CD1d1 mutant mice are deficient in natural T cells that promptly produce IL-4

Cutting Edge: Anti-CD1 Monoclonal Antibody Treatment Reverses the Production Patterns of TGF-β2 and Th1 Cytokines and Ameliorates Listeriosis in Mice

Protection against intracellular bacteria by T cells is regulated by Ag-presenting molecules, which comprise classical MHC class I molecules, MHC class II molecules, and nonclassical MHC class Ib molecules. The role of CD1 molecules, which are structurally similar to classical MHC class I gene products, but less polymorphic, is not understood so far. We show that CD1 surface expression increased on APC in Listeria-infected mice. The in vivo treatment with anti-CD1 mAb reduced TGF-β2 levels and concomitantly increased secretion of the proinflammatory cytokine TNF, the Th1 cell promoting cytokine IL-12, and the Th1 cell cytokine IFN-γ at the onset of listerial infection. These findings point to a regulatory role of CD1-reactive cells in the immune response against listeriosis.

IL-7 Up-Regulates IL-4 Production by Splenic NK1.1+ and NK1.1− MHC Class I-Like/CD1-Dependent CD4+ T Cells

NK T cells are an unusual subset of T lymphocytes. They express NK1.1 Ag, are CD1 restricted, and highly skewed toward Vβ8 for their TCR usage. They express the unique potential to produce large amounts of IL-4 and IFN-γ immediately upon TCR cross-linking. We previously showed in the thymus that the NK T subset requires IL-7 for its functional maturation. In this study, we analyzed whether IL-7 was capable of regulating the production of IL-4 and IFN-γ by the discrete NK T subset of CD4+ cells in the periphery. Two hours after injection of IL-7 into mice, or after a 4-h exposure to IL-7 in vitro, IL-4 production by CD4+ cells in response to anti-TCR-αβ is markedly increased. In contrast, IFN-γ production remains essentially unchanged. In β2-microglobulin- and CD1-deficient mice, which lack NK T cells, IL-7 treatment does not reestablish normal levels of IL-4 by CD4+ T cells. Moreover, we observe that in wild-type mice, the memory phenotype (CD62L−CD44+) CD4+ T cells responsible for IL-4 production are not only NK1.1+ cells, but also NK1.1− cells. This NK1.1−IL-4-producing subset shares three important characteristics with NK T cells: 1) Vβ8 skewing; 2) CD1 restriction as demonstrated by their absence in CD1-deficient mice and relative overexpression in MHC II null mice; 3) sensitivity to IL-7 in terms of IL-4 production. In conclusion, the present study provides evidence that CD4+MHC class I-like-dependent T cell populations include not only NK1.1+ cells, but also NK1.1− cells, and that these two subsets are biased toward IL-4 production by IL-7.

The CD1 system: antigen-presenting molecules for T cell recognition of lipids and glycolipids

Recent studies have identified the CD1 family of proteins as novel antigen-presenting molecules encoded by genes located outside of the major histocompatibility complex. CD1 proteins are conserved in all mammalian species so far examined and are prominently expressed on cells involved in antigen presentation, which suggests a role in activation of cell-mediated immunity. This has now been confirmed by functional studies demonstrating the ability of CD1 proteins to restrict the antigen-specific responses of T cells in humans and mice. Identification of naturally occurring antigens presented by CD1 has revealed the surprising finding that these are predominantly a variety of foreign lipids and glycolipids, including several found prominently in the cell walls and membranes of pathogenic mycobacteria. Structural, biochemical, and biophysical studies support the view that CD1 proteins bind the hydrophobic alkyl portions of these antigens directly and position the polar or hydrophilic head groups of bound lipids and glycolipids for highly specific interactions with T cell antigen receptors. Presentation of antigens by CD1 proteins requires uptake and intracellular processing by antigen presenting cells, and evidence exists for cellular pathways leading to the presentation of both exogenous and endogenous lipid antigens. T cells recognizing antigens presented by CD1 have a range of functional activities that suggest they are likely to mediate an important component of antimicrobial immunity and may also contribute to autoimmunity and host responses against neoplastic cells.

Absolute requirement for the pre-T cell receptor alpha chain during NK1.1+ TCRalphabeta cell development

Most natural killer T (NKT) cells express a highly skewed alphabeta TCR repertoire, consisting of an invariant V alpha14-J alpha281 chain paired preferentially with a polyclonal Vbeta8.2 chain. This repertoire is positively selected by the monomorphic CD1d molecule expressed on cells of hematopoietic origin. The origin of NKT cells and their lineage relationship to conventional T cells is controversial. We show here that the development of NKT cells is absolutely dependent on expression of the pre-TCRalpha chain, in marked contrast to conventional T cells which arise in significant numbers even in the absence of a functional pre-TCR. Distinct developmental requirements for pre-TCR expression in the NKT and T cell lineages may reflect differences in the ability of the TCRalphabeta to substitute functionally for the pre-TCR in immature precursor cells.

Molecular Cloning and Characterization of a Novel CD1 Gene from the Pig

Much effort is underway to define the immunological functions of the CD1 multigene family, which encodes a separate lineage of Ag presentation molecules capable of presenting lipid and glycolipid Ags. To identify porcine CD1 homologues, a cosmid library was constructed and screened with a degenerate CD1 α3 domain probe. One porcine CD1 gene (pCD1.1) was isolated and fully characterized. The pCD1.1 gene is organized similarly to MHC class I and other CD1 genes and contains an open reading frame of 1020 bp encoding 339 amino acids. Expression of pCD1.1 mRNA was observed in CD3− thymocytes, B lymphocytes, and tissue macrophages and dendritic cells. The pCD1.1 cDNA was transfected into Chinese hamster ovary cells, and subsequent FACS analysis demonstrated that mAb 76-7-4, previously suggested to be a pig CD1 mAb, recognizes cell surface pCD1.1. Structurally, the pCD1.1 α1 and α2 domains are relatively dissimilar to those of other CD1 molecules, whereas the α3 domain is conserved. Overall, pCD1.1 bears the highest similarity with human CD1a, and the ectodomain sequences characteristically encode a hydrophobic Ag-binding pocket. Distinct from other CD1 molecules, pCD1.1 contains a putative serine phosphorylation motif similar to that found in human, pig, and mouse MHC class Ia molecules and to that found in rodent, but not human, MHC class-I related (MR1) cytoplasmic tail sequences. Thus, pCD1.1 encodes a molecule with a conventional CD1 ectodomain and an MHC class I-like cytoplasmic tail. The unique features of pCD1.1 provoke intriguing questions about the immunologic functions of CD1 and the evolution of Ag presentation gene families.

Tissue-Specific Segregation of CD1d-Dependent and CD1d-Independent NK T Cells

NKT cells, defined as T cells expressing the NK cell marker NK1.1, are involved in tumor rejection and regulation of autoimmunity via the production of cytokines. We show in this study that two types of NKT cells can be defined on the basis of their reactivity to the monomorphic MHC class I-like molecule CD1d. One type of NKT cell is positively selected by CD1d and expresses a biased TCR repertoire together with a phenotype found on activated T cells. A second type of NKT cell, in contrast, develops in the absence of CD1d, and expresses a diverse TCR repertoire and a phenotype found on naive T cells and NK cells. Importantly, the two types of NKT cells segregate in distinct tissues. Whereas thymus and liver contain primarily CD1d-dependent NKT cells, spleen and bone marrow are enriched in CD1d-independent NKT cells. Collectively, our data suggest that recognition of tissue-specific ligands by the TCR controls localization and activation of NKT cells.

