Comparing the effect of IL-12 genetic adjuvant and alum non-genetic adjuvant on the efficiency of the cocktail DNA vaccine containing plasmids encoding SAG-1 and ROP-2 of Toxoplasma gondii.

Various methods are available for enhancing the potency of DNA vaccines, including employment of different forms of adjuvant. The current study was carried out to evaluate and compare the effects of genetic and non-genetic adjuvants on the immune response stimulated by DNA vaccine. Thus, two adjuvants, IL-12 (genetic adjuvant) and aluminum hydroxide (alum, non-genetic adjuvant), were used with cocktail DNA vaccine containing plasmids encoding complete rhoptry antigen 2 (ROP-2) and surface major antigen 1 (SAG-1) of Toxoplasma gondii. The efficacy of pcROP2+pcSAG1 in stimulation of the immune response against toxoplasmosis with and without adjuvant was evaluated in female BALB/c mice by measuring the level of total IgG antibody and cytokines. The results obtained indicated that after challenging the mice with the fatal RH strain of T. gondii, the survival rates of mice immunized with pcROP2+pcSAG1 (DNA cocktail), pcSAG1+pcROP2+alum, and pcSAG1+pcROP2+IL-12 were significantly greater than that of the control groups (p<0.05). Moreover, measurement of total IgG antibody indicated the significant difference between the control and experimental groups (p<0.05). Finally, the results obtained by measurement of cytokines (IFN-γ and IL-4) showed high levels of IFN-γ and low levels of IL-4 in groups vaccinated with pcROP2+pcSAG1 (DNA cocktail), pcSAG1+pcROP2+alum, and pcSAG1+pcROP2+IL-12 as the experiment groups, in comparison with the controls groups (PBS, pc-DNA3, alum+PBS, and pCAGGS-IL-12+pcDNA3). The results of the study showed that use of adjuvants (IL-12 and alum) coincident with DNA cocktail leads to significant change in the survival rates of the experiment groups in comparison with control groups. Also, there is no significant difference between adjuvants to induce immune responses.

Modulation of early ß-defensin-2 production as a mechanism developed by type I Toxoplasma gondii to evade human intestinal immunity.

We investigated the early innate immune responses induced in human intestinal epithelial cells (IEC) by the three defined Toxoplasma gondii genotype strains. Transcriptome analysis revealed that among differentially expressed genes, ß-defensins distinguished the most IEC infected by fast- or slow-replicating T. gondii genotypes. Although ß-defensin 1 and 3 genes were not expressed in host cells at early time points postinfection, the slow-replicating type II and III parasites induced high levels of ß-defensin 2 gene expression. Notably, no ß-defensin 2 gene expression occurred early after infection with the fast-replicating type I parasite. However, activation of this gene in IEC by poly(I:C) treatment prior to infection substantially decreased parasite viability, and pretreatment of parasites with synthetic ß-defensin 2 significantly reduced their infectivity of IEC. These findings strongly support the modulation of early ß-defensin 2 expression as a mechanism used by type I T. gondii parasites to mediate immune evasion.

Culture filtrate specific H-2(b) restricted CD8+ T cells activated in vivo by Mycobacterium tuberculosis or bovis BCG recognize a restricted number of immunodominant peptides.

We previously demonstrated that Bacillus Calmette-Guerin (BCG) immunization activated D(b) restricted CD8+ cytolytic T lymphocyte (CTL) recognizing target cells incubated with mycobacterial culture filtrate. Here, we show that in vitro restimulation of spleen cells from BCG vaccinated or Mycobacterium tuberculosis infected mice with culture filtrate antigens leads to the appearance of a high percentage of D(b) restricted IFNgamma synthesizing CD8+ T cell blasts. Transporter associated protein-2 mutated RMA-S cells incubated with soluble culture filtrate proteins had their MHC class I D(b) but not K(b) molecules stabilized at the surface indicating that only D(b) ligands might be generated by antigen presenting cells. MHC class I bound peptides were acid eluted from the surface of RMA-S cells incubated with M. tuberculosis culture filtrate proteins. The crude peptide preparation was able to sensitize RMA-S cells for recognition by culture filtrate-specific cytolytic T cells. Peptides were subsequently fractionnated by reverse-phase high performance liquid chromatography and the main biological activity was identified in two fractions. These results provide a further evidence that the processing of exogenous culture filtrate proteins in vitro leads to the presentation of a restricted number or even a single immunodominant peptide to culture filtrate-specific CD8+ T cells.

Partial depletion of CD4(+)CD25(+)Foxp3(+) T regulatory cells significantly increases morbidity during acute phase Toxoplasma gondii infection in resistant BALB/c mice.

