Comparison of a novel microcrystalline tyrosine adjuvant with aluminium hydroxide for enhancing vaccination against seasonal influenza.

BACKGROUND: Vaccination against seasonal influenza strains is recommended for "high risk" patient groups such as infants, elderly and those with respiratory or circulatory diseases. However, efficacy of the trivalent influenza vaccine (TIV) is poor in many cases and in the event of an influenza pandemic, mono-valent vaccines have been rapidly developed and deployed. One of the main issues with use of vaccine in pandemic situations is the lack of a suitable quantity of vaccine early enough during the pandemic to exert a major influence on the transmission of virus and disease outcome. One approach is to use a dose-sparing regimen which inevitably involves enhancing the efficacy using adjuvants. METHODS: In this study we compare the use of a novel microcrystalline tyrosine (MCT) adjuvant, which is currently used in a niche area of allergy immunotherapy, for its ability to enhance the efficacy of a seasonal TIV preparation. The efficacy of the MCT adjuvant formulation was compared to alum adjuvanted TIV and to TIV administered without adjuvant using a ferret challenge model to determine vaccine efficacy. RESULTS: The MCT was found to possess high protein-binding capacity. In the two groups where TIV was formulated with adjuvant, the immune response was found to be higher (as determined by HAI titre) than vaccine administered without adjuvant and especially so after challenge with a live influenza virus. Vaccinated animals exhibited lower viral loads (as determined using RT-PCR) than control animals where no vaccine was administered. CONCLUSIONS: The attributes of each adjuvant in stimulating single-dose protection against a poorly immunogenic vaccine was demonstrated. The properties of MCT that lead to the reported effectiveness warrants further exploration in this and other vaccine targets - particularly where appropriate immunogenic, biodegradable and stable alternative adjuvants are sought.

A study of the physiology of Bacillus anthracis Sterne during manufacture of the UK acellular anthrax vaccine.

AIM: To analyse the growth of Bacillus anthracis during simulations of the UK anthrax vaccine manufacturing process. METHODS AND RESULTS: Simulated vaccine production runs were performed using the toxigenic, acapsulate Sterne 34F(2) strain of B. anthracis in semi-defined medium. After rising during the logarithmic growth phase, the pH of the culture starts to fall at about 18 h from pH 8.7 to reach <7.6 at 26 h, coincident with consumption of glucose and optimal production of protective antigen (PA; 7.89 g ml(-1), SD 1.0) and lethal factor (LF; 1.85 g ml(-1), SD 0.29). No increased breakdown of toxin antigens was seen over the 26-32 h period. When glucose was exhausted, amino acids (principally serine) were utilized as an alternative carbon source. Sporulation was not observed during the 32 h. CONCLUSIONS: PA and LF, the principal constituents in the UK anthrax vaccine, undergo little degradation during vaccine fermentation. The vaccine manufacturing process is robust and reproducible. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first detailed analysis of the manufacturing process used for the UK acellular anthrax vaccine; insight gained into the process will support continued and safe vaccine manufacture.

Novel in vitro functional assays for the determination of anthrax toxin components.

The characterisation and evaluation of the UK licensed human anthrax vaccine depends on several in vivo tests that determine its safety and potency. Assays for the determination of functionally active and/or immunoreactive toxin components and S-layer proteins have been developed and applied to the characterisation of anthrax vaccine. These technologies may support production of consistent and effective vaccines, and may ultimately reduce the requirements for in vivo testing.

Tyrosine-1290 of tetanus neurotoxin plays a key role in its binding to gangliosides and functional binding to neurones.

Tetanus toxin acts by blocking the release of glycine from inhibitory neurones within the spinal cord. An initial stage in the toxin's action is binding to acceptors on the nerve surface and polysialogangliosides are a component of these acceptor moieties. Using site-directed mutagenesis, we identify tyrosine-1290 of tetanus toxin as a key residue that is involved in ganglioside binding. This residue, which is located at the centre of a shallow pocket on the beta-trefoil domain of the tetanus H(c) fragment, is also shown to play a key role in the functional binding of tetanus toxin to spinal cord neurones leading to the inhibition of neurotransmitter release.

Development of an in vitro bioassay for Clostridium botulinum type B neurotoxin in foods that is more sensitive than the mouse bioassay.

