Unique IL-13Rα2-based HIV-1 vaccine strategy to enhance mucosal immunity,CD8+ T-cell avidity and protective immunity

We have established that mucosal immunization can generate high-avidity human immunodeficiency virus (HIV)-specific CD8⁺ T cells compared with systemic immunization, and interleukin (IL)-13 is detrimental to the functional avidity of these T cells. We have now constructed two unique recombinant HIV-1 vaccines that co-express soluble or membrane-bound forms of the IL-13 receptor α2 (IL-13Rα2), which can “transiently” block IL-13 activity at the vaccination site causing wild-type animals to behave similar to an IL-13 KO animal. Following intranasal/intramuscular prime-boost immunization, these IL-13Rα2-adjuvanted vaccines have shown to induce (i) enhanced HIV-specific CD8⁺ T cells with higher functional avidity, with broader cytokine/chemokine profiles and greater protective immunity using a surrogate mucosal HIV-1 challenge, and also (ii) excellent multifunctional mucosal CD8⁺ T-cell responses, in the lung, genito-rectal nodes (GN), and Peyer's patch (PP). Data revealed that intranasal delivery of these IL-13Rα2-adjuvanted HIV vaccines recruited large numbers of unique antigen-presenting cell subsets to the lung mucosae, ultimately promoting the induction of high-avidity CD8⁺ T cells. We believe our novel IL-13R cytokine trap vaccine strategy offers great promise for not only HIV-1, but also as a platform technology against range of chronic infections that require strong sustained high-avidity mucosal/systemic immunity for protection.     

Role of novel type I interferon epsilon in viral infection and mucosal immunity

Intranasal infection with vaccinia virus co-expressing interferon epsilon (VV-HIV-IFN-ɛ) was used to evaluate the role of IFN-ɛ in mucosal immunity. VV-HIV- IFN-ɛ infection induced a rapid VV clearance in lung that correlated with (i) an elevated lung VV-specific CD8⁺CD107a⁺IFN-γ⁺ population expressing activation markers CD69/CD103, (ii) enhanced lymphocyte recruitment to lung alveoli with reduced inflammation, and (iii) an heightened functional/cytotoxic CD8⁺CD4⁺ T-cell subset (CD3^hiCCR7^hiCD62L^lo) in lung lymph nodes. These responses were different to that observed with intranasal VV-HA-IFN-α₄ or VV-HA-IFN-β infections. When IFN-ɛ was used in an intranasal/intramuscular heterologous HIV prime-boost immunization, elevated HIV-specific effector, but not memory CD8⁺T cells responses, were observed in spleen, genito-rectal nodes, and Peyer’s patch. Homing marker α4β7 and CCR9 analysis indicated that unlike other type I IFNs, IFN-ɛ could promote migration of antigen-specific CD8⁺T cells to the gut. Our results indicate that IFN-ɛ has a unique role in the mucosae and most likely can be used to control local lung and/or gut infections (i.e., microbicide) such as tuberculosis, HIV-1, or sexually transmitted diseases.     

Intradermal Delivery of Recombinant Vaccinia Virus Vector DIs Induces Gut‐Mucosal Immunity

Antigen‐specific mucosal immunity is generally induced by the stimulation of inductive mucosal sites. In this study, we found that the replication‐deficient vaccinia virus vector, DIs, generates antigen‐specific mucosal immunity and systemic responses. Following intradermal injection of recombinant DIs expressing simian immunodeficiency virus gag (rDIsSIVgag), we observed increased levels of SIV p27‐specific IgA and IgG antibodies in faecal extracts and plasma samples, and antibody‐forming cells in the intestinal mucosa and spleen of C57BL/6 mice. Antibodies against p27 were not detected in nasal washes, saliva, and vaginal washes. The enhanced mucosal and systemic immunity persisted for 1 year of observation. Induction of Gag‐specific IFN‐γ spot‐forming CD8⁺ T cells in the spleen, small intestinal intraepithelial lymphocytes, and submandibular lymph nodes was observed in the intradermally injected mice. Heat‐inactivated rDIsSIVgag rarely induced antigen‐specific humoral and T‐helper immunity. Moreover, rDIsSIVgag was detected in MHC class II IA antigen‐positive (IA⁺) cells at the injection site. Consequently, intradermal delivery of rDIs effectively induces antigen‐specific humoral and cellular immunity in gut‐mucosal tissues of mice. Our data suggest that intradermal injection of an rDIs vaccine may be useful against mucosally transmitted pathogens.     

