Three outer membrane proteins with molecular masses of 40, 38, and 27 kDa of the hypertoxinogenic strain 569B of Vibrio cholerae have been purified to homogeneity. The synthesis of all the three proteins is regulated by the osmolarity of the growth medium. The pore-forming ability of the 40-kDa protein, OmpT, and the 38-kDa protein, OmpU, has been demonstrated by using liposomes, in which these proteins were embedded. The 27-kDa protein, OmpX, though osmoregulated, is not a porin. OmpU constitutes 30% of the total outer membrane protein when grown in the presence of 1.0% NaCl in the growth medium and 60% in the absence of NaCl. OmpU is an acidic protein and is a homotrimer of 38-kDa monomeric units. Its secondary structure contains predominantly a beta-sheet, and three to four Ca2+ ions are associated with each monomeric unit. Removal of Ca2+ irreversibly disrupts the structure and pore-forming ability of the protein. The pore size of OmpU is 1.6 nm, and the specific activity of the OmpU channel is two- to threefold higher than that of Escherichia coli porin OmpF, synthesis of which resembles that of OmpU with respect to the osmolarity of the growth medium. The pore size of OmpT, which is analogous to OmpC of E. coli, is smaller than that of OmpU. Southern blot hybridization of V. cholerae genomic DNA digested with several restriction endonucleases with nick-translated E. coli ompF as the probe revealed no nucleotide sequence homology between the ompU and ompF genes. OmpU is also not antigenically related to OmpF. Anti-OmpF antiserum, however, cross-reacted with the 45-kDa V. cholerae outer membrane protein, OmpS, the synthesis of which is regulated by the presence of maltose in the growth medium. OmpU hemagglutinated with rabbit and human blood. This toxR-regulated protein is one of the possible virulence determinants in V. cholerae (V. L. Miller and J. J. Mekalanos, J. Bacteriol. 170:2575-2583, 1988).
The synthesis of alkaline phosphatase by two strains of Vibrio cholerae belonging to the Inaba and Ogawa serotypes has been examined in relation to the phosphate concentration of the culture medium. The synthesis of the enzyme in both strains was repressed in cells grown in the presence of a high concentration of inorganic phosphate. Lowering the phosphate content of the growth medium led to a derepression of enzyme activity. The presence of glucose in low phosphate medium stimulated the degree of derepression. The synthesis of the enzyme by strain Inaba 569B was more sensitive to inorganic phosphate than that of strain Ogawa 154. The enzyme was presumably located in the periplasmic space since it was released when the organisms were converted to spheroplasts.
PFGE analysis of the Notl-and Sfil-digested genome of Vibrio cholerae O139 strains isolated from different epidemic regions of India showed that all the strains are of clonal origin and the genome size is about 2·2 Mb. An analysis of the electrophoretic profiles of the genome of O139 strains, the RFLP of the cholera toxin (ctx) gene and Southern blot hybridization of Notl-digested genomes of classical, El Tor and 0139 with a Notl-linking clone of classical strain 569B, suggest that these strains closely resemble V. cholerae 01 biotype El Tor, but are widely different from the classical 01 vibrios. Using restriction enzymes which cleave a single site in either the core region or in the direct repeat sequence (RS) of the CTX genetic element, it has been shown that the genome of most of the O139 strains has two copies of the ctx gene in tandem connected by two RSs. The chromosomal location of the CTX genetic element in the 0139 strain is the same as that reported for El Tor vibrios. The organization of the virulence gene cassettes in different O139 strains shows genetic heterogeneity in the population. Whilst most of the epidemic strains have two copies of the CTX genetic element, in some strains the number of elements has been amplified and in at least one strain a single copy of the element has been deleted.
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