Functional and phenotypical characteristics of hepatic NK-like T cells in NK1.1-positive and -negative mouse strains

We previously reported and partially characterized a unique monoclonal antibody (mAb), U5A2-13, which recognizes a T cell subset similar to NK1.1+ T cells, not only in NK1.1-positive mouse strains but also in NK1.1-negative strains. In NK1.1-positive C57BL/6 mice, U5A2-13+ TCRalphabeta+ cells produced abundant IL-4 as well as extremely high levels of IFN-gamma upon CD3 cross-linking, but this did not occur with U5A2-13- TCRalphabeta+ cells. In NK1.1-negative C3H/He mice, U5A2-13+ TCRalphabeta+ cells produced high levels of IL-4 and IFN-gamma upon CD3 cross-linking, but this was not observed with U5A2-13- TCRalphabeta+ cells. To the best of our knowledge, this is the first direct evidence of the presence of NK-like T cells defined phenotypically by U5A2-13 mAb and functionally by IL-4/IFN-gamma production in NK1.1-negative mouse strains. We also demonstrated that U5A2-13- NK1.1+ T cells and U5A2-13+ NK1.1- T cells in C57BL/6 mice could produce both IL-4 and IFN-gamma. In addition, Vbeta8 or Vbeta7 usage by U5A2-13+ NK1.1- T cells was lower than that by U5A2-13+ NK1.1+ T cells, but remained higher than that by U5A2-13- NK1.1- T cells. Based on the present results, U5A2-13 mAb appears to be a valuable tool in the study of NK-like T cells.

The roles of intrahepatic Valpha14(+) NK1.1(+) T cells for liver injury induced by Salmonella infection in mice

To investigate the roles of intrahepatic T cells in liver injury after Salmonella infection, we examined serum alanine transaminase (ALT), histopathology, and bacterial numbers in liver after infection with Salmonella choleraesuis strain 31N-1 in mice genetically lacking TCRalpha beta+, CD4(+), CD8(+), or NK1.1(+)T cells with C57BL/6 background. In control (+/+) mice, serum ALT reached a peak level by day 7 after an intraperitoneal inoculation of 2 x 10(6) CFU Salmonella choleraesuis 31N-1. In TCR-beta-/- mice, liver injury, as assessed by serum ALT level and histological examination, was significantly suppressed on day 7 after Salmonella infection but the numbers of bacteria in liver did not differ from those in normal mice, suggesting that alpha beta T cells are responsible for liver injury induced by Salmonella infection. To further determine which subsets in alpha beta T cells are important for the liver injury, we compared serum ALT level in mice genetically lacking CD4, CD8, beta2-microglobulin (beta2m, IAbeta, or Jalpha281 after Salmonella infection. In CD4(-/-) mice, serum ALT was significantly lower in comparison with control mice, but there was no difference in serum ALT levels in CD8(-/-) and IAbeta-/- mice from that in control mice. Notably, serum ALT levels and pathological lesions in liver were significantly decreased in beta2m-/- or Jalpha281(-/-) mice, which lacked in NK1.1(+) T cells bearing TCR Valpha14-Jalpha281 specific for beta2m-associated CD1d, following Salmonella infection. Taken together, it is suggested that alpha beta T cells bearing NK1.1 and CD4 may be main effector cells for liver injury after Salmonella infection.

Immunization with alpha-galactosylceramide polarizes CD1-reactive NK T cells towards Th2 cytokine synthesis

We have compared the immune responses of mice immunized either with alpha-galactosylceramide (alpha-GalCer), capable of eliciting a CD1-metiated stimulation of V alpha14+ NK T cells, or with lipoarabinomannan (LAM), a glycophospholipid derived from mycobacteria which is known to be presented by CD1b in humans. Within 24 h, alpha-GalCer induces a burst of IFN-gamma secretion in vivo, and recall with antigen in vitro leads to the synthesis of IL-4 and IL-10 in addition to IFN-gamma. Associated with this in vivo cytokine release is a polyclonal activation of splenic B and T cells. CD1-reactive NK T lymphocytes mediate these events, because none of them are observed in alpha-GalCer-immunized CD1-/- mice. LAM immunization fails to promote similar early responses in vivo. Repeated exposure of mice to alpha-GalCer induces splenic T cells to secrete IL-4 and IL-10 but dramatically reduced levels of IFN-gamma. Such a bias in the cytokine balance triggered by NK T cells stimulated with multiple doses of alpha-GalCer suggests that this compound might be useful in the induction of Th2 immune responses and the prevention of chronic inflammatory conditions mediated by Th1 cytokines.

Lipid antigen presentation in the immune system: lessons learned from CD1d knockout mice

CD1 molecules represent a distinct lineage of antigen-presenting molecules that are evolutionarily related to the classical major histocompatibility complex (MHC) class I and class II molecules. Unlike the classical MHC products that bind peptides, CD1 molecules have evolved to bind lipids and glycolipids. Murine and human CD1d molecules can present glycolipid antigens such as alpha-galactosylceramide (alpha-GalCer) to CD1d-restricted natural killer (NK) T cells. Using CD1d knockout mice we demonstrated that CD1d expression is required for the development of NK T cells. These animals were also deficient in the rapid production of interleukin-4 and interferon-gamma in response to stimulation by anti-CD3 antibodies. Despite these defects, CD1d knockout animals were able to generate strong T-helper type 1 (TH1) and TH2 responses. Spleen cells from these animals neither proliferated nor produced cytokines in response to stimulation by alpha-GalCer. Repeated injection of alpha-GalCer into wild-type but not CD1d mutant mice was able to clear metastatic tumors. We further showed that alpha-GalCer can inhibit disease in diabetes-prone non-obese diabetic mice. Collectively, these findings with CD1d knockout animals indicate a critical role for CD1d-dependent T cells in various disease conditions, and suggest that alpha-GalCer may be useful for therapeutic intervention in these diseases.

Functional characteristics of human peripheral blood alpha/betaTCR+, CD4- and CD8- double-negative (DN) T cells

The function of human peripheral blood alpha/betaTCR positive, CD4- and CD8- double-negative T lymphocytes (DN cells) in vivo is not completely understood. The response of immunomagnetically isolated DN cells to PHA and anti-CD3 was compared to the response of single-positive (SP) CD4 and CD8 subsets. Proliferation of DN cells in response to PHA was largely independent of APC. This suggests activation requirements for DN cells that are different from SP cells. Upon activation, HLA-DR was found to be upregulated early on DN cells, and IL-4 and IL-10 were detected in the supernatants of DN cells. These observations in vitro could correspond with an immunoregulatory role of human DN cells in vivo.

Splenic NK1.1-Negative, TCRαβ Intermediate CD4+ T Cells Exist in Naive NK1.1 Allelic Positive and Negative Mice, with the Capacity to Rapidly Secrete Large Amounts of IL-4 and IFN-γ Upon Primary TCR Stimulation

Splenic NK1.1+CD4+ T cells that express intermediate levels of TCRαβ molecules (TCRint) and the DX5 Ag (believed to identify an equivalent population in NK1.1 allelic negative mice) possess the ability to rapidly produce high quantities of immunomodulatory cytokines, notably IL-4 and IFN-γ, upon primary TCR activation in vivo. Indeed, only T cells expressing the NK1.1 Ag appear to be capable of this function. In this study, we demonstrate that splenic NK1.1-negative TCRintCD4+ T cells, identified on the basis of FcγR expression, exist in naive NK1.1 allelic positive (C57BL/6) and negative (C3H/HeN) mice with the capacity to produce large amounts of IL-4 and IFN-γ after only 8 h of primary CD3 stimulation in vitro. Furthermore, a comparison of the amounts of early cytokines produced by FcγR+CD4+TCRint T cells with NK1.1+CD4+ or DX5+CD4+TCRint T cells, simultaneously isolated from C57BL/6 or C3H/HeN mice, revealed strain and population differences. Thus, FcγR defines another subpopulation of splenic CD4+TCRint cells that can rapidly produce large concentrations of immunomodulatory cytokines, suggesting that CD4+TCRint T cells themselves may represent a unique family of immunoregulatory CD4+ T cells whose members include FcγR+CD4+ and NK1.1/DX5+CD4+ T cells.

