactivity with intact OprF. Thus, we conclude that this first pair of cysteines at residues 176 and 185 of mature OprF form a disulfide bond