Prolonged expression of IFNgamma induced by protective blood-stage immunization against Plasmodium yoelii malaria.

Mice vaccinated with whole blood-stage antigens of Plasmodium yoelii develop protective, antibody-mediated immune responses to homologous challenge infection. In this model the level of protection induced by whole parasite antigen vaccination is dependent on antibody isotype, which can be influenced by adjuvant formulations. In this study the ability adjuvant formulations to affect cytokine production and protection against P. yoelii blood-stage infection was investigated. Survival of mice in groups vaccinated with P. yoelii antigens in an aqueous mix of copolymer P1005 + RaLPS was 100%. Mice vaccinated with either P. yoelii antigens alone or combined with a water-in-oil emulsion of copolymer P1005 + RaLPS demonstrated 83 or 50% survival, respectively. The fully protective aqueous vaccine group produced higher levels of interferon gamma (IFNgamma) and interleukin 4 (IL-4) than the water-in-oil vaccine group following a live parasite challenge infection. Furthermore, mice vaccinated with the aqueous vaccine displayed prolonged IFNgamma and IL-4 response as compared to mice that received the same antigens without adjuvants. These data support the hypothesis that both the Th1 cytokine IFNgamma, and the Th2 cytokine IL-4 are modulated by the vaccine vehicle and adjuvant used for vaccination, thus possibly affecting expression of protective immune responses. However, it is the long-lasting IFNgamma response following blood-stage P. yoelii parasite challenge that is associated with enhanced survival.     

Systemic immunization with an epitope-based vaccine elicits a Th1-biased response and provides protection against Helicobacter pylori in mice

Vaccine-mediated Th1-biased CD4+ T cell responses have been shown to be crucial for protection against Helicobacter pylori (H. pylori). In this study, we investigated whether a vaccine composed of CD4+ T cell epitopes together with Th1 adjuvants could confer protection against H. pylori in a mouse model. We constructed an epitope-based vaccine, designated Epivac, which was composed of predicted immunodominant CD4+ T cell epitopes from H. pylori adhesin A (HpaA), urease B (UreB) and cytotoxin-associated gene A product (CagA). Together with four different Th1 adjuvants, Epivac was administered subcutaneously and the prophylactic potential was examined. Compared to non-immunized mice, immunization with Epivac alone or with a Th1 adjuvant significantly reduced H. pylori colonization, and better protection was observed when an adjuvant was used. Immunized mice exhibited a strong local and systemic Th1-biased immune response, which may contribute to the inhibition of H. pylori colonization. Though a significant specific antibody response was induced by the vaccine, no correlation was found between the intensity of the humoral response and the protective effect. Our results suggest that a vaccine containing CD4+ T cell epitopes is a promising candidate for protection against H. pylori infection.     

Novel G3/DT adjuvant promotes the induction of protective T cells responses after vaccination with a seasonal trivalent inactivated split-virion influenza vaccine

Vaccines used against seasonal influenza are poorly effective against influenza A viruses of novel subtypes that may have pandemic potential. Furthermore, pre(pandemic) influenza vaccines are poorly immunogenic, which can be overcome by the use of adjuvants. A limited number of adjuvants has been approved for use in humans, however there is a need for alternative safe and effective adjuvants that can enhance the immunogenicity of influenza vaccines and that promote the induction of broad-protective T cell responses. Here we evaluated a novel nanoparticle, G3, as an adjuvant for a seasonal trivalent inactivated influenza vaccine in a mouse model. The G3 adjuvant was formulated with or without steviol glycosides (DT, for diterpenoid). The use of both formulations enhanced the virus-specific antibody response to all three vaccine strains considerably. The adjuvants were well tolerated without any signs of discomfort. To assess the protective potential of the vaccine-induced immune responses, an antigenically distinct influenza virus strain, A/Puerto Rico/8/34 (A/PR/8/34), was used for challenge infection. The vaccine-induced antibodies did not cross-react with strain A/PR/8/34 in HI and VN assays. However, mice immunized with the G3/DT-adjuvanted vaccine were partially protected against A/PR/8/34 infection, which correlated with the induction of anamnestic virus-specific CD8⁺ T cell responses that were not observed with the use of G3 without DT. Both formulations induced maturation of human dendritic cells and promoted antigen presentation to a similar extent. In conclusion, G3/DT is a promising adjuvant formulation that not only potentiates the antibody response induced by influenza vaccines, but also induces T cell immunity which could afford broader protection against antigenically distinct influenza viruses.     

