Evaluation of immune responses raised against Tc13 antigens of Trypanosoma cruzi in the outcome of murine experimental infection

We have previously reported that genetic immunization with Tc13Tul antigen of Trypanosoma cruzi, the aetiological agent of Chagas' disease, triggers harmful effects and non-protective immune responses. In order to confirm the role of Tc13 antigens during T. cruzi infection, herein we studied the humoral and cellular immune responses to the Tc13Tul molecule and its EPKSA C-terminal portion in BALB/c T. cruzi-infected mice or mice immunized with recombinant Tc13Tul. Analysis of the antibody response showed that B-cell epitopes that stimulate a sustained IgM production along the infection and high levels of IgG in the acute phase are mainly located at the Tc13 N- and C-terminal domains, respectively. DTH assays showed that T-cell epitopes are mainly at the Tc13 N-terminal segment and that they do not elicit an efficient memory response. Recombinant Tc13Tul did not induce IFN-gamma secretion in either infected or immunized mice. However, a putative CD8+Tc13Tul-derived peptide was found to elicit IFN-gamma production in chronically infected animals. Immunization with recombinant Tc13Tul did not induce pathology in tissues and neither did it protect against the infection. Our results show that in the outcome of T. cruzi infection the Tc13 family protein mainly triggers non-protective immune responses.     

Trypanosoma cruzi: sequence polymorphism of the gene encoding the Tc52 immunoregulatory-released factor in relation to the phylogenetic diversity of the species

We have previously identified a Trypanosoma cruzi gene encoding a protein named Tc52 sharing structural and functional properties with the thioredoxin and glutaredoxin family involved in thiol-disulfide redox reactions. Gene targeting strategy and immunological studies allowed showing that Tc52 is among T. cruzi virulence factors. Taking into account that T. cruzi has a genetic variability that might be important determinant that governs the different behaviour of T. cruzi clones in vitro and in vivo, we thought it was of interest to analyse the sequence polymorphism of Tc52 gene in several reference clones. The DNA sequences of 12 clones which represent the whole genetic diversity of T. cruzi allowed showing that 40 amino-acid positions over 400 analysed are targets for mutations. A number of residues corresponding to putative amino-acids playing a role in GSH binding and/or enzymatic function and others located nearby are subject to mutations. Although the immunological analysis showed that Tc52 is present in parasite extracts from different clones, it is possible that the amino-acid differences could affect the enzymatic and/or the immunomodulatory function of Tc52 variants and therefore the parasite phenotype.     

Intracellular growth and metacyclogenesis defects in Trypanosoma cruzi carrying a targeted deletion of a Tc52 protein-encoding allele

We have identified previously a Trypanosoma cruzi gene encoding a protein named Tc52 sharing structural and functional properties with the thioredoxin and glutaredoxin protein family involved in thiol-disulphide redox reactions. Furthermore, we have reported that Tc52 also played a role in T. cruzi-associated immunosuppression observed during Chagas' disease. In an effort to understand further the biological role of Tc52, we used a gene-targeted deletion strategy to create T. cruzi mutants. Although T. cruzi tolerates deletion of one wild-type Tc52 allele, deletion of both genes is a lethal event, indicating that at least one active Tc52 gene is required for parasite survival. Monoallelic disruption of Tc52 (Tc52+/-) resulted in the production of T. cruzi lines that express less Tc52 mRNA and produced lower amounts of Tc52 protein compared with wild-type cells. In axenic cultures, growth rates of epimastigote forms bearing an interrupted allele were not different from those of wild-type parasites. Furthermore, monoallelic disruption of the Tc52 gene did not modify the growth rate of epimastigotes or their sensitivity to inhibition by benznidazole and nifurtimox, the two drugs used to treat Chagasic patients. Moreover, the antimonial drug SbIII, which is known, at least in Leishmania parasites, to be conjugated to a thiol and extruded by an ATP-coupled pump, had a similar effect on wild-type and mutant parasites, being equally sensitive. Hence, parasite drug sensitivity was also observed in clones overexpressing the Tc52 protein as well as in those carrying an antisense plasmid construct. Surprisingly, a significant impairment of the ability of epimastigotes carrying a Tc52 single gene replacement or antisense construct to differentiate into metacyclic trypomastigotes and to proliferate in vitro and in vivo was observed, whereas no significant enhancement of these biological properties was seen in the case of parasites that overexpress Tc52 protein. Moreover, functional complementation of Tc52+/- single mutant or selection of antisense revertant clones demonstrated that the phenotype observed is a direct consequence of Tc52 gene manipulation. Taken together, these results may suggest that Tc52 could participate among other factors in the phenotypic expression of T. cruzi virulence.     

