27 research outputs found
Antigen-Specific T-Cell Activation Distinguishes between Recent and Remote Tuberculosis Infection
Rationale: Current diagnostic tests fail to identify individuals at higher risk of progression to tuberculosis disease, such as those with recent Mycobacterium tuberculosis infection, who should be prioritized for targeted preventive treatment. Objectives: To define a blood-based biomarker, measured with a simple flow cytometry assay, that can stratify different stages of tuberculosis infection to infer risk of disease. Methods: South African adolescents were serially tested with QuantiFERON-TB Gold to define recent (QuantiFERON-TB conversion 1 yr) infection. We defined the ΔHLA-DR median fluorescence intensity biomarker as the difference in HLA-DR expression between IFN-γ+ TNF+ Mycobacterium tuberculosis-specific T cells and total CD3+ T cells. Biomarker performance was assessed by blinded prediction in untouched test cohorts with recent versus persistent infection or tuberculosis disease and by unblinded analysis of asymptomatic adolescents with tuberculosis infection who remained healthy (nonprogressors) or who progressed to microbiologically confirmed disease (progressors). Measurements and Main Results: In the test cohorts, frequencies of Mycobacterium tuberculosis-specific T cells differentiated between QuantiFERON-TB- (n = 25) and QuantiFERON-TB+ (n = 47) individuals (area under the receiver operating characteristic curve, 0.94; 95% confidence interval, 0.87-1.00). ΔHLA-DR significantly discriminated between recent (n = 20) and persistent (n = 22) QuantiFERON-TB+ (0.91; 0.83-1.00); persistent QuantiFERON-TB+ and newly diagnosed tuberculosis (n = 19; 0.99; 0.96-1.00); and tuberculosis progressors (n = 22) and nonprogressors (n = 34; 0.75; 0.63-0.87). However, ΔHLA-DR median fluorescent intensity could not discriminate between recent QuantiFERON-TB+ and tuberculosis (0.67; 0.50-0.84). Conclusions: The ΔHLA-DR biomarker can identify individuals with recent QuantiFERON-TB conversion and those with disease progression, allowing targeted provision of preventive treatment to those at highest risk of tuberculosis. Further validation studies of this novel immune biomarker in various settings and populations at risk are warranted
Combined Use of Mycobacterium tuberculosis-Specific CD4 and CD8 T-Cell Responses Is a Powerful Diagnostic Tool of Active Tuberculosis.
Immune-based assays are promising tools to help to formulate diagnosis of active tuberculosis. A multiparameter flow cytometry assay assessing T-cell responses specific to Mycobacterium tuberculosis and the combination of both CD4 and CD8 T-cell responses accurately discriminated between active tuberculosis and latent infection
Multidimensional analyses reveal modulation of adaptive and innate immune subsets by tuberculosis vaccines
We characterize the breadth, function and phenotype of innate and adaptive cellular responses in a prevention of Mycobacterium tuberculosis infection trial. Responses are measured by whole blood intracellular cytokine staining at baseline and 70 days after vaccination with H4:IC31 (subunit vaccine containing Ag85B and TB10.4), Bacille Calmette-Guerin (BCG, a live attenuated vaccine) or placebo (n = ~30 per group). H4:IC31 vaccination induces Ag85B and TB10.4-specific CD4 T cells, and an unexpected NKTlike subset, that expresses IFN-γ, TNF and/or IL-2. BCG revaccination increases frequencies of CD4 T cell subsets that either express Th1 cytokines or IL-22, and modestly increases IFNγ-producing NK cells. In vitro BCG re-stimulation also triggers responses by donor-unrestricted T cells, which may contribute to host responses against mycobacteria. BCG, which demonstrated efficacy against sustained Mycobacterium tuberculosis infection, modulates multiple immune cell subsets, in particular conventional Th1 and Th22 cells, which should be investigated in discovery studies of correlates of protection
T cell receptor repertoires associated with control and disease progression following Mycobacterium tuberculosis infection
Antigen-specific, MHC-restricted αβ T cells are necessary for protective immunity against Mycobacterium tuberculosis, but the ability to broadly study these responses has been limited. In the present study, we used single-cell and bulk T cell receptor (TCR) sequencing and the GLIPH2 algorithm to analyze M. tuberculosis-specific sequences in two longitudinal cohorts, comprising 166 individuals with M. tuberculosis infection who progressed to either tuberculosis (n = 48) or controlled infection (n = 118). We found 24 T cell groups with similar TCR-β sequences, predicted by GLIPH2 to have common TCR specificities, which were associated with control of infection (n = 17), and others that were associated with progression to disease (n = 7). Using a genome-wide M. tuberculosis antigen screen, we identified peptides targeted by T cell similarity groups enriched either in controllers or in progressors. We propose that antigens recognized by T cell similarity groups associated with control of infection can be considered as high-priority targets for future vaccine development
Comparison of CyTOF assays across sites: Results of a six-center pilot study.
