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