National outbreak of Salmonella Give linked to a local food manufacturer in Malta, October 2016.

Salmonella Give is a rare serotype across Europe. In October 2016, a national outbreak of S. Give occurred in Malta. We describe the epidemiological, environmental, microbiological and veterinary investigations. Whole-genome sequencing (WGS) was performed on human, food, environmental and veterinary isolates. Thirty-six human cases were reported between October and November 2016, 10 (28%) of whom required hospitalisation. Twenty-six (72%) cases were linked to four restaurants. S. Give was isolated from ready-to-eat antipasti served by three restaurants which were all supplied by the same local food manufacturer. Food-trace-back investigations identified S. Give in packaged bean dips, ham, pork and an asymptomatic food handler at the manufacturer; inspections found inadequate separation between raw and ready-to-eat food during processing. WGS indicated two genetically distinguishable strains of S. Give with two distinct clusters identified; one cluster linked to the local food manufacturer and a second linked to veterinary samples. Epidemiological, environmental and WGS evidence pointed towards cross-contamination of raw and ready-to-eat foods at the local manufacturer as the likely source of one cluster. Severity of illness indicates a high virulence of this specific serotype. To prevent future cases and outbreaks, adherence to food safety practices at manufacturing level need to be reinforced.

Taking stock of the first 133 MERS coronavirus cases globally--Is the epidemic changing?

Since June 2012, 133 Middle East respiratory syndrome coronavirus (MERS-CoV) cases have been identified in nine countries. Two time periods in 2013 were compared to identify changes in the epidemiology. The case-fatality risk (CFR) is 45% and is decreasing. Men have a higher CFR (52%) and are over-represented among cases. Thirteen out of 14 known primary cases died. The sex-ratio is more balanced in the latter period. Nosocomial transmission was implied in 26% of the cases.

CTA1-DD-immune stimulating complexes: a novel, rationally designed combined mucosal vaccine adjuvant effective with nanogram doses of antigen.

Mucosally active vaccine adjuvants that will prime a full range of local and systemic immune responses against defined antigenic epitopes are much needed. Cholera toxin and lipophilic immune stimulating complexes (ISCOMS) containing Quil A can both act as adjuvants for orally administered Ags, possibly by targeting different APCs. Recently, we have been successful in separating the adjuvant and toxic effects of cholera toxin by constructing a gene fusion protein, CTA1-DD, that combines the enzymatically active CTA1-subunit with a B cell-targeting moiety, D, derived from Staphylococcus aureus protein A. Here we have extended this work by combining CTA1-DD with ISCOMS, which normally target dendritic cells and/or macrophages. ISCOMS containing a fusion protein comprising the OVA(323-339) peptide epitope linked to CTA1-DD were highly immunogenic when given in nanogram doses by the s.c., oral, or nasal routes, inducing a wide range of T cell-dependent immune responses. In contrast, ISCOMS containing the enzymatically inactive CTA1-R7K-DD mutant protein were much less effective, indicating that at least part of the activity of the combined vector requires the ADP-ribosylating property of CTA1. No toxicity was observed by any route. To our knowledge, this is the first report on the successful combination of two mechanistically different principles of adjuvant action. We conclude that rationally designed vectors consisting of CTA1-DD and ISCOMS may provide a novel strategy for the generation of potent and safe mucosal vaccines.

The mucosal adjuvant effects of cholera toxin and immune-stimulating complexes differ in their requirement for IL-12, indicating different pathways of action.

Adjuvants that can improve mucosal vaccine efficacy are much warranted. In this comparative study between cholera toxin (CT) and immune-stimulating complexes (ISCOM) we found that, contrary to CT, ovalbumin (OVA)-ISCOM were poor inducers of mucosal anti-OVA IgA responses, but induced similar or better systemic immunity following oral immunizations. The addition of CT to the oral OVA-ISCOM protocol did not stimulate local anti-OVA IgA immunity, nor did it change the quality or magnitude of the systemic responses. Both vectors recruited strong innate immunity, but only OVA-ISCOM could directly induce IL-12, demonstrable at the protein and mRNA levels. CT had no inhibitory effects on lipopolysaccharide/IFN-gamma-induced IL-12 mRNA expression or IL-12 production. Furthermore, adjuvanticity of CT was unaffected in IL-12-deficient mice, while OVA-ISCOM showed partly impaired adjuvant effects by the lack of IL-12. CT abrogated the induction of oral tolerance stimulated by antigen feeding in these mice. In addition, CT did not alter TGF-beta levels, suggesting that the immunomodulating effect of CT was independent of IL-12 as well as TGF-beta production. Taken together, these findings indicate that mucosal adjuvanticity of CT and ISCOM are differently dependent on IL-12, suggesting that separate and distinct antigen-processing pathways are involved.