Intraperitoneal immunization of recombinant HSP70 (DnaK) of Salmonella Typhi induces a predominant Th2 response and protective immunity in mice against lethal Salmonella infection

Heat shock proteins serve as important antigens in defense against infectious diseases. Members of HSP70 family, particularly microbial HSP70s have acquired special significance in immunity. In the present study, we evaluated the immunogenicity and protective efficacy of HSP70 of Salmonella enterica serovar Typhi against lethal infection by Salmonella in mice with or without adjuvants. The HSP70 gene was cloned and expressed in Escherichia coli BL21 and purified by affinity chromatography. Immunization of mice with HSP70 either alone or in combination with complete Freund's adjuvant (CFA) resulted in a significant increase in antibody titers as compared to control. Antibody isotyping revealed that HSP70 immunization induces both IgG1 and IgG2a antibodies to a significant extent but a higher IgG1/IgG2a ratio indicates a predominant Th2 response. There was a significant increase in lymphocyte proliferation, and levels of both Th2 and Th1 cytokines in cells isolated from immunized mice as compared to control. Immunization of mice with recombinant HSP70 either alone or in combination with CFA conferred 70-90% protection against lethal infections by Salmonella Typhi Ty2 or Salmonella Typhimurium. However, passive immunization with anti-HSP70 sera induced only partial protection in the immunized mice.     

Lipophosphoglycan-3 protein from Leishmania infantum chagasi plus saponin adjuvant: A new promising vaccine against visceral leishmaniasis

Visceral leishmaniasis (VL) is a serious neglected tropical disease that affects humans and dogs in urban areas. There are no vaccines against human VL, and few licensed canine VL vaccines are currently available, which instigates the search for new antigens and vaccine formulations with prophylactic potential against VL in these hosts. In this study, we evaluated the immunization using the native and recombinant Leishmania infantum chagasi (L. chagasi) lipophosphoglycan-3 (LPG3) and the adjuvants saponin (SAP) and incomplete Freund adjuvant (IFA) against L. chagasi infection in BALB/c mice. The native LPG3 vaccine was immunogenic, inducing splenic IFN-γ and IL-10 production, and mixed Th1/Th2 response when associated with IFA. However, only mice vaccinated with LPG3-IFA presented a reduction in the splenic parasite load (96% in comparison to the PBS control group), but without a significant reduction in the hepatic parasitism. On the other hand, mice immunized with the LPG3-SAP vaccine presented a reduction of approximately 98% in both splenic and hepatic parasite load, accompanied by a Th1/Th17 response and IL-10 production by L. chagasi antigen (AgLc)-stimulated splenic cells. Importantly, vaccination with recombinant LPG3 (rLPG3)-SAP presented similar results to the native LPG3-SAP vaccine. Therefore, the rLPG3-SAP vaccine is qualified to be used in future tests in canine and human models, considering the technical and economic advantages of the recombinant protein production compared to the native protein and the results obtained in the murine model.     

A universal virus-like particle-based vaccine for human papillomavirus: Longevity of protection and role of endogenous and exogenous adjuvants

Antibodies targeting epitopes within the amino terminus of the minor capsid protein L2 of human papillomavirus (HPV) are broadly neutralizing against diverse HPV isolates. We have constructed bacteriophage virus-like particle (VLP)-based vaccines that display short L2 peptides and elicit high-titer and broadly protective antibody responses. Here, we further characterize two additional features of these VLP-based vaccines; the longevity of protection and the role of endogenous and exogenous adjuvants on the magnitude and characteristics of the antibody response. We show that vaccinated mice have long-lived antibody responses against L2, persisting over 18 months after vaccination. Vaccinated mice were strongly protected against infection by diverse HPV pseudoviruses over a year after immunization. We also show that exogenous and endogenous adjuvants (LPS and encapsidated single-stranded RNA) have minor effects on antibody titers. Immunization with VLPs containing encapsidated ssRNA predominantly shifts the response to a Th1, rather than a Th2-like response. Importantly, immunization with L2-VLPs (without endogenous and exogenous adjuvants) in the presence of alum hydroxide elicited a robust antibody response.     

