Natural Killer T Cell Development Research Articles

Liver X receptors regulate natural killer T cell population and antitumor activity in the liver of mice

The nuclear receptors liver X receptor α (LXRα) and LXRβ are lipid sensors that regulate lipid metabolism and immunity. Natural killer T (NKT) cells, a T cell subset expressing surface markers of both natural killer cells and T lymphocytes and involved in antitumor immunity, are another abundant immune cell type in the liver. The potential function of the metabolic regulators LXRα/β in hepatic NKT cells remains unknown. In this study, we examined the role of LXRα and LXRβ in NKT cells using mice deficient for LXRα and/or LXRβ, and found that hepatic invariant NKT (iNKT) cells are drastically decreased in LXRα/β-KO mice. Cytokine production stimulated by the iNKT cell activator α-galactosylceramide was impaired in LXRα/β-KO hepatic mononuclear cells and in LXRα/β-KO mice. iNKT cell-mediated antitumor effect was also disturbed in LXRα/β-KO mice. LXRα/β-KO mice transplanted with wild-type bone marrow showed decreased iNKT cells in the liver and spleen. The thymus of LXRα/β-KO mice showed a decreased population of iNKT cells. In conclusion, LXRα and LXRβ are essential for NKT cell-mediated immunity, such as cytokine production and hepatic antitumor activity, and are involved in NKT cell development in immune tissues, such as the thymus.

The distinct co-stimulatory requirements for thymic MAIT and NKT cell development

Abstract Mucosal-associated invariant T (MAIT) cells are a unique lineage of T cells that develop in the thymus. MAIT cells are positively selected by TCR recognition of microbial metabolite / MHC Class I-like molecule MR1 complexes presented on CD4/CD8 double-positive thymocytes. The developmental program of MAIT cells has been characterized as similar to that of invariant Natural Killer T (NKT) cells. Both MAIT and NKT cells acquire innate-like effector phenotypes during thymic development, and in each case differentiate into multiple subsets, with mature NKT cells categorized as either NKT1, NKT2 or NKT17, and mature MAIT cells as MAIT1 or MAIT17. We previously found distinct B7/CD28 and CD40L/CD40 co-stimulatory requirements for the development of thymic NKT subsets in BALB/c mice. In the absence of B7/CD28 co-stimulation, all NKT subsets were decreased, while only the NKT2 subset was specifically abrogated when lacking CD40L/CD40 co-stimulation. In the present study, we investigated the co-stimulatory requirements for MAIT cell development. Interestingly, MAIT17 cells were significantly increased when lacking either B7 or CD40 co-stimulation, while MAIT1 development was largely unaffected. These results revealed distinct co-stimulatory requirements for the thymic development of MAIT and NKT subsets. We are currently investigating the underlying mechanisms leading to the increase of MAIT17 cells in the absence of co-stimulatory signals.

Thymic development of unconventional T cells: how NKT cells, MAIT cells and γδ T cells emerge.

T cell lineages are defined by specialized functions and differential expression of surface antigens, cytokines and transcription factors. Conventional CD4+ and CD8+ T cells are the best studied of the T cell subsets, but 'unconventional' T cells have emerged as being more abundant and influential than has previously been appreciated. Key subsets of unconventional T cells include natural killer T (NKT) cells, mucosal-associated invariant T (MAIT) cells and γδ T cells; collectively, these make up ~10% of circulating T cells, and often they are the majority of T cells in tissues such as the liver and gut mucosa. Defects and deficiencies in unconventional T cells are associated with autoimmunity, chronic inflammation and cancer, so it is important to understand how their development is regulated. In this Review, we describe the thymic development of NKT cells, MAIT cells and γδ T cells and highlight some of the key differences between conventional and unconventional T cell development.

A focus on natural killer T-cell subset characterization and developmental stages.

Almost 20years ago, CD1d tetramers were developed to track invariant natural killer T (NKT) cells based on their specificity, and to define developmental steps during which differentiation markers and functional features are progressively acquired from early NKT cell precursor to fully mature NKT cell subsets. Based on these findings, a linear developmental model was proposed and subsequently used by all studies investigating the specific role of factors that control NKT cell development. More recently, based on intracellular staining patterns of lineage-specific transcription factors such as T-bet, GATA-3, promyelocytic leukemia zinc finger and RORγt, a lineage differentiation model was proposed for NKT cell development. Currently, studies on NKT cells development present lineage differentiation model data in addition to the linear maturation model. In the perspective presented here, we discuss current knowledge relating to NKT cell developmental models and particularly focus on the approaches and strategies, some of which appear nebulous, used to define NKT cell developmental stages and subsets.

