Leishmania donovani: identification of novel vaccine candidates using human reactive sera and cell lines

Leishmaniasis is a complex of diseases caused by protozoan parasites belonging to the genus Leishmania. The development of specific resistance against re-infection after cure suggests that a vaccine approach is feasible. Various studies in humans and experimental animals strongly suggest that Th1 type of cell-mediated immune response is important for protection against the disease. A defined antigen that could elicit a specific T-cell-mediated immune response in the host would be an ideal candidate for the vaccine against this parasite. In order to select a candidate antigen, we established a screening system to identify the recombinant clone, expressing antigen having T-cell epitopes from a cDNA library. We screened the library using an established Leishmania specific cell line (LSCL) from a naive healthy human subject. The cell line with predominantly CD4+ cells behaved in a Leishmania specific manner. Fifty-two immuno-reactive clones were screened against the LSCL in vitro and we identified three cDNA clones expressing recombinant antigens that could induce proliferation of these cells to produce INFgamma. The protective efficacy of one of these recombinant proteins was investigated in a hamster model of experimental visceral leishmaniasis and showed protection against a virulent challenge. The identified antigens might be potential candidates for vaccine against Leishmania.     

Identification of novel Leishmania major antigens that elicit IgG2a response in resistant and susceptible mice

Experimental murine models with high, intermediate and low levels of genetically based susceptibility to Leishmania major infection reproduce almost entire spectrum of clinical manifestations of the human disease. There are increasing non-comparative studies on immune responses against isolated antigens of L. major in different murine strains. The aim of the present study was to find out whether there is an antigen that can induce protective immune response in resistant and susceptible murine strains. To do that, crude antigenic extract of procyclic and metacyclic promastigotes of L. major was prepared and subjected to SDS-PAGE electrophoresis. Western-blotting was used to search for antigen(s) capable of raising high antibody level of IgG2a versus IgG1 in the sera of both infected resistant and susceptible strains. Two novel antigens from metacyclic promastigotes of L. major (140 and 152 kDa) were potentially able to induce specific dominant IgG2a responses in BALB/c and C57BL/6 mice. The 2 antigens also reacted with IgG antibody of cutaneous leishmaniasis patients. We confirm that 140 and 152 kDa proteins of L. major promastigotes are inducing IgG production in mice and humans.     

Oral Salmonella typhimurium (AroA-) vaccine expressing a major leishmanial surface protein (gp63) preferentially induces T helper 1 cells and protective immunity against leishmaniasis

The gp63 gene of Leishmania major was transformed into the AroA- vaccine strain of Salmonella typhimurium (SL3261). The construct (SL3261-gp63), which stably expresses the gp63 Ag in vitro, was used to immunize CBA mice by the oral route. Spleen cells from mice inoculated with SL3261-gp63 developed antibody and proliferative T cell response to L. major. They did not express detectable delayed-type hypersensitivity reactivity. The activated T cells are mainly CD4+ and secrete IL-2 and IFN-gamma but no IL-4. The orally immunized mice developed significant resistance against a challenge L. major infection. We have, therefore, demonstrated the feasibility of oral vaccination against leishmaniasis and that the oral route of antigen delivery via the heterologous carrier may preferentially induce Th1 subsets of CD4+ cells.     

Characterization of the immune response to Leishmania infantum recombinant antigens

Leishmaniases have a high prevalence in tropical countries. In order to improve existing diagnostic systems based on total Leishmania proteins, and to identify antigen candidates for vaccine development, an intensive search for the identification of antigens was performed using molecular biology techniques. In this study, the immune response to three L. infantum recombinant antigens was evaluated. Upon stimulation with KMP11, mononuclear cells from leishmaniasis patients produced high levels of IL-10, while a predominant IFN-gamma production could be observed in cultures stimulated with H2A and soluble Leishmania antigen. All the recombinant antigens induced very little IL-5. KMP11 decreased IFN-gamma production by 48% in cultures of peripheral blood mononuclear cells from cutaneous leishmaniasis patients who had been stimulated with soluble Leishmania antigen. Furthermore, antibodies to KMP11 were detected in the sera from all patients with visceral leishmaniasis and in the majority of the sera from patients with cutaneous leishmaniasis or individuals with asymptomatic L. chagasi infection. Thus, KMP11 is recognized by cells and sera of patients with different clinical forms of leishmaniasis, and KMP11, through IL-10 production, proved to be a potent antigen in modulating type 1 immune response.     

