Shudan Shen

LAT-mediated signaling in CD4+CD25+ regulatory T cell development

Engagement of the T cell receptor for antigen (TCR) induces formation of signaling complexes mediated through the transmembrane adaptor protein, the linker for activation of T cells (LAT). LAT plays an important role in T cell development, activation, and homeostasis. A knock-in mutation at Tyr136, which is the phospholipase C (PLC)-γ1–binding site in LAT, leads to a severe autoimmune disease in mice. In this study, we show that CD4+CD25+ T reg cells that expressed Foxp3 transcription factor were nearly absent in both thymus and peripheral lymphoid organs of LATY136F mice. This defect was not a result of the autoimmune environment as LATY136F T reg cells also failed to develop in healthy LAT−/− mice that received mixed wild-type and LATY136F bone marrow cells. Moreover, adoptive transfer of normal CD4+CD25+ T reg cells protected neonatal LATY136F mice from developing this disease. These T reg cells effectively controlled expansion of CD4+ T cells in LATY136F mice likely via granzymes and/or TGF-β–mediated suppression. Furthermore, ectopic expression of Foxp3 conferred a suppressive function in LATY136F T cells. Our data indicate that the LAT–PLC-γ1 interaction plays a critical role in Foxp3 expression and the development of CD4+CD25+ T reg cells

Cutting Edge: Localization of Linker for Activation of T Cells to Lipid Rafts Is Not Essential in T Cell Activation and Development

It has been proposed that upon T cell activation, linker for activation of T cells (LAT), a transmembrane adaptor protein localized to lipid rafts, orchestrates formation of multiprotein complexes and activates signaling cascades in lipid rafts. However, whether lipid rafts really exist or function remains controversial. To address the importance of lipid rafts in LAT function, we generated a fusion protein to target LAT to nonraft fractions using the transmembrane domain from a nonraft protein, linker for activation of X cells (LAX). Surprisingly, this fusion protein functioned well in TCR signaling. It restored MAPK activation, calcium flux, and NFAT activation in LAT-deficient cells. To further study the function of this fusion protein in vivo, we generated transgenic mice that express this protein. Analysis of these mice indicated that it was fully capable of replacing LAT in thymocyte development and T cell function. Our results demonstrate that LAT localization to lipid rafts is not essential during normal T cell activation and development.

The Role of the LAT–PLC-γ1 Interaction in T Regulatory Cell Function

The interaction between the linker for activation of T cells (LAT) with PLC-γ1 is important for TCR-mediated Ca2+ signaling and MAPK activation. Knock-in mice harboring a mutation at the PLC-γ1 binding site (Y136) of LAT develop a severe lymphoproliferative syndrome. These mice have defective thymic development and selection and lack natural regulatory T cells, implicating a breakdown of both central and peripheral tolerance. To bypass this developmental defect, we developed a conditional knock-in line in which only LATY136F is expressed in mature T cells after deletion of the wild type LAT allele. Analysis of LATY136F T cells indicated that the interaction between LAT and PLC-γ1 plays an important role in TCR-mediated signaling, proliferation, and IL-2 production. Furthermore, the deletion of LAT induced development of the lymphoproliferative syndrome in these mice. Although Foxp3+ natural Treg cells were present in these mice after deletion, they were unable to suppress the proliferation of conventional T cells. Our data indicate that the binding of LAT to PLC-γ1 is essential for the suppressive function of CD4+CD25+ regulatory T cells.

Murine Regulatory T Cells Contain Hyperproliferative and Death-Prone Subsets with Differential ICOS Expression

Regulatory T cells (Treg) are crucial for self-tolerance. It has been an enigma that Treg exhibit an anergic phenotype reflected by hypoproliferation in vitro after TCR stimulation but undergo vigorous proliferation in vivo. We report in this study that murine Treg are prone to death but hyperproliferative in vitro and in vivo, which is different from conventional CD4+Foxp3− T cells (Tcon). During in vitro culture, most Treg die with or without TCR stimulation, correlated with constitutive activation of the intrinsic death pathway. However, a small portion of the Treg population is more sensitive to TCR stimulation, particularly weak stimulation, proliferates more vigorously than CD4+ Tcon, and is resistant to activation-induced cell death. Treg proliferation is enhanced by IL-2 but is less dependent on CD28-mediated costimulation than that of Tcon. We demonstrate further that the surviving and proliferative Treg are ICOS+ whereas the death-prone Treg are ICOS−. Moreover, ICOS+ Treg contain much stronger suppressive activity than that of ICOS− Treg. Our data indicate that massive death contributes to the anergic phenotype of Treg in vitro and suggest modulation of Treg survival as a therapeutic strategy for treatment of autoimmune diseases and cancer.