Protective effect of NK1.1(+) T cells as well as NK cells against intraperitoneal tumors in mice

Peritoneal resident cells of mice normally contain small populations of NK cells and NK1.1(+) alphabetaT cells. These populations increased after either 3LL or EL4 tumor inoculations into the peritoneal cavity. In vivo depletion of NK cell alone by anti-asialo GM1 (ASGM1) Ab significantly decreased survival time of tumor-injected mice, while depletion of both NK cells and NK1.1(+) T cells by anti-NK 1.1 Ab greatly shortened mouse survival time. NK1. 1(+) T cells in peritoneal cavity consist of a larger proportion of double-negative T cells and smaller populations of CD4(+) T cells and Vbeta8(+) T cells compared with liver NK1.1(+) T cells and normally lack Vbeta2(+) T cells. Tumor inoculation induced rapid IL-12 and IFN-gamma mRNA in tumor-infiltrating mononuclear cells (TIM). Although anti-NK1 Ab pretreatment in vivo abrogated IFN-gamma mRNA expression and IFN-gamma production of TIM, NK cell depletion alone by anti-ASGM1 Ab pretreatment retained IFN-gamma mRNA expression and partly inhibited IFN-gamma production of TIM. Peritoneal NK cells as well as NK1.1(+) T cells but not NK1.1(-) T cells of 3LL cell- or EL4 cell-injected mice showed cytotoxicities against the same tumor cells. Further, either anti-IL-12 Ab or anti-IFN-gamma Ab ip injection significantly shortened EL4 cell-inoculated mouse survival time. Our findings suggest that peritoneal macrophages activated by tumors produce IL-12 which activates NK cells and NK1.1(+) T cells to produce IFN-gamma and both NK cells and NK1.1(+) T cells are important in suppressing the growth of the intraperitoneal tumors.

Expression of CD1d2 on Thymocytes Is Not Sufficient for the Development of NK T Cells in CD1d1-Deficient Mice

CD1 is an MHC class I-like molecule that has been conserved throughout mammalian evolution. Unlike MHC class I molecules, CD1 can present unique nonprotein antigens to T cells. The murine CD1 locus contains two highly homologous genes, CD1d1 and CD1d2. CD1d1 is essential for the development of a major subset of NK T cells that promptly secrete IL-4 following activation. However, the function of CD1d2 has not yet been demonstrated. In the present study, we examined the expression of CD1d2 in CD1d1-deficient (CD1d1°) mice with the anti-CD1 Ab 3H3. Unlike CD1d1, which is expressed by all lymphocytes, CD1d2 can be detected only on the surface of thymocytes. To determine whether CD1d2 can select a unique subset of NK T cells, we compared the remnant population of NK T cells in CD1d1° and CD1d1, CD1d2-double deficient (CD1d1°CD1d2°) mice. No significant difference in the number of NK T cells and cytokine secretion capacity can be detected between CD1d1° and CD1d1°CD1d2° mice, indicating that CD1d2 cannot substitute for CD1d1 in NK T cell development. The inability of CD1d2 to select NK T cells is not due to the structural constraints of CD1d2 since CD1d2-transfected cells can be recognized by both NK T cell hybridomas and freshly isolated NK T cells. Given the structural similarities, it is possible that the low levels of surface expression and limited tissue distribution of CD1d2 may prevent it from functioning in the selection and expansion of NK T cells.

The natural killer T (NKT) cell ligand alpha-galactosylceramide demonstrates its immunopotentiating effect by inducing interleukin (IL)-12 production by dendritic cells and IL-12 receptor expression on NKT cells

The natural killer T (NKT) cell ligand alpha-galactosylceramide (alpha-GalCer) exhibits profound antitumor activities in vivo that resemble interleukin (IL)-12-mediated antitumor activities. Because of these similarities between the activities of alpha-GalCer and IL-12, we investigated the involvement of IL-12 in the activation of NKT cells by alpha-GalCer. We first established, using purified subsets of various lymphocyte populations, that alpha-GalCer selectively activates NKT cells for production of interferon (IFN)-gamma. Production of IFN-gamma by NKT cells in response to alpha-GalCer required IL-12 produced by dendritic cells (DCs) and direct contact between NKT cells and DCs through CD40/CD40 ligand interactions. Moreover, alpha-GalCer strongly induced the expression of IL-12 receptor on NKT cells from wild-type but not CD1(-/-) or Valpha14(-/-) mice. This effect of alpha-GalCer required the production of IFN-gamma by NKT cells and production of IL-12 by DCs. Finally, we showed that treatment of mice with suboptimal doses of alpha-GalCer together with suboptimal doses of IL-12 resulted in strongly enhanced natural killing activity and IFN-gamma production. Collectively, these findings indicate an important role for DC-produced IL-12 in the activation of NKT cells by alpha-GalCer and suggest that NKT cells may be able to condition DCs for subsequent immune responses. Our results also suggest a novel approach for immunotherapy of cancer.

Cutting Edge: LFA-1 Is Required for Liver NK1.1+TCRαβ+ Cell Development: Evidence That Liver NK1.1+TCRαβ+ Cells Originate from Multiple Pathways

Using mice deficient for LFA-1, CD44, and ICAM-1, we examined the role of these adhesion molecules in NK1.1+TCRαβ+ (NKT) cell development. Although no defect in NKT cell development was observed in CD44−/− and ICAM-1−/− mice, a dramatic reduction of liver NKT cells was observed in LFA-1−/− mice. Normal numbers of NKT cells were present in other lymphoid organs in LFA-1−/− mice. When LFA-1−/− splenocytes were injected i.v. into wild-type mice, the frequency of NKT cells among donor-derived cells in the recipient liver was normal. In contrast, when LFA-1−/− bone marrow (BM) cells were injected i.v. into irradiated wild-type mice, the frequency of liver NKT cells was significantly lower than that of mice injected with wild-type BM cells. Collectively, these data indicate that LFA-1 is required for the development of liver NKT cells, rather than the migration to and/or subsequent establishment of mature NKT cells in the liver.

Expression of CD1D mRNA transcripts in human choriocarcinoma cell lines and placentally derived trophoblast cells

Human placental trophoblast is critically involved in mediating maternal tolerance of the fetal semiallograft. Genes encoding highly polymorphic major histocompatibility complex (MHC) class I and class II antigens that could provoke maternal immune rejection responses are silenced in trophoblast. However, several MHC class I or class I-related products exhibiting reduced or negligible polymorphism are expressed and assumed to be functionally involved in maintaining pregnancy. The CD1 gene family encodes non-polymorphic MHC class I-like products that have the unusual ability to present non-peptide antigens to T cells. One member, CD1D, is expressed in certain epithelial cells and interacts with a specific T-cell subset that may promote the development of Th2-mediated responses believed to be associated with pregnancy. In this study we examined the expression of CD1D in human trophoblast cell lines and placentally derived trophoblast cells by reverse transcriptase-polymerase chain reaction using CD1D-specific oligonucleotide primers. We have found that CD1D mRNA transcripts are expressed in trophoblast cells and cell lines. We have also identified a novel alternatively spliced CD1D mRNA transcript lacking exon 4. Exon 4-intact and exon 4-deficient CD1D transcripts appear to be differentially expressed in different trophoblast and non-trophoblast cell populations. Our studies suggest that at least one member of the CD1 family is transcribed in human trophoblast.

