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T cell factor-1 regulates CD4+ and CD8+ T cell responses in a stage-specific mannerGullicksrud, Jodi Ann 01 August 2017 (has links)
CD4+ and CD8+ T cells are critical components of the adaptive arm of immune responses. During viral infection, CD8+ T cells utilize their cytotoxic function to kill infected cells and clear the infection. In addition, CD4+ T cells differentiate into either T helper 1 (Th1) or T follicular helper (Tfh) cells, which provide essential help to enhance the efficacy of other response immune cells, including macrophages, CD8+ T cells, and B cells. The transcription factor, T cell factor-1 (TCF1), and its homologue, Lymphoid enhancer-binding factor-1 (LEF1), have critical roles in the development, differentiation, and persistence of both CD4+ and CD8+ T cells. However, the influence of TCF1 and LEF1 on Th1 and Tfh differentiation remains to be examined. Furthermore, due to alternative promoter usage, TCF1 and LEF1 are expressed as both long and short isoforms. The distinct roles of the long and short isoforms of TCF1 in the context of CD4+ and CD8+ T cell responses have not been defined.
My studies utilized multiple novel mouse strains to examine the roles of TCF1 and LEF1 in Tfh and Th1 differentiation during viral infection, and the unique requirements of TCF1 long isoforms in CD4+ and CD8+ T cell responses. Specifically, my initial studies characterized a new TCF1 reporter construct (referred to as p45GFP reporter) and used this reporter to address the specific contributions of TCF1 long isoforms to the CD8+ T cell response. Previous studies have abrogated all TCF1 isoforms and shown that in the absence of TCF1, the memory CD8+ T cell population is dramatically impaired and exhibits defective persistence over time. Here, I showed that TCF1 short isoforms are sufficient for the generation of memory CD8+ T cells, however TCF1 long isoforms are important for the maturation of memory CD8+ T cells.
Another critical component of pathogen clearance and long-term protection is a productive humoral response, which is optimized by the B cell help provided by Tfh cells. Using the p45GFP reporter, I showed that TCF1 is specifically retained in Tfh cells, but downregulated in Th1 cells. I utilized a huCd2-Cre system to conditionally delete TCF1 and LEF1 in mature T cells. In response to viral infection, TCF1 and LEF1 double-deficient mice showed normal Th1 responses, but severely defective Tfh differentiation and a concomitant impaired B cell response. I further demonstrated that TCF1 promotes Tfh differentiation by directly regulating many Tfh-associated genes. Furthermore, I used the p45GFP reporter to I identified distinct, but critical, roles for both long and short isoforms of TCF1 in driving Tfh differentiation and repressing differentiation toward Th1 or germinal center Tfh cells.
Finally, while TCF1 is known to be critical in the formation of memory CD8+ T cells, its impact on memory CD4+ T cell generation has not been assessed. Once again utilizing the p45GFP reporter, my studies identified an important role for TCF1 long isoforms in the survival of both Th1 and Tfh cells through contraction. In the absence of TCF1 long isoforms, the memory CD4+ T cell population is severely reduced. Taken together, my work has demonstrated critical roles for TCF1 during both effector and memory phases of the CD4+ T cell response to viral infection.
In summary, TCF1 is crucial for CD4+ T cells to effectively differentiate and provide important help to B cells during viral infection. Moreover, my studies have identified critical and unique roles for long and short isoforms of TCF1. Finally, TCF1 is necessary for optimal formation of memory CD4+ and CD8+ T cells, and thus is an essential component in achieving protective immunological memory after viral infection.