Fibronectin-binding protein I of Streptococcus pyogenes is a promising adjuvant for antigens delivered by mucosal route

A common problem in human vaccinology is the limited availability of efficient and non-toxic adjuvants capable of promoting mucosal responses. The potential usefulness of fibronectin-binding protein I (SfbI) of Streptococcus pyogenes as immunological adjuvant was assessed using ovalbumin (OVA) as a model antigen. Mice were immunized by intranasal route, either with soluble OVA or OVA covalently coupled to SfbI. Immunization with OVA-SfbI resulted in the elicitation of about 100-fold higher titers of anti-OVA serum IgG than using OVA alone. The anti-OVA IgG subclass pattern was dominated in both groups of mice by IgG1, followed by IgG2b, IgG2a, and IgG3. Immunization with OVA-SfbI also resulted in the elicitation of OVA-specific IgA in lung washes (24 % of the total IgA), which was absent in mice immunized with OVA alone. Spleen cells from OVA-SfbI-immunized mice also gave a much stronger proliferative response to restimulation with soluble OVA in vitro. Phenotypic analysis of proliferating cells showed an enrichment in CD4⁺ T cells, producing a pattern of cytokines (IL-4, IL-5, IL-6 and IL-10) characteristic of Th2-type cells. In contrast to immunization with soluble OVA alone, OVA-SfbI induced the generation of CD8⁺ OVA-specific cytotoxic cells. These results demonstrate that SfbI represents a promising mucosal adjuvant able to substantially improve cellular, humoral and mucosal responses when coupled to an antigen administered by intranasal route.     

Enhanced protection conferred by mucosal BCG vaccination associates with presence of antigen-specific lung tissue-resident PD-1+ KLRG1− CD4+ T cells

BCG, the only vaccine licensed against tuberculosis, demonstrates variable efficacy in humans. Recent preclinical studies highlight the potential for mucosal BCG vaccination to improve protection. Lung tissue-resident memory T cells reside within the parenchyma, potentially playing an important role in protective immunity to tuberculosis. We hypothesised that mucosal BCG vaccination may enhance generation of lung tissue-resident T cells, affording improved protection against Mycobacterium tuberculosis. In a mouse model, mucosal intranasal (IN) BCG vaccination conferred superior protection in the lungs compared to the systemic intradermal (ID) route. Intravascular staining allowed discrimination of lung tissue-resident CD4⁺ T cells from those in the lung vasculature, revealing that mucosal vaccination resulted in an increased frequency of antigen-specific tissue-resident CD4⁺ T cells compared to systemic vaccination. Tissue-resident CD4⁺ T cells induced by mucosal BCG displayed enhanced proliferative capacity compared to lung vascular and splenic CD4⁺ T cells. Only mucosal BCG induced antigen-specific tissue-resident T cells expressing a PD-1⁺ KLRG1⁻ cell-surface phenotype. These cells constitute a BCG-induced population which may be responsible for the enhanced protection observed with IN vaccination. We demonstrate that mucosal BCG vaccination significantly improves protection over systemic BCG and this correlates with a novel population of BCG-induced lung tissue-resident CD4⁺ T cells.     

