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Published July 21, 2020 | Published + Supplemental Material
Journal Article Open

Nur77 controls tolerance induction, terminal differentiation, and effector functions in semi-invariant natural killer T cells

Kumar, Amrendra ORCID icon
Hill, Timothy M. ORCID icon
Gordy, Laura E. ORCID icon
Suryadevara, Naveenchandra ORCID icon
Wu, Lan ORCID icon
Flyak, Andrew I. ORCID icon
Bezbradica, Jelena S. ORCID icon
Van Kaer, Luc ORCID icon
Joyce, Sebastian ORCID icon

Abstract

Semi-invariant natural killer T (iNKT) cells are self-reactive lymphocytes, yet how this lineage attains self-tolerance remains unknown. iNKT cells constitutively express high levels of Nr4a1-encoded Nur77, a transcription factor that integrates signal strength downstream of the T cell receptor (TCR) within activated thymocytes and peripheral T cells. The function of Nur77 in iNKT cells is unknown. Here we report that sustained Nur77 overexpression (Nur77^(tg)) in mouse thymocytes abrogates iNKT cell development. Introgression of a rearranged Vα14-Jα18 TCR-α chain gene into the Nur77^(tg) (Nur77^(tg);Vα14^(tg)) mouse rescued iNKT cell development up to the early precursor stage, stage 0. iNKT cells in bone marrow chimeras that reconstituted thymic cellularity developed beyond stage 0 precursors and yielded IL-4–producing NKT2 cell subset but not IFN-γ–producing NKT1 cell subset. Nonetheless, the developing thymic iNKT cells that emerged in these chimeras expressed the exhaustion marker PD1 and responded poorly to a strong glycolipid agonist. Thus, Nur77 integrates signals emanating from the TCR to control thymic iNKT cell tolerance induction, terminal differentiation, and effector functions.

Additional Information

© 2020 National Academy of Sciences. Published under the PNAS license. Edited by Philippa Marrack, National Jewish Health, Denver, CO, and approved June 2, 2020 (received for review January 28, 2020). PNAS first published July 1, 2020. We thank Drs. A. Winoto (University of California Berkeley) and M. Taniguchi (RIKEN, Japan) for the B6- B6-Nur77^(tg) (Nur77^(tg)) and B6-Jα18^(−/−) (Jα18^(−/−)) mice, respectively. We also thank A. J. Joyce for maintaining our mouse colony. We thank Vanderbilt University Medical Centre Flow Cytometry Shared Resources, supported by Vanderbilt Ingram Cancer Center (CA68485), and the NIH Tetramer Core, for the CD1d-αGC tetramer. This work was supported by NIH Grants AI137082, AI061721, and AI042284 (to S.J.), DK081536 (to L.W. and L.V.K.), and DK104817 and AI139046 (to L.V.K.); American Heart Association Grant 19TPA34910078 (to L.V.K.); and VA Merit Award BX001444 (to S.J.). Data Availability: All data are presented in the main figures and supplemental figures. Raw data and replicates are available from the corresponding author on request. Author contributions: A.K., T.M.H., L.E.G., L.W., J.S.B., and S.J. designed research; A.K., T.M.H., L.E.G., N.S., L.W., A.I.F., and J.S.B. performed research; L.V.K. contributed new reagents/analytic tools; A.K., T.M.H., L.E.G., A.I.F., J.S.B., and S.J. analyzed data; and A.K. and S.J. wrote the paper. The authors declare no competing interest. This article is a PNAS Direct Submission. This article contains supporting information online at https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2001665117/-/DCSupplemental.

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Additional details

Identifiers Funding Dates
Created:
August 22, 2023
Modified:
October 20, 2023