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Initiation and regulation of effector T cell responses in the prostateHaverkamp, Jessica M. 01 July 2011 (has links)
Myeloid-derived suppressor cells (MDSC) are a heterogeneous population of immature myeloid cells identified in mice as Gr-1+CD11b+ cells with the ability to inhibit T cell function. MDSC are emerging as important regulators of T cell mediated immune responses. Current paradigm suggests that despite heterogeneity, all Gr-1+CD11b+ cells are suppressive when exposed to inflammatory stimuli. In vitro evaluation shows MDSC from multiple tissue sites have suppressive activity, and in vivo inhibition of MDSCenhances T cell function. However, the relative capacity of MDSC present at localized inflammatory sites or in peripheral tissues to suppress T cell responses in vivo has not been directly evaluated. Using a tissue specific acute inflammatory prostatitis model, we demonstrate that MDSC inhibition of CD8+ T-cell proliferation is restricted to the inflammatory site.Further, MDSC from inflammatory sites possess immediate capacity to inhibit T-cell function, whereas those isolated from peripheral tissues (spleens and liver) were not suppressive without activation of iNOS by exposure to IFN-_.Using two mouse models of prostate cancer, we extend these findings to thetumor micro-environment. During a chronic inflammatory response induced by tumorgrowth, we show Gr-1+CD11b+ cells from the tumor site possess immediate capacity toregulate effector T cell function whereas those from the spleen do not. In both tumormodels and in our prostatitis model, long term culture of activated T cells with splenicGr-1+CD11b+ cells converted precursor cells into functional MDSC during standard in vitro suppression assays. These data highlight the importance of MDSC in the prostate, and demonstrate the function of MDSC during a localized inflammatory response isrestricted to the site of an ongoing immune responseGrowing evidence suggests that prostatitis associated with chronic prostatitis/chronic pelvic pain syndrome (CP/CPPS) is mediated in part by the loss of T cell and B cell tolerance to prostate antigens. Clinical data demonstrates the presence of T cell proliferative responses to prostate auto-antigens in CP/CPPS patients. However, the mechanisms leading to this loss of tolerance are not clearly understood, largely because of a lack of available animal models. We report the development of a new mouse model for the study of chronic prostate inflammation (CPI), the Prostate Ovalbumin Expressing Transgenic-3 (POET-3) model. Adoptive transfer of antigen specific OT-I T cells induces CPI characterized by infiltration of exogenous (OT-I) and endogenous T cells into the prostate persisting as long as 45 days after transfer. In vitro and in vivo data demonstrate inflammation induced loss of T cell tolerance to prostate auto-antigens. Auto-antibody responses to prostate antigens were detected in POET-3 mice after induction of CPI. These data have important therapeutic implications for treatment of CPI.
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T-Cell Immunogenicity and Dysfunction in Cancer and Viral DiseasesJanuary 2017 (has links)
abstract: CD8+ T-lymphocytes (CTLs) are central to the immunologic control of infections and are currently at the forefront of strategies that enhance immune based treatment of a variety of tumors. Effective T-cell based vaccines and immunotherapies fundamentally rely on the interaction of CTLs with peptide-human leukocyte antigen class I (HLA-I) complexes on the infected/malignant cell surface. However, how CTLs are able to respond to antigenic peptides with high specificity is largely unknown. Also unknown, are the different mechanisms underlying tumor immune evasion from CTL-mediated cytotoxicity. In this dissertation, I investigate the immunogenicity and dysfunction of CTLs for the development of novel T-cell therapies. Project 1 explores the biochemical hallmarks associated with HLA-I binding peptides that result in a CTL-immune response. The results reveal amino acid hydrophobicity of T-cell receptor (TCR) contact residues within immunogenic CTL-epitopes as a critical parameter for CTL-self/nonself discrimination. Project 2 develops a bioinformatic and experimental methodology for the identification of CTL-epitopes from low frequency T-cells against tumor antigens and chronic viruses. This methodology is employed in Project 3 to identify novel immunogenic CTL-epitopes from human papillomavirus (HPV)-associated head and neck cancer patients. In Project 3, I further study the mechanisms of HPV-specific T-cell dysfunction, and I demonstrate that combination inhibition of Indoleamine 2, 3-dioxygenase (IDO-1) and programmed cell death protein (PD-1) can be a potential immunotherapy against HPV+ head and neck cancers. Lastly, in Project 4, I develop a single-cell assay for high-throughput identification of antigens targeted by CTLs from whole pathogenome libraries. Thus, this dissertation contributes to fundamental T-cell immunobiology by identifying rules of T-cell immunogenicity and dysfunction, as well as to translational immunology by identifying novel CTL-epitopes, and therapeutic targets for T-cell immunotherapy. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2017