Development status and future prospects for a vaccine against Chlamydia trachomatis infection

Chlamydia trachomatis continues to be the most commonly reported sexually transmitted bacterial infection in many countries with more than 100 million new cases estimated annually. These acute infections translate into significant downstream health care costs, particularly for women, where complications can include pelvic inflammatory disease and other disease sequelae such as tubal factor infertility. Despite years of research, the immunological mechanisms responsible for protective immunity versus immunopathology are still not well understood, although it is widely accepted that T cell driven IFN-g and Th17 responses are critical for clearing infection. While antibodies are able to neutralize infections in vitro, alone they are not protective, indicating that any successful vaccine will need to elicit both arms of the immune response. In recent years, there has been an expansion in the number and types of antigens that have been evaluated as vaccines, and combined with the new array of mucosal adjuvants, this aspect of chlamydial vaccinology is showing promise. Most recently, the opportunities to develop successful vaccines have been given a significant boost with the development of a genetic transformation system for Chlamydia, as well as the identification of the key role of the chlamydial plasmid in virulence. While still remaining a major challenge, the development of a successful C. trachomatis vaccine is starting to look more likely.     

Exploring the vaccine potential of Dec-205 targeting in Mycobacterium tuberculosis infection in mice

Protein subunit vaccines are an attractive mode of immunisation against infectious diseases but the approach is hampered by the lack of suitable adjuvants for human use. We investigated if antigen targeting to the endocytic cell receptor Dec-205 on dendritic cells (DCs) could induce a protective immune response to Mycobacterium tuberculosis (MTB) infection in the absence of conventional adjuvants. Dec-205 receptor expressed by several subsets of DC has been shown in previous studies to be an efficient endocytic receptor for inducing both humoral and cellular immune responses, but this immunisation approach has not been tested in an experimental model of infection. We therefore prepared chemical conjugates of an anti-mouse Dec-205 monoclonal antibody (mAb) and the highly immunogenic antigen 85B (Ag85B) of MTB and showed that they bound efficiently to bone-marrow derived DC. Moreover, DC stimulated in vitro with Dec-205 conjugates could induce proliferation of splenocytes from Ag85B-immunised mice, while the negative control conjugates failed to do so. Following immunisation of mice with the anti-Dec-205-Ag85B conjugates administered together with a co-stimulatory anti-CD40 mAb, antigen-specific humoral and cellular responses were detected. Although the conjugates induced a strong Ag85B-specific humoral response, T cell proliferation and interferon-γ production were observed only when the conjugates were used to boost BCG vaccine. Importantly though, the conjugate vaccine did not offer significant protection against MTB challenge when used on its own or as a boost to BCG. Therefore, we conclude that Ag85B-based vaccine targeting to Dec-205 alone is not a sufficiently robust vaccination strategy for tuberculosis, although this approach might be more successful with other antigens or infections.     

Development of adjuvant nanocarrier systems for seasonal influenza A (H3N2) vaccine based on Astragaloside VII and gum tragacanth (APS)

Adjuvants are chemical/biological substances that are used in vaccines to increase the immunogenicity of antigens. A few adjuvants have been developed for use in human vaccines because of their limitations including lack of efficacy, unacceptable local or systemic toxicity, the difficulty of manufacturing, poor stability, and high cost. For that reasons, novel adjuvants/adjuvant systems are under search. Astragaloside VII (AST-VII), isolated from Astragalus trojanus, exhibited significant cellular and humoral immune responses. The polysaccharides (APS) obtained from the roots of Astragalus species have been used in traditional Chinese medicine and possess strong immunomodulatory properties. In the present study, the immunomodulatory effects of a newly developed nanocarrier system (APNS: APS containing carrier) and its AST-VII containing formulation (ANS: AST-VII + APNS), on seasonal influenza A (H3N2) vaccine were investigated. Inactivated H3N2 alone or its combinations with test compounds/formulations were intramuscularly injected into Swiss albino mice. Four weeks after immunization, the immune responses were evaluated in terms of antibody and cytokine responses as well as splenocyte proliferation. APNS demonstrated Th2 mediated response by increasing IgG1 antibody titers, whereas ANS showed response towards Th1/Th2 balance and Th17 by producing of IFN-γ, IL-17A and IgG2a. Based on these results, we propose that APNS and ANS are good candidates to be utilized in seasonal influenza A vaccines as adjuvants/carrier systems.     

