Project description:M. tuberculosis strain 1254 wild type (WT) and its isogenic delta Rv3662c-Rv3665c KO (opp KO) and complemented opp::opp were cultured in vitro, in liquid 7H9 media supplemented with OADC and 0.05% Tween 80, 0.5% glycerol, in a 150 mL volume, contained in roller bottles, incubated at 37oC. Growth was monitored as OD600 nm and recorded on a daily basis. In all experiments, the starting OD600 nm was 0.04-0.05. Aliquots were removed at each OD600 nm to make serial dilutions, plate onto 7H10 OADC agar plates for CFU counts. When cells reached OD600 nm of 0.3, 1.0, and 1.5, a 10-30 mL aliquot was taken, centrifuged 3 min at 3000 g, at room temperature, and the supernatant was discarded, with cell pellets being immediately frozen by inclusion into dry ice. Frozen cell pellets were stored at -80oC for later RNA isolation. In all experiments, RNA from WT was labeled with Cy5, and RNA from the opp KO was labeled with Cy3. In all experiments, the microarray comparsion used RNA from cells of the same growth stage, i.e., WT OD 0.3 vs opp KO OD 0.3, WT OD 1.0 vs opp KO OD 1.0, and WT OD 1.5 vs opp KO OD 1.5. When comparing the Complemented opp::opp vs the mutant opp KO, RNA from the later strain was Cy3-labeled. A cell type comparison design experiment design type compares cells of different type for example different cell lines.

Project description:M. tuberculosis strain 1254 wild type (WT) and its isogenic delta Rv3662c-Rv3665c KO (opp KO) and complemented opp::opp were cultured in vitro, in liquid 7H9 media supplemented with OADC and 0.05% Tween 80, 0.5% glycerol, in a 150 mL volume, contained in roller bottles, incubated at 37oC. Growth was monitored as OD600 nm and recorded on a daily basis. In all experiments, the starting OD600 nm was 0.04-0.05. Aliquots were removed at each OD600 nm to make serial dilutions, plate onto 7H10 OADC agar plates for CFU counts. When cells reached OD600 nm of 0.3, 1.0, and 1.5, a 10-30 mL aliquot was taken, centrifuged 3 min at 3000 g, at room temperature, and the supernatant was discarded, with cell pellets being immediately frozen by inclusion into dry ice. Frozen cell pellets were stored at -80oC for later RNA isolation. In all experiments, RNA from WT was labeled with Cy5, and RNA from the opp KO was labeled with Cy3. In all experiments, the microarray comparsion used RNA from cells of the same growth stage, i.e., WT OD 0.3 vs opp KO OD 0.3, WT OD 1.0 vs opp KO OD 1.0, and WT OD 1.5 vs opp KO OD 1.5. When comparing the Complemented opp::opp vs the mutant opp KO, RNA from the later strain was Cy3-labeled. A cell type comparison design experiment design type compares cells of different type for example different cell lines. cell_type_comparison_design

Project description:The bacterium Xenorhabdus nematophila is a mutualist of Steinernema carpocapsae nematodes and a pathogen of insects. Presently, it is not known what nutrients the bacterium uses to thrive in these host environments. In other symbiotic bacteria, oligopeptide permeases have been shown to be important in host interactions, and we therefore sought to determine if oligopeptide uptake is essential for growth or symbiotic functions of X. nematophila in laboratory or host environments. We identified an X. nematophila oligopeptide permease (opp) operon of two sequential oppA genes, predicted to encode oligopeptide-binding proteins, and putative permease-encoding genes oppB, oppC, oppD, and oppF. Peptide-feeding studies indicated that this opp operon encodes a functional oligopeptide permease. We constructed strains with mutations in oppA(1), oppA(2), or oppB and examined the ability of each mutant strain to grow in a peptide-rich laboratory medium and to interact with the two hosts. We found that the opp mutant strains had altered growth phenotypes in the laboratory medium and in hemolymph isolated from larval insects. However, the opp mutant strains were capable of initiating and maintaining both mutualistic and pathogenic host interactions. These data demonstrate that the opp genes allow X. nematophila to utilize peptides as a nutrient source but that this function is not essential for the existence of X. nematophila in either of its host niches. To our knowledge, this study represents the first experimental analysis of the role of oligopeptide transport in mediating a mutualistic invertebrate-bacterium interaction.