CD160 serves as a negative regulator of NKT cells in acute hepatic injury

CD160 and BTLA both bind to herpes virus entry mediator. Although a negative regulatory function of BTLA in natural killer T (NKT) cell activation has been reported, whether CD160 is also involved is unclear. By analyzing CD160−/− mice and mixed bone marrow chimeras, we show that CD160 is not essential for NKT cell development. However, CD160−/− mice exhibit severe liver injury after in vivo challenge with α-galactosylceramide (α-GalCer). Moreover, CD160−/− mice are more susceptible to Concanavalin A challenge, and display elevated serum AST and ALT levels, hyperactivation of NKT cells, and enhanced IFN-γ, TNF, and IL-4 production. Lastly, inhibition of BTLA by anti-BTLA mAb aggravates α-GalCer-induced hepatic injury in CD160−/− mice, suggesting that both CD160 and BTLA serve as non-overlapping negative regulators of NKT cells. Our data thus implicate CD160 as a co-inhibitory receptor that delivers antigen-dependent signals in NKT cells to dampen cytokine production during early innate immune activation.

NKT Cells in Neurological Diseases.

Natural killer T (NKT) cells are a unique subset of T lymphocytes with the expression of T cell receptor (TCR) and NK cell lineage receptors. These cells can rapidly release large quantities of cytokines and function as a bridge between innate and adaptive immunity. To date, multiple reports have investigated the role of NKT cells under various pathological conditions, such as cancer, autoimmune disease, and infection. Knowledge about NKT cells in neurological diseases is increasing, albeit limited. Here, we review evidence for the involvement of NKT cells in neurological diseases, and discuss immunotherapeutic potential and future study goals. As the development and function of NKT cells become increasingly well understood, the next few years should yield many new insights into NKT cell function, and mechanistic regulation in neurological disorders.

Keap1-Nrf2 System Plays an Important Role in Invariant Natural Killer T Cell Development and Homeostasis

Kelch-like ECH-associated protein 1 (Keap1) and nuclear factor (erythroid-derived 2)-like 2 (Nrf2) proteins work in concert to regulate the levels of reactive oxygen species (ROS). The Keap1-Nrf2 antioxidant system also participates in Tcell differentiation and inflammation, but its role in innate Tcell development and functions remains unclear. We report that Tcell-specific deletion of Keap1 results in defective development and reduced numbers of invariant natural killer T (NKT) cells in the thymus and the peripheral organs in a cell-intrinsic manner. The frequency of NKT2 and NKT17 cells increases while NKT1 decreases in these mice. Keap1-deficient NKT cells show increased rates of proliferation and apoptosis, as well as increased glucose uptake and mitochondrial function, but reduced ROS, CD122, and Bcl2 expression. In NKT cells deficient in Nrf2 and Keap1, all these phenotypic and metabolic defects are corrected. Thus, the Keap1-Nrf2 system contributes to NKT cell development and homeostasis by regulating cell metabolism.

Ezh2 controls development of natural killer T cells, which cause spontaneous asthma-like pathology

Natural killer T (NKT) cells express a T-cell receptor that recognizes endogenous and environmental glycolipid antigens. Several subsets of NKT cells have been identified, including IFN-γ-producing NKT1 cells, IL-4-producing NKT2 cells, and IL-17-producing NKT17cells. However, little is known about the factors that regulate their differentiation and respective functions within the immune system. We sought to determine whether the polycomb repressive complex 2 protein enhancer of zeste homolog 2 (Ezh2) restrains pathogenicity of NKT cells in the context of asthma-like lung disease. Numbers of invariant natural killer T (iNKT) 1, iNKT2, and iNKT17cells and tissue distribution, cytokine production, lymphoid tissue localization, and transcriptional profiles of iNKT cells from wild-type and Ezh2 knockout (KO) iNKT mice were determined. The contribution of NKT cells to development of spontaneous and house dust mite-induced airways pathology, including airways hyperreactivity (AHR) to methacholine, was also assessed in wild-type, Ezh2 KO, and Ezh2 KO mice lacking NKT cells. Ezh2 restrains development of pathogenic NKT cells, which induce spontaneous asthma-like disease in mice. Deletion of Ezh2 increased production of IL-4 and IL-13 and induced spontaneous AHR, lung inflammation, mucus production, and IgE. Increased IL-4 and IL-13 levels, AHR, lung inflammation, and IgE levels were all dependent on iNKT cells. In house dust mite-exposed animals Ezh2 KO resulted in enhanced AHR that was also dependent on iNKT cells. Ezh2 is a central regulator of iNKT pathogenicity and suppresses the ability of iNKT cells to induce asthma-like pathology.