Trypanosoma cruzi: roles for perforin-dependent and perforin-independent immune mechanisms in acute resistance

CD8+ T cells have been shown to be required for acute resistance to infection with the protozoan parasite, Trypanosoma cruzi, the causative agent of Chagas' disease. However, to date, the mechanism by which CD8+ T cells mediate protection in vivo has not been determined. While CD8+ T cells can exhibit cytolytic function, they also secrete cytokines such as IFN-gamma, which is known to mediate protection against T. cruzi infections. To determine whether cytolysis is an important effector function in vivo, we have compared outcomes of T. cruzi infection in normal and perforin-deficient mice. Our results indicate that while perforin-dependent cytolytic mechanisms clearly make a major contribution to acute resistance to T. cruzi infection, this contribution may be strain and challenge dose-dependent, since perforin-deficient mice challenged with lower doses of a less virulent strain survived and were subsequently resistant to challenge with virulent organisms. In vivo depletion studies demonstrated that survival of perforin-deficient mice challenged with low doses of T. cruzi requires both CD4+ and CD8+ T cells and is dependent on IFN-gamma secretion. These studies document the participation of both perforin-dependent cytotoxic and perforin-independent, IFN-gamma-dependent immune mechanisms in acute resistance to T. cruzi infection.     

Heat-killed Trypanosoma cruzi induces acute cardiac damage and polyantigenic autoimmunity

Chagas heart disease, caused by the protozoan parasite Trypanosoma cruzi, is a potentially fatal cardiomyopathy often associated with cardiac autoimmunity. T. cruzi infection induces the development of autoimmunity to a number of antigens via molecular mimicry and other mechanisms, but the genesis and pathogenic potential of this autoimmune response has not been fully elucidated. To determine whether exposure to T. cruzi antigens alone in the absence of active infection is sufficient to induce autoimmunity, we immunized A/J mice with heat-killed T. cruzi (HKTC) emulsified in complete Freund's adjuvant, and compared the resulting immune response to that induced by infection with live T. cruzi. We found that HKTC immunization is capable of inducing acute cardiac damage, as evidenced by elevated serum cardiac troponin I, and that this damage is associated with the generation of polyantigenic humoral and cell-mediated autoimmunity with similar antigen specificity to that induced by infection with T. cruzi. However, while significant and preferential production of Th1 and Th17-associated cytokines, accompanied by myocarditis, develops in T. cruzi-infected mice, HKTC-immunized mice produce lower levels of these cytokines, do not develop Th1-skewed immunity, and lack tissue inflammation. These results demonstrate that exposure to parasite antigen alone is sufficient to induce autoimmunity and cardiac damage, yet additional immune factors, including a dominant Th1/Th17 immune response, are likely required to induce cardiac inflammation.     

CD28 is required for T cell activation and IFN-gamma production by CD4+ and CD8+ T cells in response to Trypanosoma cruzi infection

In the present study we evaluated the mechanisms behind the implication of the costimulatory molecule CD28 for the immune response against the intracellular protozoan parasite Trypanosma cruzi. Our results reveal a critical role for CD28 in the activation of both CD4+ and CD8+ T cells and induction of the effector mechanisms that ultimately mediate the control of parasite growth and pathogenesis in infected mice. CD28-deficient (CD28-/-) mice are highly susceptible to T. cruzi infection, presenting higher parasitemia and tissue parasitism, but less inflammatory cell infiltrate in the heart than C57Bl/6 wild-type (WT) mice. All the infected WT mice survived acute infection, whereas 100% of CD28-/- mice succumbed to it. The increased susceptibility of the CD28-/- mice was associated with a dramatic decrease in the production of IFN-gamma by both CD4+ and CD8+ T cells resulting in a diminished capacity to produce nitric oxide (NO) and mediate parasite killing. T cell activation was also profoundly impaired in CD28-/- mice, which presented decreased lymphoproliferative response after the infection compared to WT mice. Together, these data represent the first evidence that CD28 is critical for efficient CD4+ T cell activation in response to T. cruzi infection in mice.     