Marking IL-4-producing cells by knock-in of the IL-4 gene

IL-4 is a cytokine which can be expressed by a number of cell types including Th2 cells, mast cells and a population of CD4+ NK1.1+ NK T cells. Although phenotypic markers exist for identifying each of these cell types, there is at present no known cell surface marker common to all IL-4-producing cells. Using gene targeting in embryonic stem cells, we have modified the IL-4 locus by knock-in of a transmembrane domain to generate mice that express a membrane-bound form of IL-4 (mIL-4). Flow cytometry using an IL-4-specific mAb allowed the detection of IL-secreting Th2 cells, mast cells and NK T cells from mIL-4 mice. Furthermore, the analysis of immune responses in mIL-4 mice following immunization with anti-CD3 and anti-IgD has allowed us to identify distinct subpopulations of IL-4-producing NK T cells. Thus, the expression of IL-4 in a membrane-bound form provides a novel method for the identification and characterization of IL-4-producing cells.

Functions of nonclassical MHC and non-MHC-encoded class I molecules

Fascinating recent discoveries have focused attention on the nonclassical class I molecules. They can exert their function at most levels of the immune response, being part of both innate and adaptive immune systems. They not only have specialized antigen-presentation functions but also play important immunoregulatory roles: HLA-E regulates natural killer cells by interacting with CD94/NKG2 receptors; the MIC (MHC class I chain related) glycoproteins appear crucial to the activation of gammadelta T cells in the gastrointestinal epithelium; HLA-G may play a role in controlling the immune response to the fetus; and CD1 molecules are important in defense against bacterial infections, as well as in the development and regulation of a subset of NKT cells expressing a highly restricted TCR repertoire; however not all nonclassical class I molecules have an immunological function, as demonstrated by HFE which is implicated in iron metabolism.

Natural killer cells determine development of allergen-induced eosinophilic airway inflammation in mice

The earliest contact between antigen and the innate immune system is thought to direct the subsequent antigen-specific T cell response. We hypothesized that cells of the innate immune system, such as natural killer (NK) cells, NK1.1(+) T cells (NKT cells), and gamma/delta T cells, may regulate the development of allergic airway disease. We demonstrate here that depletion of NK1.1(+) cells (NK cells and NKT cells) before immunization inhibits pulmonary eosinophil and CD3(+) T cell infiltration as well as increased levels of interleukin (IL)-4, IL-5, and IL-12 in bronchoalveolar lavage fluid in a murine model of allergic asthma. Moreover, systemic allergen-specific immunoglobulin (Ig)E and IgG2a levels and the number of IL-4 and interferon gamma-producing splenic cells were diminished in mice depleted of NK1.1(+) cells before the priming regime. Depletion of NK1.1(+) cells during the challenge period only did not influence pulmonary eosinophilic inflammation. CD1d1 mutant mice, deficient in NKT cells but with normal NK cells, developed lung tissue eosinophilia and allergen-specific IgE levels not different from those observed in wild-type mice. Mice deficient in gamma/delta T cells showed a mild attenuation of lung tissue eosinophilia in this model. Taken together, these findings suggest a critical role of NK cells, but not of NKT cells, for the development of allergen-induced airway inflammation, and that this effect of NK cells is exerted during the immunization. If translatable to humans, these data suggest that NK cells may be critically important for deciding whether allergic eosinophilic airway disease will develop. These observations are also compatible with a pathogenic role for the increased NK cell activity observed in human asthma.

Induction of IFN-gamma-producing CD4+ natural killer T cells by Mycobacterium bovis bacillus Calmette Guérin

The CD4+ natural killer (NK)T cells in the liver are potent IL-4 producers and hence may promote Th2 cell development. Following Mycobacterium bovis bacillus Calmette Guérin (BCG) infection, IL-4-producing CD4+ NKT cells become undetectable in liver mononuclear cells of normal density (interface between 40 and 70% Percoll) by flow cytometry. The present study shows that M. bovis BCG infection changes the density of liver CD4+ NKT cells and shifts cytokine production from IL-4 to IFN-gamma. The number of CD4+ NK1+ TCR alpha/beta(intermediate) cells increased in the low-density fraction (<40% Percoll density gradient) in parallel to the reduction of this cell population in the fraction of normal density. The number of IL-4-producing cells, however, was small and high frequencies of IFN-gamma-secreting cells were identified in the low-density fraction after TCR/CD3 ligation. Accordingly, selected low-density CD4+ NKT cells encompassed high numbers of IFN-gamma producers and minute numbers of IL-4-secreting cells. Induction of low-density CD4+ NKT cells by M. bovis BCG was abrogated by endogenous IL-12 neutralization which also caused increased bacterial growth in the liver. We assume that M. bovis BCG infection changes cytokine secretion by the CD4+ NKT cell population from IL-4 to IFN-gamma through IL-12 induction. Thus, CD4+ NKT cells may contribute to host resistance against intracellular bacteria prior to conventional IFN-gamma-producing Th1 cells.

Diverse TCRs Recognize Murine CD1

Human and murine T cells that specifically recognize CD1d and produce IL-4 and IFN-γ play a role in immunoregulation and tumor rejection. In the mouse, most CD1d1-reactive T cells described express an invariant Vα14-Jα281 TCR associated with TCR β-chains of limited diversity. Similarly, human CD1d-reactive T cells express a highly restricted TCR repertoire. Here we report the unexpected result that in mice immunized with CD1d1-bearing transfectant cells, a diverse repertoire of TCRs was expressed by CD1d1-reactive T cell clones isolated by limiting dilution without preselection for NK1 expression. Only 3 of 10 CD1d1-reactive T cell clones expressed the invariant Vα14-Jα281 TCRα rearrangement. T cells expressing Vα10, -11, -15, and -17, and having non-germline-encoded nucleotides resulting in diverse V-J junctions were identified. Like CD1d1-reactive T cells expressing the invariant Vα14-Jα281 TCR α-chain, CD1d1-reactive clones with diverse TCRs produced both Type 1 (IFN-γ) and Type 2 (IL-4, IL-10) cytokines. This establishes the existence of significant diversity in the TCRs directly reactive to the CD1d1 protein. Our findings reveal that CD1d interacts with a broad array of TCRs, suggesting substantial redundancy and flexibility of the immune system in providing T cells serving the role(s) mediated by CD1d reactivity.

Diverse CD1d-restricted reactivity patterns of human T cells bearing "invariant" AV24BV11 TCR

Human and murine natural T (NT) cells, also referred to as NK1.1+ or NK T cells, express TCR with homologous V regions (hAV24/BV11 and mAV14/BV8, respectively) and conserved "invariant" TCR AVAJ junctional sequences, suggesting recognition of closely related antigens. Murine NT cells recognize CD1-expressing cells and are activated in a CD1-restricted fashion by several synthetic alpha-glycosylceramides, such as alpha-GalCer. Here we studied the reactivity of human T cells against CD1d+ cells pulsed or not with alpha-GalCer and other related ceramides. CD1d-restricted recognition of alpha-GalCer was a general and specific feature of T cell clones expressing both BV11 and canonical AV24AJ18 TCR chains. Besides, human and murine NT cells showed the same reactivity patterns against a set of related glycosylceramides, suggesting a highly conserved mode of recognition of these antigens in humans and rodents. We also identified several AV24BV11 T cell clones self reactive against CD1+ cells of both hemopoietic and nonhemopoietic origin, suggesting the existence of distinct NT cell subsets differing by their ability to recognize self CD1d molecules.

