Genetic analysis of spontaneous lactose-utilizing mutants from vibrio vulnificus.

Wild-type V. vulnificus cannot grow using lactose as the sole carbon source or take up the sugar. However, prolonged culture of this species in media containing lactose as the sole carbon source leads to the generation of a spontaneous lactose-utilizing (LU) mutant. This mutant showed strong beta- galactosidase activity, whereas the wild-type strain showed a barely detectable level of the activity. A mutant with a lesion in a gene homologous to the lacZ of E. coli in the bacterium no longer showed beta-galactosidase activity or generated spontaneous LU mutants, suggesting that the lacZ homolog is responsible for the catabolism of lactose, but the expression of the gene and genes for transport of lactose is tightly regulated. Genetic analysis of spontaneous LU mutants showed that all the mutations occur in a lacI homolog, which is located downstream to the lacZ and putative ABC-type lac permease genes. Consistent with this, a genomic library clone containing the lacI gene, when present in trans, made the spontaneous LU mutants no longer able to utilize lactose as the sole carbon source. Taken together with the observation that excessive amounts of exogenously supplemented possible catabolic products of lactose have negative effects on the growth and survivability of V. vulnificus, we suggest that V. vulnificus has evolved to carry a repressor that tightly regulates the expression of lacZ to keep the intracellular toxic catabolic intermediates at a sublethal level.

IVET-based identification of virulence factors in Vibrio vulnificus MO6-24/O.

Vibrio vulnificus is an opportunistic pathogen that causes septicemia in humans. To identify the genes associated with its pathogenicity, in vivo expression technology (IVET) was used to select genes specifically expressed in a host, yet not significantly in vitro. Random lacZ-fusions in the genome of V. vulnificus strain MO6-24/O were constructed using an IVET vector, pSG3, which is a suicide vector containing promoterless-aph and -lacZ as reporter genes. A total of approximately 18,000 resulting library clones were then intraperitoneally injected into BALB/c mice using a colony forming unit (CFU) of 1.6 x 10(6). Two hours after infection, kanamycin was administered at 200 microg per gram of mouse weight. After two selection cycles, 11 genes were eventually isolated, which were expressed only in the host. Among these genes, VV20781 and VV21007 exhibiting a homology to a hemagglutinin gene and tolC, respectively, were selected based on having the highest frequency. When compared to wild-type cells, mutants with lesions in these genes showed no difference in the rate of growth rate, yet a significant decrease in cytotoxicity and the capability to form a biofilm.

Genes for utilization of deoxyfructosyl glutamine (DFG), an amadori compound, are widely dispersed in the family Rhizobiaceae.

Amadori compounds form spontaneously in decomposing plant material and can be found in the rhizosphere. As such, these compounds could influence microbial populations by serving as sources of carbon, nitrogen and energy to microorganisms expressing suitable catabolic pathways. Two distinct sets of genes for utilization of deoxyfructosyl glutamine (DFG), an Amadori compound, have been identified in isolates of Agrobacterium spp. One, the soc gene set, is encoded by pAtC58, a 543 kb plasmid in A. tumefaciens strain C58. The second, mocD dissimilates DFG formed in the pathway for catabolism of mannopine (MOP) a non-Amadori, imine-type member of the mannityl opine family characteristic of certain Ti and Ri plasmids. To assess the level of dispersal of these two Amadori-utilizing systems, isolates of Agrobacterium spp. and related bacteria in the family Rhizobiaceae were examined by Southern analysis for homologs of socD and mocD. Homologs of mocD were associated only with Ti plasmid-encoded pathways for catabolism of MOP. Homologs of socD were more widely distributed, being detectable in many but not all of the isolates of Agrobacterium, Sinorhizobium, and Rhizobium spp. tested. However, this gene was never associated with the virulence elements, such as the Ti and Ri plasmids, in these strains. Regardless of genus most of the isolates containing socD homologs could utilize DFG as sole source of carbon, nitrogen and energy. Correlation studies suggested that mocD has evolved uniquely as part of the mannityl opine catabolic pathway while socD has evolved for the general utilization of Amadori compounds. Certain isolates of Agrobacterium and Rhizobium that lacked detectable homologs of socD and mocD also could utilize DFG suggesting the existence of additional, unrelated pathways for the catabolism of this Amadori compound. These results suggest that Amadori compounds constitute a source of nutrition that is important to microflora in the rhizosphere.

Corrective osteotomy technique for a posttraumatic deviated nose.

Posttraumatic nasal deformities may not be adequately corrected by conventional osteotomy techniques when the configuration of the nasal bone has been changed as a result of malunion. The purpose of this study is to present an osteotomy technique, including refracture along malunion sites and anatomic reduction of a malformed nasal bone, for the correction of a posttraumatic deviated nose. From March 2003 to May 2004, 27 patients, who underwent corrective rhinoplasty for the correction of bony pyramid deviation, were included in this study. Postoperative results were evaluated regarding nasal midline location, nasal symmetry, and nasal contour. All patients were also evaluated subjectively for cosmetic improvement, changes in breathing, and overall satisfaction. Objective results of the technique were excellent and patients' satisfaction levels were also very positive. The osteotomy technique presented in this study is simple, effective, and safe for correcting posttraumatic nasal deviation and also produces consistent results.

