Formulation technologies for oral vaccines.

Many options now exist for constructing oral vaccines which, in experimental systems, have shown themselves to be able to generate highly effective immunity against infectious diseases. Their suitability for implementation in clinical practice, however, for prevention of outbreaks, particularly in low- and middle-income countries (LMIC), is not always guaranteed, because of factors such as cost, logistics and cultural and environmental conditions. This brief overview provides a summary of the various approaches which can be adopted, and evaluates them from a pharmaceutical point, taking into account potential regulatory issues, expense, manufacturing complexity, etc., all of which can determine whether a vaccine approach will be successful in the late stages of development. Attention is also drawn to problems arising from inadequate diet, which impacts upon success in stimulating effective immunity, and identifies the use of lipid-based carriers as a way to counteract the problem of nutritional deficiencies in vaccination campaigns.

Antibody-mediated protection against MERS-CoV in the murine model.

Murine antisera with neutralising activity for the coronavirus causative of Middle East respiratory syndrome (MERS) were induced by immunisation of Balb/c mice with the receptor binding domain (RBD) of the viral Spike protein. The murine antisera induced were fully-neutralising in vitro for two separate clinical strains of the MERS coronavirus (MERS-CoV). To test the neutralising capacity of these antisera in vivo, susceptibility to MERS-CoV was induced in naive recipient Balb/c mice by the administration of an adenovirus vector expressing the human DPP4 receptor (Ad5-hDPP4) for MERS-CoV, prior to the passive transfer of the RBD-specific murine antisera to the transduced mice. Subsequent challenge of the recipient transduced mice by the intra-nasal route with a clinical isolate of the MERS-CoV resulted in a significantly reduced viral load in their lungs, compared with transduced mice receiving a negative control antibody. The murine antisera used were derived from mice which had been primed sub-cutaneously with a recombinant fusion of RBD with a human IgG Fc tag (RBD-Fc), adsorbed to calcium phosphate microcrystals and then boosted by the oral route with the same fusion protein in reverse micelles. The data gained indicate that this dual-route vaccination with novel formulations of the RBD-Fc, induced systemic and mucosal anti-viral immunity with demonstrated in vitro and in vivo neutralisation capacity for clinical strains of MERS-CoV.

Dual route vaccination for plague with emergency use applications.

Here, we report a dual-route vaccination approach for plague, able to induce a rapid response involving systemic and mucosal immunity, whilst also providing ease of use in those resource-poor settings most vulnerable to disease outbreaks. This novel vaccine (VypVaxDuo) comprises the recombinant F1 and V proteins in free association. VypVaxDuo has been designed for administration via a sub-cutaneous priming dose followed by a single oral booster dose and has been demonstrated to induce early onset immunity 14 days after the primary immunisation; full protective efficacy against live organism challenge was achieved in Balb/c mice exposed to 2 × 104 median lethal doses of Yersinia pestis Co92, by the sub-cutaneous route at 25 days after the oral booster immunisation. This dual-route vaccination effectively induced serum IgG and serum and faecal IgA, specific for F1 and V, which constitute two key virulence factors in Y. pestis, and is therefore suitable for further development to prevent bubonic plague and for evaluation in models of pneumonic plague. This is an essential requirement for control of disease outbreaks in areas of the world endemic for plague and is supported further by the observed exceptional stability of the primary vaccine formulation in vialled form under thermostressed conditions (40 °C for 29 weeks, and 40 °C with 75% relative humidity for 6 weeks), meaning no cold chain for storage or distribution is needed. In clinical use, the injected priming dose would be administered on simple rehydration of the dry powder by means of a dual barrel syringe, with the subsequent single booster dose being provided in an enteric-coated capsule suitable for oral self-administration.

Influence of the A and B subunits of cholera toxin (CT) and Escherichia coli toxin (LT) on TNF-alpha release from macrophages.