Interleukin 12 and innate molecules for enhanced mucosal immunity

Recent strategies for understanding the mechanisms underlying mucosal immune responses and subsequent development of mucosal vaccines for induction of targeted immunity now include cytokines and molecules of innate immunity. These studies have shown that cytokines influencing the development of T helper (Th) cells differentially affect the outcome of mucosal vs systemic immune responses to mucosal vaccines. Serum antigen-specific antibody (Ab) responses were enhanced when either IL-6 or IL-12 was mucosally administered with a protein antigen, while only IL-12 induced antigen-specific mucosal IgA Ab responses. Mucosal IL-6 and IL-12 also affected the type of Th cell responses induced by CD4⁺ T cells from mice that received IL-12 secreted larger amounts of IFN-γ and IL-6 when compared with mice nasally treated with IL-6. Discrepancies in the ability to enhance mucosal or systemic immune responses were also observed when human neutrophil peptide (HNP) defensins or lymphotactin were nasally coadministered with protein antigens. Only lymphotactin promoted mucosal secretory IgA (S-IgA) Ab responses while both lymphotactin and defensins enhanced systemic immunity to mucosally co-administered protein antigens. Mixed antigen-specific Th1-and Th2-type CD4⁺ T cell responses were induced in the systemic compartment by both lymphotactin and the mixture of HNP-1, HNP-2, and HNP-3 defensins. However, HNPs failed to significantly enhance cytokine secretion by mucosally derived, antigen-specific CD4⁺ T cells relative to those isolated from the systemic compartment. In summary, these studies clearly show that IL-12 and lymphotactin are able to trigger S-IgA Ab responses and provide new avenues for the design of safe and targeted mucosal vaccines.     

Mucosal immunization with a novel nanoemulsion-based recombinant anthrax protective antigen vaccine protects against Bacillus anthracis spore challenge

The currently available commercial human anthrax vaccine requires multiple injections for efficacy and has side effects due to its alum adjuvant. These factors limit its utility when immunizing exposed populations in emergent situations. We evaluated a novel mucosal adjuvant that consists of a nontoxic, water-in-oil nanoemulsion (NE). This material does not contain a proinflammatory component but penetrates mucosal surfaces to load antigens into dendritic cells. Mice and guinea pigs were intranasally immunized with recombinant Bacillus anthracis protective antigen (rPA) mixed in NE as an adjuvant. rPA-NE immunization was effective in inducing both serum anti-PA immunoglobulin G (IgG) and bronchial anti-PA IgA and IgG antibodies after either one or two mucosal administrations. Serum anti-PA IgG2a and IgG2b antibodies and PA-specific cytokine induction after immunization indicate a Th1-polarized immune response. rPA-NE immunization also produced high titers of lethal-toxin-neutralizing serum antibodies in both mice and guinea pigs. Guinea pigs nasally immunized with rPA-NE vaccine were protected against an intradermal challenge with approximately 1,000 times the 50% lethal dose ( approximately 1,000x LD(50)) of B. anthracis Ames strain spores (1.38 x 10(3) spores), which killed control animals within 96 h. Nasal immunization also resulted in 70% and 40% survival rates against intranasal challenge with 10x LD(50) and 100x LD(50) (1.2 x 10(6) and 1.2 x 10(7)) Ames strain spores. Our results indicate that NE can effectively adjuvant rPA for intranasal immunization. This potentially could lead to a needle-free anthrax vaccine requiring fewer doses and having fewer side effects than the currently available human vaccine.     

Mucosal IgA responses in healthy adult volunteers following intranasal spray delivery of a live attenuated measles vaccine

