Estudos neuroimunológicos da doença de Chagas experimental. Análises histomoleculares da medula espinal de camundongos imunocompetentes e deficientes em IL-12 e IL-23 infectados com Trypanosoma cruzi da cepa Sylvio  X10/4. / Neuroimmunological studies of experimental Chagas\' disease. Histomolecular analysis of the spinal cord of immunecompetent and immunedeficient mice that have been infected with parasites of Sylvio X10/4 strain of Trypanosoma cruzi.

André Luis Bombeiro

05 August 2011

O estabelecimento de uma resposta TH1 com a produção de IL-12, IFN-gama e de óxido nítrico é crucial no controle do Trypanosoma cruzi, o qual pode colonizar o SNC de crianças e pacientes imunossuprimidos. A inflamação exacerbada em decorrência da persistência de um estímulo antigênico gera o acúmulo de substâncias potencialmente citotóxicas, como mediadores pró-inflamatórios e radicais livres. A partir da infecção de camundongos imunodeficientes (IL-12p40KO) com T. cruzi Sylvio X10/4, avaliamos os danos causados à medula espinal com enfoque na inflamação e neurodegeneração. Além da desmielinização, alta reatividade glial e morte de neurônios no ponto mais tardio da doença, constatamos uma baixa produção de mediadores inflamatórios nas primeiras semanas após a infecção, acompanhada pela proliferação ascendente do parasita no tecido nervoso. Acreditamos que um atraso na produção de IFN-gama seja responsável pela ativação tardia ou ineficiente dos fagócitos da medula espinal, favorecendo a disseminação descontrolada do protozoário e subsequentes danos teciduais. / The establishment of a TH1 response with IL-12, IFN-gamma and nitric oxide production is crucial for controlling the proliferation of Trypanosoma cruzi, which may colonize the CNS of children and immunosuppressed hosts. The exacerbated inflammation due to the persistence of an antigenic stimulus results on the accumulation of potentially cytotoxic substances, such as pro-inflammatory mediators and free radicals. By the infection of immunodeficient mice (IL-12p40KO) with T. cruzi Sylvio X10/4 parasites we evaluated the spinal cord damages, focusing on the inflammation and neurodegeneration. Besides demyelization, high glial reactivity and neuron death at the latest stage of the disease, we noticed low production of inflammatory mediators during the first weeks of the infection, accompanied by an ascendant parasite proliferation in the nervous tissue. We believe that a delay on IFN-gamma production is responsible for the late or inefficient phagocyte activation in the spinal cord, contributing to the uncontrolled protozoan proliferation and subsequent tissue injury.

Trypanosoma cruzi

Doença de Chagas

Inflamação Interferon tipo II

Óxido nítrico

Sistema nervoso central

Trypanosoma cruzi

Central Nervous System

Chagas disease

Inflammation Interferon Type II

Nitric oxide

Long term non progressors : clues for defining immune correlates of protection from HIV disease progression

Peretz, Yoav.

January 2007

No description available.

Interferon Type II -- immunology.

HIV Long-Term Survivors.

HIV -- immunology.

Interleukin-2 -- immunology.

HIV Infections -- immunology.

The Role of Janus-Kinase-3 in CD4⁺ T Cell Proliferation and Differentiation: A Dissertation

Shi, Min

27 October 2008

Jak3, a member of the Janus family of tyrosine kinases, is essential for signaling via the receptors for IL-2, IL-4, IL-7, IL-9, IL-15 and IL-21. These Jak3-dependent cytokines primarily activate STAT5 and are critical for lymphoid generation and differentiation. Using naïve CD4+ T cells from Jak3-deficient mice and wild type CD4+ T cells treated with a pharmacological inhibitor of Jak3, we report that Jak3-dependent cytokine signals are not required for the proliferation of naïve CD4+ T cells. This is illustrated by the similar percentage of divided cells, comparable cell divisions, intact cell cycle progression and unaffected regulation of cell cycle proteins in the absence of Jak3. In contrast to proliferation, differentiation of naïve CD4+ T cells into Th1 effector cells requires Jak3-dependent cytokine signals. In the absence of Jak3, naïve CD4+ T cells proliferate robustly, but produce little IFN-γ after Th1 polarization in vitro. This defect is not due to reduced activation of STAT1 or STAT4, nor to impaired up-regulation of the transcription factor T-bet. Instead, we find that T-bet binding to the Ifng promoter is greatly diminished in the absence of Jak3-dependent signals, correlating with a decrease in Ifng promoter accessibility and histone acetylation. These data indicate that while Jak3-dependent signals are dispensable for naïve CD4+ T cell proliferation, Jak3 regulates epigenetic modification and chromatin remodeling of the Ifng locus during Th1 differentiation.