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Oncolytic virus therapy with HSV-1 for hematologic malignancies / がん治療用HSV-1を用いた造血器腫瘍に対するウイルス療法の開発Ishino, Ryo 23 March 2021 (has links)
京都大学 / 新制・課程博士 / 博士(医科学) / 甲第23109号 / 医科博第120号 / 新制||医科||8(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 河本 宏, 教授 中島 貴子, 教授 小川 誠司 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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CD8 T cell differentiation during immune responsesDe Campos Pereira Lemos, Sara Sofia 23 May 2014 (has links) (PDF)
CD8 T cells are essential for the elimination of intracellular pathogens and tumor cells. Understanding how naïve CD8 T cells differentiate into effector cells capable of eliminating pathogens and to generate adequate memory cells during immune responses is fundamental for optimal T cell vaccine design. In this PhD thesis work we addressed two central questions: 1) What are the mechanisms by which early effector T cells could act as pro-inflammatory effectors? And what is their role in the immune response? 2) How heterogeneous are CD8 responses? Could different pathogens modulate CD8 T cell differentiation programs and be responsible for CD8 cell-to-cell heterogeneity? Could they also generate memory cells with different protection capacities? To address these questions related to the diversity of CD8 T cell differentiation during immune responses, we used the single cell RT-PCR technique to detect ex vivo expression of mRNA in each individual cell, and Brefeldin A injected mice to detect ex vivo intracellular proteins. As experimental system to evaluate in vivo cell activation we used T cell receptor transgenic (TCR-Tg) CD8 T cells. Since the use of TCR-Tg cells to study immune responses has been subjected to criticism (due to high frequency of naïve-precursor transfers), in a first Ms. we compared the behavior of TCR-Tg and endogenous (non-transgenic and present at low frequency) cells in the same mouse. We found fully overlapping behavior between these two cell populations, which reinforced the advantage of using TCR-Tg cells to study CD8 immune responses. In addition, we concluded that the frequency of naïve-precursors do not induce diversity on CD8 T cell differentiation patterns. In a second Ms. we evaluated the impact of different pathogens in the diversity of CD8 T cell properties during two different immune responses: OT1 TCR-Tg cells (specific for OVA antigen) in the response to LM-OVA (Listeria Monocytogenes expressing OVA) infection; and P14 TCR-Tg cells (specific for GP33 epitope) in the response to Lymphocytic choriomeningitis vírus (LCMV) infection. We found that OT1 and P14 cells had different properties. As this difference could also be attributed to the different TCR avidity between OT1 and P14 cells, we then compared the behavior of P14 and OT-1 cells in the same mouse, co-injected with LM-OVA and LM-GP33. Since no differences were then detected, these results demonstrated that priming with different pathogens generates CD8 T cells with different characteristics that are not determined by TCR usage, but rather by the infection context. In addition, when looking for the protection capacity of endogenous CD8 memory cells generated in bacterial or viral context, we found that memory cells generated after LCMV priming were more efficient in responding to a second challenge, than memory cells generated after LM-GP33 priming. We also found that this better protection is associated with a T cell effector memory (TEM) phenotype associated with the LCMV infection, in contrast with a T cell central memory (TCM) phenotype generated after LM-OVA infection. These results demonstrate that different pathogens are responsible for diversity of CD8 T cell differentiation patterns and that even when distinct pathogens are efficiently eliminated during the primary immune response the quality of the memory generated may differ. In a third Ms. we studied the mechanisms by which effector CD8 T cells attracted other cell types in the early days of an immune response. We used two experimental systems: the response of OT1 TCR-Tg cells to LM-OVA infection; and the response of anti-HY TCR-Tg cells to male cells ("sterile"-non infectious context). In both cases we found that immediately after activation, CD8 T cells expressed high levels of pro-inflammatory cytokines and chemokines (such as TNFα, XCL1, CCL3 and CCL4). (...)
