mTORC1 in Thymic Epithelial Cells Is Critical for Thymopoiesis, T-Cell Generation, and Temporal Control of γδT17 Development and TCRγ/δ Recombination

Thymus is crucial for generation of a diverse repertoire of T cells essential for adaptive immunity. Although thymic epithelial cells (TECs) are crucial for thymopoiesis and T cell generation, how TEC development and function are controlled is poorly understood. We report here that mTOR complex 1 (mTORC1) in TECs plays critical roles in thymopoiesis and thymus function. Acute deletion of mTORC1 in adult mice caused severe thymic involution. TEC-specific deficiency of mTORC1 (mTORC1KO) impaired TEC maturation and function such as decreased expression of thymotropic chemokines, decreased medullary TEC to cortical TEC ratios, and altered thymic architecture, leading to severe thymic atrophy, reduced recruitment of early thymic progenitors, and impaired development of virtually all T-cell lineages. Strikingly, temporal control of IL-17-producing γδT (γδT17) cell differentiation and TCRVγ/δ recombination in fetal thymus is lost in mTORC1KO thymus, leading to elevated γδT17 differentiation and rearranging of fetal specific TCRVγ/δ in adulthood. Thus, mTORC1 is central for TEC development/function and establishment of thymic environment for proper T cell development, and modulating mTORC1 activity can be a strategy for preventing thymic involution/atrophy.

[1]  W. M. Foster,et al.  iNKT cells require TSC1 for terminal maturation and effector lineage fate decisions. , 2017, The Journal of clinical investigation.

[2]  笠田 篤郎,et al.  Loss of mTOR complex 1 induces developmental blockage in early T-lymphopoiesis and eradicates T-cell acute lymphoblastic leukemia cells , 2016 .

[3]  L. Lefrançois,et al.  IL-15 receptor α signaling constrains the development of IL-17–producing γδ T cells , 2015, Proceedings of the National Academy of Sciences.

[4]  H. Takayanagi,et al.  The thymic cortical epithelium determines the TCR repertoire of IL‐17‐producing γδT cells , 2015, EMBO reports.

[5]  D. Wiest,et al.  Origins of γδ T Cell Effector Subsets: A Riddle Wrapped in an Enigma , 2014, The Journal of Immunology.

[6]  J. Gordon,et al.  Distinct contributions of Aire and antigen-presenting-cell subsets to the generation of self-tolerance in the thymus. , 2014, Immunity.

[7]  S. Ziegler,et al.  A regulatory role for TGF-β signaling in the establishment and function of the thymic medulla , 2014, Nature Immunology.

[8]  L. Klein,et al.  Positive and negative selection of the T cell repertoire: what thymocytes see (and don't see) , 2014, Nature Reviews Immunology.

[9]  M. Farrar,et al.  Costimulation via the tumor-necrosis factor receptor superfamily couples TCR signal strength to the thymic differentiation of regulatory T cells , 2014, Nature Immunology.

[10]  Y. Chien,et al.  γδ T cells: first line of defense and beyond. , 2014, Annual review of immunology.

[11]  K. Yamamura,et al.  Loss of mTOR complex 1 induces developmental blockage in early T-lymphopoiesis and eradicates T-cell acute lymphoblastic leukemia cells , 2014, Proceedings of the National Academy of Sciences.

[12]  Jimin Gao,et al.  Mechanistic target of rapamycin complex 1 is critical for invariant natural killer T-cell development and effector function , 2014, Proceedings of the National Academy of Sciences.

[13]  S. Parnell,et al.  An Essential Role for Medullary Thymic Epithelial Cells during the Intrathymic Development of Invariant NKT Cells , 2014, The Journal of Immunology.

[14]  T. Boehm,et al.  Thymus involution and regeneration: two sides of the same coin? , 2013, Nature Reviews Immunology.

[15]  Peter Vogel,et al.  mTORC1 couples immune signals and metabolic programming to establish Treg cell function , 2013, Nature.

