MHC class II-expressing thymocytes suppress invariant NKT cell development.

Natural killer T (NKT) cells are positively selected on cortical thymocytes expressing the non-classical major histocompatibility complex (MHC) class I CD1d molecules. However, it is less clear how NKT cells are negatively selected in the thymus. In this study, we investigated the role of MHC class II expression in NKT cell development. Transgenic mice expressing MHC class II on thymocytes and peripheral T cells had a marked reduction in invariant NKT (iNKT) cells. Reduced numbers of iNKT cells correlated with the absence of in vivo production of cytokines in response to the iNKT cell agonist alpha-galactosylceramide. Using mixed bone marrow chimeras, we found that MHC class II-expressing thymocytes suppressed the development of iNKT cells in trans in a CD4-dependent manner. Our observations have significant implications for human iNKT cell development as human thymocytes express MHC class II, which can lead to an inefficient selection of iNKT cells.

Homotypic interactions mediated by Slamf1 and Slamf6 receptors control NKT cell lineage development.

Commitment to the T and natural killer T (NKT) cell lineages is determined during alphabeta T cell receptor (TCR)-mediated interactions of common precursors with ligand-expressing cells in the thymus. Whereas mainstream thymocyte precursors recognize major histocompatibility complex (MHC) ligands expressed by stromal cells, NKT cell precursors interact with CD1d ligands expressed by cortical thymocytes. Here, we demonstrated that such homotypic T-T interactions generated "second signals" mediated by the cooperative engagement of the homophilic receptors Slamf1 (SLAM) and Slamf6 (Ly108) and the downstream recruitment of the adaptor SLAM-associated protein (SAP) and the Src kinase Fyn, which are essential for the lineage expansion and differentiation of the NKT cell lineage. These receptor interactions were required during TCR engagement and therefore only occurred when selecting ligands were presented by thymocytes rather than epithelial cells, which do not express Slamf6 or Slamf1. Thus, the topography of NKT cell ligand recognition determines the availability of a cosignaling pathway that is essential for NKT cell lineage development.

A distal effect of microsomal triglyceride transfer protein deficiency on the lysosomal recycling of CD1d.

Microsomal triglyceride transfer protein (MTP) is an endoplasmic reticulum (ER)-resident lipid transfer protein involved in the biosynthesis and lipid loading of apolipoprotein B. MTP was recently suggested to directly regulate the biosynthesis of the MHC I-like, lipid antigen presenting molecule CD1d, based on coprecipitation experiments and lipid loading assays. However, we found that the major impact of MTP deficiency occurred distal to the ER and Golgi compartments. Thus, although the rates of CD1d biosynthesis, glycosylation maturation, and internalization from the cell surface were preserved, the late but essential stage of recycling from lysosome to plasma membrane was profoundly impaired. Likewise, functional experiments indicated defects of CD1d-mediated lipid presentation in the lysosome but not in the secretory pathway. These intriguing findings suggest a novel, unexpected role of MTP at a late stage of CD1d trafficking in the lysosomal compartment.

Mechanisms imposing the Vbeta bias of Valpha14 natural killer T cells and consequences for microbial glycolipid recognition.

Mouse and human natural killer T (NKT) cells recognize a restricted set of glycosphingolipids presented by CD1d molecules, including self iGb3 and microbial alpha-glycuronosylceramides. The importance of the canonical Valpha14-Jalpha18 TCR alpha chain for antigen recognition by NKT cells is well recognized, but the mechanisms underlying the Vbeta8, Vbeta7, and Vbeta2 bias in mouse have not been explored. To study the influences of thymic selection and the constraints of pairing with Valpha14-Jalpha18, we have created a population of mature T cells expressing Valpha14-Jalpha18 TCR alpha chain in CD1d-deficient mice and studied its recognition properties in vitro and in vivo. Transgenic cells expressed a diverse Vbeta repertoire but their recognition of endogenous ligands and synthetic iGb3 was restricted to the same biased Vbeta repertoire as expressed in natural NKT cells. In contrast, alpha-GalCer, a synthetic homologue of microbial alpha-glycuronosylceramides, was recognized by a broader set of Vbeta chains, including the biased NKT set but also Vbeta6, Vbeta9, Vbeta10, and Vbeta14. These surprising findings demonstrate that, whereas Vbeta8, Vbeta7, and Vbeta2 represent the optimal solution for recognition of endogenous ligand, many Vbeta chains that are potentially useful for the recognition of foreign lipids fail to be selected in the NKT cell repertoire.

Characterization of the early stages of thymic NKT cell development.

Upon reaching the mature heat stable antigen (HSA)low thymic developmental stage, CD1d-restricted Valpha14-Jalpha18 thymocytes undergo a well-characterized sequence of expansion and differentiation steps that lead to the peripheral interleukin-4/interferon-gamma-producing NKT phenotype. However, their more immature HSAhigh precursors have remained elusive, and it has been difficult to determine unambiguously whether NKT cells originate from a CD4+ CD8+ double-positive (DP) stage, and when the CD4+ and CD4- CD8- double-negative (DN) NKT subsets are formed. Here, we have used a CD1d tetramer-based enrichment strategy to physically identify HSAhigh precursors in thymuses of newborn mice, including an elusive DPlow stage and a CD4+ stage, which were present at a frequency of approximately 10(-6). These HSAhigh DP and CD4+ stages appeared to be nondividing, and already exhibited the same Vbeta8 bias that characterizes mature NKT cells. This implied that the massive expansion of NKT cells is separated temporally from positive selection, but faithfully amplifies the selected TCR repertoire. Furthermore, we found that, unlike the DN gammadelta T cells, the DN NKT cells did not originate from a pTalpha-independent pathway bypassing the DP stage, but instead were produced during a short window of time from the conversion of a fraction of HSAlow NK1.1neg CD4 cells. These findings identify the HSAhigh CD4+ stage as a potential branchpoint between NKT and conventional T lineages and between the CD4 and DN NKT sublineages.

Expansion and long-range differentiation of the NKT cell lineage in mice expressing CD1d exclusively on cortical thymocytes.

Unlike conventional major histocompatibility complex-restricted T cells, Valpha14-Jalpha18 NKT cell lineage precursors engage in cognate interactions with CD 1 d-expressing bone marrow-derived cells that are both necessary and sufficient for their thymic selection and differentiation, but the nature and sequence of these interactions remain partially understood. After positive selection mediated by CD1d-expressing cortical thymocytes, the mature NKT cell lineage undergoes a series of changes suggesting antigen priming by a professional antigen-presenting cell, including extensive cell division, acquisition of a memory phenotype, the ability to produce interleukin-4 and interferon-gamma, and the expression of a panoply of NK receptors. By using a combined transgenic and chimeric approach to restrict CD1d expression to cortical thymocytes and to prevent expression on other hematopoietic cell types such as dendritic cells, macrophages, or B cells, we found that, to a large extent, expansion and differentiation events could be imparted by a single-cognate interaction with CD1d-expressing cortical thymocytes. These surprising findings suggest that, unlike thymic epithelial cells, cortical thymocytes can provide unexpected, cell type-specific signals leading to lineage expansion and NKT cell differentiation.