Immune-stimulating complexes induce an IL-12-dependent cascade of innate immune responses.

The development of subunit vaccines requires the use of adjuvants that act by stimulating components of the innate immune response. Immune-stimulating complexes (ISCOMS) containing the saponin adjuvant Quil A are potential vaccine vectors that induce a wide range of Ag-specific responses in vivo encompassing both humoral and CD4 and CD8 cell-mediated immune responses. ISCOMS are active by both parenteral and mucosal routes, but the basis for their adjuvant properties is unknown. Here we have investigated the ability of ISCOMS to recruit and activate innate immune responses as measured in peritoneal exudate cells. The i.p. injection of ISCOMS induced intense local inflammation, with early recruitment of neutrophils and mast cells followed by macrophages, dendritic cells, and lymphocytes. Many of the recruited cells had phenotypic evidence of activation and secreted a number of inflammatory mediators, including nitric oxide, reactive oxygen intermediates, IL-1, IL-6, IL-12, and IFN-gamma. Of the factors that we investigated further only IL-12 appeared to be essential for the immunogenicity of ISCOMS, as IL-6- and inducible nitric oxide synthase knockout (KO) mice developed normal immune responses to OVA in ISCOMS, whereas these responses were markedly reduced in IL-12KO mice. The recruitment of peritoneal exudate cells following an injection of ISCOMS was impaired in IL-12KO mice, indicating a role for IL-12 in establishing the proinflammatory cascade. Thus, ISCOMS prime Ag-specific immune responses at least in part by activating IL-12-dependent aspects of the innate immune system.

Oral vaccination with immune stimulating complexes.

There is a need for non-living adjuvant vectors which will induce a full range of local and systemic immune responses to orally administered purified antigens. Here we describe our experience with lipophilic immune stimulating complexes (ISCOMS) containing the saponin adjuvant Quil A. When given orally, ISCOMS containing the model protein antigen ovalbumin (OVA) induce a wide range of systemic immune responses, including Th1 and Th2 CD4 dependent activity, class I MHC restricted cytotoxic T-cell responses and local production of secretory IgA antibodies. More recent results indicate that ISCOMS may act partly by enhancing the uptake of protein from the gut. In addition, intraperitoneal injection of ISCOMS recruits and activates many components of the innate immune system. including neutrophils, macrophages, and dendritic cells. In parallel, there is increased production of nitric oxide (NO), reactive oxygen intermediates (ROI), interleukins (IL) 1, 6, 12, and gamma interferon (gammaIFN). Of these factors, only IL12 is essential for the immunogenicity of ISCOMS in vivo, as mucosal and systemic responses to ISCOMS are reduced in IL12KO mice, but not in IL4KO, IL6KO, inducible NO synthase (iNOS) KO, or gammaIFN receptor KO mice. We propose that ISCOMS act by targetting antigen and adjuvant to macrophages and/or dendritic cells. This pathway may be amenable to exploitation for vaccine development, especially if combined with another vector with a different mucosal adjuvant profile, such as cholera toxin.

Preservation of mucosal and systemic adjuvant properties of ISCOMS in the absence of functional interleukin-4 or interferon-gamma.

Adjuvants are a critical component of non-viable vaccine vectors, particularly for those to be used via mucosal routes. Although most adjuvants act by inducing local inflammatory responses, the molecular basis of many of these effects is unclear. Here we have investigated whether interleukin-4 (IL-4) and interferon-gamma (IFN-gamma) are required for the induction of local and systemic immune responses by oral and parenteral administration of ovalbumin (OVA) in immune stimulating complexes (ISCOMS), a potent mucosal adjuvant vector. Our results show that after oral or systemic immunization with OVA ISCOMS, IL-4 knockout (IL4KO) and IFN-gamma receptor knockout (IFN-gamma RKO) mice develop an entirely normal range of immune responses including delayed-type hypersensitivity (DTH), serum immunoglobulin G (IgG) antibodies, T-cell proliferation and cytokine production, class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocyte (CTL) activity and intestinal IgA antibodies. These responses were of a similar magnitude to those found in the wild-type mice, indicating that the immunogenicity of ISCOMS is not influenced by the presence of IL-4 or IFN-gamma and emphasizing the potential of ISCOMS as widely applicable mucosal adjuvants.

