Sequence analysis of mutA and mutM genes involved in the biosynthesis of the lantibiotic mutacin II in Streptococcus mutans.

Streptococcus mutans, along with many other gram-positive bacteria produce small antibacterial peptides called bacteriocins. Bacteriocins elaborated by S. mutans, termed mutacins, may provide a selective force necessary for initial or sustained colonization in dental plaque by this major dental pathogen. Previously, we purified and characterized mutacin II, the first lantibiotic found in S. mutans. Specific oligonucleotides designed according to the N-terminal amino acid sequence permitted amplification of 0.7 kb upstream and 2.1 kb downstream of the N-terminus, using single-specific-primer PCR (SSP-PCR). The gene encoding the mutacin II prepeptide, mutA, was subsequently cloned and sequenced. The complete prepeptide consists of 53 amino acids, including the 26 amino acid amphipathic leader peptide with the Gly(-2)-Gly(-1) sequence at the processing site. The prepeptide showed similarity to the lantibiotics lacticin 481, variacin, salivaricin and streptococcin A-FF22. A 3 kb open reading frame immediately downstream of mutA, denoted mutM, showed sequence similarities to LCNDR2 from Lactococcus lactis. By analogy, mutM is probably involved in post-translational modification of the mutacin prepeptide. Gene disruption with an insertional vector pVA891 showed that intact copies of mutA and mutM are required for production of mutacin II.

Cloning and characterization of the Pseudomonas aeruginosa sodA and sodB genes encoding manganese- and iron-cofactored superoxide dismutase: demonstration of increased manganese superoxide dismutase activity in alginate-producing bacteria.

Pseudomonas aeruginosa is a strict aerobe which is likely exposed to oxygen reduction products including superoxide and hydrogen peroxide during the metabolism of molecular oxygen. To counterbalance the potentially hazardous effects of elevated endogenous levels of superoxide, most aerobic organisms possess one or more superoxide dismutases or compounds capable of scavenging superoxide. We have previously shown that P. aeruginosa possesses both an iron- and a manganese-cofactored superoxide dismutase (D. J. Hassett, L. Charniga, K. A. Bean, D. E. Ohman, and M. S. Cohen, Infect. Immun. 60:328-336, 1992). In this study, the genes encoding manganese (sodA)- and iron (sodB)- cofactored superoxide dismutase were cloned by using a cosmid library of P. aeruginosa FRD which complemented an Escherichia coli (JI132) strain devoid of superoxide dismutase activity. The sodA and sodB genes of P. aeruginosa, when cloned into a high-copy-number vector (pKS-), partially restored the aerobic growth rate defect, characteristic of the Sod- strain, to that of the wild type (AB1157) when grown in Luria broth. The nucleotide sequences of sodA and sodB have open reading frames of 612 and 579 bp that encode dimeric proteins of 22.9 and 21.2 kDa, respectively. These data were also supported by the results of in vitro expression studies. The deduced amino acid sequence of the P. aeruginosa manganese and iron superoxide dismutase revealed approximately 50 and 67% similarity with manganese and iron superoxide dismutases from E. coli, respectively. There was also remarkable similarity with iron and manganese superoxide dismutases from other phyla. The mRNA start site of sodB was mapped to 174 bp upstream of the ATG codon. A likely promoter with similarity to the -10 and -35 consensus sequence of E. coli was observed upstream of the ATG start codon of sodB. Regions sequenced 519 bp upstream of the sodA electrophoresis, sodA gene revealed no such promoter, suggesting an alternative mode of control for sodA. By transverse field electrophoresis, sodA and sodB were mapped to the 71- to 75-min region on the P. aeruginosa PAO1 chromosome. Strikingly, mucoid alginate-producing bacteria generated greater levels of manganese superoxide dismutase than nonmucoid revertants, suggesting that mucoid P. aeruginosa is responding to oxidative stress and/or changes in the redox status of the cell.

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. Nine 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.

Pseudomonas aeruginosa outer membrane protein F: structural role and relationship to the Escherichia coli OmpA protein.

A Pseudomonas aeruginosa outer membrane protein F-deficient omega-insertion mutant strain H636, in contrast to its protein F-sufficient parent strain H103, was unable to grow on unsupplemented Proteose Peptone no. 2 broth (Difco Laboratories, Detroit, Mich.). Addition of high concentrations of NaCl, KCl, glucose, sucrose, or potassium succinate permitted growth of strain H636 at rates approaching those of the parent strain H103. Strain H636 cells were 33% shorter and had a 46% smaller cross-sectional area than did the parent strain growing at similar rates on the same medium. These properties of the oprF::omega mutant were analogous to those previously observed for Escherichia coli ompA mutants in an lpp (Braun lipoprotein-deficient) mutant background. Therefore, we compared P. aeruginosa protein F and the E. coli OmpA protein. In addition to many similarities previously described, sequence alignment demonstrated substantial amino acid sequence homology throughout the carboxy-terminal 168 to 180 amino acids of the two proteins. Consistent with this observation, polyclonal antiserum specific for OmpA reacted on Western blots (immunoblots) with protein F. Expression of protein F from the cloned oprF gene in an E. coli ompA lpp double mutant resulted in a 1.7-fold increase in cell length and a 2.1-fold increase in cross-sectional area compared with values for the same mutant containing only the plasmid vector onto which the oprF gene had been cloned. These results favor a structural role for P. aeruginosa protein F and suggest that it is strongly related to the E. coli OmpA protein.

