Anthony J. Stagg

A comparison of Plague vaccine, USP and EV76 vaccine induced protection against Yersinia pestis in a murine model

The median lethal dose (MLD) of a pathogenic strain of Yersinia pestis was established by three routes of administration in three strains of mouse. There was no significant difference between the MLDs in the different strains of mouse. The MLD by the subcutaneous route in Balb/C and an outbred line was approximately 1 c.f.u.; the MLD following intraperitoneal administration was tenfold higher. There were significant differences in the mean times to death after administration of the challenge by different routes. The relative efficacy of a live attenuated vaccine strain of Y. pestis (EV76) was compared with that of the formaldehyde-killed vaccine (Plague vaccine, USP). EV76 protected against high challenge doses (up to 5.75 x 10(6) MLD), though immunized animals showed side effects of varying severity. The killed vaccine was less effective in terms of dose-protection (deaths occurred after challenge with 4000 MLD) and several of the vaccinated animals suffered sub-lethal, plague-related sequelae to the challenge.

A sub-unit vaccine elicits IgG in serum, spleen cell cultures and bronchial washings and protects immunized animals against pneumonic plague

In this study, the protection afforded against aerosolized Yersinia pestis by injection of an alhydrogel-adsorbed sub-unit vaccine has been compared with that given by an existing killed whole cell vaccine licensed for human use. The sub-unit vaccine protected mice against exposure to > 10(4) colony-forming units (c.f.u.) of virulent plague organisms (100 LD50 doses), whereas the whole cell vaccine provided only 50% protection against 1.8 x 10(3) c.f.u. In sub-unit vaccinees, IgG to each of the F1 and V antigens contained in the vaccine, was detected in serum, on direct secretion by spleen cells and in broncho-alveolar washings (BAL). In killed whole cell vaccinees, physiologically significant levels of IgG to F1 only were detectable in equivalent samples. Levels of F1-specific IgG in serum, secreted from spleen cells and in BAL were significantly higher (P < 0.01) in sub-unit compared with killed whole cell vaccinees. IgA was not detected in BAL from intra-muscularly dosed sub-unit vaccinees and thus the protection achieved against inhalational challenge with Yersinia pestis is attributed to the induction of systemic immunity to both the F1 and V antigens in the sub-unit vaccine. The enhanced protective efficacy of this sub-unit vaccine over an existing vaccine has been demonstrated in an animal model of pneumonic plague.

A single dose sub-unit vaccine protects against pneumonic plague

In this study, the protection afforded against aerosolised Yersinia pestis by injection of a single dose of an alhydrogel-adsorbed sub-unit vaccine has been compared with that given by an existing killed whole cell vaccine licensed for human use. The sub-unit vaccine, prepared by admixing F1 antigen derived from a Y. pestis cell culture supernatant with recombinant V antigen derived from an E. coli cell lysate, fully protected an outbred strain of mouse against exposure to 10(6) CFU of virulent plague organisms (10(4) mouse lethal doses, MLD). In contrast, the whole cell vaccine provided only 16% protection against the same level of challenge. Furthermore, sub-unit vaccinees were able to clear the bacteria from their lungs post-challenge whereas bacteria were cultured from the lungs of a surviving KWC vaccinee post-challenge. In killed whole cell vaccinees, physiologically significant levels of IgG to F1 only were detectable and the levels of F1-specific IgG in serum and in broncho-alveolar washings were significantly lower (p<0.05) compared with sub-unit vaccinees. In sub-unit vaccinees, an IgG titre to the F1 and V antigens was detected in serum where it was significantly higher (p<0.05) compared with broncho-alveolar washings suggesting that, at the time of challenge, protection is attributable mainly to the combined circulating IgG titre to the F1 and V sub-units. The enhanced protective efficacy of this sub-unit vaccine administered as a single dose compared with an existing vaccine has been demonstrated in an outbred animal model of pneumonic plague.

Synergistic Protection of Mice against Plague with Monoclonal Antibodies Specific for the F1 and V Antigens of Yersinia pestis

ABSTRACT Monoclonal antibodies specific for Yersinia pestis V antigen and F1 antigen, administered singly or in combination, protected mice in models of bubonic and pneumonic plague. Antibodies showed synergy when administered prophylactically and as a therapy 48 h postinfection. Monoclonal antibodies therefore have potential as a treatment for plague.

Protection conferred by a fully recombinant sub-unit vaccine against Yersinia pestis in male and female mice of four inbred strains.

In this paper, we describe for the first time the use of a fully recombinant sub-unit vaccine for plague. We have compared the protection afforded by the recombinant vaccine against Yersinia pestis in male and female mice of four inbred strains. We also determined the in vivo cellular memory and antibody response after one year. The recombinant vaccine was capable of inducing protective immunity, against subcutaneous and aerosol challenge, in mice from all four strains. Although, there was some breakthrough in the CBA males challenged with 10(7) median lethal dose (MLDs) the other mice regardless of sex or strain were well protected even at this extreme challenge dose. In both male and female mice, the specific IgG titres to both antigens peaked at day 28 and 35 and in female mice these titres were maintained for >1 year.