Early IL-4 Induction in Bone Marrow Lymphoid Precursor Cells by Mycobacterial Lipoarabinomannan

IL-4 is produced promptly in response to certain infections and plays a key role in the Th1/Th2 T cell dichotomy; however, the cellular source remains a matter of debate. Here we describe the induction of IL-4 in bone marrow cells of normal and RAG−/− mice by both Mycobacterium tuberculosis and its major cell wall glycolipid, lipoarabinomannan. Characterization of the cell type responsible indicated that it was distinct from the NK1+ or CD4+ T cell previously ascribed the function of rapid IL-4 secretion. Cell-sorting experiments identified CD19+/B220+ precursor cells, presumably pre-B cells that produced IL-4 constitutively and whose frequency was rapidly and markedly up-regulated by lipoarabinomannan. Thus, pathogenic mycobacteria and their glycolipids may influence hemopoiesis by rapidly inducing IL-4 secretion in the bone marrow.

CD1d-mediated recognition of an alpha-galactosylceramide by natural killer T cells is highly conserved through mammalian evolution

Natural killer (NK) T cells are a lymphocyte subset with a distinct surface phenotype, an invariant T cell receptor (TCR), and reactivity to CD1. Here we show that mouse NK T cells can recognize human CD1d as well as mouse CD1, and human NK T cells also recognize both CD1 homologues. The unprecedented degree of conservation of this T cell recognition system suggests that it is fundamentally important. Mouse or human CD1 molecules can present the glycolipid alpha-galactosylceramide (alpha-GalCer) to NK T cells from either species. Human T cells, preselected for invariant Valpha24 TCR expression, uniformly recognize alpha-GalCer presented by either human CD1d or mouse CD1. In addition, culture of human peripheral blood cells with alpha-GalCer led to the dramatic expansion of NK T cells with an invariant (Valpha24(+)) TCR and the release of large amounts of cytokines. Because invariant Valpha14(+) and Valpha24(+) NK T cells have been implicated both in the control of autoimmune disease and the response to tumors, our data suggest that alpha-GalCer could be a useful agent for modulating human immune responses by activation of the highly conserved NK T cell subset.

Major histocompatibility complex (MHC) class I KbDb -/- deficient mice possess functional CD8+ T cells and natural killer cells

We obtained mice deficient for major histocompatibility complex (MHC) molecules encoded by the H-2K and H-2D genes. H-2 KbDb -/- mice express no detectable classical MHC class I-region associated (Ia) heavy chains, although beta2-microglobulin and the nonclassical class Ib proteins examined are expressed normally. KbDb -/- mice have greatly reduced numbers of mature CD8+ T cells, indicating that selection of the vast majority (>90%) of CD8+ T cells cannot be compensated for by beta2-microglobulin-associated molecules other than classical H-2K and D locus products. In accord with the greatly reduced number of CD8+ T cells, spleen cells from KbDb -/- mice do not generate cytotoxic responses in primary mixed-lymphocyte cultures against MHC-disparate (allogeneic) cells. However, in vivo priming of KbDb -/- mice with allogeneic cells resulted in strong CD8+ MHC class Ia-specific allogeneic responses. Thus, a minor population of functionally competent peripheral CD8+ T cells capable of strong cytotoxic activity arises in the complete absence of classical MHC class Ia molecules. KbDb -/- animals also have natural killer cells that retain their cytotoxic potential.

Biology of the interleukin-2 receptor

Studies of the biology of the IL-2 receptor have played a major part in establishing several of the fundamental principles that govern our current understanding of immunology. Chief among these is the contribution made by lymphokines to regulation of the interactions among vast numbers of lymphocytes, comprising a number of functionally distinct lineages. These soluble mediators likely act locally, within the context of the microanatomic organization of the primary and secondary lymphoid organs, where, in combination with signals generated by direct membrane-membrane interactions, a wide spectrum of cell fate decisions is influenced. The properties of IL-2 as a T-cell growth factor spawned the view that IL-2 worked in vivo to promote clonal T-cell expansion during immune responses. Over time, this singular view has suffered from increasing appreciation that the biologic effects of IL-2R signals are much more complex than simply mediating T-cell growth: depending on the set of conditions, IL-2R signals may also promote cell survival, effector function, and apoptosis. These sometimes contradictory effects underscore the fact that a diversity of intracellular signaling pathways are potentially activated by IL-2R. Furthermore, cell fate decisions are based on the integration of multiple signals received by a lymphocyte from the environment; IL-2R signals can thus be regarded as one input to this integration process. In part because IL-2 was first identified as a T-cell growth factor, the major focus of investigation in IL-R2 signaling has been on the mechanism of mitogenic effects in cultured cell lines. Three critical events have been identified in the generation of the IL-2R signal for cell cycle progression, including heterodimerization of the cytoplasmic domains of the IL-2R beta and gamma(c) chains, activation of the tyrosine kinase Jak3, and phosphorylation of tyrosine residues on the IL-2R beta chain. These proximal events led to the creation of an activated receptor complex, to which various cytoplasmic signaling molecules are recruited and become substrates for regulatory enzymes (especially tyrosine kinases) that are associated with the receptor. One intriguing outcome of the IL-2R signaling studies performed in cell lines is the apparent functional redundancy of the A and H regions of IL-2R beta, and their corresponding downstream pathways, with respect to the proliferative response. Why should the receptor complex induce cell proliferation through more than one mechanism or pathway? One possibility is that this redundancy is an unusual property of cultured cell lines and that primary lymphocytes require signals from both the A and the H regions of IL-2R beta for optimal proliferative responses in vivo. An alternative possibility is that the A and H regions of IL-2R beta are only redundant with respect to proliferation and that each region plays a unique and essential role in regulating other aspects of lymphocyte physiology. As examples, the A or H region could prove to be important for regulating the sensitivity of lymphocytes to AICD or for promoting the development of NK cells. These issues may be resolved by reconstituting IL-2R beta-/-mice with A-and H-deleted forms of the receptor chain and analyzing the effect on lymphocyte development and function in vivo. In addition to the redundant nature of the A and H regions, there remains a large number of biochemical activities mediated by the IL-2R for which no clear physiological role has been identified. Therefore, the circumstances are ripe for discovering new connections between molecular signaling events activated by the IL-2R and the regulation of immune physiology. Translating biochemical studies of Il-2R function into an understanding of how these signals regulate the immune system has been facilitated by the identification of natural mutations in IL-2R components in humans with immunodeficiency and by the generation of mice with targeted mutations in these gen

Selective Ability of Mouse CD1 to Present Glycolipids: α-Galactosylceramide Specifically Stimulates Vα14+ NK T Lymphocytes

Mouse CD1 (mCD1) glycoproteins are known to present peptides, while human CD1 molecules present glycolipids. In mice, mCD1-autoreactive NK T cells play critical roles in various immune responses, through the secretion of high amounts of cytokines. This study was initiated to determine whether glycolipids are involved in the autorecognition of mCD1 by NK T cells. α-Galactosylceramide (α-GalCer) was the only glycolipid tested capable of eliciting an mCD1-restricted response by splenic T cells. Moreover, splenic T cells derived from mCD1-deficient mice were not stimulated by α-GalCer, suggesting that the responsive T cells are selected by mCD1. Using cytoflow techniques, we confirmed that, in response to α-GalCer, IFN-γ-secreting cells displayed an NK T cell phenotype. The predominance of IFN-γ vs IL-4, however, is determined by the type of mCD1+ APC, suggesting the potential for APC regulation of cytokine production by NK T cells. Among a panel of 10 mCD1-autoreactive T cell hybridomas, only the ones that express the typical Vα14Jα281 TCR rearrangement of NK T cells responded to α-GalCer. Fixation or treatment of mCD1+ APCs with an inhibitor of endosomal acidification and the use of mCD1 mutants unable to traffic through endosome still allowed α-GalCer to stimulate NK T cells. Thus, endosomal trafficking and Ag processing are not required for glycolipid recognition. In summary, α-GalCer might be the autologous ligand, or a mimic of a glycolipid ligand, involved in the mCD1-mediated stimulation of NK T cells.

