David J. Stewart

Amino acid sequence of pilin from Bacteroides nodosus (strain 198), the causative organism of ovine footrot

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Antigenic competition in a multivalent foot rot vaccine.

The antigenic competition that occurs when pilus antigens of different serogroups are combined in multivalent vaccines for foot rot has been investigated using recombinant pilus antigens. Our prototype vaccine contains pili from nine serogroups of Dichelobacter nodosus which are expressed in Pseudomonas aeruginosa. Sheep inoculated with this multivalent vaccine were not as well protected against foot rot as those given the monovalent vaccine. Levels of agglutinating and total antibody specific for any particular pili serogroup were found to be significantly reduced in sheep vaccinated with six or more closely related pili. This effect was more pronounced for agglutinating antibody, which is thought to mediate protection, but was also observed with total antibody levels measured by ELISA. The antigenic competition was not associated with the total antigen load as a tenfold higher dose of monovalent pili induced high titres of antibody. Furthermore, distributing the vaccine to four sites, each draining to a different lymph node, failed to overcome the competition. Experiments with mixtures of monospecific sera indicate that the phenomenon is unlikely to be due to blocking of serogroup-specific protective antibodies by an excess of cross-reactive non-protective antibody elicited by heterologous pili.

Immunological parameters associated with antigenic competition in a multivalent footrot vaccine.

A murine model for antigenic competition with multivalent D. nodosus pili vaccine has been established that parallels the phenomenon observed in sheep where levels of antibody, specific for any particular serogroup of pili, are significantly lower following vaccination in the presence of multiple serogroups of pili than with that serogroup alone. This competition was observed in both high and low responder strains of mice and was not dependent on the multiplicity of the antigens in the multivalent vaccine but could be observed with a large excess of a single heterologous serogroup. Competition was manifest by a reduction in the number of serogroup-specific antibody secreting cells elicited in response to vaccination. The antibody response to a single serogroup of pili reached a plateau at high doses and it was at these doses that antigenic competition was most pronounced, under conditions where both B- and T-cell responses were limiting. The limit in T-cell responsiveness was not imposed at the level of presentation of antigen. Pili-specific T cells were largely cross-reactive for different serogroups, and under conditions of limiting T-cell stimulation within a lymph node the available T cells would have to be shared between B cells specific for each serogroup of pili, which may in turn result in the decrease of serogroup-specific antibody induced following inoculation with the multivalent vaccine.

Comparison of gene probe and conventional methods for the differentiation of ovine footrot isolates of Dichelobacter nodosus.

In a collaborative study that involved four Australian veterinary diagnostic laboratories a gene probe test based on the recombinant plasmids pJIR318, pJIR314B, and pJIR313, which contain genomic vap or vrl regions, was compared with conventional tests used for the differential diagnosis of ovine footrot. A total of 771 clinical dichelobacter nodosus isolates were tested and designated as belonging to one of several gene probe categories. The results showed that 87% of the virulent isolates belonged to gene probe category 1, compared to only 6% of the benign isolates. It was concluded that there was good correlation between the gene probe test and the virulence designation of these isolates as well as the results of elastase, gelatin-gel and protease isoenzyme tests. Furthermore, the gene probe test was converted to a polymerase chain reaction (PCR)-based test. It is suggested that diagnostic laboratories consider carrying out both this PCR test and tests based on the extracellular proteases of D. nodosus.

Analysis of the outer membrane proteins of Bacteroides nodosus, the causal organism of ovine footrot.

Examination by SDS-PAGE of lithium acetate extracts of several strains of depiliated Bacteroides nodosus revealed 6 major outer membrane proteins (including pilin). The 5 membrane proteins exhibited approximate molecular weights of 75000, 50000, 38000, 34500 and 26500 whereas pilin had a MW of 17500 for the majority of strains. All proteins were accessible to lactoperoxidase-catalysed iodination and proteins 1, 2 and 5 were shown to be glycoproteins. Several attempts to isolate individual OMC proteins in pure form by selective solubilization and gel filtration were unsuccessful, but electroelution of individual outer membrane complex proteins resolved by SDS-PAGE provided sufficient quantities of antigen for immunization of sheep and for immunochemical analysis.