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Identificação e avaliação imunológica de potenciais epítopos de linfócitos T CD4+ e T CD8+ no proteoma de Leishmania (Viannia) braziliensisSILVA, Rafael de Freitas e 06 September 2016 (has links)
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Previous issue date: 2016-09-06 / As leishmanioses são doenças causadas por protozoários do gênero Leishmania e
estão presentes em 98 países e territórios e possuem incidência anual de 2
milhões de casos. A Leishmania (Viannia) braziliensis (L.V. braziliensis) é uma das
principais espécies causadoras da leishmaniose cutânea (LC) no Brasil. Apesar
disso, ainda não há uma vacina segura e eficaz para ser utilizada em seres
humanos. Nesse sentido, o objetivo deste trabalho foi identificar no proteoma
predito de L.V. braziliensis, potenciais epítopos de linfócitos T e avaliá-los por meio
de ensaios imunológicos. No primeiro capítulo, o proteoma predito de L.
braziliensis foi comparado ao de outras espécies e analisado quanto a presença de
epítopos. Nessa etapa foram encontrados epítopos derivados de mais de 8 mil
proteínas conservadas entre diferentes espécies de Leishmania. Os epítopos
foram clusterizados e então utilizados para etapa de docagem molecular com
estruturas de MHC I e MHC II depositadas no Protein Data Bank. A docagem
molecular resultou em epítopos peptídicos de 15 aminoácidos com alta afinidade
de ligação às moléculas de MHC I e MHC II. Os 10 melhores resultados foram
então sintetizados e avaliados, in vitro, quanto à capacidade de estimular a
proliferação de células mononucleares do sangue periférico (PBMC) de indivíduos
com LC após o tratamento (PT). Os resultados indicaram que 50% das moléculas
testadas apresentaram capacidade de estimular, significativamente (p<0,05), a
proliferação celular quando comparado às células de indivíduos saudáveis que não
vivem em região endêmica para LC. No segundo capítulo, os peptídeos foram
avaliados quanto à capacidade de estimular a proliferação de PBMC de indivíduos
com LC em sua fase ativa (AD) e indivíduos moradores de área endêmica para LC
resistentes à infecção (RT). Em paralelo, quantificou-se a expressão do fator de
transcrição T-bet em PBMC de indivíduos PT, e citocinas dos perfis Th1, Th2 e
Th17 foram mensuradas no sobrenadante de cultura das células de indivíduos PT
e AD. Os resultados demonstraram altos níveis de proliferação nas células do
grupo RT para todos os peptídeos testados. Além disso, níveis significativos de Tbet
foram observados em linfócitos T CD4+ e CD8+ após estímulo com seis
peptídeos. Níveis significativos de IFN-γ, TNF e IL-6 foram observados no
sobrenadante das células do grupo PT com quatro dos peptídeos testados. Altos
níveis dessas citocinas também foram encontrados no sobrenadante do grupo AD.
No terceiro capítulo, avaliou-se o efeito dos peptídeos sobre células dendríticas de
medula (BMDC) murinas, produção de citocinas de sobrenadante, e células
dendríticas esplênicas murinas após estímulo com os peptídeos. Verificou-se altos
níveis de MHC II e CD40 em uma subpopulação de BMDC estimuladas com as
moléculas e altos níves de TNF e IL-6 após 48h de estímulo. Para as células
esplênicas, foram observados altos níveis de subpopulações celulares
expressando CD11b+, IL-12p70+, CD205+ e CD11b+ após estímulo com o peptídeo
que teve o melhor resultado in silico. Por fim, os resultados indicam o grande
potencial imunogênico que os epítopos identificados apresentam, o que dá suporte
ao desenvolvimento futuro de abordagens vacinais. / The leishmaniasis are diseases caused by protozoans from the genus
Leishmania which are present in 98 countries and territories, with an annual
incidence of 2 million cases. Among the other species, Leishmania (Viannia)
braziliensis is the main specie implicated with cutaneous leishmaniasis (CL) in
Brazil. Besides that, there is no safe and effective vaccine against leishmaniasis
to be applied in humans. In this context, the aim of this work was to identify in
the predicted proteome of L. braziliensis potential CD4+ and CD8+ T cell
epitopes and evaluate them by immunological assays. In the first chapter, the
predicted proteome of L. braziliensis was compared with other species and
analyzed for the presence of epitopes. In this step, epitopes from more than
8,000 conserved proteins were found among other species of Leishmania. The
epitopes were clustered and then used for the molecular docking with MHC I
and MHC II structures deposited in the Protein Data Bank. This approach
resulted in 15 aminoacids peptide epitopes with high binding affinity for MHC I
and MHC II. The 10 best results were synthesized and evaluated in vitro for
their capacity to stimulate the proliferation of peripheral blood mononuclear cells
(PBMC) of individuals with CL post treatment (PT). The results have shown that
50% of the tested molecules had the capacity to stimulate, significantly
(p<0.05), cell proliferation when compared with cells of healthy individuals living
in non-endemic regions. For the second chapter, the peptides were evaluated
for their capacity to stimulate the proliferation of PBMC from CL individuals with