IL-10-IFN-γ double producers CD4+ T cells are induced by immunization with an amastigote stage specific derived recombinant protein of Trypanosoma cruzi

During the acute phase of infection, T. cruzi replicates extensively and releases immunomodulatory molecules that delay parasite-specific responses mediated by effector T cells. This mechanism of evasion allows the parasite to spread in the host. Parasite molecules that regulate the host immune response during Chagas'disease have not been fully identified. GPI-anchored mucins, glycoinositolphospholipids, and glycoproteins comprise some of the most abundant T. cruzi surface molecules. IL-10 IFN-γ-secreting CD4+ T cells are activated during chronic infections and are responsible for prolonged persistence of parasite and for host protection against severe inflammatory responses. In this work we evaluated the role of rMBP::SSP4 protein of T. cruzi, a recombinant protein derived from a GPI anchored antigen, SSP4, as an immunomodulator molecule, finding that it was able to induce high concentrations of IL-10 and IFN-γ both in vivo and in vitro; during this last condition, both cytokines were produced by IL-10-IFN-γ-secreting CD4+ T cells.     

Comparative evaluation of therapeutic DNA vaccines against Trypanosoma cruzi in mice

Chagas disease, caused by the protozoan parasite Trypanosoma cruzi, is a major public health problem in most of Latin America. A key priority is the development of new treatments, due to the poor efficacy of current ones. We report here the comparative evaluation of therapeutic DNA vaccines encoding various T. cruzi antigens. ICR mice infected with 500 parasites intraperitoneally were treated at 5 and 12 days postinfection with 20 microg of plasmid DNA encoding T. cruzi antigens TSA-1, TS, ASP-2-like, Tc52 or Tc24. Treatment with plasmid encoding TS and/or ASP-2-like antigens had no significant effect on parasitemia or survival. Treatment with Tc52 DNA significantly reduced parasitemia, as well as cardiac parasite burden, and improved survival, although myocarditis was not significantly affected. Finally, treatment with plasmids encoding Tc24 and TSA-1 induced the most complete control of disease as evidenced by significant reductions in parasitemia, mortality, myocarditis and heart parasite burden. These data demonstrate that therapeutic vaccine efficacy is dependent on the antigen and suggest that DNA vaccines encoding Tc24, TSA-1, and Tc52 represent the best candidates for further studies of a therapeutic vaccine against Chagas disease.     

Immunopathology of cardiomyopathy in the experimental Chagas disease

The mechanisms by which Trypanosoma cruzi causes cardiomyopathy and induces neuronal destruction are discussed in this paper. The results suggest that autoimmunity in the chronic phase is the main cause of the progressive cardiac destruction, and that autoreactivity is restricted to the CD4+ T cell compartment. During the acute phase, the neuronal and cardiac fiber destruction occurs when ruptured parasite nests release T. cruzi antigens that bind to the cell surface in the vicinity which become targets for the cellular and humoral immune response against T. cruzi. The various factors involved in the genesis of autoimmunity in chronic T. cruzi infection include molecular mimicry, presentation of self-antigens and imbalance of immune regulation.     

The increase in mannose receptor recycling favors arginase induction and Trypanosoma cruzi survival in macrophages

The macrophage mannose receptor (MR) is a pattern recognition receptor of the innate immune system that binds to microbial structures bearing mannose, fucose and N-acetylglucosamine on their surface. Trypanosoma cruzi antigen cruzipain (Cz) is found in the different developmental forms of the parasite. This glycoprotein has a highly mannosylated C-terminal domain that participates in the host-antigen contact. Our group previously demonstrated that Cz-macrophage (Mo) interaction could modulate the immune response against T. cruzi through the induction of a preferential metabolic pathway. In this work, we have studied in Mo the role of MR in arginase induction and in T. cruzi survival using different MR ligands. We have showed that pre-incubation of T. cruzi infected cells with mannose-Bovine Serum Albumin (Man-BSA, MR specific ligand) biased nitric oxide (NO)/urea balance towards urea production and increased intracellular amastigotes growth. The study of intracellular signals showed that pre-incubation with Man-BSA in T. cruzi J774 infected cells induced down-regulation of JNK and p44/p42 phosphorylation and increased of p38 MAPK phosphorylation. These results are coincident with previous data showing that Cz also modifies the MAPK phosphorylation profile induced by the parasite. In addition, we have showed by confocal microscopy that Cz and Man-BSA enhance MR recycling. Furthermore, we studied MR behavior during T. cruzi infection in vivo. MR was up-regulated in F4/80+ cells from T. cruzi infected mice at 13 and 15 days post infection. Besides, we investigated the effect of MR blocking antibody in T. cruzi infected peritoneal Mo. Arginase activity and parasite growth were decreased in infected cells pre-incubated with anti-MR antibody as compared with infected cells treated with control antibody. Therefore, we postulate that during T. cruzi infection, Cz may contact with MR, increasing MR recycling which leads to arginase activity up-regulation and intracellular parasite growth.     