Measles remains an important cause of morbidity and mortality among children in the developing world. The goal of this study was to examine measles virus-specific mucosal immune responses in healthy immune (n = 24; plaque reduction neutralization [PRN] titers of ≥200 mIU/ml) and nonimmune (n = 24) young adult volunteers who received the monovalent Moraten measles vaccine via intranasal (spray delivery) or subcutaneous immunization. Serum, oral fluid, and nasal wash samples were examined for measles virus-specific and total IgG and IgA on day 0 (prior to vaccination) and on days 14, 28, and 90 after vaccination. Nonimmune subjects vaccinated subcutaneously developed high levels of measles virus PRN, IgG, and IgA antibodies in serum, oral fluid, and nasal washes. Total IgG and secretory IgA (sIgA) titers were increased in nasal washes, and total IgG was increased in oral fluid specimens. There was a strong correlation between PRN and measles virus-specific IgG titers measured in serum, oral fluid, and nasal washes, whereas a weak correlation was found between PRN and measles virus-specific IgA titers. Notably, intranasal measles vaccination resulted in increased production of measles virus-specific sIgA in oral fluid and nasal washes in nonimmune individuals, without evidence of a systemic immune response. In contrast, no significant vaccine-induced responses were observed in immune subjects, regardless of the route of immunization. These results demonstrate that (i) intranasal measles immunization can elicit a mucosal response independent of the induction of serum antibodies and (ii) both mucosal and systemic antibody responses following nasal or subcutaneous immunization are blunted by preexisting measles immunity.     

Interferon-gamma receptor-deficient mice exhibit impaired gut mucosal immune responses but intact oral tolerance.

Interferon-gamma (IFN-gamma) receptor knock-out (IFN-gamma R -/-) mice were used to analyse the role of IFN-gamma in mucosal immune responses following oral immunization. We found that the IFN-gamma R -/- mice demonstrated 50% reduced spot-forming cell (SFC) responses in the gut lamina propria and spleen after oral immunization with keyhold limpet haemocyanin (KLH) plus cholera toxin (CT) adjuvant. The IFN-gamma R -/- mice exhibited 10-fold reduced total serum KLH-specific antibody levels compared with wild-type mice after oral immunization, while after intravenous immunization, no such difference was seen, suggesting a selective impairment of mucosal immune responses. Moreover, oral immunizations resulted in impaired interleukin-4 (IL-4), IL-10 and IFN-gamma production by spleen T cells from IFN-gamma R -/- mice, indicating that no reciprocal up-regulation of Th2-activities had occurred despite the lack of IFN-gamma R function. No reduction in Th1 or Th2 cytokines was observed following systemic immunizations. Despite potentially strong modulating effects of IFN-gamma on epithelial cell IgA transcytosis and electrolyte barrier functions, CT-immunized IFN-gamma R -/- mice demonstrated unaltered protection against CT in ligated intestinal loops together with normal anti-CT IgA and total IgA levels in gut lavage. Oral feeding with KLH followed by parenteral immunization resulted in strongly suppressed SFC numbers and reduced cell-mediated immunity in both wild-type and IFN-gamma R -/- mice. CT-adjuvant abrogated induction of oral tolerance in both IFN-gamma R -/- and wild-type mice. Collectively, our data argue that the two major response patterns induced by oral administration of protein antigen, i.e. active IgA immunity and oral tolerance, are differently regulated. Thus, IFN-gamma R -/- mice have impaired mucosal immune responses while induction of oral tolerance appears to be unaffected by the lack of IFN-gamma functions.     

Molecular and cellular signatures underlying superior immunity against Bordetella pertussis upon pulmonary vaccination

Mucosal immunity is often required for protection against respiratory pathogens but the underlying cellular and molecular mechanisms of induction remain poorly understood. Here, systems vaccinology was used to identify immune signatures after pulmonary or subcutaneous immunization of mice with pertussis outer membrane vesicles. Pulmonary immunization led to improved protection, exclusively induced mucosal immunoglobulin A (IgA) and T helper type 17 (Th17) responses, and in addition evoked elevated systemic immunoglobulin G (IgG) antibody levels, IgG-producing plasma cells, memory B cells, and Th17 cells. These adaptive responses were preceded by unique local expression of genes of the innate immune response related to Th17 (e.g., Rorc) and IgA responses (e.g., Pigr) in addition to local and systemic secretion of Th1/Th17-promoting cytokines. This comprehensive systems approach identifies the effect of the administration route on the development of mucosal immunity, its importance in protection against Bordetella pertussis, and reveals potential molecular correlates of vaccine immunity to this reemerging pathogen.     