Flagella hook protein FlgE is a novel vaccine candidate of Pseudomonas aeruginosa identified by a genomic approach

Infections due to Pseudomonas aeruginosa (PA) are becoming a serious threat to patients in intensive care units. A PA vaccine is a practical and economical solution to solve the problems caused by PA infection successfully. In recent years, several antigen candidates have been tested in animal and human clinical trials, but none of them has been approved to date. An alternative strategy for antigen screening and protective antigens is in urgent demand. In this study, we generated a genome-wide library of PA protein fragments tagged with maltose-binding protein (MBP). Using sera from patients who recovered after PA infection, we identified a novel protective antigen, FlgE, which is the structural component of the flagella hook. Vaccination with recombinant FlgE (reFlgE) induced a Th2-predominant immune response and reduced bacterial load and inflammation in PA-infected mice. Anti-reFlgE antibodies recognized native FlgE on the bacterial membrane in vitro and conferred protection in mice, which may be due to the mediation of opsonophagocytic killing and inhibition of bacterial motility. In addition, the combination of reFlgE with rePcrV_NH, an engineered antigen we reported previously, provided elevated protection against PA infection. Our data demonstrate that FlgE is a promising vaccine candidate for PA and provide a new strategy for the efficient screening of antigens of other pathogens.     

Identification of immunodominant antigens of Chlamydia trachomatis using proteome microarrays

Chlamydia trachomatis is the most common bacterial sexually transmitted pathogen in the world. In order to control this infection there is an urgent need to formulate a vaccine. Identification of protective antigens is required to implement a subunit vaccine. To identify potential antigen vaccine candidates, three strains of mice, BALB/c, C3H/HeN and C57BL/6, were inoculated with live and inactivated C. trachomatis mouse pneumonitis (MoPn) by different routes of immunization. Using a protein microarray, serum samples collected after immunization were tested for the presence of antibodies against specific chlamydial antigens. A total of 225 open reading frames (ORF) of the C. trachomatis genome were cloned, expressed, and printed in the microarray. Using this protein microarray, a total of seven C. trachomatis dominant antigens were identified (TC0052, TC0189, TC0582, TC0660, TC0726, TC0816 and, TC0828) as recognized by IgG antibodies from all three strains of animals after immunization. In addition, the microarray was probed to determine if the antibody response exhibited a Th1 or Th2 bias. Animals immunized with live organisms mounted a predominant Th1 response against most of the chlamydial antigens while mice immunized with inactivated Chlamydia mounted a Th2-biased response. In conclusion, using a high throughput protein microarray we have identified a set of novel proteins that can be tested for their ability to protect against a chlamydial infection.     

Immunological and physical evaluation of the multistage tuberculosis subunit vaccine candidate H56/CAF01 formulated as a spray-dried powder

Liquid vaccine dosage forms have limited stability and require refrigeration during their manufacture, distribution and storage. In contrast, solid vaccine dosage forms, produced by for example spray drying, offer improved storage stability and reduced dependence on cold-chain facilities. This is advantageous for mass immunization campaigns for global public health threats, e.g., tuberculosis (TB), and offers cheaper vaccine distribution. The multistage subunit vaccine antigen H56, which is a fusion protein of the Mycobacterium tuberculosis (Mtb) antigens Ag85B, ESAT-6, and Rv2660, has been shown to confer protective efficacy against active TB before and after Mtb exposure in preclinical models, and it is currently undergoing clinical phase 2a testing. In several studies, including a recent study comparing multiple clinically relevant vaccine adjuvants, the T helper type 1 (Th1)/Th17-inducing adjuvant CAF01 was the most efficacious adjuvant for H56 to stimulate protective immunity against Mtb. With the long-term goal of designing a thermostable and self-administrable dry powder vaccine based on H56 and CAF01 for inhalation, we compared H56 spray-dried with CAF01 with the non-spray-dried H56/CAF01 vaccine with respect to their ability to induce systemic Th1, Th17 and humoral responses after subcutaneous immunization. Here we show that spray drying of the H56/CAF01 vaccine results in preserved antigenic epitope recognition and adjuvant activity of CAF01, and the spray-dried, reconstituted vaccine induces antigen-specific Th1, Th17 and humoral immune responses, which are comparable to those stimulated by the non-spray-dried H56/CAF01 vaccine. In addition, the spray-dried and reconstituted H56/CAF01 vaccine promotes similar polyfunctional CD4⁺ T-cell responses as the non-spray-dried vaccine. Thus, our study provides proof-of-concept that spray drying of the subunit vaccine H56/CAF01 preserves vaccine-induced humoral and cell-mediated immune responses. These results support our ongoing efforts to develop a thermostable, dry powder-based TB vaccine.     