Isolation of the gene encoding pilin of Bacteroides nodosus (strain 198), the causal organism of ovine footrot

The gene for pilin, the monomeric protein subunit from which the pilus of Bacteroides nodosus is constructed, has been isolated. Isolation was achieved by cloning the fragmented genome of B. nodosus in Escherichia coli RR1 using the plasmid vector pBR322. Pilin‐producing colonies were identified by screening with a colony immunoassay using antiserum from a sheep immunized against purified pili from B. nodosus strain 198, and were further characterized by immunoblot analysis. Final confirmation of the presence of the pilin gene was by nucleotide sequence data which translated to the known pilin amino acid sequence.

Primary structure of pilin protein from Bacteroides nodosus strain 216: comparison with the corresponding protein from strain 198.

The amino acid sequence of pilin protein from Bacteroides nodosus strain 216 was determined. The protein had a calculated molecular weight of 15962 and contained the same number of amino acid residues (151) as the pilin from the previously sequenced strain 198. The sequence of the first 44 residues was common to both strains, including the unusual amino-terminal amino acid, N-methylphenylalanine. Of the remaining 107 residues, 37% of them differed between the two strains. Comparison of hydrophilicity profiles constructed from the sequence data indicated that a conserved region around residues 71-72 was probably the site of an antigenic determinant.

The recovery of Mycobacterium avium subspecies paratuberculosis from the intestine of infected ruminants for proteomic evaluation

Johnes disease is a slowly developing intestinal disease, primarily of ruminants, caused by Mycobacterium avium subspecies paratuberculosis. The disease contributes to significant economic losses worldwide in agricultural industry. Analysis of bacterial proteomes isolated directly from infected animals can provide important information about the repertoire of proteins present during infection and disease progression. In this study, M. avium subspecies paratuberculosis has been extracted from Johnes disease-infected cattle and goat intestinal tissue sections in a manner compatible with direct 2-DE proteomic analysis for comparison with in vitro-cultured bacteria. M. avium subspecies paratuberculosis was harvested from the submucosa and mucosa of intestinal sections and enriched from macerated tissue by hypotonic lysis, sonication and centrifugation through a viscosity gradient. Subsequent comparison of the proteomes of the in vivo- and in vitro-derived bacteria identified a number of proteins that were differentially expressed. Among them, a number of hypothetical proteins of unknown function and a hypothetical fatty acyl dehydrogenase (FadE3_2) and 3-hydroxyacyl-CoA dehydrogenase, possibly important for in vivo metabolism, utilising the pathway for the beta-oxidation of fatty acids.

Cloning, sequence and expression of the gene (aprV5) encoding extracellular serine acidic protease V5 from Dichelobacter nodosus

The acidic protease V5-encoding gene (aprV5) from Gram- Dichelobacter nodosus virulent strain 198 was isolated from a cosmid bank by activity screening and sequenced. The 2371-bp nucleotide (nt) sequence contained an open reading frame coding for a protein precursor of 595 amino acid (aa) residues composed of a signal peptide, a pro-region, a mature active protease of 347 aa and a C-terminal extension region of 120 aa. The deduced aa sequence of the pre-pro-mature protease regions showed about 65% similarity to that of D. nodosus basic protease while the C-terminal extension region showed only about 26% similarity. The aprV5 gene, without its C-terminal extension region, was cloned and expressed in Escherichia coli. The acidic protease B5-encoding gene (aprB5) from non-virulent strain 305 was also cloned and sequenced. The aprB5 nt sequence showed 99% homology to that of aprV5 with two single-aa changes occurring in the precursor.

Monoclonal antibodies defining immunogenic regions of pili from Bacteroides nodosus strains 198 (A1), 265 (H1) and 336 (F1)

A total of 17 monoclonal antibodies (MoAb) were used to analyse the antigenic structure of pilus protein from three serogroups of Bacteroides nodosus. The four MoAb which agglutinated pili were serogroup (and subgroup) specific, and the agglutinating epitope was present on the pili monomer and dependent on the intra‐chain disulfide bond.