For more than five years, high-dimensional mass cytometry has been employed to study immunology. However, these studies have typically been performed in one laboratory on one or few instruments. We present the results of a six-center study using healthy control human peripheral blood mononuclear cells (PBMCs) and commercially available reagents to test the intra-site and inter-site variation of mass cytometers and operators. We used prestained controls generated by the primary center as a reference to compare against samples stained at each individual center. Data were analyzed at the primary center, including investigating the effects of two normalization methods. All six sites performed similarly, with CVs for both Frequency of Parent and median signal intensity (MSI) values<30%. Increased background was seen when using the premixed antibody cocktail aliquots at each site, suggesting that cocktails are best made fresh. Both normalization methods tested performed adequately for normalizing MSI values between centers. Clustering algorithms revealed slight differences between the prestained and the sites-stained samples, due mostly to the increased background of a few antibodies. Therefore, we believe that multicenter mass cytometry assays are feasible
Mixed Th1 and Th2 Mycobacterium tuberculosis-specific CD4 T cell responses in patients with active pulmonary tuberculosis from Tanzania.
Mycobacterium tuberculosis (Mtb) and helminth infections elicit antagonistic immune effector functions and are co-endemic in several regions of the world. We therefore hypothesized that helminth infection may influence Mtb-specific T-cell immune responses. We evaluated the cytokine profile of Mtb-specific T cells in 72 individuals with pulmonary TB disease recruited from two Sub-Saharan regions with high and moderate helminth burden i.e. 55 from Tanzania (TZ) and 17 from South Africa (SA), respectively. We showed that Mtb-specific CD4 T-cell functional profile of TB patients from Tanzania are primarily composed of polyfunctional Th1 and Th2 cells, associated with increased expression of Gata-3 and reduced expression of T-bet in memory CD4 T cells. In contrast, the cytokine profile of Mtb-specific CD4 T cells of TB patients from SA was dominated by single IFN-γ and dual IFN-γ/TNF-α and associated with TB-induced systemic inflammation and elevated serum levels of type I IFNs. Of note, the proportion of patients with Mtb-specific CD8 T cells was significantly reduced in Mtb/helminth co-infected patients from TZ. It is likely that the underlying helminth infection and possibly genetic and other unknown environmental factors may have caused the induction of mixed Th1/Th2 Mtb-specific CD4 T cell responses in patients from TZ. Taken together, these results indicate that the generation of Mtb-specific CD4 and CD8 T cell responses may be substantially influenced by environmental factors in vivo. These observations may have major impact in the identification of immune biomarkers of disease status and correlates of protection
A quantitative analysis of complexity of human pathogen-specific CD4 T cell responses in healthy M. tuberculosis infected South Africans
Author Summary: Human pathogen-specific immune responses are tremendously complex and the techniques to study them ever expanding. There is an urgent need for a quantitative analysis and better understanding of pathogen-specific immune responses. Mycobacterium tuberculosis (Mtb) is one of the leading causes of mortality due to an infectious agent worldwide. Here, we were able to quantify the Mtb-specific response in healthy individuals with Mtb infection from South Africa. The response is highly diverse and 66 epitopes are required to capture 80% of the total reactivity. Our study also show that the majority of the identified epitopes are restricted by multiple HLA alleles. Thus, technical advances are required to capture and characterize the complete pathogen-specific response. This study demonstrates further that the approach combining identified epitopes into "megapools" allows capturing a large fraction of the total reactivity. This suggests that this technique is generally applicable to the characterization of immunity to other complex pathogens. Together, our data provide for the first time a quantitative analysis of the complex pathogen-specific T cell response and provide a new understanding of human infections in a natural infection setting
Salmonella Typhi-specific multifunctional CD8+ T cells play a dominant role in protection from typhoid fever in humans.
BACKGROUND: Typhoid fever, caused by the human-restricted organism Salmonella Typhi (S. Typhi), is a major public health problem worldwide. Development of novel vaccines remains imperative, but is hampered by an incomplete understanding of the immune responses that correlate with protection.
METHODS: Recently, a controlled human infection model was re-established in which volunteers received ~10(3) cfu wild-type S. Typhi (Quailes strain) orally. Twenty-one volunteers were evaluated for their cell-mediated immune (CMI) responses. Ex vivo PBMC isolated before and up to 1 year after challenge were exposed to three S. Typhi-infected targets, i.e., autologous B lymphoblastoid cell-lines (B-LCL), autologous blasts and HLA-E restricted AEH B-LCL cells. CMI responses were evaluated using 14-color multiparametric flow cytometry to detect simultaneously five intracellular cytokines/chemokines (i.e., IL-17A, IL-2, IFN-g, TNF-a and MIP-1b) and a marker of degranulation/cytotoxic activity (CD107a).