Characterization of protective immune responses promoted by human antigen targets in a urogenital Chlamydia trachomatis mouse model

A vaccine against genital tract infections caused by Chlamydia trachomatis is urgently needed. We have previously identified a number of immunodominant human T- and/or B-cell antigen targets in patients with a C. trachomatis infection. Herein we use a urogenital C. trachomatis mouse model to investigate the protective efficacy of these antigens. C3H/HeN mice were immunized with recombinant antigens formulated in the adjuvant CAF01. Immunity post vaccination was analyzed and the protective efficacy against vaginal challenge with C. trachomatis was monitored by vaginal swabbing. All antigens elicited a significant immune response when administered in CAF01 but the balance between CMI and humoral responses differed markedly for the different antigens. Six (CT443, CT043, CT858, CT610, CT004 and CT681) antigens were found to be protective. We demonstrated by T-cell depletion studies that the protection promoted by the two antigens CT043 and CT004 was mediated by CD4⁺ T-cells. Both antigens are frequently recognized by T-cells during a natural Chlamydia infection in humans and if included in a future multi-component Chlamydia vaccine probably would operate mainly through the induction of a CMI response.     

Gastric eosinophils are detrimental for Helicobacter pylori vaccine efficacy

Helicobacter pylori (Hp) colonizes the human gastric mucosa with a high worldwide prevalence. Currently, Hp can be eradicated by the use of antibiotics. Due to the increase of antibiotic resistance, new therapeutic strategies need to be devised: one such approach being prophylactic vaccination. Pre-clinical and clinical data showed that a urease-based vaccine is efficient in decreasing Hp infection through the mobilization of T helper (Th)-dependent immune effectors, including eosinophils. Preliminary data have shown that upon vaccination and subsequent Hp infection, eosinophils accumulate in the gastric mucosa, suggesting a possible implication of this granulocyte subset in the vaccine-induced reduction of Hp infection.In our study, we confirm that activated eosinophils, expressing CD63, CD40, MHCII and PD-L1 at their cell surface, infiltrate the gastric mucosa during vaccine-induced reduction of Hp infection. Strikingly, we provide evidence that bone marrow derived eosinophils efficiently kill Hp in vitro, suggesting that eosinophils may participate to the vaccine-induced reduction of Hp infection. However, conversely to our expectations, the absence of eosinophils does not decrease the efficacy of this Hp vaccine in vivo. Indeed, vaccinated mice that have been genetically ablated of the eosinophil lineage or that have received anti-Sialic acid-binding immunoglobulin-like lectin F eosinophil-depleting antibodies, display a lower Hp colonization when compared to their eosinophil sufficient counterparts. Although the vaccine induces similar urease-specific humoral and Th responses in both eosinophil sufficient and deficient mice, a decreased production of anti-inflammatory cytokines, such as IL-10, TGFβ, and calgranulin B, was specifically observed in eosinophil depleted mice.Taken together, our results suggest that gastric eosinophils maintain an anti-inflammatory environment, thus sustaining chronic Hp infection. Because eosinophils are one of the main immune effectors mobilized by Th2 responses, our study strongly suggests that the formulation of an Hp vaccine needs to include an adjuvant that preferentially primes Hp-specific Th1/Th17 responses.     

