Structural requirements for galactosylceramide recognition by CD1-restricted NK T cells

The reactivity of a group of mouse Valpha14+ NK T cell hybridomas was tested with a panel of analogs of the glycolipid alpha-galactosylceramide (alpha-GalCer). Interestingly, the nearly complete truncation of the acyl chain from 24 to 2 carbons does not significantly affect the mouse NK T cell response to glycolipid presented by either mouse CD1 (mCD1) or its human homolog CD1d (hCD1d). Therefore, we propose that only one of the two hydrophobic pockets of the CD1 Ag-binding groove needs to be filled by Ag. In terms of the sphingosine base, the mCD1 binding groove has less-demanding structural requirements for presentation to NK T cells than hCDld. Tests of NK T cell reactivity to analogs presented by hCDld demonstrates that the invariant TCRs expressed by mouse and human NK T cells are surprisingly similar in their requirements for glycolipid recognition.

Presentation of bacterial lipid antigens by CD1 molecules

Human CD1 molecules bind and display or present lipid and glycolipid antigens from mycobacteria for recognition by T cells. Presentation requires uptake of antigen into endosomes, where it binds to CD1. T-cell recognition of CD1-presented nonpeptide antigens is a newly defined immune response that could be important for host defense against a variety of pathogens.

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.

Selective ability of mouse CD1 to present glycolipids: alpha-galactosylceramide specifically stimulates V alpha 14+ 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. Alpha-galactosylceramide (alpha-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 alpha-GalCer, suggesting that the responsive T cells are selected by mCD1. Using cytoflow techniques, we confirmed that, in response to alpha-GalCer, IFN-gamma-secreting cells displayed an NK T cell phenotype. The predominance of IFN-gamma 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 V alpha 14 J alpha 281 TCR rearrangement of NK T cells responded to alpha-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 alpha-GalCer to stimulate NK T cells. Thus, endosomal trafficking and Ag processing are not required for glycolipid recognition. In summary, alpha-GalCer might be the autologous ligand, or a mimic of a glycolipid ligand, involved in the mCD1-mediated stimulation of NK T cells.

CD1 expression defines subsets of follicular and marginal zone B cells in the spleen: beta 2-microglobulin-dependent and independent forms

We have used multicolor FACS analysis, immunohistology, and functional assays to study the expression of CD1 on B cell subsets from normal and beta 2m-/- mice. Two B cell subpopulations were identified that express high levels of CD1 in normal mice: splenic marginal zone B cells (IgMhigh IgDlow CD21high CD24intermediate CD23- CD43-) and a newly identified subpopulation of follicular B cells. The latter cells are unusual, because they are IgDhigh CD23+, like follicular B cells, but express high levels of CD21 and IgM, an expression pattern that is associated with marginal zone B cells. Therefore, the high-level expression of CD1 and CD21 was found to be closely associated on splenic B cells. Immunohistology confirmed the expression of CD1 on marginal zone B cells and on clusters of B cells in splenic follicles. Both the high-level CD1 expression by these cells and the low-level CD1 expression by subpopulations of B cells in the spleen, lymph node, peritoneal cavity, and bone marrow were markedly reduced in beta 2m-/- mice. Despite this, a CD1-restricted T cell clone proliferated vigorously in response to LPS-activated spleen cells that had been obtained from both beta 2m-/- and wild-type mice. This response was inhibited by the 3C11 anti-CD1 mAb. These results show the heterogeneity of B cell subsets in their expression of the beta 2m-dependent form of CD1. They further suggest that a beta 2m-independent form of CD1 is expressed on B cells that can stimulate T cells; however, this form is not easily visualized with the anti-CD1 mAb used here.