In this study an in vitro model was developed with the aim of investigating the modulatory effect of cholera toxin (CT) and its counterpart the heat labile toxin of Escherichia coli (LT) on TNF-alpha release induced by murine macrophages and primary human monocytes. Previous studies have demonstrated that the enzymatic activity of CT and LT molecules can inhibit TNF-alpha release by macrophages. The results obtained in this study showed that CT and LT are both, in a dose dependent manner, able either to induce or inhibit TNF-alpha release by murine macrophages and primary human monocytes. The results also showed that recombinant B subunits of CT and LT in the absence of their A subunit induce high levels of TNF-alpha release by macrophages and, in addition, increase the level of TNF-alpha release induced by LPS. The ability of both B subunits (CTB and LTB) in inducing TNF-alpha release by macrophages is not related to the level of LPS contamination, since direct measurements of LPS made in the samples employed in this study showed only traces of LPS (3.4 x 10(-8) EU/ml) which is in our system does not induce TNF-alpha release by macrophages. In contrast to the results obtained with the B subunits, incubation of cells with the A subunit of CT (CTA) inhibit TNF-alpha release induced by native CT, native LT, recombinant LTB and LPS. This inhibitory effect must be related to the activity of the A subunit since viability tests performed in terms of metabolic rate demonstrated that high concentrations of CTA are not toxic to the cells. The data presented herein demonstrate that the A subunits of CT and LT have an inhibitory effect on TNF-alpha release in macrophages, whereas their B subunits have a stimulatory effect on TNF-alpha. The results also suggest that the dose dependent bi-modal effect of native CT and native LT on TNF-alpha release by macrophages is a result of the combined effect of their individual A and B subunits.

Influence of sphingomyelin and TNF-alpha release on lethality and local inflammatory reaction induced by Loxosceles gaucho spider venom in mice.

It is well known that Loxosceles venom induces local dermonecrosis in rabbits, guinea pigs and humans but not in mice, although, depending on the dose, Loxosceles venom can be lethal to mice. In this work we demonstrate that mice injected intradermally in the dorsal area of the back can survive a lethal dose of Loxosceles gaucho venom and also develop an inflammatory reaction (with infiltration of leukocytes shown by histological analysis) at the local injection site when the venom is co-administered with sphingomyelin. It was observed that more venom was retained for a longer period of time at the local injection site when venom was co-administered with sphingomyelin. The presence of exogenous sphingomyelin did not influence significantly the release of TNF-alpha induced by L. gaucho venom. These results suggest that the action of venom on sphingomyelin, producing ceramide phosphate, causes the development of an inflammatory reaction, which in turn traps the venom in the local area for a long period of time and does not allow it to disperse systemically in a dose sufficient to cause death. Our findings also indicate that the size and availability of the local sphingomyelin pool may be important in determining the outcome of Loxosceles envenoming in different mammalian species.

Effect of Loxosceles gaucho venom on cell morphology and behaviour in vitro in the presence and absence of sphingomyelin.

This study was performed to investigate whether the toxic effects of Loxosceles gaucho venom on cells might be exerted via stimulators of TNF-alpha release generated by sphingomyelinase D--a major component of the venom. It was demonstrated that L. gaucho venom alone is unable to induce TNF-alpha release by J774A.1 cells, while in the presence of exogenous sphingomyelin it induces a high level of TNF-alpha release which is significantly increased by incubation with non-inactivated serum. Ceramide phosphate also induces TNF-alpha release in J774A.1 cells, but (unlike sphingomyelin/sphingomyelinase) the level of release is not influenced by the presence or otherwise of non-inactivated serum. L. gaucho venom does not induce proliferation of J774A.1 cells and even at high concentrations it does not affect their viability. J774A.1 cells, which prior to venom treatment were elongated and clumped, round up after venom treatment, but, revert to their original morphology after incubation with fresh medium. TNF-alpha resistant MRC-5 cells and TNF-alpha sensitive MCF-7 cells are susceptible to the toxic effect of both L. gaucho venom and ceramide phosphate. The results obtained in this study demonstrate that exogenous sphingomyelin can modulate, in vitro, the release of TNF-alpha induced by L. gaucho venom in mouse macrophages. In addition, the results also indicate that ceramide phosphate and L. gaucho venom are toxic to several different cell types, via a variety of mechanisms, some, but not all, of which may involve TNF-alpha as an intermediary.