Second-generation vaccines against leishmaniasis

Several species of Leishmania cause human diseases that range from self-healing cutaneous lesions to fatal visceral leishmaniasis, mucosal leishmaniasis and diffuse cutaneous leishmaniasis. Drug resistance and toxicities associated with chemotherapy emphasize the need for a safe, effective vaccine. Studies of the immunopathogenesis and mechanisms of protective immunity define several features that should be met by an effective vaccine. The leishmaniases are unique among parasitic diseases because a single vaccine has the potential to protect against more than one species (disease) and be successful at both treating and preventing disease. In addition, several antigens have been identified and characterized that might be potential vaccine candidates. In this article, we focus on advances made with second-generation vaccines against leishmaniasis.     

A gp63 based vaccine candidate against Visceral Leishmaniasis

Visceral leishmaniasis is a macrophage associated disorder which leads to a profound decrease in the natural immunotherapeutic potential of the infected subjects to combat the disease. The major surface glycoprotein gp63 has been found to be a significant vaccine candidate against visceral leishmaniasis. The current study addresses the levels of similarity and identity in the gp63 obtained from different species of Leishmania viz donovoni, chagasi and infantum linked to the cause of visceral leishmaniasis. The results from BLAST, Phylogram and Cladogram studies indicate significant identity, similarity and conservation of important residues in the protein which lead us to conclude that a common gp63 based vaccine can be used as a therapeutical tool against visceral leishmaniasis caused by different species strains of leishmania.     

A strategy for identifying serodiagnostically relevant antigens of Leishmania or other pathogens in genetic libraries.

Different individuals, when infected with the same parasite, rarely produce antibodies against the same set of antigens. Indeed, unless a particular antigen happens to be recognized by antibodies in all individuals, the use of a single antigen in the serodiagnosis of parasitic diseases leads, invariably, to false-negative results. A straightforward method for pin-pointing, in genetic libraries, the precise antigens that would increase serodiagnostic assay sensitivities is presented. The method is based on the utilization of sera that produced false-negative results against previously available antigens. Employing this false-negative serum-selection methodology for the identification of new Leishmania infantum recombinant antigens (rAgs), the sensitivity of a dipstick assay for anti-Leishmania antibodies in a panel of sera from patients with visceral leishmaniasis was increased from 83.3% to 98.1%, without affecting its specificity, by the inclusion of a fifth and a sixth L. infantum rAg.     

The Leishmania promastigote surface antigen-2 (PSA-2) is specifically recognised by Th1 cells in humans with naturally acquired immunity to L. major

The promastigote surface antigen-2 (PSA-2) is a Leishmania parasite antigen, which can induce Th1-mediated protection against murine leishmaniasis when used as a vaccine. To evaluate PSA-2 as a human vaccine candidate the specific T-cell response to PSA-2 was characterised in individuals immune to cutaneous leishmaniasis. Peripheral blood mononuclear cells from Sudanese individuals with a past history of self-healing cutaneous leishmaniasis proliferated vigorously in response to PSA-2 isolated from Leishmania major, whereas the antigen did not activate cells from presumably unexposed Danes. Peripheral blood mononuclear cells from individuals with previous L. major infection had varying proliferative responses to PSA-2 derived from L. donovani promastigotes. Peripheral blood mononuclear cells activated by PSA-2 from L. major produced high amounts of interferon-γ and tumour necrosis factor-β, and little interleukin-4, thereby showing a Th1 cytokine pattern. Parallel cultures showed clear Th1 and Th2 response patterns to purified protein derivative of tuberculin or tetanus toxoid, respectively. Flow cytometric analysis revealed that PSA-2 induced blastogenesis in the CD3 positive population and that these cells were the major source of interferon-γ. The results show that Th1-like cells recognising PSA-2 are expanded during infection by L. major and that they maintain their Th1-like cytokine profile upon reactivation in vitro. Since immunity to cutaneous leishmaniasis is mediated by antigen-specific Th1-like cells, PSA-2 might be considered a vaccine candidate for human leishmaniasis.     

A proteogenomic approach to map the proteome of an unsequenced pathogen - Leishmania donovani

Visceral leishmaniasis or kala azar is the most severe form of leishmaniasis and is caused by the protozoan parasite Leishmania donovani. There is no published report on L. donovani genome sequence available till date, although the genome sequences of three related Leishmania species are already available. Thus, we took a proteogenomic approach to identify proteins from two different life stages of L. donovani. From our analysis of the promastigote (insect) and amastigote (human) stages of L. donovani, we identified a total of 22,322 unique peptides from a homology-based search against proteins from three Leishmania species. These peptides were assigned to 3711 proteins in L. infantum, 3287 proteins in L. major, and 2433 proteins in L. braziliensis. Of the 3711 L. donovani proteins that were identified, the expression of 1387 proteins was detectable in both life stages of the parasite, while 901 and 1423 proteins were identified only in promastigotes and amastigotes life stages, respectively. In addition, we also identified 13 N-terminally and one C-terminally extended proteins based on the proteomic data search against the six-frame translated genome of the three related Leishmania species. Here, we report results from proteomic profiling of L. donovani, an organism with an unsequenced genome.     