An opposite pattern of selection of a single T cell antigen receptor in the thymus and among intraepithelial lymphocytes

The differentiation of intestinal intraepithelial lymphocytes (IEL) remains controversial, which may be due in part to the phenotypic complexity of these T cells. We have investigated here the development of IEL in mice on the recombination activating gene (RAG)-2(-/-) background which express a T cell antigen receptor (TCR) transgene specific for an H-Y peptide presented by Db (H-Y/Db x RAG-2(-) mice). In contrast to the thymus, the small intestine in female H-Y/Db x RAG-2(-) mice is severely deficient in the number of IEL; TCR transgene+ CD8alphaalpha and CD8alphabeta are virtually absent. This is similar to the number and phenotype of IEL in transgenic mice that do not express the Db class I molecule, and which therefore fail positive selection. Paradoxically, in male mice, the small intestine contains large numbers of TCR+ IEL that express high levels of CD8alphaalpha homodimers. The IEL isolated from male mice are functional, as they respond upon TCR cross-linking, although they are not autoreactive to stimulator cells from male mice. We hypothesize that the H-Y/Db TCR fails to undergo selection in IEL of female mice due to the reduced avidity of the TCR for major histocompatibility complex peptide in conjunction with the CD8alphaalpha homodimers expressed by many cells in this lineage. By contrast, this reduced TCR/CD8alphaalpha avidity may permit positive rather than negative selection of this TCR in male mice. Therefore, the data presented provide conclusive evidence that a TCR which is positively selected in the thymus will not necessarily be selected in IEL, and furthermore, that the expression of a distinct CD8 isoform by IEL may be a critical determinant of the differential pattern of selection of these T cells.

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.

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 Vbeta8 and Valpha14, 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.

Generation of intestinal mucosal lymphocytes in SCID mice reconstituted with mature, thymus-derived T cells

Transfer of peripheral lymph node lymphocytes to SCID mice leads to the long term establishment of mucosal T lymphocytes within the epithelium and lamina propria of the small and large intestines. Analysis of engrafted intraepithelial lymphocytes (IEL) showed that they had acquired a surface phenotype that in several respects is typical of IEL. In addition, the functional profile of engrafted IEL derived from lymph node T cells was similar to that of normal IEL; as the donor-derived T cells exhibited a strong cytolytic activity, a poor proliferative response to mitogenic stimuli, and a tendency to home and expand specifically in the intestine upon transfer to secondary SCID recipients. Optimal engraftment of intestinal T cells required bacterial flora, as the number of lymphocytes was greatly reduced in SCID recipients with a reduced flora. These results demonstrate that mature, thymus-derived T cells can migrate to the intestine and become functionally specialized to the intestinal milieu. The acquisition of phenotypic markers characteristic of the intestinal microenvironment by engrafted cells suggests that T cell migration of lymphocytes to the SCID intestine is not aberrant, but it may reflect processes that are ongoing in immunocompetent mice. Furthermore, these data suggest that the homing and/or expansion of typical, thymus-derived T cells in the intestine may be driven by luminal Ags such as those derived from bacterial flora.

Molecular interaction of CD1b with lipoglycan antigens

The ability of human CD1b molecules to present nonpeptide antigens is suggested by the T cell recognition of microbial lipids and lipoglycans in the presence of CD1b-expressing antigen-presenting cells. We demonstrate the high-affinity interaction of CD1b molecules with the acyl side chains of known T cell antigens, lipoarabinomannan, phosphatidylinositol mannoside, and glucose monomycolate. Furthermore, CD1b-antigen binding was optimal at acidic pH, consistent with the known requirement for endosomal acidification in CD1b-restricted antigen presentation. The mechanism for CD1b-ligand interaction involves the partial unfolding of the alpha helices of CD1b at acidic pH, revealing a hydrophobic binding site that could accommodate lipid. These data provide direct evidence that the CD1b molecule has evolved unique biochemical properties that enable the binding of lipid-containing antigens from intracellular pathogens.

Mouse CD1 is mainly expressed on hemopoietic-derived cells

The mouse CD1 (mCD1) is a class I-like molecule that is encoded outside the MHC. Recent studies demonstrate that mCD1 presents hydrophobic peptides to CD8+ T cells and also that it is recognized by a population of NK1.1+ T cells that are thought to play an immunoregulatory role because of their ability to secrete IL-4. It has previously been reported that mCD1 is expressed predominantly by intestinal epithelial cells, although most NK1.1+ T cells are located elsewhere. We, therefore, have generated new mAbs to mCD1 to investigate its tissue distribution. The principal site of mCD1 expression in normal mice is on cells in the hemopoietic series, including constitutive expression on nearly all T and B cells, on macrophages, and on dendritic cells. Other than bone marrow-derived cells, mCD1 is not widely expressed and is not detectable on great majority of intestinal epithelial cells. The B cells, but not the T cells, from beta2m-deficient mice can be recognized by two mCD1 autoreactive T hybridomas. Therefore, although we could not detect a beta2m-independent form of mCD1 using these mAbs, mCD1 in a different conformation or a mCD1-related molecule is likely to be expressed in the absence of beta2m on some cell types. The pattern of expression of mCD1 correlates with the distribution of NK1 T cells and is consistent with an important Ag-presenting function for this molecule.