RESULTS: Herein we provide the first evidence that S. Typhi-specific CD8+ responses correlate with clinical outcome in humans challenged with wild-type S. Typhi. Higher multifunctional S. Typhi-specific CD8+ baseline responses were associated with protection against typhoid and delayed disease onset. Moreover, following challenge, development of typhoid fever was accompanied by decreases in circulating S. Typhi-specific CD8+ T effector/memory (TEM) with gut homing potential, suggesting migration to the site(s) of infection. In contrast, protection against disease was associated with low or no changes in circulating S. Typhi-specific TEM.
CONCLUSIONS: These studies provide novel insights into the protective immune responses against typhoid disease that will aid in selection and development of new vaccine candidates
Cellular immune responses against mycobacterium tuberculosis
Mycobacterium tuberculosis (Mtb) infection is known to have two main outcomes: latent infection (LTBI) where the pathogen is in a dormant form or active tuberculosis disease (TB), which is, most of the time, highly transmissible.
Over one-third of the world's population asymptomatically harbours a latent form of Mtb with a 10% risk of disease reactivation. Efficient vaccine strategies remain unknown and the existing BCG vaccine is believed to protect against only some forms of TB (extra-pulmonary TB in children). Moreover, timely identification of TB remains complex with the actual diagnosis based on clinical observations associated to low efficient tests. Furthermore, current therapies are expensive, heavy and long for patients, and present lesser and lesser efficiency against new drug-resistant strains of Mtb.
It is thus important to develop our knowledge on host -Mtb relationship to propose new vaccines, diagnosis tools and medications for the future. This thesis aims at improving our understanding of human immunology in the field of TB. All along this work, the same algorithm has been used and points towards the discovery of new correlates of protection through the comparison of T-cell immune responses in patients with LTBI or TB.
We performed a comprehensive analysis of T-cell immune responses to Mtb using polychromatic flow cytometiy to study the functional profile of Μ/ό-specific CD4 Τ cells. We observed a polyfunctional profile in LTBI where CD4 Τ cells mainly co-produced IFN-γ, TNF-α and IL-2. In contrast, in TB, Mtó-specific CD4 Τ cells were mostly single TNF-a positive. Thus, analysis of the cytokine profiles was a strong immunological measure discriminating TB and LTBI. We next analyzed Thl7 cells. Mtò-specific Thl7 cells lacked immediate {i.e. ex vivo) IL-17A effector function in both LTBI and TB individuals. Moreover, they were also absent in bronchoalveolar lavages (BALs). Interestingly, we noticed that Mtb- specific Thl7 cells from LTBI but not from TB subjects acquired the ability to produce IL- 17A following Mtb-specific T-cell expansion.
We finally performed a comprehensive characterization of Mfè-specific CD8 Τ cells that were detected in most (60%) TB patients and few (15%) LTBI subjects. We observed differences in the phenotype, the cytotoxicity and the proliferative capacities but not in the cytokine profile of Mtò-specific CD8 Τ cells between LTBI and TB. We concluded that the activity of Mtb infection (i.e. latent versus active) and the clinical presentation were associated to distinct profiles of Mtó-specific CD8 T-cell responses.
To conclude, a multiparametric analysis including both CD4 and CD8 T-cell responses to Mtb lead to the development of a significantly improved diagnostic test discriminating between LTBI and TB.
All together, these results provide new insights into the interaction between Mtb and the host immune response and expand upon our prior knowledge of tuberculosis.
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L'infection par Mycobacterium tuberculosis peut résulter en une infection tuberculeuse latente et asymptomatique ou encore en une forme active et la plupart du temps contagieuse, la tuberculose. Un tiers de la population mondiale serait infectée de manière chronique avec 10 % de risques de développer la maladie durant la vie. Il n'existe actuellement aucun vaccin efficace, le BCG ne conférant qu'une protection partielle contre certaines formes extrapulmonaires de la maladie chez l'enfant. D'autre part, il n'existe pas de méthode diagnostique fiable et rapide, celle-ci se basant dans un premier temps sur l'analyse de la situation clinique des patients. Enfin, les thérapies actuelles sont couteuses et contraignantes pour les patients et tendent à ne plus être efficaces contre les souches émergentes de mycobactérie multi-résistantes.
Aussi, il est important de bien comprendre la relation hôte-pathogène de manière à pouvoir proposer de nouveaux outils vaccinaux, diagnostiques et thérapeutiques. Ce manuscrit s'inscrit dans cette direction et vise à améliorer nos connaissances de la réponse immunitaire humaine dans le cadre de la tuberculose. Nous avons suivi un algorithme similaire tout au long des études proposées en comparant les réponses immunes des patients latents à celles des patients actifs, et ce, dans le but de mettre en évidence de potentiels corrélats de protection.