[16]  J. Caamaño,et al.  The thymic medulla is required for Foxp3+ regulatory but not conventional CD4+ thymocyte development , 2013, The Journal of experimental medicine.

[17]  D. Pennington,et al.  Epithelial and dendritic cells in the thymic medulla promote CD4+Foxp3+ regulatory T cell development via the CD27–CD70 pathway , 2013, The Journal of experimental medicine.

[18]  W. Born,et al.  Diversity of γδ T-cell antigens , 2012, Cellular and Molecular Immunology.

[19]  Danli Xie,et al.  Tumor suppressor TSC1 is critical for T-cell anergy , 2012, Proceedings of the National Academy of Sciences.

[20]  A. Krueger,et al.  Development of interleukin-17-producing γδ T cells is restricted to a functional embryonic wave. , 2012, Immunity.

[21]  Y. Takahama,et al.  Thymic epithelial cells: working class heroes for T cell development and repertoire selection. , 2012, Trends in immunology.

[22]  T. Soga,et al.  mTORC1 is essential for leukemia propagation but not stem cell self-renewal. , 2012, The Journal of clinical investigation.

[23]  Keunwook Lee,et al.  Vital roles of mTOR complex 2 in Notch-driven thymocyte differentiation and leukemia , 2012, The Journal of experimental medicine.

[24]  D. Sabatini,et al.  mTOR Signaling in Growth Control and Disease , 2012, Cell.

[25]  B. Gorentla,et al.  Critical Roles of RasGRP1 for Invariant NKT Cell Development , 2011, The Journal of Immunology.

[26]  D. Roopenian,et al.  Foxn1 Regulates Lineage Progression in Cortical and Medullary Thymic Epithelial Cells But Is Dispensable for Medullary Sublineage Divergence , 2011, PLoS genetics.

[27]  A. Hayday,et al.  Skint-1 identifies a common molecular mechanism for the development of interferon-γ-secreting versus interleukin-17-secreting γδ T cells. , 2011, Immunity.

[28]  R. Kageyama,et al.  Notch-Hes1 pathway is required for the development of IL-17-producing γδ T cells. , 2011, Blood.

[29]  T. Boehm,et al.  Three chemokine receptors cooperatively regulate homing of hematopoietic progenitors to the embryonic mouse thymus , 2011, Proceedings of the National Academy of Sciences.

[30]  B. Gorentla,et al.  Negative regulation of mTOR activation by diacylglycerol kinases. , 2011, Blood.

[31]  D. Sabatini,et al.  mTORC1 controls fasting-induced ketogenesis and its modulation by ageing , 2010, Nature.

[32]  A. Bhandoola,et al.  T‐cell lineage determination , 2010, Immunological reviews.

[33]  A. Bhandoola,et al.  CCR7 and CCR9 together recruit hematopoietic progenitors to the adult thymus. , 2010, Blood.

[34]  E. Kremmer,et al.  CC chemokine receptor 7 and 9 double-deficient hematopoietic progenitors are severely impaired in seeding the adult thymus. , 2010, Blood.

[35]  W. Leonard,et al.  Cutting Edge: Spontaneous Development of IL-17–Producing γδ T Cells in the Thymus Occurs via a TGF-β1–Dependent Mechanism , 2010, The Journal of Immunology.

[36]  N. Manley,et al.  Transcriptional regulation of thymus organogenesis and thymic epithelial cell differentiation. , 2010, Progress in molecular biology and translational science.

[37]  P. Chambon,et al.  Postnatal Tissue-specific Disruption of Transcription Factor FoxN1 Triggers Acute Thymic Atrophy* , 2009, The Journal of Biological Chemistry.

[38]  M. V. D. van den Brink,et al.  Rejuvenation of the aging T cell compartment. , 2009, Current opinion in immunology.