Cholera toxin adjuvant greatly promotes antigen priming of T cells

Cholera toxin (CT) given perorally is a powerful mucosal immunogen and adjuvant. Information that explains the adjuvant effect of CT may be used for the development of more effective oral vaccines and might also contribute to our understanding of the mechanisms involved in regulating mucosal immunity. The present study was undertaken to investigate if CT administered together with keyhole limpet hemocyanin (KLH) would act to promote or inhibit priming of KLH-specific T cells and whether the adjuvant effect of CT is restricted to mucosal immune responses or is a generalized phenomenon due to direct immunomodulating effects of CT. We found that CT adjuvant greatly augmented the effectiveness of a single oral priming immunization with KLH: re-challenge with KLH in vitro 1 week following immunization gave several-fold stronger proliferation in KLH-specific spleen, mesenteric lymph node, Peyer's patch and gut lamina propria T cells from KLH + CT adjuvant as opposed to KLH only-treated mice. Moreover, several-fold stronger cytokine production, i.e. interleukin (IL)-2, IL-4, IL-5, IL-6, IL-10 and interferon-Y accompanied the enhanced proliferative response of T cells from CT adjuvant-treated mice. The adjuvant effect of CT was not restricted to mucosal immune responses but was evident also following a single parenteral immunization with KLH + CT. Limiting dilution analysis revealed that CT adjuvant promoted a 20- to 40-fold increase in the frequency of primed KLH-specific T cells. Phenotypic and functional analyses clearly demonstrated that CT adjuvant primarily enhanced priming of CD4⁺ rather than CD8⁺ T cells and the pattern of lymphokine secretion disclosed that CT most probably promoted antigen priming of both T_hl and T_h2 type of CD4⁺ T precursor cells.     

Enhanced resistance to coxsackievirus B3-induced myocarditis by intranasal co-immunization of lymphotactin gene encapsulated in chitosan particle

Coxsackievirus B3 (CVB3) is a gastrointestinal virus causing myocarditis in human and mice. An ideal vaccine for CVB3-myocarditis requires both humoral and cellular immunity at systemic and mucosal compartments. We described here an enhancing strategy for chitosan-pVP1 vaccine by co-immunizing with lymphotactin (LTN) gene, a T cell-attractive-chemokine, encapsulated in chitosan particle to provide more protection against CVB3. Mice were intranasally co-immunized with 4 doses of chitosan-DNA vaccines separately encapsulating VP1 and LTN plasmids by 2 week-intervals and challenged with CVB3 4 weeks after the last immunization. Compared with chitosan-pVP1 alone, co-immunization with chitosan-pLTN significantly increased high-avidity-neutralizing antibody levels in serum and in intestinal mucosa, and promoted systemic and mucosal Th1 and CD8⁺CTL immune responses. Accordingly, enhanced resistance to CVB3-myocarditis was evidenced by reduced myocardial viral load, profound subsidence of myocarditis and increased survival rate. This strategy represents a promising platform for Th1 polarization and protection against mucosal infectious pathogens.     

Mucosal and systemic anti-GAG immunity induced by neonatal immunization with HIV LAMP/gag DNA vaccine in mice