Identification of OmpU of Vibrio vulnificus as a fibronectin-binding protein and its role in bacterial pathogenesis.

Vibrio vulnificus is a pathogenic bacterium that causes gastroenteritis and primary septicemia. To identify factors involved in microbial adherence to the host cells, we investigated bacterial proteins capable of binding to fibronectin, one of the main components comprised of the extracellular matrix of mammalian cells. A protein of approximately 35 kDa was purified from the extracts of V. vulnificus by its property to bind to immobilized fibronectin. This protein was identified as OmpU, one of the major outer membrane proteins of V. vulnificus. In binding assays using immobilized fibronectin, the number of ompU mutant cells bound to fibronectin was only 4% of that of wild-type cells bound to fibronectin. In addition, the exogenous addition of antibodies against OmpU resulted in a decreased ability of wild-type V. vulnificus to adhere to fibronectin. The ompU mutant was also defective in its adherence to RGD tripeptide (5% of the adherence of the wild type to RGD), cytoadherence to HEp-2 cells (7% of the adherence of the wild type to HEp-2), cytotoxicity to cell cultures (39% of the cytotoxicity of the wild type), and mortality in mice (10-fold increase in the 50% lethal dose). The ompU mutant complemented with the intact ompU gene restored its abilities for adherence to fibronectin, RGD tripeptide, and HEp-2 cells; cytotoxicity to HEp-2 cells; and mouse lethality. This study indicates that OmpU is an important virulence factor involved in the adherence of V. vulnificus to the host cells.

Cyclo(Phe-Pro) modulates the expression of ompU in Vibrio spp.

Vibrio vulnificus was found to produce a chemical that induced the expression of Vibrio fischeri lux genes. Electron spray ionization-mass spectrometry and 1H nuclear magnetic resonance analyses indicated that the compound was cyclo(L-Phe-L-Pro) (cFP). The compound was produced at a maximal level when cell cultures reached the onset of stationary phase. Sodium dodecyl sulfate-polyacrylamide gel analysis of the total proteins of V. vulnificus indicated that expression of OmpU was enhanced by exogenously added synthetic or purified cFP. A toxR-null mutant failed to express ompU despite the addition of cFP. The related Vibrio spp. V. cholerae, V. parahaemolyticus, and V. harveyi also produced cFP, which induced the expression of their own ompU genes. cFP also enhanced the expression in V. cholerae of the ctx genes, which are known to be regulated by ToxR. Our results suggest that cFP is a signal molecule controlling the expression of genes important for the pathogenicity of Vibrio spp.

Convergent evolution of Amadori opine catabolic systems in plasmids of Agrobacterium tumefaciens.

Deoxyfructosyl glutamine (DFG, referred to elsewhere as dfg) is a naturally occurring Amadori compound found in rotting fruits and vegetables. DFG also is an opine and is found in tumors induced by chrysopine-type strains of Agrobacterium tumefaciens. Such strains catabolize this opine via a pathway coded for by their plasmids. NT1, a derivative of the nopaline-type A. tumefaciens strain C58 lacking pTiC58, can utilize DFG as the sole carbon source. Genes for utilization of DFG were mapped to the 543-kb accessory plasmid pAtC58. Two cosmid clones of pAtC58 allowed UIA5, a plasmid-free derivative of C58, harboring pSa-C that expresses MocC (mannopine [MOP] oxidoreductase that oxidizes MOP to DFG), to grow by using MOP as the sole carbon source. Genetic analysis of subclones indicated that the genes for utilization of DFG are located in a 6.2-kb BglII (Bg2) region adjacent to repABC-type genes probably responsible for the replication of pAtC58. This region contains five open reading frames organized into at least two transcriptional soc (santhopine catabolism) groups: socR and socABCD. Nucleotide sequence analysis and analyses of transposon-insertion mutations in the region showed that SocR negatively regulates the expression of socR itself and socABCD. SocA and SocB are responsible for transport of DFG and MOP. SocA is a homolog of known periplasmic amino acid binding proteins. The N-terminal half of SocB is a homolog of the transmembrane transporter proteins for several amino acids, and the C-terminal half is a homolog of the transporter-associated ATP-binding proteins. SocC and SocD could be responsible for the enzymatic degradation of DFG, being homologs of sugar oxidoreductases and an amadoriase from Corynebacterium sp., respectively. The protein products of socABCD are not related at the amino acid sequence level to those of the moc and mot genes of Ti plasmids responsible for utilization of DFG and MOP, indicating that these two sets of genes and their catabolic pathways have evolved convergently from independent origins.