Project description:Bacterial oligopeptide permeases are members of the large family of ATP binding cassette transporters and typically import peptides of 3 to 5 amino acids, apparently independently of sequence. Oligopeptide permeases are needed for bacteria to utilize peptides as nutrient sources and are sometimes involved in signal transduction pathways. The Bacillus subtilis oligopeptide permease stimulates competence development and the initiation of sporulation, at least in part, by importing specific signaling peptides. We isolated rare, partly functional mutations in B. subtilis opp. The mutants were resistant to a toxic tripeptide but still retained the ability to sporulate and/or become competent. The mutations, mostly in the oligopeptide binding protein located on the cell surface, affected residues whose alteration appears to change the specificity of oligopeptide transport.

Project description:Alginate lyases show great potential for industrial and medicinal applications, especially as an attractive biocatalyst for the production of oligosaccharides with special bioactivities. A novel alginate lyase, AlyH1, from the marine bacterium Vibrio furnissii H1, which has been newly isolated from rotten seaweed, was purified and characterized. The purified enzyme showed the specific activity of 2.40 U/mg. Its molecular mass was 35.8 kDa. The optimal temperature and pH were 40 °C and pH 7.5, respectively. AlyH1 maintained stability at neutral pH (7.0-8.0) and temperatures below 30 °C. Metal ions Na⁺, Mg2+, and K⁺ increased the activity of the enzyme. With sodium alginate as the substrate, the Km and Vmax values of AlyH1 were 2.28 mg/mL and 2.81 U/mg, respectively. AlyH1 exhibited activities towards both polyguluronate and polymannuronate, and preferentially degraded polyguluronate. Products prepared from sodium alginate by AlyH1 were displayed to be di-, tri-, and tetra-alginate oligosaccharides. A partial amino acid sequence (190 aa) of AlyH1 analysis suggested that AlyH1 was an alginate lyase of polysaccharide lyase family 7. The sequence showed less than 77% identity to the reported alginate lyases. These data demonstrated that AlyH1 could be as a novel and potential candidate in application of alginate oligosaccharides production with low polymerization degrees.

Project description:We found a new qnr gene, qnrVF1, carried by a multidrug resistance plasmid in a clinical Vibrio furnissii isolate. QnrVF1 exhibits 44.6% to 72.5% similarity in identity with other Qnr family proteins. QnrVF alleles are mainly encoded by chromosomes of V. furnissii and Vibrio fluvialis. Phylogenic analysis showed that QnrVF1 and QnrVF2 form a distinct clade in Qnr proteins. Thus, qnrVF represents a new qnr family. In addition, the qnrVF1 gene is often flanked by the mobile element ISCR1. Thus, it is likely that qnrVF1 is mobilized by ISCR1 from chromosome to plasmid in V. furnissii. IMPORTANCE Quinolones are widely used drugs. Bacteria contain a quinolone resistance gene, which mediates resistance to quinolones. Currently, seven families of Qnr proteins, QnrVC, QnrA, QnrB, QnrC, QnrD, QnrE, and QnrS, have been identified. However, it is unclear whether there are any other qnr families. In this study, we identified a new qnr family, qnrVF. We found many V. furnissii and V. fluvialis strains that possess chromosomal qnrVF alleles, suggesting that V. furnissii and V. fluvialis are the reservoirs of qnrVF. We also found that QnrVF1 confers low-level resistance to quinolones. ISCR1 may facilitate the spread of qnrVF1. The emergence and spread of qnrVF may pose a considerable threat to public health.