Mouse CD1 is mainly expressed on hemopoietic-derived cells

The mouse CD1 (mCD1) is a class I-like molecule that is encoded outside the MHC. Recent studies demonstrate that mCD1 presents hydrophobic peptides to CD8+ T cells and also that it is recognized by a population of NK1.1+ T cells that are thought to play an immunoregulatory role because of their ability to secrete IL-4. It has previously been reported that mCD1 is expressed predominantly by intestinal epithelial cells, although most NK1.1+ T cells are located elsewhere. We, therefore, have generated new mAbs to mCD1 to investigate its tissue distribution. The principal site of mCD1 expression in normal mice is on cells in the hemopoietic series, including constitutive expression on nearly all T and B cells, on macrophages, and on dendritic cells. Other than bone marrow-derived cells, mCD1 is not widely expressed and is not detectable on great majority of intestinal epithelial cells. The B cells, but not the T cells, from beta2m-deficient mice can be recognized by two mCD1 autoreactive T hybridomas. Therefore, although we could not detect a beta2m-independent form of mCD1 using these mAbs, mCD1 in a different conformation or a mCD1-related molecule is likely to be expressed in the absence of beta2m on some cell types. The pattern of expression of mCD1 correlates with the distribution of NK1 T cells and is consistent with an important Ag-presenting function for this molecule.

The role of CD1 molecules in immune responses to infection

Recent work on CD1 molecules has demonstrated that human CD1b and a lipoglycan from mycobacteria that CD1b presents colocalize to late endosomes. Presentation of this lipoglycan by CD1b requires antigen uptake via the mannose receptor. CD8(+) CD1-restricted T cells can decrease the load of intracellular mycobacteria by granule release. TCR-transgenic and CD1-deficient mice have provided insights into the role of CD1 in the T helper responses required for the clearance of some microorganisms.

Altered immune responses in interleukin 10 transgenic mice

Interleukin (IL)-10 is a pleiotropic cytokine which inhibits a broad array of immune parameters including T helper cell type 1 (Th1) cytokine production, antigen presentation, and antigen-specific T cell proliferation. To understand the consequences of altered expression of IL-10 in immune models of autoimmune disease, the response to infectious agents, and the response to tumors, we developed transgenic mice expressing IL-10 under the control of the IL-2 promoter. Upon in vitro stimulation, spleen cells from unimmunized transgenic mice secrete higher levels of IL-10 and lower amounts of IFN-gamma than do controls, although no gross abnormalities were detected in lymphocyte populations or serum Ig levels. Transfer of normally pathogenic CD4(+) CD45RBhigh splenic T cells from IL-10 transgenic mice did not cause colitis in recipient severe combined immunodeficiency mice. Furthermore, co-transfer of these transgenic cells with CD4(+) CD45RBhigh T cells from control mice prevented disease. Transgenic mice retained their resistance to Leishmania major infection, indicating that their cell-mediated immune responses were not globally suppressed. Lastly, in comparison to controls, IL-10 transgenic mice were unable to limit the growth of immunogenic tumors. Administration of blocking IL-10 mAbs restored in vivo antitumor responses in the transgenic mice. These results demonstrate that a single alteration in the T cell cytokine profile can lead to dramatic changes in immune responses in a manner that is stimulus dependent. These mice will be useful in defining differences in inflammatory conditions and cellular immunity mediated by IL-10.