The importance of LAT in the activation, homeostasis, and regulatory function of T cells

LAT (linker for activation of T cells) is a transmembrane adaptor protein that plays an essential role in TCR-mediated signaling and thymocyte development. Because LAT-deficient mice have an early block in thymocyte development, we utilized an inducible system to delete LAT in primary T cells to study LAT function in T cell activation, homeostasis, and survival. Deletion of LAT caused primary T cells to become unresponsive to stimulation from the TCR and impaired T cell homeostatic proliferation and long term survival. Furthermore, deletion of LAT led to reduced expression of Foxp3, CTLA-4, and CD25 in Treg cells and impaired their function. Consequently, mice with LAT deleted developed a lymphoproliferative syndrome similar to that in LATY136F mice, although less severe. Our data implicate that LAT has positive and negative roles in the regulation of mature T cells.

The Essential Role of LAT in Thymocyte Development during Transition from the Double-Positive to Single-Positive Stage

The linker for activation of T cells (LAT) is an adaptor protein that couples TCR engagement to downstream signaling cascades. LAT is important in early thymocyte development as LAT-deficient mice have a complete block at the double-negative (DN) 3 stage. To study the role of LAT beyond the DN3 stage, we generated mice in which the lat gene could be deleted by the Cre recombinase. Analysis of these mice showed that deletion of LAT after the DN3 stage allowed thymocytes to develop past the DN3 to DN4 checkpoint and to generate double-positive thymocytes. However, LAT-deficient DP thymocytes were severely defective in responding to stimulation via the TCR and failed to differentiate into single-positive thymocytes efficiently. Consequently, few LAT-deficient mature T cells could be found in the periphery. These T cells had undergone extensive homeostatic proliferation and expressed low levels of the TCR on their surface. Collectively, our data indicate that in addition to its role in pre-TCR signaling, LAT also plays an essential role in thymocyte development during transition from the double-positive to single-positive stage.

Critical Roles of RasGRP1 for Invariant NKT Cell Development

The invariant NKT (iNKT) cell lineage contains CD4+ and CD4− subsets. The mechanisms that control such subset differentiation and iNKT cell maturation in general have not been fully understood. RasGRP1, a guanine nucleotide exchange factor for TCR-induced activation of the Ras–ERK1/2 pathway, is critical for conventional αβ T cell development but dispensable for generating regulatory T cells. Its role in iNKT cells has been unknown. In this study, we report severe decreases of iNKT cells in RasGRP1−/− mice through cell intrinsic mechanisms. In the remaining iNKT cells in RasGRP1−/− mice, there is a selective absence of the CD4+ subset. Furthermore, RasGRP1−/− iNKT cells are defective in TCR-induced proliferation in vitro. These observations establish that RasGRP1 is not only important for early iNKT cell development but also for the generation/maintenance of the CD4+ iNKT cells. Our data provide genetic evidence that the CD4+ and CD4− iNKT cells are distinct sublineages with differential signaling requirements for their development.

Tight Regulation of Diacylglycerol-Mediated Signaling Is Critical for Proper Invariant NKT Cell Development

Type I NKT cells, or invariant NKT (iNKT) cells, express a semi-invariant TCR characterized by its unique Vα14-Jα18 usage (iVα14TCR). Upon interaction with glycolipid/CD1d complexes, the iVα14TCRs transduce signals that are essential for iNKT selection and maturation. However, it remains unclear how these signals are regulated and how important such regulations are during iNKT development. Diacylglycerol (DAG) is an essential second messenger downstream of the TCR that activates the protein kinase Cθ-IκB kinase (IKK)α/β-NF-κB pathway, known to be crucial for iNKT development, as well as the RasGRP1–Ras-Erk1/2 pathway in T cells. DAG kinases play an important role in controlling intracellular DAG concentration and thereby negatively regulate DAG signaling. In this article, we report that simultaneous absence of DAG kinase α and ζ causes severe defects in iNKT development, coincident with enhanced IKK-NF-κB and Ras-Erk1/2 activation. Moreover, constitutive IKKβ and Ras activities also result in iNKT developmental defects. Thus, DAG-mediated signaling is not only essential but also needs to be tightly regulated for proper iNKT cell development.

Diacylglycerol kinase zeta positively controls the development of iNKT-17 cells.

Invariant natural killer T (iNKT) cells play important roles in bridging innate and adaptive immunity via rapidly producing a variety of cytokines. A small subset of iNKT cells produces IL-17 and is generated in the thymus during iNKT-cell ontogeny. The mechanisms that control the development of these IL-17-producing iNKT-17 cells (iNKT-17) are still not well defined. Diacylglycerol kinase ζ (DGKζ) belongs to a family of enzymes that catalyze the phosphorylation and conversion of diacylglycerol to phosphatidic acid, two important second messengers involved in signaling from numerous receptors. We report here that DGKζ plays an important role in iNKT-17 development. A deficiency of DGKζ in mice causes a significant reduction of iNKT-17 cells, which is correlated with decreased RORγt and IL-23 receptor expression. Interestingly, iNKT-17 defects caused by DGKζ deficiency can be corrected in chimeric mice reconstituted with mixed wild-type and DGKζ-deficient bone marrow cells. Taken together, our data identify DGKζ as an important regulator of iNKT-17 development through iNKT-cell extrinsic mechanisms.