active disease (AD) and of individuals resistant to infection (RT) living in
endemic region. In parallel, the T-bet transcription factor expression was
quantified in PBMC of PT individuals, and cytokines from the Th1, Th2 and
Th17 profiles were measured in culture supernatant of PT and AD groups. High
levels of cell proliferation in the RT group were demonstrated for all peptides
tested. Moreover, significant levels of T-bet in CD4+ and CD8+ T cells were
verified after stimulation with six peptides. For IFN-γ, TNF and IL-6, significant
levels were detected in the supernatant of cultures from the PT group with four
peptides tested. High levels of these same cytokines were also present in the
supernatant of AD group. In the third chapter, the peptide effects over murine
bone marrow dendritic cells (BMDC), the production of cytokines in the
supernatant and murine spleen dendritic cell subsets were evaluated after
peptide stimuli. High levels of MHC II and CD40 were verified for stimulated
BMDC and high levels of TNF and IL-6 after 48h of stimuli. For spleen cells,
high levels of cells expressing CD11b+, IL-12p70+, CD205+ e CD11b+ were
observed after stimulation with the peptide which showed the best in silico
result. In conclusion, the results indicate the great immunogenic potential of the
identified peptides and support the further development of vaccine approaches
using those molecules.
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Rôle de la déubiquitinase BAP1 dans la réponse et la différenciation des lymphocytes T CD8+Mezrag, Sarah 04 1900 (has links)
L’activation des lymphocytes T (LT) CD8 naïfs mène à leur différenciation en deux sous-populations d'effecteurs, les SLEC (short-lived effector cells) et MPEC (memory precursor effector cells). Après contrôle de l’infection, les SLEC meurent par apoptose tandis que les MPEC deviennent des cellules mémoires qui protègent contre la réinfection. Peu de choses sont connues sur le rôle des mécanismes post-traductionnels, tel que la déubiquitination lors de la différenciation des LT CD8+. La déubiquitinase (DUB) BAP1 joue un rôle clé dans la différenciation thymique et dans le maintien des populations de LT matures. Elle interagit avec plusieurs partenaires comme YY1 et EZH2 dans des cellules autres que les LT. Certains de ces partenaires ont des rôles importants dans la biologie des LT CD8 notamment en contexte infectieux suggérant que BAP1 régule la réponse des LT CD8+ lors d’une infection. Afin de tester cela, des LT CD8 OT-I spécifiques pour le peptide ovalbumine dans lesquelles BAP1 a été surexprimé ont été transférés dans des souris infectées avec la bactérie Listeria monocytogenes codant pour l’ovalbumine (LM-OVA). Nos résultats au pic de la réponse démontrent un défaut de l’expansion clonale des LT CD8+, de la différenciation en SLEC et une augmentation de la différenciation en MPEC. Nous observons aussi une augmentation de la différenciation en LT centrale mémoire (TCM) au stade mémoire. Finalement, nous évaluerons aussi l’impact de la délétion de Bap1 dans la réponse des LT CD8+. Cela contribuera à une meilleure compréhension du rôle de l’ubiquitination dans la biologie des LT CD8+ dont l’importance est centrale dans la réponse face aux infections et au cancer. / Following antigen recognition, naive CD8+ T cells expand massively and differentiate into effector cells. After pathogen clearance, the short-lived effector cells (SLECs) die while memory precursor effector cells (MPECS) persist and differentiate into memory T cells to confer long-term protection against reinfection. The transcriptional network controlling the SLEC/MPEC differentiation is well characterized but little is known about the role of posttranslational modifications, such as deubiquitination, in this process. The deubiquitinase BAP1 interacts with multiple partners including YY1 and EZH2 that are important for CD8+ T cell response. BAP1 has been shown to participate in thymic differentiation and in the maintenance of mature peripheral T cells. However, the function of BAP1 during CD8+ T cell response to infection is unknow. To address this, we overexpressed BAP1 wild type (WT) in ovalbumin-specific (OT-I) CD8+ T cells by retroviral transduction and analysed their response after adoptive transfer into mice infected with Listeria monocytogenes encoding ovalbumin. The overexpression of BAP1 WT severely reduced CD8+ T cell expansion, SLEC differentiation and functionality. It also induces enhanced MPEC differentiation. In fact, we observed an increase in central memory CD8 T cell (TCM) differentiation 30 days following infection. Finally, we confirmed the presence of key partners of BAP1 complex in activated and naïve CD8+ T cells. As next steps, we will analyse the impact of BAP1-deficiency in CD8+ T cell response to infection. This will contribute to a better understanding of the role of deubiquitination in CD8+ T cell response
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Syntheses and Immunological Evaluation of Zwitterionic Polysaccharide (PS A1) Based VaccinesNishat, Sharmeen January 2016 (has links)
No description available.