A population of CD62Llow Nk1.1- CD4+ T cells that resembles NK1.1+ CD4+ T cells

In MHC class II-/- C57BL/6 (II-/-) mouse spleen, a small population of CD4+ T cells is present of which NK1.1+ CD4+ (NK) T cells comprise 40 to 45%. We report here that many of the NK1.1- CD4+ T cells derived from II-/- mice are also NK T cells. They produce large amounts of IL-4 in response to anti-CD3 ligation and do so without any requirement for the presence of IL-4 in the priming culture, a property characteristic of NK T cells. Their IFN-gamma production is large and is enhanced by IL-12. In addition, II-/- NK1.1- CD4+ T cells produce IL-4 as a result of culture with L cells expressing murine CD1 (L-CD1). We report that CD49b, a component of integrin VLA-2, is expressed on the majority of both NK1.1+ and NK1.1- NK T cells. NK1.1- NK T cells also exist in wild-type C57BL/6 mice. Evidence supporting this is that Vbeta8 usage by CD62Llow NK1.1- CD4+ T cells was approximately 5% higher than that by CD62Lhigh CD4+ T cells in wild-type mice in keeping with the estimated proportion of NK1.1- NK T cells in the CD62Llow population. CD62Llow CD4+ T cells from beta2-m(-/-) mice, which lack NK T cells, showed no increase in Vbeta8 usage. When activated by anti-CD3 or L-CD1, CD62Llow NK1.1- CD4+ T cells from conventional but not beta2-m(-/-) and CD1-/- mice produce IL-4 in a manner indistinguishable from II-/- NK1.1- CD4+ T cells. NK1.1- NK T cells in normal mouse spleens are approximately as numerous as NK1.1+ NK T cells.

CD161 (NKR-P1A) costimulation of CD1d-dependent activation of human T cells expressing invariant V alpha 24 J alpha Q T cell receptor alpha chains

A population of human T cells expressing an invariant V alpha 24 J alpha Q T cell antigen receptor (TCR) alpha chain and high levels of CD161 (NKR-P1A) appears to play an immunoregulatory role through production of both T helper (Th) type 1 and Th2 cytokines. Unlike other CD161(+) T cells, the major histocompatibility complex-like nonpolymorphic CD1d molecule is the target for the TCR expressed by these T cells (V alpha 24(invt) T cells) and by the homologous murine NK1 (NKR-P1C)+ T cell population. In this report, CD161 was shown to act as a specific costimulatory molecule for TCR-mediated proliferation and cytokine secretion by V alpha 24(invt) T cells. However, in contrast to results in the mouse, ligation of CD161 in the absence of TCR stimulation did not result in V alpha 24(invt) T cell activation, and costimulation through CD161 did not cause polarization of the cytokine secretion pattern. CD161 monoclonal antibodies specifically inhibited V alpha 24(invt) T cell proliferation and cytokine secretion in response to CD1d+ target cells, demonstrating a physiological accessory molecule function for CD161. However, CD1d-restricted target cell lysis by activated V alpha 24(invt) T cells, which involved a granule-mediated exocytotic mechanism, was CD161-independent. In further contrast to the mouse, the signaling pathway involved in V alpha 24(invt) T cell costimulation through CD161 did not appear to involve stable association with tyrosine kinase p56(Lck). These results demonstrate a role for CD161 as a novel costimulatory molecule for TCR-mediated recognition of CD1d by human V alpha 24(invt) T cells.

Rapid death and regeneration of NKT cells in anti-CD3epsilon- or IL-12-treated mice: a major role for bone marrow in NKT cell homeostasis

Natural killer T (NKT) cells express a T cell receptor (TCR) and markers common to NK cells, including NK1.1. In vivo, NKT cells are triggered by anti-CD3epsilon MAb to rapidly produce large amounts of IL-4 and by IL-12 to reject tumors. We show here that anti-CD3epsilon MAb treatment rapidly depletes the liver (and partially the spleen) of NKT cells and that homeostasis is achieved 1 to 2 days later via NKT cell proliferation that occurs mainly in bone marrow. Similar results were obtained in mice treated with IL-12. Collectively, our data demonstrate that peripheral NKT cells are highly sensitive to activation-induced cell death and that bone marrow plays a major role in restoring NKT cell homeostasis.

Positive selection of extrathymically developed T cells by self-antigens

Most T cells develop through the thymus, where they undergo positive and negative selection. Some peripheral T cells are known to develop in the absence of thymus, but there is insufficient information about their selection. To analyze the selection of extrathymically developed T cells, we reconstituted thymectomized male or female recipient mice with bone marrow cells of mice transgenic for male H-Y antigen-specific T cell receptor (TCR). It was revealed that the T cells bearing self-antigen-specific TCR were not deleted in thymectomized male recipients. More importantly, the absence of H-Y antigen-specific T cells in thymectomized female recipients suggests positive selection of extrathymically developed T cells by the self-antigen. The extrathymically developed T cells in male mice expressed interleukin (IL)-2 receptor beta chain (IL-2Rbeta) and intermediate levels of CD3 (CD3(int)) but were natural killer cell (NK)1.1(-). They rapidly produced interferon gamma but not IL-4 after TCR cross-linking. Furthermore, a similar pattern of cytokine production was observed in CD3(int)IL-2Rbeta+NK1.1(-) cells in normal mice which have been shown to develop extrathymically. These results suggest that extrathymically developed CD3(int)IL-2Rbeta+NK1. 1(-) cells in normal mice are also positively selected by self-antigens.

Impaired NK1.1+ T cells do not prevent the development of an IgE-dependent allergic phenotype

BACKGROUND

The induction of TH2 immune responses is critically dependent on initial IL-4. Although crucial, the source of this early IL-4 has not been identified. One candidate is a CD1 restricted NK1.1+ T cell subpopulation which is known to produce such early IL-4.

OBJECTIVES AND METHODS

The necessity of NK1.1+ T cells for the expression of an IgE-dependent phenotype was investigated in a NK1.1+ T cell deficient mouse model. The allergic phenotype was defined as immediate cutaneous hypersensitivity. It was induced by immunization of mice with ovalbumin. Mouse strains used were C57BL/6 mice and C57BL/6 mice homozygous for a targeted mutation of the beta2 microglobulin gene with consecutive loss of CD1 expression, which leads to a drastic reduction of NK1.1+ T cells. Manifestation of an allergic sensitization was assessed by intradermal allergen challenge after i.v. injection of Evans blue solution. The blue stained weal formations were quantified with the Bonitur method. In addition, the Th2 response was confirmed by the measurement of cytokines and serum immunoglobulins. The capability to produce early IL-4 was tested through the assessment of IL-4 mRNA shortly after a single challenge.

RESULTS

Wild type and mutated mice did not differ in any of the immunological parameters measured.

CONCLUSION

A single exposure to antigen with or without adjuvant induces early IL-4 production in C57BL/6 beta2m-/- mice. This early IL-4 is therefore independent of the presence of NK1.1+ T cells and functional MHC class I molecules and leads to IgE production and immediate cutaneous hypersensitivity.