Nous avons réalisé par cytométrie en flux une analyse du profil fonctionnel des cellules lymphocytaires CD4 dans la réponse au pathogène. Dans le cas de la tuberculose active, les cellules CD4 sécrètent majoritairement du TNF-α quand, au contraire, elles sécrètent à la fois du TNF-α, de l'IFN-γ et de l'IL-2 (poly-fonctionnalité) dans l'infection latente. Cette observation nous a permis de proposer un nouveau test diagnostique de la maladie active. Nous avons aussi étudié les cellules CD4 Thl7, impliquées dans la réponse immunitaire cellulaire contre les pathogènes extracellulaires et les champignons. Nous avons souligné une variation dans la production d'IL-17 entre infection latente et tuberculose active qui pourrait être impliquée dans la protection de l'individu contre le pathogène.
D'autre part, ce manuscrit propose une caractérisation des cellules Τ CD8 dites cytotoxiques dans la tuberculose. Des divergences dans la fréquence des réponses observées, le phénotype mais aussi les capacités prolifératives et cytotoxiques ont pu être mises en évidence entre latence et tuberculose active. Ces observations soulignent le rôle important de ce groupe cellulaire dans l'évolution de la maladie et permettent de proposer une amélioration de l'outil diagnostic précédemment proposé et se basant à la fois sur le profil fonctionnel des cellules Τ CD4 ainsi que sur la présence potentielle d'une réponse CD8 spécifique au pathogène.
Ces diverses études réalisées sur les cellules Τ humaines répondant spécifiquement à Mtb nous permettent de faire un pas supplémentaire dans la compréhension de notre réponse immunitaire face à ce pathogène particulièrement dangereux qui continue à l'heure actuelle à tuer chaque année des millions de personnes.
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La tuberculose (TB) résulte d'une infection bactérienne par Mycobacterium tuberculosis (Mtb) et existe sous deux formes majeures: une forme latente, lorsque la bactérie est en phase de dormance ainsi qu'une forme active durant laquelle la bactérie se divise activement, entraînant les symptômes de la maladie. La personne infectée devient alors contagieuse dans la plupart des cas. Aujourd'hui des études épidémiologiques assument que plus d'un tiers de la population mondiale serait infectée par la forme latente de la bactérie et que 10% des cas réactiveront donnant lieu à diverses présentations de la maladie.
Il n'existe actuellement aucun vaccin réellement efficace chez l'adulte. D'autre part, les traitements antibiotiques utilisés sont très lourds pour les patients et les cliniciens doivent faire face à l'émergence de nouvelles souches bactériennes multi-résistantes non affectées par les thérapies existantes. Les autorités sanitaires sont, d'autre part, confrontées à l'absence d'un outil diagnostique rapide, fiable et efficace. En effet, la méthode de référence reste la culture microbiologique du pathogène qui prend généralement plusieurs semaines, pendant lesquelles le patient pourra contaminer d'autres personnes.
En résumé, la lutte contre la tuberculose doit passer par l'élaboration d'un vaccin efficace, de nouvelles thérapies, mais aussi par la mise en place de nouveaux tests diagnostics plus rapides afin d'éviter la dissémination de la maladie. Aussi, la relation hôte-bactérie qui n'est actuellement que peu comprise doit être investiguée. Ce travail de thèse a pour but d'étudier la réponse immunitaire chez l'homme infecté par Mtb et vise plus particulièrement l'étude d'une population clé de cellules immunitaires: les lymphocytes T.
L'étude des cellules Τ CD4 nous a permis dans un premier temps de proposer un nouveau test diagnostic de la maladie active. Nous avons aussi analysé plus en détail une population spécifique des cellules Τ CD4 (les cellules Thl7), nous permettant d'associer leur fonction avec un possible état physiologique de protection contre le pathogène.
En second lieu nous avons réalisé une caractérisation des cellules Τ CD8, à la fois chez les personnes avec des infections latentes et chez les personnes malades. Nous avons mis en évidence des différences fonctionnelles chez les deux groupes de patients, nous permettant ainsi une meilleure compréhension de l'immunité contre Mtb. Enfin, nous avons combiné les différents profils immunologiques obtenus pour développer un test diagnostic plus performant et sensible que celui proposé antérieurement.
Ces diverses études réalisées sur les cellules Τ humaines nous permettent de faire un pas supplémentaire dans la compréhension de la réponse immunitaire face à ce pathogène particulièrement dangereux qui continue à tuer chaque année des millions de personnes