MR1-restricted T cell clonotypes are associated with “resistance” to Mycobacterium tuberculosis infection
Deborah L. Cross, … , Evan W. Newell, Chetan Seshadri
Deborah L. Cross, … , Evan W. Newell, Chetan Seshadri
Published May 8, 2024
Citation Information: JCI Insight. 2024;9(9):e166505. https://doi.org/10.1172/jci.insight.166505.
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Research Article Immunology Infectious disease

MR1-restricted T cell clonotypes are associated with “resistance” to Mycobacterium tuberculosis infection

Abstract

T cells are required for protective immunity against Mycobacterium tuberculosis. We recently described a cohort of Ugandan household contacts of tuberculosis cases who appear to “resist” M. tuberculosis infection (resisters; RSTRs) and showed that these individuals harbor IFN-γ–independent T cell responses to M. tuberculosis–specific peptide antigens. However, T cells also recognize nonprotein antigens via antigen-presenting systems that are independent of genetic background, known as donor-unrestricted T cells (DURTs). We used tetramer staining and flow cytometry to characterize the association between DURTs and “resistance” to M. tuberculosis infection. Peripheral blood frequencies of most DURT subsets were comparable between RSTRs and latently infected controls (LTBIs). However, we observed a 1.65-fold increase in frequency of MR1-restricted T (MR1T) cells among RSTRs in comparison with LTBIs. Single-cell RNA sequencing of 18,251 MR1T cells sorted from 8 donors revealed 5,150 clonotypes that expressed a common transcriptional program, the majority of which were private. Sequencing of the T cell receptor α/T cell receptor δ (TCRα/δ) repertoire revealed several DURT clonotypes were expanded among RSTRs, including 2 MR1T clonotypes that recognized mycobacteria-infected cells in a TCR-dependent manner. Overall, our data reveal unexpected donor-specific diversity in the TCR repertoire of human MR1T cells as well as associations between mycobacteria-reactive MR1T clonotypes and resistance to M. tuberculosis infection.

Authors

Deborah L. Cross, Erik D. Layton, Krystle K.Q. Yu, Malisa T. Smith, Melissa S. Aguilar, Shamin Li, Elise C. Wilcox, Aude G. Chapuis, Harriet Mayanja-Kizza, Catherine M. Stein, W. Henry Boom, Thomas R. Hawn, Philip Bradley, Evan W. Newell, Chetan Seshadri

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Figure 1

MR1T cells are expanded in the peripheral blood of RSTRs compared with LTBI controls.

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MR1T cells are expanded in the peripheral blood of RSTRs compared with L...
(A) Overview of study design. Household contacts of active TB cases were classified as RSTR or LTBI as defined by longitudinal testing with TST and IGRA. Combinatorial tetramer staining and multiparameter flow cytometry were used to quantify frequencies of DURTs in RSTRs (n = 25) and LTBI cases (n = 25). MR1-5-OP-RU tetramer was used to sort MR1T cells for multimodal scRNA-Seq from RSTRs (n = 4) and LTBI cases (n = 4), including identification of TCR clonotype, transcriptional profiling, and surface protein expression with Cellular Indexing of Transcriptomes and Epitopes sequencing (CITE-Seq). Deep sequencing of the TCRα and TCRδ repertoire was performed using the immunoSEQ platform (Adaptive Biotechnologies) on RSTRs (n = 20) and LTBIs (n = 20). (B) Frequencies of CD1-restricted and γδ T cells stratified by group as a proportion of live CD3+ T cells. (C) Frequencies of MR1-5-OP-RU–staining T cells as a proportion of live CD3+ T cells stratified by group. (D) Among MR1–OP-RU–staining T cells, the frequencies of T cells expressing CD4, CD8, or TRAV1-2 as a proportion of live CD3+ T cells stratified by group. Statistical testing was performed using the Wilcoxon rank sum test and unadjusted P values are displayed. A P value of less than 0.05 was considered significant. For all box plots, the upper whisker extends to the highest value within 1.5× IQR, and the lower whisker extends to the lowest value within 1.5× IQR. The horizontal line in the center of the box reflects the median value of the data. α-GalCer, α-galactosylceramide.