Immune stimulating complexes as mucosal vaccines.

There is a need for non-living adjuvant vectors that will allow a full range of local and systemic immune responses to orally administered purified antigens. Here we describe our experience with lipophilic immune-stimulating complexes (ISCOMs) containing the saponin adjuvant Quil A. When given orally, ISCOMs containing the model protein antigen ovalbumin (OVA) induce a wide range of systemic immune responses, including Th1 and Th2 CD4-dependent activity, serum IgG antibodies and class I MHC-restricted cytotoxic T cell responses. In addition, there is local production of secretory IgA antibodies in the intestine itself, as well as priming of CD4 and CD8 T cell responses in the draining lymphoid tissues. Preliminary results indicate that the mucosal adjuvant properties of ISCOMs may reflect their ability to deliver antigen combined with the pro-inflammatory properties of Quil A in a particulate form. Of the many inflammatory mediators induced, interleukin-12, derived from dendritic cells and/or macrophages, appears to be of central importance. These results indicate that ISCOMs may prove to be useful mucosal vaccine vectors with functions which are distinct from existing vectors of this type.

Antigen-specific chemotaxis of B cells.

The chemoattractant effect of soluble protein antigens for B cells from immunized mice was examined. Mice were immunized either via the footpad with ovalbumin (OVA) in complete Freund's adjuvant (CFA) or with CFA alone; or intraperitoneally with OVA incorporated in immune-stimulating complexes (OVA-ISCOM) or with saline. After 8-14 days B cells were purified from the spleens or the draining popliteal nodes and tested in vitro for locomotor responses to antigen using polarization (shape-change) and filter assays. Cells obtained by both routes of immunization, but not cells from control mice, gave locomotor responses to OVA. Responses were seen in B cells directly after preparation (5-8% of cells responding) but were enhanced if the cells were cultured overnight in the presence of interleukin-4 (IL-4) before testing (10-12% of cells responding). Checkerboard filter assays suggested that the response to OVA was chemotactic. The response was antigen specific since cells from OVA-immunized mice did not respond to bovine serum albumin (BSA), and cells from BSA-immunized mice responded to BSA but not to OVA. The response to OVA was inhibited by preincubation of OVA with anti-OVA but not with anti-BSA. Many of the cells that polarized in response to antigen were larger than any B cells found in control populations suggesting that the responsive cells are those that had been stimulated to enter cell cycle following immunization.

Induction of Th1 and Th2 CD4+ T cell responses by oral or parenteral immunization with ISCOMS.

We examined the ability of oral or parenteral immunization with immune stimulating complexes containing ovalbumin (ISCOMS-OVA) to prime T cell proliferative and cytokine responses. A single subcutaneous immunization with ISCOMS-OVA primed potent antigen-specific proliferative responses in the draining popliteal lymph node, which were entirely dependent on the presence of CD4+ T cells. CD8+ T cells did not proliferate in vitro even in the presence of the appropriate peptide epitope and exogenous interleukin (IL)-2. Primed popliteal lymph node cells produced IL-2, IL-5 and interferon (IFN)-gamma, but not IL-4 when restimulated with OVA in vitro. Serum antigen-specific IgG1 and IgG2a antibody responses were also primed by subcutaneous immunization with ISCOMS-OVA, confirming the stimulation of both Th1 and Th2 cells in vivo. Spleen cells from subcutaneously primed mice produced a similar pattern of cytokines, indicating that disseminated priming had occurred. Oral immunization with ISCOMS-OVA also primed local antigen-specific proliferative responses in the mesenteric lymph node and primed an identical pattern of systemic cytokine responses in the spleen. The ability of ISCOMS to prime both Th1 and Th2 CD4+ T cell responses may be central to their potent adjuvant activities and confirm the potential of ISCOMS as future oral vaccine vectors.

Induction of mucosal and systemic immune responses by immunization with ovalbumin entrapped in poly(lactide-co-glycolide) microparticles.