TBK-binding protein 1 regulates IL-15-induced autophagy and NKT cell survival

The cytokine IL-15 mediates development and survival of immune cells, including natural killer T (NKT) cells, but the underlying mechanism of IL-15 function is incompletely understood. Here we show that IL-15 induces autophagy in NKT cells with a mechanism that involves a crucial signaling component, TBK-binding protein 1 (Tbkbp1). Tbkbp1 facilitates activation of the autophagy-initiating kinase Ulk1 through antagonizing the inhibitory action of mTORC1. This antagonization involves the recruitment of an mTORC1-opposing phosphatase to Ulk1. Tbkbp1 deficiency attenuates IL-15-stimulated NKT cell autophagy, and is associated with mitochondrial dysfunction, aberrant ROS production, defective Bcl2 expression and reduced NKT cell survival. Consequently, Tbkbp1-deficient mice have profound deficiency in NKT cells, especially IFN-γ-producing NKT1. We further show that Tbkbp1 regulates IL-15-stimulated autophagy and survival of NK cells. These findings suggest a mechanism of autophagy induction by IL-15, and establish Tbkbp1 as a regulator of NKT cell development and survival.

CD70 Modulates Thymocyte Development and Type 1 Diabetes in NOD Mice

CD70 is a tumor necrosis factor (TNF) superfamily member expressed by activated T cells, B cells, dendritic cells, NK cells and mature macrophages. It interacts with CD27, a TNF receptor family member on T cells that regulates T cell activation, proliferation and survival. Type 1 diabetes (T1D) is caused by T cell mediated beta cell destruction, however, T1D-prone NOD mice developed accelerated disease in the absence of CD70. This was associated with altered proportions of double negative vs. double positive thymocytes in CD70 knockout mice, indicating that CD70 modulates global thymopoiesis. Also affected, but in opposing directions, was the development of regulatory T cells (Treg) and natural killer T (NKT) cells, two immunoregulatory lymphocyte subsets that are functionally and numerically deficient in NOD mice. Tregs frequencies were reduced by 23% and 32% in CD70 heterozygous (CD70-/+) and homozygous (CD70-/-) knockout mice. In contrast, NKT cell frequencies were respectively increased by 48% and 61% in CD70-/+ and CD70-/- mice compared to standard NOD mice. The higher level of NKT cells in CD70 knockout mice was unexpectedly associated with reduced levels of thymic CD1d, a molecule that is required for NKT cell development. Collectively, our results show that CD70 controls the development of several T cell populations that are known to modulate T1D development in NOD mice and that, in the absence of CD70, T1D is exacerbated. These finding may facilitate the development of clinical therapeutics aimed at enhancing the stimulatory function of CD70 as a way to suppress disease. Disclosure C. Ye: None. J. Driver: None. M.V. Wiles: None. D. Serreze: None.

Differing roles of CD1d2 and CD1d1 proteins in type I natural killer T cell development and function

MHC class I-like CD1 molecules have evolved to present lipid-based antigens to T cells. Differences in the antigen-binding clefts of the CD1 family members determine the conformation and size of the lipids that are presented, although the factors that shape CD1 diversity remain unclear. In mice, two homologous genes, CD1D1 and CD1D2, encode the CD1d protein, which is essential to the development and function of natural killer T (NKT) cells. However, it remains unclear whether both CD1d isoforms are equivalent in their antigen presentation capacity and functions. Here, we report that CD1d2 molecules are expressed in the thymus of some mouse strains, where they select functional type I NKT cells. Intriguingly, the T cell antigen receptor repertoire and phenotype of CD1d2-selected type I NKT cells in CD1D1-/- mice differed from CD1d1-selected type I NKT cells. The structures of CD1d2 in complex with endogenous lipids and a truncated acyl-chain analog of α-galactosylceramide revealed that its A'-pocket was restricted in size compared with CD1d1. Accordingly, CD1d2 molecules could not present glycolipid antigens with long acyl chains efficiently, favoring the presentation of short acyl chain antigens. These results indicate that the two CD1d molecules present different sets of self-antigen(s) in the mouse thymus, thereby impacting the development of invariant NKT cells.