The Ag85B protein of the BCG vaccine facilitates macrophage uptake but is dispensable for protection against aerosol Mycobacterium tuberculosis infection

Defining the function and protective capacity of mycobacterial antigens is crucial for progression of tuberculosis (TB) vaccine candidates to clinical trials. The Ag85B protein is expressed by all pathogenic mycobacteria and is a component of multiple TB vaccines under evaluation in humans. In this report we examined the role of the BCG Ag85B protein in host cell interaction and vaccine-induced protection against virulent Mycobacterium tuberculosis infection. Ag85B was required for macrophage infection in vitro, as BCG deficient in Ag85B expression (BCG:^Δ85B) was less able to infect RAW 264.7 macrophages compared to parental BCG, while an Ag85B-overexpressing BCG strain (BCG:^oex85B) demonstrated improved uptake. A similar pattern was observed in vivo after intradermal delivery to mice, with significantly less BCG:^Δ85B present in CD64^hiCD11b^hi macrophages compared to BCG or BCG:^oex85B. After vaccination of mice with BCG:^Δ85B or parental BCG and subsequent aerosol M. tuberculosis challenge, similar numbers of activated CD4⁺ and CD8⁺ T cells were detected in the lungs of infected mice for both groups, suggesting the reduced macrophage uptake observed by BCG:^Δ85B did not alter host immunity. Further, vaccination with both BCG:^Δ85B and parental BCG resulted in a comparable reduction in pulmonary M. tuberculosis load. These data reveal an unappreciated role for Ag85B in the interaction of mycobacteria with host cells and indicates that single protective antigens are dispensable for protective immunity induced by BCG.     

Characterization of the immune response induced by pertussis OMVs-based vaccine

For the development of a third generation of pertussis vaccine that could improve the control of the disease, it was proposed that the immune responses induced by the classic whole cell vaccine (wP) or after infection should be used as a reference point. We have recently identified a vaccine candidate based on outer membrane vesicles (OMVs) derived from the disease etiologic agent that have been shown to be safe and protective in mice model of infection. Here we characterized OMVs-mediated immunity and the safety of our new candidate. We also deepen the knowledge of the induced humoral response contribution in pertussis protection. Regarding the safety of the OMVs based vaccine (Tdap_OMVsBp,) the in vitro whole blood human assay here performed, showed that the low toxicity of OMVs-based vaccine previously detected in mice could be extended to human samples.Stimulation of splenocytes from immunized mice evidenced the presence of IFN-γ and IL-17-producing cells, indicated that OMVs induces both Th1 and Th17 response. Interestingly Tdap_OMVsBp-raised antibodies such as those induced by wP and commercial acellular vaccines (aP) which contribute to induce protection against Bordetella pertussis infection. As occurs with wP-induced antibodies, the TdapOMVsBp-induced serum antibodies efficiently opsonized B. pertussis. All the data here obtained shows that OMVs based vaccine is able to induce Th1/Th17 and Th2 mixed profile with robust humoral response involved in protection, positioning this candidate among the different possibilities to constitute the third generation of anti-pertussis vaccines.     

Genetic background impacts vaccine-induced reduction of pneumococcal colonization

Vaccination has been one of the most successful strategies to reduce morbidity and mortality caused by respiratory infections. Recent evidence suggests that differences in the host genetic background and environmental factors may contribute to heterogeneity in the immune response to vaccination. During pre-clinical testing, vaccines are often evaluated in a single mouse inbred strain, which may not translate well to the heterogeneous human population. Here, we examined the influence of host genetic background on vaccine-induced protection against pneumococcal colonization in two commonly used inbred mouse strains, i.e. C57BL/6 and BALB/c as well as the F1 cross of these two strains. Groups of mice were vaccinated intranasally with a vaccine formulation containing a model pneumococcal antigen, i.e. pneumococcal surface protein A (PspA), adjuvanted with cholera toxin subunit B (CTB). Even in the absence of vaccination, differences in colonization density were observed between mouse strains. Although vaccination significantly reduced pneumococcal density in all mouse strains, differences were observed in the magnitude of protection. We therefore examined immunological parameters known to be involved in vaccine-induced mucosal clearance of S. pneumoniae. We found that PspA-specific IgG levels in nasal tissue differed between mouse strains, but in all cases it correlated significantly with a reduction in colonization. Furthermore, increased mucosal IL17A, but not IFNγ, IL10, or IL4, was found to be mouse strain specific. This suggests that the reduction of bacterial load may be accompanied by a Th17 response in all genetic backgrounds, although the cytokine dynamics may differ. Increased insight into the different immune mechanisms that affect pneumococcal carriage will contribute to development of future vaccines against S. pneumoniae     