Analysis of intestinal lymphocytes in mouse colitis mediated by transfer of CD4+, CD45RBhigh T cells to SCID recipients

Transfer of specific T lymphocyte subsets isolated from the spleens of healthy donor mice into immunodeficient SCID mice leads to chronic intestinal inflammation with characteristics similar to those of human inflammatory bowel disease (IBD). CD4+, CD45RBhigh cells cause disease, whereas CD4+, CD45RBlow and CD8+, CD45RBhigh cells do not. Despite this difference, we demonstrate that all three T cell populations reconstitute the intraepithelial and lamina propria compartments of both small and large intestines of SCID recipients. Therefore, infiltration of lymphocytes alone is not sufficient for disease development. CD4+ lymphocytes that have trafficked to the SCID intestine exhibit a phenotype characteristic of normal mucosal lymphocytes. This includes high expression of alpha E integrin and CD69, expression of CD8 alpha alpha homodimers in some of the intraepithelial lymphocytes, as well as low expression of CD62L and CD45RB. The phenotype of the infiltrating mucosal cells is indistinguishable, with respect to the cell surface markers tested, regardless of whether the starting donor population is CD45RBhigh or CD45RBlow. Severe inflammation is restricted primarily to the colon despite lymphocyte infiltration throughout the length of the intestine. This suggests that some property of the colon microenvironment contributes to inflammation. Consistent with this, transfer of CD4+, CD45RBhigh cells to SCID mice that have significantly reduced numbers of enteric flora results in attenuation of the wasting and colitis. Fewer numbers of donor lymphocytes are recovered from the intraepithelial and lamina propria compartments of reduced flora SCID mice. We hypothesize that the ability of pathogenic cells to traffic to the intestine and mediate colitis may be driven by T cell reactivity to bacteria or bacterial products.

Analysis of intestinal lymphocytes in mouse colitis mediated by transfer of CD4+, CD45RBhigh T cells to SCID recipients

Transfer of specific T lymphocyte subsets isolated from the spleens of healthy donor mice into immunodeficient SCID mice leads to chronic intestinal inflammation with characteristics similar to those of human inflammatory bowel disease (IBD). CD4+, CD45RBhigh cells cause disease, whereas CD4+, CD45RBlow and CD8+, CD45RBhigh cells do not. Despite this difference, we demonstrate that all three T cell populations reconstitute the intraepithelial and lamina propria compartments of both small and large intestines of SCID recipients. Therefore, infiltration of lymphocytes alone is not sufficient for disease development. CD4+ lymphocytes that have trafficked to the SCID intestine exhibit a phenotype characteristic of normal mucosal lymphocytes. This includes high expression of alpha E integrin and CD69, expression of CD8 alpha alpha homodimers in some of the intraepithelial lymphocytes, as well as low expression of CD62L and CD45RB. The phenotype of the infiltrating mucosal cells is indistinguishable, with respect to the cell surface markers tested, regardless of whether the starting donor population is CD45RBhigh or CD45RBlow. Severe inflammation is restricted primarily to the colon despite lymphocyte infiltration throughout the length of the intestine. This suggests that some property of the colon microenvironment contributes to inflammation. Consistent with this, transfer of CD4+, CD45RBhigh cells to SCID mice that have significantly reduced numbers of enteric flora results in attenuation of the wasting and colitis. Fewer numbers of donor lymphocytes are recovered from the intraepithelial and lamina propria compartments of reduced flora SCID mice. We hypothesize that the ability of pathogenic cells to traffic to the intestine and mediate colitis may be driven by T cell reactivity to bacteria or bacterial products.

Nonclassical behavior of the mouse CD1 class I-like molecule

The mouse CD1 (mCD1) molecule is a class I-like molecule that is encoded outside of the MHC. We show here that mCD1 shares several properties with Ag-presenting class I molecules, including a requirement for beta2-microglobulin for stable cell-surface expression in T lymphocyte transfectants and thymocytes. mCD1 is also capable of binding to mouse CD8alphabeta heterodimers participating in the activation of CD8+ T cells in a manner similar to classical class I molecules. However, mCD1 surface expression is not decreased at high temperatures in cells that lack the transporter associated with Ag processing (TAP), including both RMA-S and Drosophila melanogaster cells. The data indicate that mCD1 does not require TAP to be expressed in a stable fashion at the cell surface. We speculate that the ability of mCD1 to reach the cell surface in transporter-deficient cells may reflect its ability to present a distinct set of ligands. The properties of mCD1 described here can account, in part, for the selection of the diverse populations of T cells that are known to be mCD1 reactive.