Project description:Moraxella catarrhalis is a common cause of otitis media in children and of lower respiratory tract infections in adults with chronic obstructive pulmonary disease; therefore, these two groups would benefit from a vaccine to prevent M. catarrhalis infections. A genome mining approach for vaccine antigens identified oligopeptide permease protein A (OppA), an oligopeptide binding protein of an apparent oligopeptide transport system. Analysis of the oppA gene by PCR and sequence analysis revealed that OppA is highly conserved among clinical isolates of M. catarrhalis. Recombinant OppA was expressed as a lipoprotein and purified, and an oppA knockout mutant was constructed. Antiserum raised to recombinant purified OppA recognized epitopes on the bacterial surface of the wild type but not the OppA knockout mutant. Antibodies raised to purified recombinant OppA recognized native OppA in multiple strains. Intranasal immunization of mice induced systemic and mucosal antibodies to OppA and resulted in enhanced clearance of M. catarrhalis in a mouse pulmonary clearance model. OppA is a highly conserved, immunogenic protein that expresses epitopes on the bacterial surface and that induces potentially protective immune responses in a mouse model. OppA should be evaluated further as a vaccine antigen for M. catarrhalis.

Project description:The oligopeptide permease (Opp) of group A streptococci (GAS) is a membrane-associated protein and belongs to the ATP-binding cassette transporter family. It is encoded by a polycistronic operon containing oppA, oppB, oppC, oppD, and oppF. The biological function of these genes in GAS is poorly understood. In order to understand more about the effects of Opp on GAS virulence factors, an oppA isogenic mutant was constructed by using an integrative plasmid to disrupt the opp operon and confirmed by Southern blot hybridization. No transcript was detected in the oppA isogenic mutant by Northern blot analysis and reverse transcriptase PCR. The growth curve for the oppA isogenic mutant was similar to that for wild-type strain A-20. The oppA isogenic mutant not only decreased the transcription of speB, speX, and rofA but also increased the transcription of speF, sagA (streptolysin S-associated gene A), slo (streptolysin O), pel (pleotrophic effect locus), and dppA (dipeptide permease). No effects on the transcription of emm, sda, speJ, speG, rgg, and csrR were found. The phenotypes of the oppA mutant were restored by the oppA revertant and by the complementation strain. The oppA mutant caused less mortality and tissue damage than the wild-type strain when inoculated into BALB/c mice via an air pouch. Based on these data, we suggest that the opp operon plays an important role in the pathogenesis of GAS infection.

Project description:Occasional human pathogen

Project description:We recently reported the genome sequence of a free-living strain of Vibrio furnissii (NCTC 11218) harvested from an estuarine environment. V. furnissii is a widespread, free-living proteobacterium and emerging pathogen that can cause acute gastroenteritis in humans and lethal zoonoses in aquatic invertebrates, including farmed crustaceans and molluscs. Here we present the analyses to assess the potential pathogenic impact of V. furnissii. We compared the complete genome of V. furnissii with 8 other emerging and pathogenic Vibrio species. We selected and analyzed more deeply 10 genomic regions based upon unique or common features, and used 3 of these regions to construct a phylogenetic tree. Thus, we positioned V. furnissii more accurately than before and revealed a closer relationship between V. furnissii and V. cholerae than previously thought. However, V. furnissii lacks several important features normally associated with virulence in the human pathogens V. cholera and V. vulnificus. A striking feature of the V. furnissii genome is the hugely increased Super Integron, compared to the other Vibrio. Analyses of predicted genomic islands resulted in the discovery of a protein sequence that is present only in Vibrio associated with diseases in aquatic animals. We also discovered evidence of high levels horizontal gene transfer in V. furnissii. V. furnissii seems therefore to have a dynamic and fluid genome that could quickly adapt to environmental perturbation or increase its pathogenicity. Taken together, these analyses confirm the potential of V. furnissii as an emerging marine and possible human pathogen, especially in the developing, tropical, coastal regions that are most at risk from climate change.