CD4-Positive T-Lymphocytes

Chromatin Assembly and Disassembly

Cytokines

Interferon Type II

Janus Kinase 3

Th1 Cells

Interferons

Amino Acids, Peptides, and Proteins

Biological Factors

Cell and Developmental Biology

Cells

Enzymes and Coenzymes

Genetic Phenomena

Hemic and Immune Systems

Immunology and Infectious Disease

Serotype Cross-Reactive CD8+ T Cell Response to Heterologous Secondary Dengue Virus Infections in Humans: a Dissertation

Bashyam, Hema Sundara

18 October 2006

The generation of memory T cells following primary exposure to a pathogen is a critical feature of the vertebrate immune system which has evolved as a protective mechanism in order to defend the host against repeated assaults by the patnogen. Memory T cells are long-lived, undergo rapid proliferation upon re-activation, mediate a robust secondary response and clear the pathogen much more efficiently. These aspects have made the generation of memory T cells an attractive goal for the production of both prophylactic and therapeutic vaccines. However, the degeneracy of the T cell receptor, whereby a given T cell recognizes more than one epitope, allows the T cell to be modulated by epitope variants which could be self-ligands, ligands related to the original epitope but altered in sequence, or completely unrelated epitopes. Experiments in both mice and humans show that such cross-reactive stimulation of memory T cells results in complete, partial, or no activation of T cells, and in some cases, even alters the functional identity of the T cell (for example, T helper 1 cells start secreting IL-4, IL-5 and become part of a T helper 2 response). In the context of secondary infection of immune organisms with pathogens containing mutated or related T cell epitopes, such alterations at the cellular level translate into drastic changes in the overall clinical outcome of the infection. Thus, the presence of cross-reactive T cells in the memory population implies that the protective or pathologic nature of the secondary immune response is a consequence of the host's infection history. Although several murine models of heterologous infection resulting in altered pathological outcome have been studied, the exact immune correlates of protection versus immunopathology are still unclear. This thesis addresses this issue in dengue virus infections in humans. Dengue fever (DF) and Dengue Hemorrhagic Fever (DHF) are two disease manifestations caused by infections of humans by the dengue viruses. These are a group of 4 serologically distinct flaviviruses (D1-4) which often co-circulate among endemic populations. While primary infection with any of the four serotypes can result in the more severe clinical disease characterized by DHF, epidemiological data from several outbreaks show that 80% - 90% of DHF cases occur among individuals with secondary infection. This implies that prior immunity to dengue is actually a risk factor for developing severe disease. In these DHF cases, there are increased numbers of CD69+ CD8+ T cells in circulation, with increases observed in the frequency of epitope-specific T cells, and the serum levels of several T cell produced cytokines, chemokines, and immune receptors are highly elevated. Since the four serotypes share 65% - 75% amino acid sequence homology, the possibility that unconserved T cell epitope sequences stimulated cross-reactive responses was borne out in in vitroexaminations. In these studies, peripheral blood mononuclear cells (PBMC) and cloned T cells from both vaccinated and infected donors contained large populations of memory T cells that were cross-reactive for heterologous viral serotypes in proliferation and CTL assays. These data suggest that the severity of disease seen in DHF patients can be attributed to an immunopathologic secondary response during heterologous infection, and highlight a role for serotype cross-reactive T cells in this process. This thesis addresses the hypothesis that the recognition of the natural variants of dengue virus T cell epitopes by serotype cross-reactive CD8+ T cells of a dengue-immune donor results in an altered secondary response profile, with the changes reflected in both the quantitative and qualitative nature of the response. In order to compare the functional profile of the secondary response of dengue-immune PBMC re-activated with heterologous serotypes, we focused on a panel of 4 donors who were vaccinated with live attenuated monovalent vaccines corresponding to D1, D2, or D4 serotypes. We screened a panel of peptides predicted to bind to HLA-A*0201 for cytokine responses and identified 4 novel epitopes that were highly immunogenic in all four donors. Direct ex vivo stimulation of donor PBMC with the heterologous sequences of these epitopes also