[39]  A. Hayday,et al.  CD27 is a thymic determinant of the balance between interferon-γ- and interleukin 17–producing γδ T cell subsets , 2009, Nature Immunology.

[40]  N. Manley,et al.  Foxn1 is required to maintain the postnatal thymic microenvironment in a dosage-sensitive manner. , 2009, Blood.

[41]  S. Parnell,et al.  Checkpoints in the Development of Thymic Cortical Epithelial Cells1 , 2009, The Journal of Immunology.

[42]  H. Takayanagi,et al.  The tumor necrosis factor family receptors RANK and CD40 cooperatively establish the thymic medullary microenvironment and self-tolerance. , 2008, Immunity.

[43]  D. Gray,et al.  Unbiased analysis, enrichment and purification of thymic stromal cells. , 2008, Journal of immunological methods.

[44]  A. Gudkov,et al.  Keratinocyte growth factor (KGF) enhances postnatal T-cell development via enhancements in proliferation and function of thymic epithelial cells. , 2007, Blood.

[45]  P. Scholtes,et al.  Isolation of CD4+ T cells from murine lungs: a method to analyze ongoing immune responses in the lung , 2006, Nature Protocols.

[46]  N. Manley,et al.  Specific expression of lacZ and cre recombinase in fetal thymic epithelial cells by multiplex gene targeting at the Foxn1 locus , 2007, BMC Developmental Biology.

[47]  D. Gray,et al.  Developmental kinetics, turnover, and stimulatory capacity of thymic epithelial cells. , 2006, Blood.

[48]  K. Calame,et al.  Blimp-1 is required for maintenance of long-lived plasma cells in the bone marrow , 2005, The Journal of experimental medicine.

[49]  L. Hennighausen,et al.  Genetic evidence supporting selection of the Valpha14i NKT cell lineage from double-positive thymocyte precursors. , 2005, Immunity.

[50]  Cunlan Liu,et al.  The role of CCL21 in recruitment of T-precursor cells to fetal thymi. , 2005, Blood.

[51]  N. Killeen,et al.  CCR7 Directs the Migration of Thymocytes into the Thymic Medulla1 , 2004, The Journal of Immunology.

[52]  W. Born,et al.  Subset‐specific, uniform activation among Vγ6/Vδ1+ γδ T cells elicited by inflammation , 2004 .

[53]  A. Singer,et al.  CD4/CD8 coreceptors in thymocyte development, selection, and lineage commitment: analysis of the CD4/CD8 lineage decision. , 2004, Advances in immunology.

[54]  N. Manley,et al.  A domain of Foxn1 required for crosstalk-dependent thymic epithelial cell differentiation , 2003, Nature Immunology.

[55]  S. Scheu,et al.  Thymic Medullary Epithelial Cell Differentiation, Thymocyte Emigration, and the Control of Autoimmunity Require Lympho–Epithelial Cross Talk via LTβR , 2003, The Journal of experimental medicine.

[56]  Mark S. Anderson,et al.  Projection of an Immunological Self Shadow Within the Thymus by the Aire Protein , 2002, Science.

[57]  L. Klein,et al.  Promiscuous gene expression in medullary thymic epithelial cells mirrors the peripheral self , 2001, Nature Immunology.

[58]  B. Kyewski,et al.  Two Genetically Separable Steps in the Differentiation of Thymic Epithelium , 1996, Science.

[59]  Hongyu Luo,et al.  The effect of rapamycin on T cell development in mice , 1994, European journal of immunology.

[60]  I. Weissman Developmental switches in the immune system , 1994, Cell.

[61]  S. Tonegawa,et al.  Gamma/delta cells. , 1993, Annual review of immunology.

[62]  I. Weissman,et al.  A developmental switch in thymic lymphocyte maturation potential occurs at the level of hematopoietic stem cells , 1990, Cell.

[63]  J. Allison,et al.  Developmentally ordered appearance of thymocytes expressing different T-cell antigen receptors , 1988, Nature.