CD4(+)CD25(+)Foxp3(+) T regulatory (Treg) cells, are known to regulate responses to infectious agents. Here we compared disease progression in BALB/c and C57BL/6(B6) mice infected perorally with Toxoplasma gondii for 7 days and examined the affect of partial depletion of Treg cells in these mice. BALB/c mice were seen to be resistant to peroral infection whereas B6 mice were susceptible in terms of mortality. Although the depletion of Treg cells before infection had no effect on the survival of B6 or BALB/c mice, it resulted in increased parasite burdens in BALB/c mice, especially in the lamina propria, but not in B6 mice. Pro-inflammatory cytokines were also increased in Treg cells depleted BALB/c mice as compared to B6 mice. In addition Treg cell depleted BALB/c mice displayed increased ileal histopathology compared to their non-treated counterparts. These findings provide evidence for the contribution of Treg cells, in the resistance of BALB/c mice against peroral T. gondii infection.

Functional characterization of in vivo effector CD4(+) and CD8(+) T cell responses in acute Toxoplasmosis: an interplay of IFN-gamma and cytolytic T cells.

Development of prophylactic vaccines against Toxoplasma gondii is based on the observation that latently infected subjects are protected against secondary infection during pregnancy. Cocktail DNA vaccines have been shown to provide high resistance to parasite challenge, and latently infected mice are protected against acute disease. In order to characterize the associated Th1 cellular immune responses in vivo, we used H2-K(k) bone marrow macrophage cell lines constitutively expressing T. gondii GRA1, GRA7 or ROP2 antigens, for the in vivo characterization of antigen-specific T cells in an antigenic challenge model, and as target cells in an in vivo CTL assay. In latently infected C3H/HeN mice, CD4(+) and CD8(+) T cells were recruited to the peritoneal cavity after i.p. challenge with these syngeneic cell lines. GRA1 and GRA7-specific T cells from infected mice were IFN-gamma(+) FasL(-) CD107(-). No IFN-gamma or lytic markers were observed against ROP2. In cocktail DNA vaccinated C3H/HeN mice, the response was restricted to GRA1-specific CD8(+) IFN-gamma(-) FasL(-) CD107(+) T cells. Target cells expressing GRA1 and GRA7, but not ROP2, were efficiently killed in an in vivo CTL assay in latently infected mice, while in DNA vaccinated mice only lysis of GRA1 expressing target cells was observed. Both forms of immunization, DNA vaccination and latent infection, completely protected mice against acute Toxoplasmosis. The results obtained in this work suggest that distinct in vivo cytolytic effector mechanisms are at work in DNA vaccinated and latently infected mice, but both converge to protect against acute toxoplasmosis.

Partial reconstitution of the CD4+-T-cell compartment in CD4 gene knockout mice restores responses to tuberculosis DNA vaccines.

Reactivation tuberculosis (TB) is a serious problem in immunocompromised individuals, especially those with human immunodeficiency virus (HIV) coinfection. The adaptive immune response mediated by CD4+ and CD8+ T cells is known to confer protection against TB. Hence, vaccines against TB are designed to activate these two components of the immune system. Anti-TB DNA vaccines encoding the immunodominant proteins Ag85A, Ag85B, and PstS-3 from Mycobacterium tuberculosis are ineffective in mice lacking CD4+ T cells (CD4-/- mice). In this study, we demonstrate that reconstitution of the T-cell compartment in CD4-/- mice restores vaccine-specific antibody and gamma interferon (IFN-gamma) responses to these DNA vaccines. The magnitude of the immune responses correlated with the extent of reconstitution of the CD4+-T-cell compartment. Reconstituted mice vaccinated with DNA encoding PstS-3, known to encode a dominant D(b)-restricted CD8+-T-cell epitope, displayed CD8+-T-cell responses not observed in CD4-/- mice. M. tuberculosis challenge in reconstituted mice led to the extravasation of IFN-gamma-producing CD4+ and CD8+ T cells into lungs, the primary site of bacterial replication. Importantly, a reconstitution of 12 to 15% of the CD4+-T-cell compartment resulted in Ag85B plasmid DNA-mediated protection against a challenge M. tuberculosis infection. Our findings provide evidence that anti-TB DNA vaccines could be effective in immunodeficient individuals after CD4+-T-lymphocyte reconstitution, as may occur following antiretroviral therapy in HIV+ patients.

Priming but not boosting with plasmid DNA encoding mycolyl-transferase Ag85A from Mycobacterium tuberculosis increases the survival time of Mycobacterium bovis BCG vaccinated mice against low dose intravenous challenge with M. tuberculosis H37Rv.