showed sizeable serotype cross-reactive T cell populations. CFSE- and intracellular staining for cytokines and chemokines showed that these cross-reactive T cells not only expanded but also produced IFNγ, TNFα, and MIP-1β. Multi-parameter staining revealed functionally diverse populations comprised of single cytokine (IFNγ+, TNFα+, MIP-1β+, double cytokine (IFNγ+TNFα+, IFNγ+MIP-1β+, TNFα+MIP-1β+, and triple cytokine (IFNγ+TNFα+MIP-1β+ secreting sub-sets. Stimulation with the epitope variants altered the magnitude of the overall response as well as the relative sizes of these sub-sets. The patterns of responses revealed the effects of epitope immunogenicity, infection history and donor-specific variability. All 4 donors showed the highest cytokine response to a -single epitope (NS4b 2353). The same two peptide variants (D2 NS4a 2148 and D3 NS4b 2343) induced the highest response in all 4 donors regardless of the serotype of primary dengue infection. Interestingly, the epitope variants which showed the highest immunogenecity in our donors corresponded to the D2 and D3 serotypes which have been documented as being more virulent as well as a viral risk factor for DHF. In one donor, the response to all peptide variants was dominated by the same cytokine sub-sets. These data suggested that the dengue-immune memory T cell repertoire was functionally diverse and underwent alterations in size after secondary stimulation. Therefore, we also investigated the effect of epitope variants on dengue-specific CD8+T cell clones isolated from vaccinated and infected donors in order to determine if epitope variants induced altered functional outcomes at the clonal level. The epitope variants functioned either as strong agonists (particularly the D2 and D3 sequences), partial agonists, or null ligands. Some variants were able to induce cytolysis but not other effector functions at low concentrations. The variant ligands also influenced the hierarchy of cytokine responses within each clone. The third part of this thesis focused on the characterization of the frequency and phenotypic profile of epitope-specific CD8+ T cells in patients with DHF and DF at different times in the disease course in order to better understand the kinetics of the response and delineate any differences between the immune profile of severe vs. moderate disease. Tetramer staining for a previously identified HLA-B*07 restricted epitope was combined with staining for activation markers (CD69, CD38, HLA-DR), homing receptors (CCR7, CD62L), and programmed death receptor 1 (PD-1). The DHF subjects had early T cell activation with higher frequencies of tetramer+CD69+ cells as compared to DF subjects, in whom T cell frequencies peaked around the time of defervescence. While each subject had a unique phenotypic profile of tetramer+ cells, there was a difference between DF and DHF subjects in terms of CCR 7 expression; all subjects expressed low levels of CCR7 during acute illness but only the DHF subjects did not show upregulation of CCR7 on tetramer+ cells during convalescence. These data suggest that there is a sustained alteration in memory phenotype in those who recovered from severe dengue disease. A majority of the tetramer+cells also expressed PD-1 during acute illness but not during convalescence. Double-staining with variant tetramers allowed us to directly visualize serotype cross-reactivity of the epitope-specific population, and showed that secondary stimulation did induce the expansion of cells with low avidity for that secondary serotype and higher avidity to the variant. Furthermore, the ratios of these sub-sets changed during the course of the response. Taken together, these studies suggest that the immune response to heterologous secondary dengue infection is mediated by a heterogeneous population of serotype-cross reactive T cells that have different functional avidities to epitope variants and is influenced by the serotype of the secondary infection as well as the prior infection history of the individual. The preferential expansion of clones which secrete IFNγ but not inflammatory MIP-1β or TNFα or a repertoire characterized by a higher ratio of cytolytic to cytokine producing clones could limit immune mediated damage while efficiently clearing the virus. This information will be useful in the design of vaccine strategies aimed at inducing protective cross-reactive responses against all 4 dengue serotypes while preventing immunopathological outcomes following secondary infection.

Dengue Virus

CD8-Positive T-Lymphocytes

Epitopes

T-Lymphocyte

Variation (Genetics)

Immunity

Cellular

Dengue Vaccines

Interferon Type II

Macrophage Inflammatory Protein-1

Tumor Necrosis Factor-alpha

Biological Factors

Cells

Hemic and Immune Systems

Viruses