NF-\u03baB Protects NKT Cells from Tumor Necrosis Factor Receptor 1-induced Death

Semi-invariant natural killer T (NKT) cells are innate-like lymphocytes with immunoregulatory properties. NKT cell survival during development requires signal processing by activated RelA/NF-κB. Nonetheless, the upstream signal(s) integrated by NF-κB in developing NKT cells remains incompletely defined. We show that the introgression of Bcl-xL-coding Bcl2l1 transgene into NF-κB signalling-deficient IκBΔN transgenic mouse rescues NKT cell development and differentiation in this mouse model. We reasoned that NF-κB activation was protecting developing NKT cells from death signals emanating either from high affinity agonist recognition by the T cell receptor (TCR) or from a death receptor, such as tumor necrosis factor receptor 1 (TNFR1) or Fas. Surprisingly, the single and combined deficiency in PKC-θ or CARMA-1—the two signal transducers at the NKT TCR proximal signalling node—only partially recapitulated the NKT cell deficiency observed in IκBΔNtg mouse. Accordingly, introgression of the Bcl2l1 transgene into PKC-θ null mouse failed to rescue NKT cell development. Instead, TNFR1-deficiency, but not the Fas-deficiency, rescued NKT cell development in IκBΔNtg mice. Consistent with this finding, treatment of thymocytes with an antagonist of the inhibitor of κB kinase —which blocks downstream NF-κB activation— sensitized NKT cells to TNF-α-induced cell death in vitro. Hence, we conclude that signal integration by NF-κB protects developing NKT cells from death signals emanating from TNFR1, but not from the NKT TCR or Fas.

Invariant natural killer T-cell development and function with loss of microRNA-155.

Invariant natural killer T (iNKT) cells are adaptive T cells with innate-like characteristics including rapid cytokine production and a proliferative response to stimulation. Development of these cells in the thymus is dependent on expression of the microRNA (miRNA) processing enzyme Dicer, indicating that iNKT cells probably have distinct miRNA requirements for gene regulation during development. The miRNA miR-155 has previously been shown to have numerous roles in T cells, including regulation of proliferation and differentiation, and positive modulation of interferon-γ expression. We examined the role of miR-155 in the development and function of iNKT cells. Using germline-deficient miR-155 mice, we showed that loss of miR-155 resulted in unchanged iNKT cell frequency and cell number. Although miR-155 was up-regulated in iNKT cells upon activation with α-galactosylceramide, loss of miR-155 did not affect cytokine production or proliferation by iNKT cells. Hence, cytokine production occurs in iNKT cells independently of miR-155 expression.

Abstract 4622: Characterization of sulfatide reactive type II NKT cells from mouse lung

Abstract The immune system plays a major role in the elimination of tumors. CD8 T cell infiltration is known to be a good prognostic indicator. The development of therapies based on checkpoint inhibitor antibodies was an important breakthrough in increasing survival by limiting the exhaustion of cytotoxic cells and increasing tumor cell eradication. However, the immune system also contains regulatory cells that protect the organism from inappropriate activation of immune cells against self-antigens. Thus, the fact that tumor cells are autologous leads regulatory cells to inhibit the activation of anti-tumor cytotoxic cells and thus increase tumor escape. Therefore, understanding the function and the activation of regulatory cells might help to develop therapies to limit the activation of regulatory cells in order to increase tumor clearance. Natural killer T (NKT) cells are lymphocytes with features of natural killer (NK) and of T cells placing them at the interface of innate and adaptive immunity. Like NK cells, they rapidly produce cytokines after stimulation, orienting the immune response. As T cells, they express a T cell receptor (TCR) that allows the recognition of specific lipids presented by the non-classical MHC-I molecule CD1d. According to their TCR usage, two populations of NKT cells are described: type I and type II. All type I NKT cells express a semi-invariant TCR (Valpha24Jalpha18 in humans, Valpha14Jalpah18 in mice) that recognizes α-galactosylceramide (αGalCer). They can be identified with the αGalCer-loaded CD1d tetramer. In contrast, type II NKT cells express a more diverse TCR repertoire. There is no currently identified lipid antigen recognized by all type II NKT cells, making their identification more difficult. A fraction of them recognize sulfatide. By using sulfatide-loaded CD1d-tetramers, we observed for the first time that sulfatide-reactive type II NKT cells were enriched in the lung, a major site of tumor metastasis. Moreover, we previously showed that in vivo stimulation of type II NKT cells with sulfatide increased the number of tumor nodules in the lung. An in-depth phenotype analysis revealed that they were CD4 or CD8 single positive cells, like conventional T cells, whereas type I NKT cells are either CD4+CD8- or double negative. Type II NKT cells do not express PLZF, the master regulator of NKT cell development and exist in PLZF-/- mice contrary to type I NKT cells. We showed that type II NKT cells also expressed markers of myeloid cells, c-Kit, CD11b and Ly6C even though histological analysis revealed lymphocytic morphology. Interestingly, at steady state, type II NKT cells expressed granzyme A but not granzyme B or perforin. The in vivo injection of sulfatide increased the expression of the activation markers CD69 and CD44 as well as granzyme A. Since the regulatory functions of type II NKT cells have been shown to be critical in tumor immunity, the detailed characterization of these cells could help to develop a new immunotherapy for cancer. Citation Format: Lise Pasquet, Shingo Kato, Tony Adams, Susan Sharrow, Theresa Davies-Hill, Elaine Jaffe, Xia Zheng, Motoshi Suzuki, Damian Kovalovsky, Jay Berzofsky, Masaki Terabe. Characterization of sulfatide reactive type II NKT cells from mouse lung [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 4622. doi:10.1158/1538-7445.AM2017-4622