Intrathymic selection of NK1.1(+)alpha/beta T cell antigen receptor (TCR)+ cells in transgenic mice bearing TCR specific for chicken ovalbumin and restricted to I-Ad

Generation and negative selection of NK1.1(+)alpha/beta T cell receptor (TCR)+ thymocytes were analyzed using TCR-transgenic (B10. D2 x DO10)F1 and (C57BL/6 x DO10)F1 mice and Rag-1(-/-)/DO10 mice, which had been established by breeding and backcrossing between Rag-1(-/-) and DO10 mice. Almost all T cells from these mice were shown to bear Valpha13/Vbeta8.2 that is specific for chicken ovalbumin (cOVA) and restricted to I-Ad. A normal proportion of the NK1.1(+) Valpha13/Vbeta8.2(+) thymocytes was generated in these mice. However, the actual cell number of both NK1.1(+) and NK1.1(-) thymocytes in I-Ad/d mice (positive selecting background) was larger than that in I-Ab/d mice (negative selecting background). Markedly low but significant proportions of NK1.1(+) Valpha13/Vbeta8.2(+) cells were detected in the spleens from I-Ad/d and I-Ab/d mice. It was shown that the splenic NK1.1(+) T cells of the I-Ab/d mice were anergized against stimulation through TCR. When (B10.D2 x DO10)F1 and (C57BL/6 x DO10)F1 mice were given cOVA, extensive or intermediate elimination of NK1.1(+)alpha/betaTCR+ thymocytes was induced in I-Ad/d or I-Ab/d mice, respectively. However, the clonal elimination was not as complete as that seen in the major NK1.1(-) thymocyte population. The present findings indicate that normal generation of NK1.1(+)alpha/betaTCR+ thymocytes occurs in the absence of Valpha14-Jalpha281 and that substantial negative selection operates on the NK1.1(+)alpha/betaTCR+ cells.

Developmentally regulated extinction of Ly-49 receptor expression permits maturation and selection of NK1.1+ T cells

Clonally distributed inhibitory receptors negatively regulate natural killer (NK) cell function via specific interactions with allelic forms of major histocompatibility complex (MHC) class I molecules. In the mouse, the Ly-49 family of inhibitory receptors is found not only on NK cells but also on a minor (NK1.1+) T cell subset. Using Ly-49 transgenic mice, we show here that the development of NK1.1+ T cells, in contrast to NK or conventional T cells, is impaired when their Ly-49 receptors engage self-MHC class I molecules. Impaired NK1.1+ T cell development in transgenic mice is associated with a failure to select the appropriate CD1-reactive T cell receptor repertoire. In normal mice, NK1.1+ T cell maturation is accompanied by extinction of Ly-49 receptor expression. Collectively, our data imply that developmentally regulated extinction of inhibitory MHC-specific receptors is required for normal NK1.1+ T cell maturation and selection.

Antigen-presenting function of mouse CD1: one molecule with two different kinds of antigenic ligands

Mouse CD1 (mCD1) is an antigen-presenting molecule that is constitutively expressed by most bone marrow-derived cells. Peptides with a hydrophobic binding motif can bind to mCD1, and the peptide-CD1 complex is recognized by CD8+ cytolytic T cells. In contrast, NK1.1+ T cells, which are CD8-, are autoreactive for mCD1 molecules. This autoreactivity, along with the ability of NK T cells to rapidly produce large amounts of cytokine, has led to the suggestion that these cells may be immunoregulatory. We have shown that the mCD1-autoreactive T cells can distinguish between different cell types that express similar levels of mCD1, suggesting that mCD1-bound autologous ligands may be critical for T-cell stimulation. Consistent with this, some of these mCD1-restricted T cells can recognize the glycolipid alpha-galactosylceramide presented by mCD1, while others do not respond. The mCD1 crystal structure reveals a deep and narrow hydrophobic antigen-binding site which can more easily bind lipid antigens than the long hydrophobic peptides that we have defined as mCD1 antigens. The ability of mCD1 to bind and present two different types of ligands raises the question as to how mCD1 can accommodate both types of antigens.

Tissue distribution, regulation and intracellular localization of murine CD1 molecules

CD1 molecules are MHC-unlinked class Ib molecules consisting of classical (human CD 1a-c) and non-classical subsets (human CD1d and murine CD1). The characterization of non-classical subsets of CD1 is limited due to the lack of reagents. In this study, we have generated two new anti-mouse CD1 monoclonal antibodies, 3H3 and 5C6, by immunization of hamsters with purified CD1 protein. These antibodies recognize CD1-transfected cells and have no reactivity to cells isolated from CD1-/- mice. Both antibodies precipitate the 52 kDa heavy chain and 12 kDa beta2m from thymocytes and splenocytes by radio-immunoprecipitation. Deglycosylation of CD1 reduces molecular mass of the heavy chain by 7.5 kDa, which can be detected by 3H3 but not 5C6. 3H3 and 5C6 detect surface CD1 expression on cells from the thymus, spleen, lymph node and bone marrow, but not on intestinal epithelial cells. Developmentally, CD1 is expressed on thymocytes prior to TCR rearrangement and remains constant throughout thymic development. CD1 is expressed early in the fetal liver (day 14) and remains expressed in hepatocytes postnatally. These data support evidence of a role for CD1 in the selection and/or expansion of NK1- T cells of both thymic origin and extrathymic origin. Unlike classical class I molecules, murine CD1 levels are not affected by IFN-gamma, but like human CD1b can be up-regulated by IL-4 and GM-CSF although only moderately. Similar to human CD1b, murine CD1 is found by immunofluorescence microscopy on the cell surface, and in various intracellular vesicles, including early and late endosomes. Localization in endocytic compartments indicates that murine CD1 may be capable of binding endocytosed antigens.

Mouse CD1-Autoreactive T Cells Have Diverse Patterns of Reactivity to CD1+ Targets

Humans and mice contain significant populations of T cells that are reactive for autologous CD1 molecules. Using a panel of five mouse CD1 (mCD1)-autoreactive T cell hybridomas, we show here that this autoreactivity does not correlate with the level of CD1 expression. In some cases, these autoreactive T cells can distinguish between different cell types that express the same CD1 molecule, suggesting that some factor in addition to CD1 expression is critical for autoreactive T cell stimulation. To determine whether a CD1-bound ligand may be required, we expressed mutant mCD1 molecules that are defective for the putative endosomal localization sequence in the cytoplasmic domain. We demonstrate that mCD1, like its human CD1 homologues, is found in endosomes, and that it colocalizes extensively with the DM molecule. We further demonstrate, by site-directed mutagenesis, that the tyrosine in the cytoplasmic sequence is required for this endosomal localization. A T cell hybrid expressing Vβ8 and Vα14, the major TCR expressed by NK1+ T cells, exhibited greatly diminished reactivity to mutant CD1 molecules that do not traffic through endosomes, although the reactivity of other T cell hybrids to this mutant was not greatly affected. Therefore, we propose that at least some of the autoreactive T cells require endosomally derived CD1-bound ligands, and that they are capable of distinguishing between a diverse set of such self-ligands, which might be either autologous lipoglycans or peptides.