A novel, in vitro bioassay for detection of the botulinum type B neurotoxin in a range of media was developed. The assay is amplified by the enzymic activity of the neurotoxin's light chain and includes the following three stages: first, a small, monoclonal antibody-based immunoaffinity column captures the toxin; second, a peptide substrate is cleaved by using the endopeptidase activity of the type B neurotoxin; and finally, a modified enzyme-linked immunoassay system detects the peptide cleavage products. The assay is highly specific for type B neurotoxin and is capable of detecting type B toxin at a concentration of 5 pg ml(-1) (0.5 mouse 50% lethal dose ml(-1)) in approximately 5 h. The format of the test was found to be suitable for detecting botulinum type B toxin in a range of foodstuffs with a sensitivity that exceeds the sensitivity of the mouse assay. Using highly specific monoclonal antibodies as the capture phase, we found that the endopeptidase assay was capable of differentiating between the type B neurotoxins produced by proteolytic and nonproteolytic strains of Clostridium botulinum type B.

Development of novel assays for botulinum type A and B neurotoxins based on their endopeptidase activities.

A novel assay method based on the endopeptidase activities of the botulinum neurotoxins has been developed and applied to the detection of botulinum type A and B toxins. An assay system developed for the detection of botulinum type B neurotoxin (BoNT/B) is based on the cleavage of a synthetic peptide substrate representing amino acid residues 60 to 94 of the intracellular target protein for the toxin, VAMP (vesicle-associated membrane protein, or synaptobrevin). In this assay system, immobilized VAMP (60-94) peptide substrate is cleaved by BoNT/B at the Gln-76-Phe-77 bond, leaving the C-terminal cleavage fragment on the solid phase. This fragment is then detected by the addition of an antibody-enzyme reagent which specifically recognizes the newly exposed N terminus of the cleavage product. The developed assay was specific to BoNT/B, showing no cross-reactivity with other clostridial neurotoxins, and had a sensitivity for BoNT/B of 0.6 to 4.5 ng/ml, which could be increased to 0.1 to 0.2 ng/ml by using an assay amplification system based on catalyzed reporter deposition. Trypsin treatment of BoNT/B samples, which converts the single-chain toxin to the active di-chain form, was found to increase the sensitivity of the endopeptidase assay from 5- to 10-fold. An endopeptidase assay for BoNT/A, based on the cleavage of a peptide substrate derived from the protein SNAP-25 (synaptosome-associated protein), was also developed and characterized.

Proteolytic cleavage of synthetic fragments of vesicle-associated membrane protein, isoform-2 by botulinum type B neurotoxin.

Recent data suggest that botulinum type-B neurotoxin is a protease which acts on vesicle-associated membrane protein, isoform 2 (VAMP-2). In this report, botulinum type-B neurotoxin is shown to cleave a synthetic fragment (HV62) of VAMP-2, corresponding to the bulk of the hydrophilic domain (amino acids 33-94). The neurotoxin acts at a single site between Gln76 and Phe77. Little or no proteolytic activity by botulinum type-B neurotoxin was observed with peptides containing 7, 10 or 20 amino acids spanning the site of cleavage. The proteolytic action of neurotoxin was strongly inhibited by EDTA and o-phenanthroline whereas captopril and phosphoramidon were ineffective. A series of model peptide substrates were synthesised in order to define the smallest VAMP-2 fragment to be cleaved by botulinum type-B neurotoxin. Data obtained from these substrates suggest that the neurotoxin belongs to a novel class of zinc-endoprotease; more than 12 amino acid residues are required on both the NH2- and COOH-terminal side of the cleavage site for optimal proteolytic activity. The results demonstrate that no other components of cellular vesicles are required for the specific action of the neurotoxin on VAMP-2. The data further show that the highly specific action of the neurotoxin is not dictated solely by the properties of the amino acid residues at the cleavage site but is also dependent on amino acid sequences distal to its site of action.

Glucose control of staphylococcal enterotoxin A synthesis and location is mediated by cyclic AMP.

The regulation of staphylococcal enterotoxin A (SEA) synthesis in a defined medium was studied using continuous culture techniques. SEA production was repressed by glucose and repression could be overcome by addition of exogenous cyclic AMP. As well as this classical catabolite repression control, addition of glucose to de-repressed steady-state cultures resulted in rapid disappearance of toxin from the medium (also mediated by loss of cyclic AMP). When the toxin dissappeared from the medium, it was taken up again by the bacteria without apparent modification.