Roles of porin and beta-lactamase in beta-lactam resistance of Pseudomonas aeruginosa.

Pseudomonas aeruginosa demonstrates high intrinsic resistance to most beta-lactam antibiotics. Two factors that are interrelated appear to be important in this intrinsic resistance: an inducible, chromosomally encoded type Id beta-lactamase and low outer-membrane permeability. beta-Lactamase-noninducible mutants are supersusceptible to many beta-lactam agents, whereas constitutively derepressed mutants are considerably more resistant even to so-called beta-lactamase-stable beta-lactams. For the latter mutants, by analysis of kinetics, it can be demonstrated that synergy between slow permeation across the outer membrane and slow hydrolysis of the beta-lactamase-stable beta-lactams can explain resistance. Wild-type P. aeruginosa allows outer membrane permeation of beta-lactam agents at rates 1%-8% of those measured for Escherichia coli. The majority of trans-outer-membrane channels formed by P. aeruginosa porin protein F are too small to allow passage of beta-lactam antibiotics. Nevertheless, this porin is apparently a conduit for beta-lactams, since protein F-deficient mutants have small changes in susceptibility to certain beta-lactam agents. This low outer-membrane permeability acting in synergy with beta-lactamase is probably responsible for intrinsic beta-lactam resistance in P. aeruginosa.

Construction and characterization of Pseudomonas aeruginosa protein F-deficient mutants after in vitro and in vivo insertion mutagenesis of the cloned gene.

Mutants with insertion mutations in the Pseudomonas aeruginosa protein F (oprF) gene were created in vivo by Tn1 mutagenesis of the cloned gene in Escherichia coli and in vitro by insertion of the streptomycin resistance-encoding omega fragment into the cloned gene, followed by transfer of the mutated protein F gene back to P. aeruginosa. Homologous recombination into the P. aeruginosa chromosome was driven by a bacteriophage F116L transduction method in the oprF::Tn1 mutants or Tn5-instability in the oprF::omega mutants. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western immunoblotting demonstrated that the resultant oprF insertion mutants had lost protein F, whereas restriction digestion and Southern blotting experiments proved that the mutants contained a single chromosomal oprF gene with either Tn1 or omega inserted into it. It has been proposed that protein F has a role in antibiotic uptake in P. aeruginosa. Measurement of antibiotic resistance levels showed small to marginal increases in resistance, compared with that of the parent P. aeruginosa strain, to a variety of beta-lactam antibiotics. Protein F-deficient mutants had altered barrier properties as revealed by a three- to fivefold increase in the uptake of the hydrophobic fluorescent probe 1-N-phenylnaphthylamine.

Expression in Escherichia coli and function of Pseudomonas aeruginosa outer membrane porin protein F.

The gene encoding porin protein F of Pseudomonas aeruginosa was cloned onto a cosmid vector into Escherichia coli. Protein F was expressed as the predominant outer membrane protein in a porin-deficient E. coli background and was clearly visible on one-dimensional sodium dodecyl sulfate-polyacrylamide gels in a porin-sufficient background. The identity of the protein F from the E. coli clone and native P. aeruginosa protein F was demonstrated by their identical mobilities on sodium dodecyl sulfate-polyacrylamide gel electrophoretograms, 2-mercaptoethanol modifiabilities, and reactivities with monoclonal antibodies specific of two separate epitopes of protein F. In the course of gene subcloning, a 2-kilobase DNA fragment was isolated, with an apparent truncation of the part of the gene encoding the carboxy terminus of protein F. This subclone produced a 24,000-molecular-weight, outer membrane-associated, truncated protein F derivative which was not 2-mercaptoethanol modifiable and which reacted with only one of the two classes of protein F-specific monoclonal antibodies. The 2-kilobase fragment was used in Southern blot hybridizations to construct a restriction map of the cloned and subcloned fragments and to demonstrate with restriction digests of whole P. aeruginosa DNA that only one copy of the protein F gene was present in the P. aeruginosa chromosome. The protein F produced by the original cosmid clone in a porin-deficient E. coli background was purified. To demonstrate retention of porin function after cloning, the protein F from the E. coli clone was incorporated into black lipid bilayer membranes. Two major classes of channels were revealed. The predominant class of channels had an average conductance of 0.36 nS in 1 M KCl, whereas larger channels (4 to 7 nS) were seen at a lower frequency. Similar channel sizes were observed for porin protein F purified by the same method from P. aeruginosa outer membranes.