Nonclassical behavior of the mouse CD1 class I-like molecule

The mouse CD1 (mCD1) molecule is a class I-like molecule that is encoded outside of the MHC. We show here that mCD1 shares several properties with Ag-presenting class I molecules, including a requirement for beta2-microglobulin for stable cell-surface expression in T lymphocyte transfectants and thymocytes. mCD1 is also capable of binding to mouse CD8alphabeta heterodimers participating in the activation of CD8+ T cells in a manner similar to classical class I molecules. However, mCD1 surface expression is not decreased at high temperatures in cells that lack the transporter associated with Ag processing (TAP), including both RMA-S and Drosophila melanogaster cells. The data indicate that mCD1 does not require TAP to be expressed in a stable fashion at the cell surface. We speculate that the ability of mCD1 to reach the cell surface in transporter-deficient cells may reflect its ability to present a distinct set of ligands. The properties of mCD1 described here can account, in part, for the selection of the diverse populations of T cells that are known to be mCD1 reactive.

The mannose receptor delivers lipoglycan antigens to endosomes for presentation to T cells by CD1b molecules

We have characterized the CD1b-mediated presentation pathway for the mycobacterial lipoglycan lipoarabinomannan (LAM) in monocyte-derived antigen-presenting cells. The macrophage mannose receptor (MR) was responsible for uptake of LAM. Antagonism of MR function inhibited both the internalization of LAM and the presentation of this antigen to LAM-reactive T cells. Intracellular MRs were most abundant in early endosomes, but they also were located in the compartment for MHC class II antigen loading (MIIC). Internalized LAM was transported to late endosomes, lysosomes, and MIICs. MRs colocalized with CD1b molecules, suggesting that the MR could deliver LAM to late endosomes for loading onto CD1b. LAM and CD1b colocalized in organelles that may be sites of lipoglycan antigen loading. This pathway links recognition of microbial antigens by a receptor of the innate immune system to the induction of adaptive T cell responses.

TAP-independent selection of CD8+ intestinal intraepithelial lymphocytes

Intestinal intraepithelial lymphocytes (IEL) are mostly CD8 single positive T cells. IEL with a TCR-alpha(beta) that are CD8 single positive are absent from beta(2)-microglobulin (beta(2)m)-deficient mice, consistent with the idea that these IEL, like other TCR-alpha(beta)+, CD8+ T cells, require class I molecules for positive selection. In contrast, here we show that substantial numbers of TCR-alpha(beta)+, CD8 single positive IEL are present in mice deficient for the transporter associated with Ag processing 1 (TAP 1) gene, although T cells with this phenotype are absent from thymus, spleen, and lymph nodes of these same mice. The majority of TCR-alpha(beta)+, CD8 single positive IEL in TAP-deficient mice expresses CD8 molecules composed of alpha(alpha) homodimers and they express a diverse set of V(beta) gene segments. In addition, the number of TCR-alpha(beta)+, CD4/CD8 double positive IEL is decreased in beta(2)m-deficient mice but not in TAP-deficient mice. The dependence of the two TCR-alpha(beta)+ IEL populations that express CD8alpha(alpha) homodimers on beta(2)m as opposed to TAP molecules is striking. It suggests that TAP-independent but beta(2)m-requiring nonclassical class I molecules expressed by cells in the intestine, such as the thymus leukemia Ag and CD1, could play a pivotal role in the development and/or the accumulation of major subpopulations of TCR-alpha(beta)+ IEL.