Aberrant generation and function of natural killer T (NKT) cell in absence of Utx and Jmjd3

Abstract Histone H3 lysine 27 trimethylation (H3K27Me3) demethylases Jmjd3 and Utx, the epigenetic regulators, affects transcription and cell differentiation. But their specific roles in invariant natural killer T (NKT) cells development, maturation and function remain to be explored. Using T cell-specific Utx and Jmjd3 double knock out (DKO) mouse model, we identified that Utx and Jmjd3 deletion results in profound impairment in NKT numbers and maturation of both thymic and peripheral immune organs. DKO thymus NKT cells showed dramatic blockade of maturation at stage 0 and stage 1. Defective expression of Slamf1 (CD150) in DKO CD69+DP thymocytes was identified, suggesting an interrupted DP selecting process. Additionally, we found the impaired expression of PLZF, Tbet, ICOS in DKO NKT cells, which is consistent with the defective NKT sublineage development in those mice. Furthermore, DKO iNKT cells showed significantly defective IFN-r, IL-4 and IL-17 production upon activation. Bone marrow chimera experiment confirmed the major defects of NKT cell development, maturation and function in DKO mice are cell autonomous. Altogether, our present study demonstrates critical contribution of Utx and Jmjd3 in NKT cell development, lineage differentiation and function. Utx and Jmjd3 related epigenetic landscape and gene expression network involved in NKT cell development and function regulation are currently under investigation.

The role of Id3 in regulating NKT cells of the adipose tissue

Abstract Disorders involving obesity, such as diabetes, heart disease, and metabolic syndrome have become a predominant health issues in the United States and around the world. According to the CDC 36% of adults in the US qualify as obese, leading to a variety of negative health outcomes and billions of dollars in medical costs. One of the hallmarks of obesity is inflammation of the adipose tissue mediated by a combination of molecules such as hormones and cytokines produced by immune cells. Natural killer T (NKT) cells are a heterogeneous population of innate lymphocytes, defined in part, by their ability to quickly release cytokines after activation. NKT cells have been implicated in the maintenance of healthy adipose tissue, and loss of NKT cells in obesity has been correlated with the increased inflammation, glucose and insulin intolerance. As a heterogeneous population, the exact manner by which adipose resident NKT cells modulate the adipose tissue is contentious. We hope to further elucidate NKT cells’ role in adipose tissue, after activation. We also hope to define the molecules responsible for mediating NKT cells’ activity in a healthy adipose environment, with the goal of modulating these cells to improve health outcomes in the disease state. Our first molecule of interest is the inhibitor of DNA binding protein, ID3, which has been previously implicated in NKT cell development in the thymus. Here we use both a GFP reporter and a conditionally deficient line to determine the role that Id3 plays in NKT cell activation in healthy adipose tissue.