DNA vaccination is a potent means for inducing strong CD4+ (Th1) and particularly CD8+ mediated immune responses and protective immunity against tuberculosis infection in mice. Here we have analyzed the potential of a DNA vaccine encoding the immunodominant mycolyl-transferase Ag85A for increasing the efficacy of the current tuberculosis vaccine Mycobacterium bovis Bacille Calmette-Guérin (BCG) in three long-term survival experiments. BALB/c mice were vaccinated with BCG either following DNA priming or prior to DNA boosting. Ag85A specific CD4+ and CD8+ mediated IFN-gamma responses were increased in mice primed with DNA prior to BCG, and in BCG vaccinated mice subsequently boosted with DNA. In the latter immunization protocol, antigenic stimulation also induced significant levels of IL-17. Mice were monitored for cachexia and survival following a low dose intravenous challenge with M. tuberculosis H37Rv. Priming with Ag85A but not control DNA increased significantly the protective efficacy of the BCG vaccine as indicated by reduced cachexia and prolonged survival time: 32 weeks versus 23 weeks in one experiment and 33 weeks versus 26 weeks in another experiment (MST in control, TB infected mice: 17 weeks in both experiments). On the other hand, boosting of BCG by subsequent Ag85A DNA in saline or vaxfectin--or recombinant 85A protein or MVA-85A for that matter--did not augment the efficacy of BCG (MST 19-21 weeks in all vaccinated groups versus 11 weeks in control, TB infected mice). Our results demonstrate that Ag85A DNA priming can increase efficacy of BCG and that boosting protocols of BCG may possibly be hampered by the induction of Th(IL-17) cells.

Early activation events differentiate the reactivity of two T-cell families to Staphylococcus enterotoxin A.

Analysis of early activation events in two SEA responsive T-cell families demonstrated that low doses of SEA induced CD4+Vbeta22 T-cells to down-regulate their TCR and express CD69, considerably earlier than CD4+Vbeta5 T-cells. The rapid down-regulation of Vbeta22 TCR led to its proliferation, whereas even a 10-fold higher dose of toxin induced only a partial down-regulation of Vbeta5 TCR. Stimulation with SEA induced a significantly higher percentage of Vbeta22 T-cells to produce IFN-gamma compared to Vbeta5 T-cells. SEAF47A, a mutant of SEA, known to have a lower binding affinity for the MHC class II molecule, failed to activate Vbeta5 T-cells whereas Vbeta22 T-cell activation was slightly decreased. Hence, early activation events highlighted the differential requirements of T-cell families to respond to SEA.

Induction of in vivo functional Db-restricted cytolytic T cell activity against a putative phosphate transport receptor of Mycobacterium tuberculosis.

Using plasmid vaccination with DNA encoding the putative phosphate transport receptor PstS-3 from Mycobacterium tuberculosis and 36 overlapping 20-mer peptides spanning the entire PstS-3 sequence, we determined the immunodominant Th1-type CD4(+) T cell epitopes in C57BL/10 mice, as measured by spleen cell IL-2 and IFN-gamma production. Furthermore, a potent IFN-gamma-inducing, D(b)-restricted CD8(+) epitope was identified using MHC class I mutant B6.C-H-2(bm13) mice and intracellular IFN-gamma and whole blood CD8(+) T cell tetramer staining. Using adoptive transfer of CFSE-labeled, peptide-pulsed syngeneic spleen cells from naive animals into DNA vaccinated or M. tuberculosis-infected recipients, we demonstrated a functional in vivo CTL activity against this D(b)-restricted PstS-3 epitope. IFN-gamma ELISPOT responses to this epitope were also detected in tuberculosis-infected mice. The CD4(+) and CD8(+) T cell epitopes defined for PstS-3 were completely specific and not recognized in mice vaccinated with either PstS-1 or PstS-2 DNA. The H-2 haplotype exerted a strong influence on immune reactivity to the PstS-3 Ag, and mice of the H-2(b, p, and f) haplotype produced significant Ab and Th1-type cytokine levels, whereas mice of H-2(d, k, r, s, and q) haplotype were completely unreactive. Low responsiveness against PstS-3 in MHC class II mutant B6.C-H-2(bm12) mice could be overcome by DNA vaccination. IFN-gamma-producing CD8(+) T cells could also be detected against the D(b)-restricted epitope in H-2(p) haplotype mice. These results highlight the potential of DNA vaccination for the induction and characterization of CD4(+) and particularly CD8(+) T cell responses against mycobacterial Ags.

Comparative analysis of different vaccine constructs expressing defined antigens from Mycobacterium tuberculosis.

BACKGROUND: Studies of different vaccine constructs have demonstrated variable efficacy against Mycobacterium tuberculosis in animal models. Despite the fact that these vaccines have used one or another of a very small number of immunodominant antigens, a direct comparison of the relative efficacy of the antigens and delivery systems has been difficult, because the studies have used different parameters for assessment. METHODS: We compared the efficacies of the most commonly used vaccine constructs--adjuvanted protein, plasmid DNA, and live bacterial vectors--bearing the immunodominant secreted antigens early secreted antigen target-6 and antigen 85B, either alone or as a fusion protein. Mice were vaccinated with these constructs, and the effects of different delivery systems on protective efficacy (as assessed by survival studies and by monitoring bacterial load) and antigen-specific responses (including the contribution of CD4 and CD8 T cells to these responses) were assayed by various methods. RESULTS: The relative efficacy of different vaccines is dependent on the delivery system, the antigen, and the animal model. Likewise, the relative immunodominance of individual antigens in the fusion molecule is altered by the choice of delivery system. CONCLUSION: These results clearly demonstrate the importance of assessing vaccine function by use of multiple parameters and indicate which parameters are most reliable for assessing vaccine efficacy.