Vaccines capable of inducing mucosal immunity in early postnatal life until adulthood, protecting early sexual initiation, should be considered as strategies to vaccination against HIV. The HIV-1 GAG protein as a chimera with the lysosome-associated membrane protein (LAMP/gag), encoded by a DNA vaccine, is targeted to the endosomal/lysosomal compartment that contains class II MHC molecules and has been shown to be immunogenic in adult mice. Assuming that one such strategy could help to overcome the immunological immaturity in the early postnatal period, we have evaluated the systemic and mucosal immunogenicity of LAMP/gag immunization in neonatal mice. Intranasal immunization with LAMP/gag vaccine induced higher levels of sIgA and IgG anti-GAG antibodies in intestinal washes than did the gag vaccine. The combination of ID injections and the IN protocol with the chimeric vaccine promoted the increase of Ab levels in sera. Both vaccines induced splenic IFN-γ− secreting cells against GAG peptide pools, as well as in vivo cytotoxic T lymphocyte (CTL) function, and increased the percentage of CD8+ T cells to the immunodominant class I peptide in gut and spleen. However, only the chimeric vaccine was able to enhance Th1/Th2 cytokine secretion in response to class II GAG peptide and to enhance IL-4-secreting cells against GAG peptides and p24 protein stimuli. Long-lasting humoral and cellular responses were detected until adult age, following neonatal immunization with the chimeric vaccine. The LAMP/gag vaccination was able to induce potent GAG-specific T and B cell immune responses in early life which are essential to elicit sustained and long-lasting mucosal and systemic humoral response.     

Thermal-sensitive hydrogel as adjuvant-free vaccine delivery system for H5N1 intranasal immunization

For H5N1 influenza immunization, we developed a thermal-sensitive hydrogel as intranasal vaccine delivery system, which was formulated with N-[(2-hydroxy-3-trimethylammonium) propyl] chitosan chloride (HTCC) and α, β-glycerophosphate (α, β-GP). The flowing solution of HTCC/GP under room temperature could gelate rapidly at body temperature, which significantly prolonged the H5N1 split antigen residence time in nasal cavity. This system also enhanced the transepithelial transport via the paracellular routes due to the disorganization of ZO-1 protein in nasal epithelial tissue. In comparison to naked H5N1 split antigen and MF59 adjuvanted antigen, as designed hydrogel/H5N1 vaccine induced greater antigen-specific systemic immune responses and mucosal IgA immunity without adjuvants. Furthermore, a boosted cellular and humoral response was also obtained by examination of IFN-γ and IL-4 cytokines, respectively. In addition, hydrogel based formulation promoted the antigen-specific CD8⁺ T cell immune memory as determined by the proportion of central and effector memory CD8⁺ T cells in nasal associated lymphoid tissue (NALT). These results demonstrate that the HTCC hydrogel has potential as an adjuvant-free platform for H5N1 split antigen intranasal vaccination.     

Generation of functionally active HIV-1 specific CD8+ CTL in intestinal mucosa following mucosal, systemic or mixed prime-boost immunization

Gastrointestinal and vaginal mucosa are major sites of entry in natural HIV infection and therefore the preferred sites to elicit high-avidity CD8⁺ CTL by vaccination. We directly compare systemic and mucosal immunization in mice after DNA priming and boosting with rgp160 env expressed either in MVA or Ad for their ability to induce mucosal as well as systemic HIV-specific CTL. The optimal CTL response in the gut mucosa was observed after priming with the HIV-1 gp160 env DNA vaccine and boosting with rMVA or rAd encoding the same envelope gene all administered intrarectally (IR). Maximum levels of high-avidity CD8⁺ T cells were seen in intestinal lamina propria following this regimen. When the prime and boost routes were distinct, the delivery site of the boost had a greater impact than the DNA priming. IM DNA prime and IR rMVA boost were more effective than IR DNA prime and IM rMVA boost for eliciting mucosal CD8⁺ T-cell avidity. A systemic DNA-prime-followed by systemic rMVA boost induced high levels of high-avidity CD8⁺ T cells systemically, but responses were undetectable in mucosal sites. A single systemic immunization with rMVA was sufficient to induce high-avidity IFN-γ secreting CD8⁺ T cells in systemic organs, whereas a single mucosal immunization with rMVA was not sufficient to elicit high-avidity CD8⁺ T cells in mucosa. Thus, a heterologous mucosal DNA prime-viral vectored boost strategy was needed. The requirement for a heterologous DNA prime-recombinant viral boost strategy for generation of high-avidity CD8⁺ T cells in mucosal sites in mice may be more stringent than for the induction of high-avidity CD8⁺ T cells in systemic compartments.     

