Browsing by Author "Hanekom, Willem A."

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    First-in-human trial of the post-exposure tuberculosis vaccine H56:IC31 in Mycobacterium tuberculosis infected and non-infected healthy adults
    (Vaccine, 2015) Luabeya, Angelique Kany Kany; Kagina, Benjamin M.N.; Kromann, Ingrid; Mahomed, Hassan; Hanekom, Willem A.
    H56:IC31 is a candidate tuberculosis vaccine comprising a fusion protein of Ag85B, ESAT-6 and Rv2660c, formulated in IC31 adjuvant. This first-in-human, open label phase I trial assessed the safety and immunogenicity of H56:IC31 in healthy adults without or with Mycobacterium tuberculosis (M.tb) infection. Low dose (15μg H56 protein in 500nmol IC31) or high dose (50μg H56, 500nmol IC31) vaccine was administered intramuscularly thrice, at 56-day intervals. Antigen-specific T cell responses were measured by intracellular cytokine staining and antibody responses by ELISA. One hundred and twenty-six subjects were screened and 25 enrolled and vaccinated. No serious adverse events were reported. Nine subjects (36%) presented with transient cardiovascular adverse events. The H56:IC31 vaccine induced antigen-specific IgG responses and Th1 cytokine-expressing CD4+ T cells. M.tb-infected vaccinees had higher frequencies of H56-induced CD4+ T cells than uninfected vaccinees. Low dose vaccination induced more polyfunctional (IFN-γ+TNF-α+IL-2+) and higher frequencies of H56-specific CD4+ T cells compared with high dose vaccination. A striking increase in IFN-γ-only-expressing CD4+ T cells, displaying a CD45RA−CCR7− effector memory phenotype, emerged after the second high-dose vaccination in M.tb-infected vaccinees. TNF-α+IL-2+ H56-specific memory CD4+ T cells were detected mostly after low-dose H56 vaccination in M.tb-infected vaccinees, and predominantly expressed a CD45RA−CCR7+ central memory phenotype. Our results support further clinical testing of H56:IC31.
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    Metabolite changes in blood predict the onset of tuberculosis
    (Nature communications, 2018) Weiner, January; Maertzdorf, Jeroen; Suliman, Sara; Hanekom, Willem A.; Mayanja-Kizza, Harriet; Kaufmann, Stefan H.E.; GC6-74 consortium
    New biomarkers of tuberculosis (TB) risk and disease are critical for the urgently needed control of the ongoing TB pandemic. In a prospective multisite study across Subsaharan Africa, we analyzed metabolic profiles in serum and plasma from HIV-negative, TB-exposed individuals who either progressed to TB 3–24 months post-exposure (progressors) or remained healthy (controls). We generated a trans-African metabolic biosignature for TB, which identifies future progressors both on blinded test samples and in external data sets and shows a performance of 69% sensitivity at 75% specificity in samples within 5 months of diagnosis. These prognostic metabolic signatures are consistent with development of subclinical disease prior to manifestation of active TB. Metabolic changes associated with pre-symptomatic disease are observed as early as 12 months prior to TB diagnosis, thus enabling timely interventions to prevent disease progression and transmission.
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    Postnatal Expansion, Maturation, and Functionality of MR1T Cells in Humans
    (Frontiers in Immunology, 2020) Swarbrick, Gwendolyn M.; Gela, Anele; Cansler, Meghan E.; Null, Megan D.; Duncan, Rowan B.; Nemes, Elisa; Shey, Muki; Nsereko, Mary; Mayanja-Kizza, Harriet; Kiguli, Sarah; Koh, Jeffrey; Hanekom, Willem A.; Hatherill, Mark; Lancioni, Christina; Lewinsohn, David M.; Scriba, Thomas J.; Lewinsohn, Deborah A.
    MR1-restricted T (MR1T) cells are defined by their recognition of metabolite antigens presented by the monomorphic MHC class 1-related molecule, MR1, the most highly conserved MHC class I related molecule in mammalian species. Mucosal-associated invariant T (MAIT) cells are the predominant subset of MR1T cells expressing an invariant TCR a-chain, TRAV1-2. These cells comprise a T cell subset that recognizes and mediates host immune responses to a broad array of microbial pathogens, including Mycobacterium tuberculosis. Here, we sought to characterize development of circulating human MR1T cells as defined by MR1-5-OP-RU tetramer labeling and of the TRAV1-2+ MAIT cells defined by expression of TRAV1-2 and high expression of CD26 and CD161 (TRAV1-2+CD161++CD26++ cells). We analyzed postnatal expansion, maturation, and functionality of peripheral blood MR1-5-OP-RU tetramer+ MR1T cells in cohorts from three different geographic settings with different tuberculosis (TB) vaccination practices, levels of exposure to and infection with M. tuberculosis. Early after birth, frequencies of MR1-5-OP-RU tetramer+ MR1T cells increased rapidly by several fold. This coincided with the transition from a predominantly CD4+ and TRAV1-2− population in neonates, to a predominantly TRAV1-2+CD161++CD26++ CD8+ population. We also observed that tetramer+ MR1T cells that expressed TNF upon mycobacterial stimulation were very low in neonates, but increased ∼10-fold in the first year of life. These functional MR1T cells in all age groups were MR1-5-OP-RU tetramer+TRAV1-2+ and highly expressed CD161 and CD26, markers that appeared to signal phenotypic and functional maturation of this cell subset. This age-associated maturation was also marked by the loss of naïve T cell markers on tetramer+ TRAV1-2+ MR1T cells more rapidly than tetramer+TRAV1-2− MR1T cells and non-MR1T cells. These data suggest that neonates have infrequent populations of MR1T cells with diverse phenotypic attributes; and that exposure to the environment rapidly and preferentially expands the MR1-5-OP-RU tetramer+TRAV1-2+ population of MR1T cells, which becomes the predominant population of functional MR1T cells early during childhood.
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    T Cell Receptor Repertoires Associated with Control and Disease Progression following Mycobacterium Tuberculosis Infection
    (Nature Medicine, 2023) Musvosvi, Munyaradzi; Wang, Chunlin; Cheruku, Abhilasha; Obermoser, Gerlinde; Leslie, Alasdair; Hanekom, Willem A.; Bilek, Nicole
    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.