We have examined the range of mucosal and systemic immune responses induced by oral or parenteral immunization with ovalbumin (OVA) entrapped in poly(D,L-lactide-co-glycolide) (PLG) microparticles. A single subcutaneous immunization with OVA-PLG primed significant OVA-specific IgG and delayed-type hypersensitivity (DTH) responses. The DTH responses were of similar magnitude to those obtained using immunostimulating complexes (ISCOMS) as a potent control adjuvant, although ISCOMS stimulated higher serum IgG responses. Both vectors also primed OVA-specific in vitro proliferative responses in draining lymph node cells following a single immunization and strong OVA-specific CTL responses were found after intraperitoneal (i.p.) immunization. ISCOMS were more efficient in inducing cytotoxic T lymphocytes (CTL), requiring much less antigen and only ISCOMS could stimulate primary OVA-specific CTL responses in the draining lymph nodes. Multiple oral immunizations with OVA in PLG microparticles or in ISCOMS resulted in OVA-specific CTL responses and again ISCOMS seemed more potent as fewer feeds were necessary. Lastly, multiple feeds of OVA in PLG microparticles generated significant OVA-specific intestinal IgA responses. This is the first demonstration that PLG microparticles can stimulate CTL responses in vivo and our results highlight their ability to prime a variety of systemic and mucosal immune responses which may be useful in future oral vaccine development.

Immune-stimulating complexes as adjuvants for inducing local and systemic immunity after oral immunization with protein antigens.

Orally active synthetic vaccines containing purified antigens would have many benefits for immunizing against systemic and mucosal diseases. However, several factors have limited the development of such vaccines, including the poor immunogenicity of purified proteins and their usual ability to induce tolerance when given orally. Here, we show that incorporation of ovalbumin (OVA) into immune-stimulating complexes (ISCOMS) containing saponin prevents the induction of oral tolerance in mice. In parallel, the spleen and mesenteric lymph node of mice fed OVA ISCOMS are primed for class I major histocompatibility complex (MHC)-restricted cytotoxic T-cell activity which recognizes physiologically processed epitopes on OVA. Oral immunization with OVA ISCOMS also stimulates high secretory IgA antibody responses in the intestine itself, as well as serum IgG antibodies. None of these active immune responses are detectable in mice fed OVA alone. Despite the potent priming of mucosal priming by OVA ISCOMS, re-exposure to antigen does not induce the intestinal immunopathology found in other systems after the breakdown of oral tolerance. Thus, ISCOMS have several unique properties as vectors for oral immunization and could provide a basis for future mucosal vaccines.

Biodegradable microparticles for oral immunization.

Ovalbumin (OVA) was entrapped in poly(lactide-co-glycolide) microparticles and administered to mice. Following intraperitoneal immunization, the microparticles induced both proliferative T-cell responses and cytotoxic T-cell responses in spleen cells. Following oral immunization, the mean salivary IgA antibody response to microparticles was significantly greater than the response to soluble OVA (p < 0.0001). Serum IgG antibody levels were also significantly greater in the group administered microparticles (p < 0.001). Cholera toxin B subunit was also entrapped in microparticles. Following oral immunization in mice, specific antibody-secreting cells were detected both in the spleens and in the mesenteric lymph nodes.

Studies on the immunogenicity of an endogenously processed protein antigen in mice.

We have examined the general immunogenicity of a non-replicating antigen which was introduced artificially into the endogenous pathway of antigen processing. EG7.OVA cells transfected with the OVA gene are efficient presenters of endogenously processed OVA and induced high levels of class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) in vivo. In addition, mice immunised with EG7.OVA cells developed immune responses more characteristic of class II MHC-restricted T cells, including IgG antibody production, systemic delayed type hypersensitivity (DTH) and a proliferative response to OVA in vitro. However, most of these responses were small, and EG7.OVA cells did not prime mice for secondary antibody or DTH responses. Thus endogenously synthesised, non-replicating antigens are poor stimulators of T cells which exploit the exogenous processing pathway. If vaccine vectors containing purified epitopes are to stimulate all T cells effectively, they will need to utilise strategies which enable direct entry to both antigen processing pathways.

Immune-stimulating complexes containing Quil A and protein antigen prime class I MHC-restricted T lymphocytes in vivo and are immunogenic by the oral route.