Regulatory effects of IL-18 on cytokine profiles and development of myocarditis during Trypanosoma cruzi infection

Chagas disease, caused by Trypanosoma cruzi (Tc), is an important cause of heart disease. Resistance to Tc infection is multifactorial and associated with Th1 response. IL-18 plays an important role in regulation of IFN-γ production/development of Th1 response. However, the role of IL-18 in the setting of Tc infection remains unclear. Therefore, we investigated the role of IL-18 in the modulation of immune response and myocarditis in Tc infection. C57BL/6 and IL-18 KO mice were infected with Tc (Y or Colombian strain) and parasitemia, immune response and pathology were evaluated. Y strain infection of IL-18 KO did not alter any parameters when compared with C57BL/6 mice. However, during the acute phase (20 and 40 days post infection-dpi), Colombian strain infected-IL-18 KO mice displayed higher serum levels of IL-12 and IFN-γ, respectively, and at the chronic phase (100 dpi) an increase in splenic IFN-γ-producing CD4⁺ and CD8⁺ T memory cells. There was an IL-10, FOXP3 and CD4⁺CD25⁺ cells reduction during acute infection in spleen. Additionally, there was a significant reduction in leukocyte infiltration and parasite load in myocardium of chronically infected IL-18 KO mice. Collectively, these data indicate that IL-18 contributes to the pathogenesis of Tc-induced myocarditis when infected with Colombian but not Y strain. These observations also underscore that parasite and host strain differences are important in evaluation of experimental Tc infection pathogenesis.     

Antigen-specific T cells maintain an effector memory phenotype during persistent Trypanosoma cruzi infection

Infection with the protozoan parasite Trypanosoma cruzi is a major cause of morbidity and mortality in Central and South America. Control of acute experimental infection with T. cruzi is dependent on a robust T cell and type 1 cytokine response. However, little evidence exists demonstrating the development and persistence of a potent antiparasite T cell memory response, and there has been much speculation that the majority of the immune response to T. cruzi infection is not directed against the parasite. In this study, we used an experimental mouse model of T. cruzi infection to test both the Ag specificity and the functional and phenotypic characteristics of the responding T cell population. We observed a vigorous antiparasite response from both CD4(+) and CD8(+) T cells that was maintained in the face of persistent infection. T cells from infected mice also proliferated in response to re-exposure to Ag, and CD8(+) T cells underwent spontaneous proliferation when transferred to naive congenic mice, both characteristic of central memory T cells. Interestingly, T cells from infected mice showed significant down-regulation of CD62L, a characteristic associated with an effector memory phenotype. These results suggest that T cells maintained in mice with chronic T. cruzi infection are fully functional memory cells that cannot be easily categorized in the current central/effector memory paradigm.     

Chemokines,inflammation and Trypanosoma cruzi infection

The inflammatory response that follows the infection with Trypanosoma cruzi is essential for host resistance to infection but is also responsible for the diverse pathology observed in Chagas disease. Here, we examine the stimuli and mechanisms underlying chemokine production following infection in vitro and in vivo, and the ability of chemokines to coordinate the influx of inflammatory and immune cells to the site of parasite infection, and to control T. cruzi growth.     

In vivo administration of recombinant IFN-gamma induces macrophage activation, and prevents acute disease, immune suppression, and death in experimental Trypanosoma cruzi infections