CD1.1 Expression by Mouse Antigen-Presenting Cells and Marginal Zone B Cells

Mouse CD1.1 is an MHC class I-like, non-MHC-encoded, surface glycoprotein that can be recognized by T cells, in particular NK1.1+ T cells, a subset of αβ T cells with semiinvariant TCRs that promptly releases potent cytokines such as IL-4 and IFN-γ upon stimulation. To gain insight into the function of CD1.1, a panel of nine mAbs was generated and used to biochemically characterize and monitor the surface expression of CD1.1 on different cell types. CD1.1 is a heavily glycosylated, β2-microglobulin-associated surface protein. Its recognition by a panel of 12 Vα14-positive and -negative CD1-specific αβ T cell hybridomas was blocked by two groups of mAbs that bound to adjacent clusters of epitopes, indicating that different αβ TCRs bind to the same region of CD1.1, presumably above the groove. Remarkably, CD1.1 was mainly expressed by dendritic cells, B cells, and macrophages, suggesting a function in Ag presentation to Th cells. Furthermore, the cell type that expressed the highest levels of CD1.1 was the splenic marginal zone B cell, a distinct subset of B cells that also expresses CD21 (the C3d receptor) and may be involved in natural responses to bacterial Ags. Altogether, the results support the idea that CD1.1 may function in recruiting a form of innate help from specialized cytokine producer αβ T cells to APCs, a role that might be important at the preadaptive phase of immune responses to some microbial pathogens.

T lymphocyte differentiation in the periphery

The development of immune responses is significantly influenced by emerging patterns of cytokine expression in activated CD4+ T cells. Recent efforts have clarified both cellular and molecular mechanisms, and within the past year include significant observations on potential sources of IL-4 leading to Th2 development against certain pathogens, and insights into early responses and genetic susceptibility to experimental murine Leishmaniasis and transcriptional regulation of the IL-4 locus. Advances in Th1 development have included greater understanding of IL-12 receptors in Th1 development, data regarding IFN-gamma gene expression and clarification of the action of the new cytokine IL-18.

In Vivo IL-4 Responses to Anti-IgD Antibody Are MHC Class II Dependent and β2-Microglobulin Independent and Develop Normally in the Absence of IL-4 Priming of T Cells

A crucial role for CD1-responsive, MHC class II-unrestricted T cells in the generation of T cell IL-4 responses is suggested by the: 1) requirement for IL-4 to prime in vitro IL-4 responses by naive CD4+ T cells; 2) ability of TCR cross-linking to induce CD1-responsive T cells, but not conventional naive T cells, to produce IL-4; 3) failure of anti-IgD Ab to induce an IL-4-dependent IgE response in β2-microglobulin-deficient mice, which lack CD1; and 4) reported ability of MHC class II-deficient mice to make IgE responses to anti-IgD Ab. In contrast, the Ag specificity of cytokine and Ab responses in anti-IgD-injected mice and the normal IgE responses made by anti-IgD-treated CD1-deficient mice are difficult to reconcile with this view. We now find that the failure of β2-microglobulin-deficient mice to make an IgE response to anti-IgD Ab is caused by their rapid degradation of anti-IgD; sustained anti-IgD treatment induces them to make relatively normal IL-4 and IgE responses. Furthermore, in our study, MHC class II-deficient mice make little or no IL-4 or IgE responses to anti-IgD Ab and β2-microglobulin-deficient mice make large in vivo IL-4 responses to anti-CD3 mAb. Finally, although IL-4 priming of T cells for IL-4 production is Stat6 dependent, Stat6-deficient mice make normal IL-4 responses to anti-IgD. Thus, CD1-responsive T cells and other β2-microglobulin-dependent T cells are not required to prime conventional CD4+ T cells to make IL-4 responses to anti-IgD in vivo; in fact, the large IL-4 response made in this system does not require IL-4 priming.

Tissue-Specific Recognition of Mouse CD1 Molecules

Although there is evidence that some members of the CD1 gene family may present particular types of foreign Ags, such as mycobacterial lipid Ags or synthetic hydrophobic peptides, to αβ T cells, most CD1 isotypes share the unusual property of being recognized by a high frequency of naturally autoreactive αβ T cells. In the case of mouse CD1.1 and its human counterpart CD1d, a significant fraction of the autoreactive T cells express semi-invariant TCRs. CD1.1-specific T cells have a restricted tissue distribution and very promptly secrete a large panel of potent cytokines, including IL-4 and IFN-γ, upon primary activation through their TCR, suggesting that they might regulate some immune responses in these tissues. We show here that their autorecognition of mouse CD1.1 is highly dependent upon the cell type in which CD1.1 is expressed. For example, some of these T cells only respond to CD1.1 expressed by splenic dendritic cells, some respond preferentially to cortical thymocytes, and others respond to splenic B cells. Tissue specificity of CD1.1 recognition is also observed with various cell lines transfected with CD1.1 cDNA. These results show that different CD1.1 self Ags are expressed in different tissues and can be specifically recognized by autoreactive T cells. They suggest that CD1.1 may be naturally associated with a variety of self ligands that overlap only partially in different cell types.

Age-Dependent Appearance of NK1.1+ T Cells in the Livers of β2-Microglobulin Knockout and SJL Mice

NK1.1+ T cells, a specialized set of T cells that recognize CD1, are reportedly absent in young β2-microglobulin-deficient (β2m-knockout (KO)) and SJL mice. In this study, we show that a significant number of NK1.1+ T cells exist in the livers of older β2m-KO and SJL mice, and that the number of liver NK1.1+ T cells increases as the animals age. The surface phenotypes of liver NK1.1+ T cells from β2m-KO and SJL mice were similar to NK1.1+ T cells from C57BL/6 mice, except that the bulk of these cells were CD4−CD8−. After anti-CD3 injection in vivo, the cells promptly expressed IL-4 mRNA just as NK1.1+ T cells did in normal mice. Using L cells expressing CD1, liver NK1.1+ T cells from both β2m-KO and SJL mice were stimulated to proliferate, although to a lesser degree than were such cells from C57BL/6 mice. Our studies show that some NK1.1+ T cells accumulate in the livers of older β2m-KO and SJL mice, and that they appear to have functional properties similar to “normal” NK1.1+ T cells.

Extreme Th1 bias of invariant Valpha24JalphaQ T cells in type 1 diabetes

Type 1 diabetes (insulin-dependent diabetes mellitus, IDDM) is a disease controlled by the major histocompatibility complex (MHC) which results from T-cell-mediated destruction of pancreatic beta-cells. The incomplete concordance in identical twins and the presence of autoreactive T cells and autoantibodies in individuals who do not develop diabetes suggest that other abnormalities must occur in the immune system for disease to result. We therefore investigated a series of at-risk non-progressors and type 1 diabetic patients (including five identical twin/triplet sets discordant for disease). The diabetic siblings had lower frequencies of CD4-CD8- Valpha24JalphaQ+ T cells compared with their non-diabetic sibling. All 56 Valpha24JalphaQ+ clones isolated from the diabetic twins/triplets secreted only interferon (IFN)-gamma upon stimulation; in contrast, 76 of 79 clones from the at-risk non-progressors and normals secreted both interleukin (IL)-4 and IFN-gamma. Half of the at-risk non-progressors had high serum levels of IL-4 and IFN-gamma. These results support a model for IDDM in which Thl-cell-mediated tissue damage is initially regulated by Valpha24JalphaQ+ T cells producing both cytokines; the loss of their capacity to secrete IL-4 is correlated with IDDM.

Cutting Edge: Critical Role of NK1+ T Cells in IL-12-Induced Immune Responses In Vivo

CD1-dependent NK1+ T cells rapidly produce IL-4 upon stimulation through the TCR. These cells may therefore play an important role in the initiation of Th2 responses. Here, we show that NK1+ T cells constitutively express receptors for IL-12 and IFN-γ, and that IL-12 induces production of perforin in these cells. Moreover, while IL-12 induces high levels of IFN-γ and cytotoxic activity of hepatic or splenic mononuclear cells against tumor cells, this effect of IL-12 is significantly reduced in CD1-deficient mice with impaired NK1+ T cells development. These results indicate that NK1+ T cells play a critical role in IL-12-induced production of IFN-γ to initiate Th1 immune responses and as IL-12-induced cytotoxic effector cells to initiate antitumor immunity.