Induction of all forms of protective immunity by oral immunization with subunit vaccines is an ideal goal for the development of novel vaccines, but creates several theoretical problems from the point of view of antigen processing mechanisms. We show here that incorporation of the protein antigen ovalbumin (OVA) in lipophilic immune-stimulating complexes (ISCOMS) induces very strong primary immune responses in mice and requires very small amounts of antigen. OVA ISCOMS were particularly efficient at stimulating T-cell-mediated immunity in vivo, including delayed-type hypersensitivity (DTH) and potent class I major histocompatibility complex (MHC)-restricted cytotoxic T-cell responses. Furthermore, unlike native protein, OVA in ISCOMS was immunogenic when given orally. Thus, ISCOMS seem to allow protein to enter both the endogenous and exogenous pathways of antigen processing and overcome the usual induction of tolerance after feeding antigen. ISCOMS could provide potentially useful adjuvants for the development of oral subunit vaccines.

Genetic control of immunity to Trichinella spiralis in mice. Response of rapid- and slow-responder strains to immunization with parasite antigens.

Slow-responder C57BL/10 (B10) mice responded poorly to immunization with muscle larval antigen of Trichinella spiralis showing no accelerated loss of worms from a subsequent challenge infection. In contrast, rapid-responder NIH mice and (B10 X NIH) F1 mice developed high levels of immunity after immunization. Lymphocyte proliferation studies showed that immunized B10 mice did respond to in vitro restimulation with antigen, though less well than NIH mice. Failure of B10 mice to respond to immunization did not therefore reflect a failure to recognize larval antigen, a view confirmed by the fact that immunization was achieved using abbreviated enteral infections and, to a smaller extent, by parenterally administered muscle larvae.

Genetic control of immunity to Trichinella spiralis in mice: capacity of cells from slow responder mice to transfer immunity in syngeneic and F1 hybrid recipients.

Mice of the C57BL/10 (B10) strain are slow responders to infection with T. spiralis in terms of ability to expel worms from the intestine. Compared with rapid-responder NIH mice, infection stimulates a slower and reduced blast cell response in the draining mesenteric lymph node (MLN). Transfer of immune cells from the MLN (MLNC) does not accelerate worm expulsion from naive B10 recipient mice, even though MLNC from this strain effectively transfer immunity to (B10 X NIH) F1 recipients. In common with other B10 background mice C57BL/10 show an infection-dose related suppression of immunity to T. spiralis. Such suppression does not appear to determine the response to MLNC, as adoptive transfer into B10 recipients was not enhanced by reducing the level of challenge infection given, and transfer into F1 recipients was unaffected by simultaneous transfer of lymphocyte populations from donors infected at a level which would induce suppression. A hypothesis is proposed which relates slow response status to (i) the inherent capacity of the intestinal inflammatory component of worm expulsion, and (ii) the outcome of infection-dose related stimulatory and suppressive influences acting on the two interacting lymphocyte components of expulsion. The relevance of H-2-linked and non-H-2 genes to the control of the response is discussed.

Genetic control of eosinophilia. Mouse strain variation in response to antigens of parasite origin.

Strain variation in capacity to develop peripheral blood eosinophilia was observed in inbred NIH and C57BL/10 (B10) mice exposed to parasite antigens by infection or by parenteral injection in Freund's complete adjuvant. NIH mice were good responders, showing rapid development of high eosinophil counts, B10 mice were low responders. The difference in response phenotype was independent of the parasite used for infection (Trichinella spiralis or Nematospiroides dubius) and of the antigen used for injection (T. spiralis larval antigen or Limulus haemocyanin). Pre-treatment of T. spiralis infected mice with low doses of cyclophosphamide (150 mg/kg) or restriction of the duration of infection to 7 days by anthelmintic treatment did not enhance the response of B10 mice. Thus no evidence was found that the poor response phenotype of B10 during T. spiralis infection reflected any active suppressive mechanisms developed during the adult or muscle larval phases of infection. Demonstration that eosinophilia is induced primarily by the intestinal phase allows comparison with other parameters of the immune response induced by the adult worms, namely intestinal mastocytosis and worm expulsion. From this comparison it is concluded that the low eosinophil response phenotype of B10 mice may reflect a generalized deficiency in the response of bone marrow derived precursor cells to factors of T lymphocyte origin. The significance of genetically determined variation in eosinophil responsiveness is discussed in relation to the development of protective immune or pathological responses to parasite infection.