Tolerogenic interactions between CD8+ dendritic cells and NKT cells prevent rejection of bone marrow and organ grafts

AbstractThe combination of total lymphoid irradiation and anti-T-cell antibodies safely induces immune tolerance to combined hematopoietic cell and organ allografts in humans. Our mouse model required host natural killer T (NKT) cells to induce tolerance. Because NKT cells normally depend on signals from CD8+ dendritic cells (DCs) for their activation, we used the mouse model to test the hypothesis that, after lymphoid irradiation, host CD8+ DCs play a requisite role in tolerance induction through interactions with NKT cells. Selective deficiency of either CD8+ DCs or NKT cells abrogated chimerism and organ graft acceptance. After radiation, the CD8+ DCs increased expression of surface molecules required for NKT and apoptotic cell interactions and developed suppressive immune functions, including production of indoleamine 2,3-deoxygenase. Injection of naive mice with apoptotic spleen cells generated by irradiation led to DC changes similar to those induced by lymphoid radiation, suggesting that apoptotic body ingestion by CD8+ DCs initiates tolerance induction. Tolerogenic CD8+ DCs induced the development of tolerogenic NKT cells with a marked T helper 2 cell bias that, in turn, regulated the differentiation of the DCs and suppressed rejection of the transplants. Thus, reciprocal interactions between CD8+ DCs and invariant NKT cells are required for tolerance induction in this system that was translated into a successful clinical protocol.

A non-canonical function of Ezh2 preserves immune homeostasis.

Enhancer of zeste 2 (Ezh2) mainly methylates lysine 27 of histone-H3 (H3K27me3) as part of the polycomb repressive complex 2 (PRC2) together with Suz12 and Eed. However, Ezh2 can also modify non-histone substrates, although it is unclear whether this mechanism has a role during development. Here, we present evidence for a chromatin-independent role of Ezh2 during T-cell development and immune homeostasis. T-cell-specific depletion of Ezh2 induces a pronounced expansion of natural killer T (NKT) cells, although Ezh2-deficient T cells maintain normal levels of H3K27me3. In contrast, removal of Suz12 or Eed destabilizes canonical PRC2 function and ablates NKT cell development completely. We further show that Ezh2 directly methylates the NKT cell lineage defining transcription factor PLZF, leading to its ubiquitination and subsequent degradation. Sustained PLZF expression in Ezh2-deficient mice is associated with the expansion of a subset of NKT cells that cause immune perturbation. Taken together, we have identified a chromatin-independent function of Ezh2 that impacts on the development of the immune system.

NKT sublineage specification and survival requires the ubiquitin-modifying enzyme TNFAIP3/A20.

Natural killer T (NKT) cells are innate lymphocytes that differentiate into NKT1, NKT2, and NKT17 sublineages during development. However, the signaling events that control NKT sublineage specification and differentiation remain poorly understood. Here, we demonstrate that the ubiquitin-modifying enzyme TNFAIP3/A20, an upstream regulator of T cell receptor (TCR) signaling in T cells, is an essential cell-intrinsic regulator of NKT differentiation. A20 is differentially expressed during NKT cell development, regulates NKT cell maturation, and specifically controls the differentiation and survival of NKT1 and NKT2, but not NKT17, sublineages. Remaining A20-deficient NKT1 and NKT2 thymocytes are hyperactivated in vivo and secrete elevated levels of Th1 and Th2 cytokines after TCR ligation in vitro. Defective NKT development was restored by compound deficiency of MALT1, a key downstream component of TCR signaling in T cells. These findings therefore show that negative regulation of TCR signaling during NKT development controls the differentiation and survival of NKT1 and NKT2 cells.

Induction of adipose-resident NKT cells can be instructed by non ligand-binding motifs of the TCR β chain.

Abstract Invariant Natural Killer T (NKT) cells, a CD1d-restricted subset of αβ T cells, have been increasingly recognized for their role in a wide variety of functions associated with autoimmunity, cancer, infection, tolerance, and obesity. The semi-invariant TCR expressed by NKT cells is unique in its recognition of glycolipids presented by CD1d, heterodimer rigidity, and limited binding footprint compared to conventional TCR:MHC interactions. This distinctive interaction has been studied extensively in vitro, though the role of the rigid α:β heterodimer in the selection and development of NKT cells remains elusive. We investigated a hydrophobic patch on the β chain of the NKT TCR, suggested to play a role in heterodimer stability. Partial disruption of this patch, while permissive of ligand binding, resulted in decreased populations of NKT cells, diminished development, and effector function. Complete disruption of the patch resulted in the ablation of the NKT cell compartment entirely, while still accommodating conventional T cell development. NKT cells expressing the mutant NKT TCR acquired an adipose-resident NKT phenotype while in the thymus, and accumulated in the adipose tissue in mice. Hence, we show that in vivo, non-ligand binding regions of the NKT TCR are critical for the development of these important immune cells, and mediate the selection of adipose-resident NKT cells.