Recombinant murine IFN-gamma (rMu-IFN-gamma) was demonstrated to be a potent in vivo activator of mouse peritoneal macrophages to kill Trypanosoma cruzi in vitro and to be capable of conferring protection against death from acute T. cruzi infection. Following i.p. injections of rMu-IFN-gamma, resident peritoneal macrophages were cultured and infected with T. cruzi in vitro. Numbers of intracellular parasites were determined at different times thereafter. Ten or 100 micrograms (1 microgram = 6.5 X 10(5) U) of Mu-IFN-gamma, injected both 24 and 4 h before macrophage harvest, induced up to 99% inhibition of T. cruzi. One microgram of rMu-IFN-gamma was not effective under these conditions. In vitro inhibition of T. cruzi by peritoneal macrophages occurred by 24 h after infection and continued until at least 120 h after infection. There were no significant differences in initial parasite uptake by macrophages from IFN-gamma-treated or control mice, indicating that the rMu-IFN-gamma induced parasite killing. One i.p. dose of 10 micrograms was as effective as two doses if the single injection was given 24 h before macrophage harvest. In subsequent experiments, mice were given multiple injections of 10 micrograms rMu-IFN-gamma beginning 24 h before or 2 h after infection with virulent T. cruzi. Mice treated with rMu-IFN-gamma had significantly lower parasitemias and decreased morbidity compared with control mice. Proliferative responses to Con A and antibody responses to SRBC were not significantly lowered in IFN-gamma-treated mice, in contrast to untreated infected controls. All of the IFN-gamma-treated mice survived acute T. cruzi infection, whereas 100% of saline-treated infected mice died. It was demonstrated in this study that rMu-IFN-gamma activated mouse macrophages in vivo to kill T. cruzi and that rMu-IFN-gamma significantly reduced morbidity and immune suppression, and eliminated mortality resulting from acute infection with this parasite.     

Absence of vasoactive intestinal peptide expression in hematopoietic cells enhances Th1 polarization and antiviral immunity in mice

Vasoactive intestinal peptide (VIP) induces regulatory dendritic cells (DC) in vitro that inhibit cellular immune responses. We tested the role of physiological levels of VIP on immune responses to murine CMV (mCMV) using VIP-knockout (VIP-KO) mice and radiation chimeras engrafted with syngenic VIP-KO hematopoietic cells. VIP-KO mice had less weight loss and better survival following mCMV infection compared with wild-type (WT) littermates. mCMV-infected VIP-KO mice had lower viral loads, faster clearance of virus, with increased numbers of IFN-γ(+) NK and NKT cells, and enhanced cytolytic activity of NK cells. Adaptive antiviral cellular immunity was increased in mCMV-infected VIP-KO mice compared with WT mice, with more Th1/Tc1-polarized T cells, fewer IL-10(+) T cells, and more mCMV-M45 epitope peptide MHC class I tetramer(+) CD8(+) T cells (tetramer(+) CD8 T cells). mCMV-immune VIP-KO mice had enhanced ability to clear mCMV peptide-pulsed target cells in vivo. Enhanced antiviral immunity was also seen in WT transplant recipients engrafted with VIP-KO hematopoietic cells, indicating that VIP synthesized by neuronal cells did not suppress immune responses. Following mCMV infection there was a marked upregulation of MHC-II and CD80 costimulatory molecule expression on DC from VIP-KO mice compared with DC from WT mice, whereas programmed death-1 and programmed death ligand-1 expression were upregulated in activated CD8(+) T cells and DC, respectively, in WT mice, but not in VIP-KO mice. Because the absence of VIP in immune cells increased innate and adaptive antiviral immunity by altering costimulatory and coinhibitory pathways, selective targeting of VIP signaling represents an attractive therapeutic target to enhance antiviral immunity.     

Induction of B- and T-cell responses to cruzipain in the murine model of Trypanosoma cruzi infection

Trypanosoma cruzi, the causative agent of Chagas' disease, is an important cause of heart disease in Latin America. The parasite is transmitted mucosally, with both intra- and extracellular life stages in the human host. Cruzipain, the major cysteinyl proteinase of T. cruzi, has been shown to be antigenic in both humans and mice during infection with the parasite. We extend these observations, showing here that multiple murine immune subsets of potential importance for vaccine-induced protection can be induced by cruzipain. Cruzipain-specific serum IgG responses were induced during chronic infection with T. cruzi. In addition, T. cruzi mucosal infection stimulated the development of cruzipain-specific secretory IgA detectable in fecal extracts from infected mice. Cruzipain-specific type 1 cytokine responses characterized by the production of IFN-gamma but not IL-4 were also detectable during murine infection. Furthermore, immunization of mice with a DNA vaccine encoding cruzipain was shown to stimulate cytotoxic T lymphocyte (CTL) responses capable of recognizing and lysing T. cruzi-infected cells. The induction of serum antibody, mucosal IgA, Th1 cytokine and CTL responses by cruzipain in mice supports the use of this parasite protein for further efforts in T. cruzi vaccine development.     