The ABC Transporter Protein OppA Provides Protection against Experimental Yersinia pestis Infection

ABSTRACT The identification of Yersinia pestis as a potential bioterrorism agent and the emergence of antibiotic-resistant strains have highlighted the need for improved vaccines and treatments for plague. The aim of this study was to evaluate the potential for ATP-binding cassette (ABC) transporter proteins to be exploited as novel vaccines against plague. Western blotting of ABC transporter proteins using sera from rabbits immunized with killed whole Y. pestis cells or human convalescent-phase sera identified four immunologically reactive proteins: OppA, PstS, YrbD, and PiuA. Mice immunized with these proteins developed antibody to the immunogen. When the immunized mice were challenged with Y. pestis, the OppA-immunized mice showed an increased time to death compared to other groups, and protection appeared to correlate with the level of immunoglobulin G antibody to OppA.

Characterization and Deposition of Respirable Large- and Small-Particle Bioaerosols

ABSTRACT The deposition patterns of large-particle microbiological aerosols within the respiratory tract are not well characterized. A novel system (the flow-focusing aerosol generator [FFAG]) which enables the generation of large (>10-μm) aerosol particles containing microorganisms under laboratory conditions was characterized to permit determination of deposition profiles within the murine respiratory tract. Unlike other systems for generating large aerosol particles, the FFAG is compatible with microbiological containment and the inhalational challenge of animals. By use of entrapped Escherichia coli cells, Bacillus atrophaeus spores, or FluoSphere beads, the properties of aerosols generated by the FFAG were compared with the properties of aerosols generated using the commonly available Collison nebulizer, which preferentially generates small (1- to 3-μm) aerosol particles. More entrapped particulates (15.9- to 19.2-fold) were incorporated into 9- to 17-μm particles generated by the FFAG than by the Collison nebulizer. The 1- to 3-μm particles generated by the Collison nebulizer were more likely to contain a particulate than those generated by the FFAG. E. coli cells aerosolized using the FFAG survived better than those aerosolized using the Collison nebulizer. Aerosols generated by the Collison nebulizer and the FFAG preferentially deposited in the lungs and nasal passages of the murine respiratory tract, respectively. However, significant deposition of material also occurred in the gastrointestinal tract after inhalation of both the small (89.7%)- and large (61.5%)-particle aerosols. The aerosols generated by the Collison nebulizer and the FFAG differ with respect to mass distribution, distribution of the entrapped particulates, bacterial survival, and deposition within the murine respiratory tract.

Experimental respiratory anthrax infection in the common marmoset (Callithrix jacchus)

Inhalational anthrax is a rare but potentially fatal infection in man. The common marmoset (Callithrix jacchus) was evaluated as a small non‐human primate (NHP) model of inhalational anthrax infection, as an alternative to larger NHP species. The marmoset was found to be susceptible to inhalational exposure to Bacillus anthracis Ames strain. The pathophysiology of infection following inhalational exposure was similar to that previously reported in the rhesus and cynomolgus macaque and humans. The calculated LD50 for B. anthracis Ames strain in the marmoset was 1.47 × 103 colony‐forming units, compared with a published LD50 of 5.5 × 104 spores in the rhesus macaque and 4.13 × 103 spores in the cynomolgus macaque. This suggests that the common marmoset is an appropriate alternative NHP and will be used for the evaluation of medical countermeasures against respiratory anthrax infection.

Experimental acute respiratory Burkholderia pseudomallei infection in BALB/c mice.

Burkholderia pseudomallei is the causative agent of melioidosis, which is considered a potential deliberate release agent. The objective of this study was to establish and characterise a relevant, acute respiratory Burkholderia pseudomallei infection in BALB/c mice. Mice were infected with 100 B. pseudomallei strain BRI bacteria by the aerosol route (approximately 20 median lethal doses). Bacterial counts within lung, liver, spleen, brain, kidney and blood over 5 days were determined and histopathological and immunocytochemical profiles were assessed. Bacterial numbers in the lungs reached approximately 108 cfu/ml at day 5 post‐infection. Bacterial numbers in other tissues were lower, reaching between 103 and 105 cfu/ml at day 4. Blood counts remained relatively constant at approximately 1.0 × 102 cfu/ml. Foci of acute inflammation and necrosis were seen within lungs, liver and spleen. These results suggest that the BALB/c mouse is highly susceptible to B. pseudomallei by the aerosol route and represents a relevant model system of acute human melioidosis.

Development and Characterization of Mouse Models of Infection with Aerosolized Brucella melitensis and Brucella suis

ABSTRACT There is a need to identify vaccines that can protect against Brucella, a potential bioterrorism agent. We have developed mouse models of infection with aerosolized Brucella melitensis and Brucella suis and demonstrated their utility for the evaluation of vaccines using the model live B. melitensis vaccine strain Rev.1.