iNKT cells require TSC1 for terminal maturation and effector lineage fate decisions
Jinhong Wu, … , Hongbo Chi, Xiao-Ping Zhong
Jinhong Wu, … , Hongbo Chi, Xiao-Ping Zhong
Published March 10, 2014
Citation Information: J Clin Invest. 2014;124(4):1685-1698. https://doi.org/10.1172/JCI69780.
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Research Article

iNKT cells require TSC1 for terminal maturation and effector lineage fate decisions

Abstract

Terminal maturation of invariant NKT (iNKT) cells from stage 2 (CD44+NK1.1) to stage 3 (CD44+NK1.1+) is accompanied by a functional acquisition of a predominant IFN-γ–producing (iNKT-1) phenotype; however, some cells develop into IL-17–producing iNKT (iNKT-17) cells. iNKT-17 cells are rare and restricted to a CD44+NK1.1 lineage. It is unclear how iNKT terminal maturation is regulated and what factors mediate the predominance of iNKT-1 compared with iNKT-17. The tumor suppressor tuberous sclerosis 1 (TSC1) is an important negative regulator of mTOR signaling, which regulates T cell differentiation, function, and trafficking. Here, we determined that mice lacking TSC1 exhibit a developmental block of iNKT differentiation at stage 2 and skew from a predominantly iNKT-1 population toward a predominantly iNKT-17 population, leading to enhanced airway hypersensitivity. Evaluation of purified iNKT cells revealed that TSC1 promotes T-bet, which regulates iNKT maturation, but downregulates ICOS expression in iNKT cells by inhibiting mTOR complex 1 (mTORC1). Furthermore, mice lacking T-bet exhibited both a terminal maturation defect of iNKT cells and a predominance of iNKT-17 cells, and increased ICOS expression was required for the predominance of iNKT-17 cells in the population of TSC1-deficient iNKT cells. Our data indicate that TSC1-dependent control of mTORC1 is crucial for terminal iNKT maturation and effector lineage decisions, resulting in the predominance of iNKT-1 cells.

Authors

Jinhong Wu, Jialong Yang, Kai Yang, Hongxia Wang, Balachandra Gorentla, Jinwook Shin, Yurong Qiu, Loretta G. Que, W. Michael Foster, Zhenwei Xia, Hongbo Chi, Xiao-Ping Zhong

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Figure 7

TSC1 ensures the iNKT-1/iNKT-17 dichotomy in part via by inhibiting ICOS expression.

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TSC1 ensures the iNKT-1/iNKT-17 dichotomy in part via by inhibiting ICOS...
(A) iNKT-17 cells are confined to the ICOS+ subset. CD1dTet-enriched WT thymic iNKT cells were stimulated with PMA and ionomycin for 5 hours in the presence of GolgiPlug followed by TCRβ, ICOS, NK1.1, CD4, and intracellular IFN-γ and IL-17A staining. Dot plots show IFN-γ or IL-17A and ICOS expression in live-gated CD1dTet+TCRβ+Lin (CD8, CD11b, CD11c, B220) iNKT subsets. (B) ICOS+ and ICOS iNKT cells in WT and TSC1KO thymi. (C) Expression of IFN-γ and IL-17A in ICOS+ and ICOS iNKT subsets from WT and TSC1KO thymi. (D and E) Overexpression of ICOS increases IL-17 production by iNKT cells. Thymocytes from WT mice were similarly stimulated with α-GalCer in vitro, infected with retrovirus expressing either GFP or GFP plus ICOS, and analyzed for intracellular cytokine expression, as in Figure 6F. (D) Dot plots show IFN-γ and IL-17A expression in GFP+CD1dTet+TCRβ+ iNKT cells. (E) Percentages of IFN-γ+, IFN-γ+IL-17A+, and IL-17A+ cells in GFP+ iNKT cells (mean ± SEM, n = 4). (F and G) Absence of ICOS partially reverted the iNKT-17 predominance over iNKT-1 caused by TSC1 deficiency. iNKT cells enriched from thymi of indicated mice were similarly stimulated by P + I and analyzed as in A. (F) Contour plots show IFN-γ and IL-17A expression in live-gated CD1dTet+TCRβ+Lin iNKT cells. (G) IL-17A+ to IFN-γ+ ratios in iNKT cells (mean ± SEM; n = 3). *P < 0.05; **P < 0.01; ***P < 0.001, Student’s t test (E) or 1-way ANOVA (G). Data shown represent 3 independent experiments.