Recent advances in recombinant protein-based malaria vaccines

Plasmodium parasites are the causative agent of human malaria, and the development of a highly effective vaccine against infection, disease and transmission remains a key priority. It is widely established that multiple stages of the parasite's complex lifecycle within the human host and mosquito vector are susceptible to vaccine-induced antibodies. The mainstay approach to antibody induction by subunit vaccination has been the delivery of protein antigen formulated in adjuvant. Extensive efforts have been made in this endeavor with respect to malaria vaccine development, especially with regard to target antigen discovery, protein expression platforms, adjuvant testing, and development of soluble and virus-like particle (VLP) delivery platforms. The breadth of approaches to protein-based vaccines is continuing to expand as innovative new concepts in next-generation subunit design are explored, with the prospects for the development of a highly effective multi-component/multi-stage/multi-antigen formulation seeming ever more likely. This review will focus on recent progress in protein vaccine design, development and/or clinical testing for a number of leading malaria antigens from the sporozoite-, merozoite- and sexual-stages of the parasite's lifecycle–including PfCelTOS, PfMSP1, PfAMA1, PfRH5, PfSERA5, PfGLURP, PfMSP3, Pfs48/45 and Pfs25. Future prospects and challenges for the development, production, human delivery and assessment of protein-based malaria vaccines are discussed.     

Expression,purification, immunogenicity,and protective efficacy of a recombinant Tc24 antigen as a vaccine against Trypanosoma cruzi infection in mice

The Tc24 calcium binding protein from the flagellar pocket of Trypanosoma cruzi is under evaluation as a candidate vaccine antigen against Chagas disease. Previously, a DNA vaccine encoding Tc24 was shown to be an effective vaccine (both as a preventive and therapeutic intervention) in mice and dogs, as evidenced by reductions in T. cruzi parasitemia and cardiac amastigotes, as well as reduced cardiac inflammation and increased host survival. Here we developed a suitable platform for the large scale production of recombinant Tc24 (rTc24) and show that when rTc24 is combined with a monophosphoryl-lipid A (MPLA) adjuvant, the formulated vaccine induces a Th1-biased immune response in mice, comprised of elevated IgG2a antibody levels and interferon-gamma levels from splenocytes, compared to controls. These immune responses also resulted in statistically significant decreased T. cruzi parasitemia and cardiac amastigotes, as well as increased survival following T. cruzi challenge infections, compared to controls. Partial protective efficacy was shown regardless of whether the antigen was expressed in Escherichia coli or in yeast (Pichia pastoris). While mouse vaccinations will require further modifications in order to optimize protective efficacy, such studies provide a basis for further evaluations of vaccines comprised of rTc24, together with alternative adjuvants and additional recombinant antigens.     

Leptosome-entrapped leptospiral antigens conferred significant higher levels of protection than those entrapped with PC-liposomes in a hamster model

We prepared novel liposomes from total polar lipids of non-pathogenic Leptospira biflexa serovar Potac (designated leptosomes) and evaluated their vaccine delivery/adjuvant potential with novel protective antigens (Lp0607, Lp1118 and Lp1454) of L. interrogans serovar Pomona in a hamster model. The immune response induced by three individual antigens and protective efficacy were evaluated and compared to those induced by same antigens entrapped with PC-liposomes and E. coli lipid liposomes (escheriosomes). Four-week-old hamsters were immunized subcutaneously twice at a 3-week interval, bled at various time points to evaluate antibody response and sacrificed to isolate splenocytes for lymphocyte proliferation and cytokine profiles in response to recall antigen. For the challenge test, 10× MLD₅₀ (modified lethal dose 50%) of virulent L. interrogans serovar Pomona were administered intraperitoneally. Our results demonstrate that leptosome are better adjuvant than PC-liposomes as revealed by enhanced long term antibody response, lymphocyte proliferation and significant enhancement of both Th1 (IFN-γ) and Th2 (IL-4 and IL-10) cytokines. Additionally, leptosomes and escheriosomes induced significantly higher level of memory responses than PC-liposome did. Moreover, the novel leptosomal vaccine induced significantly higher levels of protection than those prepared with PC-liposomes as revealed by enhanced survival, reduced histopathological lesions in vital organs and reduced leptospiral load in kidneys. Taken together, the results of the present study clearly reveal that both leptosomes and escheriosomes have emerged as promising delivery vehicles/adjuvants that can be widely exploited with newly discovered antigens in future leptospira vaccines.