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Induction de réponses mémoires lymphocytaires T CD8 et protection vaccinale après transfert de gènes par le vecteur AAV recombinant / Induction of lymphocytic memory CD8 T cell responses and vaccinal protection following genes transfer by recombinant Adeno-Associated Virus (rAAV) vectorGhenassia, Alexandre 30 October 2015 (has links)
La mémoire immunologique est le mécanisme biologique fondamental à la base du développement de la vaccination. La compréhension de ce mécanisme ainsi que de ses interactions avec les différents acteurs du système immunitaire a permis l’élaboration de vaccins qui sont aujourd’hui les garants d’une protection accrue face à l’émergence de maladies infectieuses potentiellement mortelles. La voie d’injection et le mode de transfert de ces vaccins sont des paramètres majeurs à prendre en considération car ils définissent une modulation des réponses immunitaires et de leurs spécificités d’action. De nos jours, seule la voie intramusculaire demeure la voie majoritaire d’administration de vaccins lors de la prophylaxie primaire en santé humaine. Au cours de notre étude, nous nous sommes intéressés à comparer l’injection d’un antigène (l’ovalbumine) selon deux voies d’administration : la voie intramusculaire et la voie intradermique. Nous nous sommes également appuyés sur une technologie du laboratoire qui consiste à transférer des gènes par des vecteurs AAV2/1 recombinants. Nous disposions de deux constructions de ces vecteurs ayant une spécificité pour cibler les cellules musculaires et permettant l’apport d’un effet auxiliaire par les lymphocytes T CD4+ lors d’injections dans des souris femelles. De plus, une de ces constructions nous permettait d’éviter la voie de présentation directe de l’antigène par les cellules dendritiques (DCs) aux lymphocytes T CD8+. Les capacités modulatrices de ces vecteurs nous permirent de montrer pour la première fois que le vecteur AAV2/1 recombinant était capable de faire exprimer un transgène au sein de la peau et d’y générer une réponse cellulaire forte. Nous avons également montré qu’il existait une synergie d’action entre l’effet auxiliaire et la voie intradermique qui améliorait considérablement les réponses cellulaires issues de la présentation croisée d’antigène. Enfin, nous avons pu démontrer que les lymphocytes T CD8+ générés suite à cette synergie d’action présentaient un profil phénotypique de cellules mémoires polyfonctionnelles et capables de protéger l’hôte face à un challenge pathogénique. / Immunological memory is the fundamental biological mechanism at the beginning of the development of vaccination. Understanding this mechanism and its interactions with the various players of the immune system has allowed the development of vaccines that are today the most effective barrier against the emergence of life-threatening infectious diseases. Route of injection and the nature of carriers of these vaccines are key parameters to be taken into consideration because they define a modulation of immune responses and their specific features. Nowadays, only the intramuscular injection route remains the major route of vaccines injection in the context of primary prophylaxis in human health. During our study, we were interested in comparing the injection of antigen (ovalbumin) following two routes of administration: intramuscular and intradermal routes. We also relied on a technology in the laboratory that involves the transfer of genes by rAAV2/1 vectors. We had two constructs of these vectors having specificity to target skeletal muscle cells and allowing us to provide a helper effect from CD4+ T cells during injections into female mice recipients. Moreover, one of these constructs enabled us to avoid the direct presentation of antigens by dendritic cells (DCs) to CD8+ T cells. The capacity of modulation of these vectors allowed us to show for the first time that the rAAV2/1 vector was able to trigger the expression of a transgene in the skin, and there to generate a strong cellular response. We have also shown that CD4+ T cell help and the intradermal route of immunization synergize to improve greatly cellular responses from the cross-presentation of antigens. Finally, we have demonstrated that CD8+ T cells generated following this synergism exhibited a phenotypic profile of polyfunctional memory cells and able to protect the host against a pathogenic challenge.