Leishmania major: immune response in BALB/c mice immunized with stress-inducible protein 1 encapsulated in liposomes

Protection against leishmaniasis is depending upon generation of a Th1 type of immune response. Field trials of first generation Leishmania vaccine showed a limited efficacy even with multiple doses mainly due to lack of an appropriate adjuvant. In this study, susceptible BALB/c mice were immunized with rLmSTI1 encapsulated in liposomes to explore the extent of protection induced by Leishmania antigen encapsulated in the liposomes against challenge with Leishmania major. The results showed that s.c. immunization of BALB/c mice with liposomal rLmSTI1 induced a significant protection against challenge and a significant lower parasite burden in spleen up to 14 weeks after challenge. The protected animals showed a significantly smaller footpad thickness after challenge, and a higher level of anti-SLA IgG antibodies before and after challenge with a predominant IgG2a titer. The data supports the possibility of using liposomal Leishmania antigens as a vaccine.     

Purification and biochemical characterization of two novel antigens from Leishmania major promastigotes

The identification and characterization of antigens that elicit human T cell responses is an important step toward understanding of Leishmania major infection and ultimately in the development of a vaccine. Micropreparative SDS-PAGE followed by electrotransfer to a PVDF membrane and elution of proteins from the PVDF, was used to separate 2 novel proteins from L. major promastigotes, which can induce antibodies of the IgG2a isotype in mice and also are recognized by antisera of recovered human cutaneous leishmaniasis subjects. Fractionation of the crude extract of L. major revealed that all detectable proteins of interest were present within the soluble Leishmania antigens (SLA). Quantitation of these proteins showed that their expression in promastigotes is relatively very low. Considering the molecular weight, immunoreactivity, chromatographic and electrophoretic behavior in reducing and non-reducing conditions, these proteins are probably 2 isoforms of a single protein. A digest of these proteins was resolved on Tricine-SDS-PAGE and immunoreactive fragments were identified by human sera. Two immunoreactive fragments (36.4 and 34.8 kDa) were only generated by endoproteinase Glu-C treatment. These immunoreactive fragments or their parent molecules may be ideal candidates for incorporation in a cocktail vaccine against cutaneous leishmaniasis.     

Species and stage specificity of Leishmania donovani antigens.

Monoclonal antibodies D2 and D13 were produced in mice using Leishmania donovani promastigote membrane fractions. To study the species and stage specificity of the antigens recognized by these antibodies, we examined amastigotes prepared in vitro and cultured promastigotes by indirect immunofluorescence with monoclonal antibodies D2 and D13. Monoclonal antibody D2 showed weak reactivity for 9 of 9 strains of L. donovani complex promastigotes and 8 of 9 amastigotes. In contrast, only 2 of 22 strains from other complexes yielded equivocal reactions. Monoclonal antibody D13, however, had much broader reactivity. D13 reacted with all the promastigotes and amastigotes of L. donovani complex isolates as well as with 10 of 22 promastigotes and 8 of 13 amastigotes from other complexes. The high degree of species specificity seen with monoclonal antibody D2 provides a rationale for further study of this antibody and its purified antigen for parasite identification and serodiagnosis of visceral leishmaniasis. The strong fluorescent signal noted with D13 and the presence of the D13 epitope on all L. donovani complex parasites supports studies on its role as an antigen in immunoprophylaxis of visceral leishmaniasis.     

Bivalent Vaccines Against Bacterial Enteropathogens: Construction of Live Attenuated Vaccine Strains With Two O-Serotype Specificities

Abstract. A considerable interest exists worldwide in the development of live attenuated oral vaccines against diarrhoeal diseases. In addition to vaccination against the corresponding pathogens, such vaccine strains can be used as carriers for the expression of protective antigens from other organisms. The antigenic repertoire of a given vaccine strain may thereby be extended, potentially leading to a bivalent vaccine. The lipopolysaccharide is known to be a major antigenic surface component of bacterial enteric pathogens. The feasibility of the development of combined vaccines based on live attenuated carriers expressing two O-serotype specificities is illustrated here by the development of candidate live oral vaccines against Shigella sonnei using Salmonella typhi and Vibrio cholerae as carriers. Various factors that may limit the potential of such hybrid strains as bivalent vaccines are discussed.     