TAP-independent selection of CD8+ intestinal intraepithelial lymphocytes

Intestinal intraepithelial lymphocytes (IEL) are mostly CD8 single positive T cells. IEL with a TCR-alpha(beta) that are CD8 single positive are absent from beta(2)-microglobulin (beta(2)m)-deficient mice, consistent with the idea that these IEL, like other TCR-alpha(beta)+, CD8+ T cells, require class I molecules for positive selection. In contrast, here we show that substantial numbers of TCR-alpha(beta)+, CD8 single positive IEL are present in mice deficient for the transporter associated with Ag processing 1 (TAP 1) gene, although T cells with this phenotype are absent from thymus, spleen, and lymph nodes of these same mice. The majority of TCR-alpha(beta)+, CD8 single positive IEL in TAP-deficient mice expresses CD8 molecules composed of alpha(alpha) homodimers and they express a diverse set of V(beta) gene segments. In addition, the number of TCR-alpha(beta)+, CD4/CD8 double positive IEL is decreased in beta(2)m-deficient mice but not in TAP-deficient mice. The dependence of the two TCR-alpha(beta)+ IEL populations that express CD8alpha(alpha) homodimers on beta(2)m as opposed to TAP molecules is striking. It suggests that TAP-independent but beta(2)m-requiring nonclassical class I molecules expressed by cells in the intestine, such as the thymus leukemia Ag and CD1, could play a pivotal role in the development and/or the accumulation of major subpopulations of TCR-alpha(beta)+ IEL.

Antigen-presenting function of the mouse CD1 molecule

CD1 molecules are distantly related to major histocompatibility complex (MHC)-encoded class I molecules, and they are coexpressed with beta2 microglobulin (beta2m). In the mouse, CD1 is expressed by intestinal epithelial cells and also by some cells in spleen and lymph node. We have shown that surface expression of mouse CD1 (mCD1) is not dependent upon a functional transporter associated with antigen processing (TAP). This, and other data, suggest that mCD1 may acquire peptides in an intracellular compartment other than the endoplasmic reticulum, where classical class I molecules bind peptide. mCD1 molecules also are distinct from classical class I molecules with regard to the types of peptides that they bind. We have demonstrated that mCD1 molecules preferentially bind peptides much longer than the 8-9 amino acids typical of the peptides that bind to classical class I molecules. The sequence motif for mCD1 peptide binding is characterized by the presence of bulky and hydrophobic amino acid side chains. We have generated mCD1-restricted and peptide-specific T-cell lines, thereby demonstrating the immunologic relevance of peptide binding to mCD1. The reactive T cells are TCR alphabeta+ and CD8+, a phenotype typical of many lymphocytes in both lymph node and intestinal mucosae. We speculate that mCD1 molecules may be capable of sampling peptides from the gut lumen and presenting them to mucosal T lymphocytes. In this way, they may function in the maintenance of normal mucosal homeostasis, and perhaps also in the induction of systemic tolerance to antigens delivered by the oral route. In summary, CD1 molecules are a novel category of antigen-presenting molecules that have features in common with class I molecules, features in common with class II, and properties distinct from either subset of antigen-presenting molecules. Further studies of the antigen-presenting function of these molecules are certain to yield new insight into immune regulation and perhaps also into the mechanism of oral tolerance.

Intestinal intraepithelial lymphocytes respond to systemic lymphocytic choriomeningitis virus infection

Intestinal intraepithelial lymphocytes (IEL) are a population of cells consisting mostly of CD8+ T lymphocytes. Although their function is unknown, because of their location within the epithelium it has been postulated that IEL may be involved in defense against infection of the gut mucosa by pathogens including viruses. To address this issue, we have examined IEL populations from BALB/c mice systemically infected with lymphocytic choriomeningitis virus (LCMV). Viral infection induced a virus-specific cytotoxic response by IEL at 8 days postinfection. This virus-specific cytotoxic T lymphocyte (CTL) response was MHC class I restricted, and as is true for splenic T cells, recognition of viral antigen occurred predominantly in the context of the Ld molecule. The effector cells could be depleted by treatment with anti-CD8 antibody plus complement. In vivo treatment of mice with anti-alpha beta T cell receptor (TCR) antibody during the course of viral infection abrogated the response, suggesting that the virus-specific CTL were cells that express the alpha beta rather than gamma delta TCR. Consistent with this, no virus-specific IEL response could be detected in athymic mice, which have TCR gamma delta+ but not TCR alpha beta+ IEL. LCMV antigen could not be detected in the epithelium of the intestine, suggesting that viral antigen may have been encountered elsewhere. These data demonstrate for the first time a specific response by IEL to virus given by a non-oral route, and they suggest that thymus-derived alpha beta T cells can migrate to the intestinal epithelium following activation, where they may play a role in the response to virus and perhaps other infections.