Intranasal delivery of group B meningococcal native outer membrane vesicle vaccine induces local mucosal and serum bactericidal antibody responses in rabbits

We have previously shown that intranasal immunization of mice with meningococcal native outer membrane vesicles (NOMV) induces both a good local mucosal antibody response and a good systemic bactericidal antibody response. However, in the intranasal mouse model, some of the NOMV entered the lung and caused an acute granulocytic response. We therefore developed an alternate animal model using the rabbit. This model reduces the probability of lung involvement and more closely mimics intranasal immunization of humans. Rabbits immunized intranasally with doses of 100 mug of NOMV in 0.5 ml of saline developed serum bactericidal antibody levels comparable to those of rabbits immunized intramuscularly with 25-mug doses, particularly when the primary intranasal immunization was given daily for 3 days. Intranasal immunization also induced a local mucosal response as evidenced by immunoglobulin A antibody in saliva, nasal washes, and lung lavage fluids. NOMV from a capsule-deficient mutant induced higher serum bactericidal antibody responses than NOMV from the encapsulated parent. Meningococcal NOMV could be administered intranasally at 400 mug with no pyrogenic activity, but as little as 0.03 mug/kg of body weight administered intravenously or 25 mug administered intramuscularly induced a pyrogenic response. These data indicate that the rabbit is a useful model for preclinical testing of intranasal meningococcal NOMV vaccines, and this immunization regimen produces a safe and substantial systemic and local mucosal antibody response.     

Elicitation of Th1/Th2 related responses in mice by chitosan nanoparticles loaded with Brucella abortus malate dehydrogenase,outer membrane proteins 10 and 19

Brucella spp. is the causative agent of brucellosis, one of the worldwide diseases. The pathogen infects humans and animals mainly through the digestive or respiratory tract. Therefore, induction of mucosal immunity is required as the first line of defense. In this study, three Brucella abortus recombinant proteins, malate dehydrogenase (rMdh), outer membrane proteins (rOmp) 10 and 19 were loaded in mucoadhesive chitosan nanoparticles (CNs) and induction of mucosal and systemic immunity were investigated after intranasal immunization of BALB/c mice. These antigens were also coimmunized as cocktail (rCocktail) to evaluate multiple antigen specific vaccine candidates. At 6-weeks post-immunization (wpi), antigen specific total IgG was increased in all of the immunized groups, predominantly IgG1. In addition, spleenocyte from rMdh-, rOmp19-, and rCocktail-immunized groups significantly produced IFN-γ and IL-4 suggesting the induction of a mixed Th1-Th2 response. For mucosal immunity, anti-Mdh IgA from nasal washes and fecal excretions, and anti-Omps IgA from sera, nasal washes, genital secretions and fecal excretions were significantly increased in single antigen immunized groups. In the rCocktail-immunized group, anti-Mdh IgA were significantly increased while anti-Omps IgA was not. Collectively, this study indicates that comprise of B. abortus antigen-loaded CNs elicited the antigen-specific IgA with a Th2-polarized immune responses and combination of the highly immunogenic antigens elicited IgG specific to each type of antigen.     