Molecular and immunological characterisation of the glucose regulated protein 78 of Leishmania donovani(1)

To identify novel potential Leishmania vaccine antigens, antibodies from patients with visceral leishmaniasis (VL) were used to isolate clones from a cDNA expression library of L. donovani amastigotes. Glucose Regulated Protein (GRP78), a member of the 70 kDa heat-shock protein family was identified and characterised. The GRP78 gene was localised to chromosome 15 in L. donovani, L. major, and L. mexicana by pulse-field gel electrophoresis. The Leishmania GRP78 protein contain a carboxy-terminal endoplasmic reticulum retention signal sequence (MDDL) as does the Trypanosoma cruzi GRP78. Immunofluorescence using antibodies to the recombinant DNA-derived GRP78 protein showed staining localised to reticular material throughout the cytoplasm and in the perinuclear region of promastigotes, suggesting that the protein is localised in the endoplasmic reticulum. The protective efficacy of GRP78 was assessed in mice vaccine experiments. A GRP78 DNA vaccine primed for an immune response that protected C57Bl/6 and C3H/He mice against infection with L. major. Similarly vaccination with a recombinant form of GRP78 purified from Escherichia coli and administered with Freund's as adjuvant induced protective immunity in C57Bl/6 mice.     

The development of oral vaccines based on live attenuated Salmonella strains

Abstract Safe, live attenuated Salmonella strains can be produced by introducing defined non-reverting mutations into the chromosome. Such rationally attenuated strains have proved to be excellent oral vaccines in several animal species and can therefore be considered as candidate vaccines against invasive salmonellosis in both animals and man. A panel of attenuating lesions is now available from which it is possible to tailor the level of attenuation and hence produce strains with different immunogenic properties. Because of the spectrum of immune responses produced by such Salmonella vaccine strains they have been utilised extensively as vectors for delivering heterologous antigens to the mammalian immune system. We have focussed on the development of a single dose oral tetanus vaccine based on attenuated Salmonella strains expressing a non-toxic, immunogenic protein derived from tetanus toxin (fragment C). Several different expression systems have been used for fragment C and candidate vaccine strains have been constructed that are capable of protecting orally immunised mice against a lethal challenge with tetanus toxin. An oral tetanus vaccine may help to reduce the mortality rate from tetanus in the developing world by overcoming the problems associated with the implementation of vaccine programmes using the current parenteral vaccine.     

Performance of LBSap Vaccine after Intradermal Challenge with L. infantum and Saliva of Lu. longipalpis: Immunogenicity and Parasitological Evaluation

In the last decade, the search for new vaccines against canine visceral leishmaniasis has intensified. However, the pattern related to immune protection during long periods after experimental infection in vaccine trials is still not fully understood. Herein, we investigated the immunogenicity and parasitological levels after intradermal challenge with Leishmania infantum plus salivary gland extract in dogs immunized with a vaccine composed of L. braziliensis antigens plus saponin as an adjuvant (LBSap vaccine). The LBSap vaccine elicited higher levels of total anti-Leishmania IgG as well as both IgG1 and IgG2. Furthermore, dogs vaccinated had increased levels of lymphocytes, particularly circulating B cells (CD21⁺) and both CD4⁺ and CD8⁺ T lymphocytes. LBSap also elicited an intense in vitro cell proliferation associated with higher levels of CD4⁺ T lymphocytes specific for vaccine soluble antigen and soluble lysate of L. infantum antigen even 885 days after experimental challenge. Furthermore, LBSap vaccinated dogs presented high IFN-γ and low IL-10 and TGF-β1 expression in spleen with significant reduction of parasite load in this tissue. Overall, our results validate the potential of LBSap vaccine to protect against L. infantum experimental infection and strongly support further evaluation of efficiency of LBSap against CVL in natural infection conditions.     