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Induction de réponses mémoires lymphocytaires T CD8 et protection vaccinale après transfert de gènes par le vecteur AAV recombinant / Induction of lymphocytic memory CD8 T cell responses and vaccinal protection following genes transfer by recombinant Adeno-Associated Virus (rAAV) vectorGhenassia, Alexandre 30 October 2015 (has links)
La mémoire immunologique est le mécanisme biologique fondamental à la base du développement de la vaccination. La compréhension de ce mécanisme ainsi que de ses interactions avec les différents acteurs du système immunitaire a permis l’élaboration de vaccins qui sont aujourd’hui les garants d’une protection accrue face à l’émergence de maladies infectieuses potentiellement mortelles. La voie d’injection et le mode de transfert de ces vaccins sont des paramètres majeurs à prendre en considération car ils définissent une modulation des réponses immunitaires et de leurs spécificités d’action. De nos jours, seule la voie intramusculaire demeure la voie majoritaire d’administration de vaccins lors de la prophylaxie primaire en santé humaine. Au cours de notre étude, nous nous sommes intéressés à comparer l’injection d’un antigène (l’ovalbumine) selon deux voies d’administration : la voie intramusculaire et la voie intradermique. Nous nous sommes également appuyés sur une technologie du laboratoire qui consiste à transférer des gènes par des vecteurs AAV2/1 recombinants. Nous disposions de deux constructions de ces vecteurs ayant une spécificité pour cibler les cellules musculaires et permettant l’apport d’un effet auxiliaire par les lymphocytes T CD4+ lors d’injections dans des souris femelles. De plus, une de ces constructions nous permettait d’éviter la voie de présentation directe de l’antigène par les cellules dendritiques (DCs) aux lymphocytes T CD8+. Les capacités modulatrices de ces vecteurs nous permirent de montrer pour la première fois que le vecteur AAV2/1 recombinant était capable de faire exprimer un transgène au sein de la peau et d’y générer une réponse cellulaire forte. Nous avons également montré qu’il existait une synergie d’action entre l’effet auxiliaire et la voie intradermique qui améliorait considérablement les réponses cellulaires issues de la présentation croisée d’antigène. Enfin, nous avons pu démontrer que les lymphocytes T CD8+ générés suite à cette synergie d’action présentaient un profil phénotypique de cellules mémoires polyfonctionnelles et capables de protéger l’hôte face à un challenge pathogénique. / Immunological memory is the fundamental biological mechanism at the beginning of the development of vaccination. Understanding this mechanism and its interactions with the various players of the immune system has allowed the development of vaccines that are today the most effective barrier against the emergence of life-threatening infectious diseases. Route of injection and the nature of carriers of these vaccines are key parameters to be taken into consideration because they define a modulation of immune responses and their specific features. Nowadays, only the intramuscular injection route remains the major route of vaccines injection in the context of primary prophylaxis in human health. During our study, we were interested in comparing the injection of antigen (ovalbumin) following two routes of administration: intramuscular and intradermal routes. We also relied on a technology in the laboratory that involves the transfer of genes by rAAV2/1 vectors. We had two constructs of these vectors having specificity to target skeletal muscle cells and allowing us to provide a helper effect from CD4+ T cells during injections into female mice recipients. Moreover, one of these constructs enabled us to avoid the direct presentation of antigens by dendritic cells (DCs) to CD8+ T cells. The capacity of modulation of these vectors allowed us to show for the first time that the rAAV2/1 vector was able to trigger the expression of a transgene in the skin, and there to generate a strong cellular response. We have also shown that CD4+ T cell help and the intradermal route of immunization synergize to improve greatly cellular responses from the cross-presentation of antigens. Finally, we have demonstrated that CD8+ T cells generated following this synergism exhibited a phenotypic profile of polyfunctional memory cells and able to protect the host against a pathogenic challenge.
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