RGD capsid modification enhances mucosal protective immunity of a non‐human primate adenovirus vector expressing Pseudomonas aeruginosa OprF

Replication‐deficient adenoviral (Ad) vectors of non‐human serotypes can serve as Ad vaccine platforms to circumvent pre‐existing anti‐human Ad immunity. We found previously that, in addition to that feature, a non‐human primate‐based AdC7 vector expressing outer membrane protein F of P. aeruginosa (AdC7OprF) was more potent in inducing lung mucosal and protective immunity compared to a human Ad5‐based vector. In this study we analysed if genetic modification of the AdC7 fibre to display an integrin‐binding arginine–glycine–aspartic acid (RGD) sequence can further enhance lung mucosal immunogenicity of AdC7OprF. Intratracheal immunization of mice with either AdC7OprF.RGD or AdC7OprF induced robust serum levels of anti‐OprF immunoglobulin (Ig)G up to 12 weeks that were higher compared to immunization with the human vectors Ad5OprF or Ad5OprF.RGD. OprF‐specific cellular responses in lung T cells isolated from mice immunized with AdC7OprF.RGD and AdC7OprF were similar for T helper type 1 (Th1) [interferon (IFN)‐γ in CD8⁺ and interleukin (IL)‐12 in CD4⁺], Th2 (IL‐4, IL‐5 and IL‐13 in CD4⁺) and Th17 (IL‐17 in CD4⁺). Interestingly, AdC7OprF.RGD induced more robust protective immunity against pulmonary infection with P. aeruginosa compared to AdC7OprF or the control Ad5 vectors. The enhanced protective immunity induced by AdC7OprF.RGD was maintained in the absence of alveolar macrophages (AM) or CD1d natural killer T cells. Together, the data suggest that addition of RGD to the fibre of an AdC7‐based vaccine is useful to enhance its mucosal protective immunogenicity.     

Using a prime and pull approach,lentivector vaccines expressing Ag85A induce immunogenicity but fail to induce protection against Mycobacterium bovis bacillus Calmette–Guérin challenge in mice

Although bacillus Calmette–Guérin (BCG) is an established vaccine with excellent efficacy against disseminated Mycobacterium tuberculosis infection in young children, efficacy in adults suffering from respiratory tuberculosis (TB) is suboptimal. Prime‐boost viral vectored vaccines have been shown to induce effective immune responses and lentivectors (LV) have been shown to improve mucosal immunity in the lung. A mucosal boost to induce local immunogenicity is also referred to as a ‘pull’ in a prime and pull approach, which has been found to be a promising vaccine strategy. The majority of infants worldwide receive BCG immunization through current vaccine protocols. We therefore aimed to investigate the role of a boost (or pull) immunization with an LV vaccine expressing the promising TB antigen (Ag85A). We immunized BALB/c mice subcutaneously with BCG or an LV vaccine expressing a nuclear factor‐κB activator vFLIP together with Ag85A (LV vF/85A), then boosted with intranasal LV vF/85A. Prime and pull immunization with LV85A induced significantly enhanced CD8⁺ and CD4⁺ T‐cell responses in the lung, but did not protect against intranasal BCG challenge. In contrast, little T‐cell response in the lung was seen when the prime vaccine was BCG, and intranasal vF/85A provided no additional protection against mucosal BCG infection. Our study demonstrates that not all LV prime and pull approaches may be successful against TB in man and careful antigen and immune activator selection is therefore required.     

Intranasal immunization with Toxoplasma gondii SAG1 induces protective cells into both NALT and GALT compartments

Intranasal (i.n.) immunization with the SAG1 protein of Toxoplasma gondii plus cholera toxin (CT) provides protective immunity. The aim of this study was to analyze the cellular activation of several mucosal compartments after i.n. immunization. Cervical and mesenteric lymph node (CLN and MLN, respectively) lymphoid cell and intraepithelial lymphocyte (IEL) passive transfer experiments were performed with CBA/J mice immunized i.n. with SAG1 plus CT. CLN and MLN cells and IEL isolated 42 days after immunization conferred protective immunity on naive recipient mice challenged with strain 76K T. gondii, as assessed by the reduction in the number of brain cysts. There were proliferative specific responses in nose-associated lymphoid tissue and the CLN and MLN cells from mice immunized with SAG1 plus CT, but no cytokine was detectable. Thus, protective immunity is associated with a specific cellular response in the nasal and mesenteric compartments after i.n. immunization.