Leishmaniasis: current status of vaccine development

Leishmaniasis, a spectrum of diseases caused by various forms of Leishmania has become a major health problem all over the world. Vaccination against leishmaniasis has passed through many developmental stages beginning with the ancient practice of 'leishmanization'. Due to various problems and difficulties associated with traditional vaccines, the interest has been shifted to novel approaches of vaccination like DNA vaccination, vaccination with live vectors encoding leishmanial antigens and finally to designer vaccines. In an effort towards developing an anti-leishmanial vaccine, our laboratory has been working on various genes present in an amplified locus of Leishmania known as the 'LD1 locus'. Two genes, ORFF and BT1 (previously ORFG), are part of the multigenic LD1 locus on chromosome 35. BT1 encodes a biopterin transporter, while the function of ORFF gene product is unknown. Immunization of mice with recombinant ORFF (rORFF) and BT1 proteins, individually, or in combination, conferred partial protection against challenge with Leishmania donovani. We also tested the protective efficacy of ORFF DNA vaccine in BALB/c mice model and found that the level of protection was significantly higher than that of ORFF protein. Protection conferred by ORFF DNA vaccine correlated with significant levels of in vitro splenocyte proliferation and low levels of antigen-specific antibodies. There was a preferential production of IFN-gamma compared to IL-4, which indicated the induction of a protective Th1 response, by the DNA vaccine. Thus, DNA immunization may offer an attractive alternative strategy against leishmaniasis. We present here the current status of vaccine development against leishmaniasis.     

Production and characterization of species-specific monoclonal antibodies against Leishmania donovani for immunodiagnosis

Sixteen species-specific monoclonal antibodies were produced against membranes of Leishmania donovani. These antibodies only reacted with determinants present on L. donovani. No cross-reactions were found with any other species of Leishmania or with membranes of Trypanosoma cruzi. An extensive analysis of the binding specificities of selected antibodies was carried out by using whole promastigote homogenates as antigen. Monoclonal antibodies D-1, D-2, D-3, and D-4 correctly identified all 44 L. donovani stocks from a cross-panel of 84 New and Old World Leishmania stocks. Antibodies D-1 and D-2 were also useful for species classification by immunofluorescence. No cross-reactions were observed with any other Leishmania species examined. Based on either Western blot and/or radioimmunoprecipitation analyses, five distinct groups of molecules associated with L. donovani-specific antigenic determinants were identified. These molecules range in m.w. from 18 to 84 kilodaltons. The antigenic molecules recognized by antibodies D-2, D-10, and D-13 are also recognized by antibodies present in sera from patients with visceral leishmaniasis (kala-azar). Kala-azar sera obtained from cases in both the Old and New World specifically compete with these monoclonal antibodies for the appropriate antigenic determinants in Western blot analysis. These monoclonal antibodies and/or the purified protein antigens may be useful in the development of a serologic assay for the clinical diagnosis of visceral leishmaniasis caused by L. donovani and in epidemiologic studies of leishmaniasis.     

Vaccination with recombinant Leishmania donovani gamma-glutamylcysteine synthetase fusion protein protects against L. donovani infection

Visceral leishmaniasis presents a serious health threat in many parts of the world. There is, therefore, an urgent need for an approved vaccine for clinical use to protect against infection. In this study, the ability of recombinant Leishmania donovani gamma-glutamyl cysteine synthetase protein (LdγGCS) alone or incorporated into a non-ionic surfactant vesicle (NIV) delivery system to protect against L. donovani infection was evaluated in a BALB/c mouse model. Immunization with LdγGCS alone or LdγGCS-NIV induced specific IgG1 and IgG2a antibodies compared to controls, with LdγGCS-NIV inducing significantly higher titers of both antibody classes (P < 0.05). Both formulations induced similar increases in splenocyte IFN-γ production following ex vivo antigen stimulation with LdγGCS compared with cells from control mice (P < 0.05). Similar levels of protection against infection were induced by LdγGCS alone and LdγGCS-NIV, based on their ability to suppress liver parasite burdens compared to control values (P < 0.01), indicating that using a carrier system did not enhance the protective responses induced by the recombinant protein. The results of this study indicate that LdγGCS may be a useful component in a vaccine against L. donovani.     

Intracellular bacteria as targets and carriers for vaccination

In this review we discuss intracellular bacteria as targets and carriers for vaccines. For clarity and ease of comprehension, we focus on three microbes, Mycobacterium tuberculosis, Listeria monocytogenes and Salmonella, with an emphasis on tuberculosis, one of the leading causes of death from infectious disease. Novel vaccination strategies against these pathogens are currently being considered. One approach favors the use of live attenuated vaccines and vaccine carrier strains thereof, either for heterologous antigen presentation or DNA vaccine delivery. This strategy includes both the improvement of attenuated vaccine strains as well as the 'de novo' generation of attenuated variants of virulent pathogens. An alternative strategy relies on the application of subunit immunizations, either as nucleic acid vaccines or protein antigens of the pathogen. Finally, we present a short summary of the vaccination strategies against tuberculosis.