Trypanosoma cruzi immune evasion mediated by host cell-derived microvesicles

The innate immune system is the first mechanism of vertebrate defense against pathogen infection. In this study, we present evidence for a novel immune evasion mechanism of Trypanosoma cruzi, mediated by host cell plasma membrane-derived vesicles. We found that T. cruzi metacyclic trypomastigotes induced microvesicle release from blood cells early in infection. Upon their release, microvesicles formed a complex on the T. cruzi surface with the complement C3 convertase, leading to its stabilization and inhibition, and ultimately resulting in increased parasite survival. Furthermore, we found that TGF-β-bearing microvesicles released from monocytes and lymphocytes promoted rapid cell invasion by T. cruzi, which also contributed to parasites escaping the complement attack. In addition, in vivo infection with T. cruzi showed a rapid increase of microvesicle levels in mouse plasma, and infection with exogenous microvesicles resulted in increased T. cruzi parasitemia. Altogether, these data support a role for microvesicles contributing to T. cruzi evasion of innate immunity.     

Infection of T lymphocytes by Trypanosoma cruzi. Possible role of CD3 and HLA-DR

The mechanisms by which the causative agent of Chagas' disease impair its host's immune response are of paramount importance but poorly understood. Results presented in this paper show for the first time that Trypanosoma cruzi trypomastigotes infect T lymphocytes in vitro and more interestingly in vivo, and that trypomastigotes released from infected cells are infectious. In addition treatment of purified human T lymphocytes with McAb against CD3 and HLA-DR antigens significantly inhibited parasite infection. T. cruzi antigens were detected on the membrane of infected T cells and could therefore represents targets for cytotoxic mechanisms. These results might have important consequences for the understanding of the dramatic disruption of immune response observed during Chagas' disease and more generally provide additional information on T lymphocyte infection by pathogens.     

Conversion of Trypanosoma cruzi Tc52 released factor to a protein inducing apoptosis

In this study Tc52, a Trypanosoma cruzi released protein, which exerts an immunoregulatory activity, was converted to a molecular form with altered biological function. Indeed, the genetic fusion of Tc52 to a carrier protein, the Shistosoma japonicum glutathione S-transferase (Tc52-Sj26), was shown to induce apoptosis in spleen cells from BALB/c or CBA mice and the human T-cell leukemic cell line (CEM). Cell death by apoptosis was evidenced by the following criteria: (1) increased binding of Annexin V to rTc52-treated spleen cells; (2) the presence of an ordered cleavage of the DNA backbone; (3) double labeling showed increased number of T cells undergoing apoptosis upon incubation with rTc52; (4) the use of a CEM cell line and TUNEL assay allowed to show in situ DNA fragmentation. Surprisingly, intraperitoneal injections of rTc52 to BALB/c mice, which were then infected with T. cruzi, resulted in increased parasiteamia levels and is congruent to 2.5 times increase of macrophages number. Since native Tc52 could not trigger, apoptosis of T cells we could hypothesized that the fusion of Tc52 with Sj26 led to conformational changes resulting in apoptosis inducing properties of rTc52. The possible in vivo physiopathological implications of these finding were discussed.     

V gamma 1 gammadelta T cells regulate type-1/type-2 immune responses and participate in the resistance to infection and development of heart inflammation in Trypanosoma cruzi-infected BALB/c mice

Many different cell populations or lineages participate in the resistance to Trypanosoma cruzi infection. gammadelta T cells may also take part in a network of interactions that lead to control of T. cruzi infection with minimal tissue damage by controlling alphabeta T cell activation, as was previously suggested. However, the gammadelta T cell population is not homogeneous and its functions might vary, depending on T cell receptor usage or distinct stimulatory conditions. In this study, we show that the in vivo depletion of V gamma 1-bearing gammadelta T cells, prior to the infection of BALB/c mice with the Y strain of T. cruzi, induces an increased susceptibility to the infection with lower amounts of IFN-gamma being produced by conventional CD4+ or CD8+ T cells. In addition, the production of IL-4 by spleen T cells in V gamma 1-depleted mice was increased and the production of IL-10 remained unchanged. Since V gamma 1(+) gammadelta T cell depletion diminished the conversion of naive to memory/activated CD4 T cells and the production of IFN-gamma during the acute infection, these cells appear to function as helper cells for conventional CD4+ Th1 cells. Depletion of V gamma 1(+) cells also reduced the infection-induced inflammatory infiltrate in the heart and skeletal muscle. More importantly, V gamma 1(+) cells were required for up-regulation of CD40L in CD4+ and CD8+ T cells during infection. These results show that a subset of gammadelta T cells (V gamma 1(+)), which is an important component of the innate immune response, up-regulates the type 1 arm of the adaptative immune response, during T. cruzi infection.