Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P06126 (CD1a)
2,221 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Taken together, the data generated thus far strongly suggest that CD1 plays a role in the immune response against various infections (table 1). For obvious reasons, the data gathered thus far using model infection systems have focused primarily on the mouse and therefore only examine the role of CD1d. This leaves an important gap in our understanding of the CD1 antigen presentation pathway given the potential role of CD1a, CD1b and CD1c for contributing to antimicrobial immunity. The functional dichotomy between group 1 and group 2 CD1 isoforms obviously requires further analysis. However, we propose that the group 1 CD1 (CD1a, CD1b, CD1c) antigen presentation pathway is closer to the traditional adaptive immune response mechanisms with the capacity to present unique foreign antigens to specific T cells. This broadens the universe antigens that T cells can use to target pathogens and provides important antimicrobial effector mechanisms that may be critical for combating some types of infections. Lipid antigens may also provide a more effective means of targeting intracellular pathogens by T cells since CD1 is able to sample almost all of the intracellular reservoirs that are exploited by this class of pathogen and may provide an important component of the cytotoxic T cell response [80]. On the other hand, the group 2 CD1 protein (CD1d) may be more intermediate in terms of lying functionally between the innate and adaptive immune systems. The activation of CD1d-restricted T cells may, therefore, help bridge the temporal gap between the onset of innate immunity and the purely adaptive responses typified by the MHC-restricted T cells. Hence, the CD1d-restricted [table: see text] T cells are primed for rapid high-level cytokine release. In addition, the interaction of CD1d-restricted T cells with CD1d on DCs can trigger the release of IL-4 and GM-CSF to promote maturation of tissue-resident DC at the site of infection. The maturation of tissue DC would lead to migration of the activated DC to regional lymph nodes and initiation of MHC-restricted T cell responses. Subsequent IL-12 production by the DC in response to CD1d-mediated T cell stimulation could then drive IFN-gamma production by CD1d-restricted T cells and influence the polarization of the T cell response to infection. In addition, early bursts of IFN-gamma by CD1d-restricted T cells could also upregulate antimicrobial activity in macrophages and activate other important effector cells such as NK cells prior to MHC-restricted T cell responses. In the constant struggle between the microbial pathogen and its host, the evolutionary balance almost always favors the microbe. The rapid rate of evolution and adaptation of the microbe accounts for most of this advantage. Hence, it is not surprising that the host immune system has evolved a complex set of pathways, in addition to the MHC, that are able to recognize and target the unique molecular signatures of infectious microorganisms. The lipid antigens presented by CD1 add to this array and thus provide a further layer of immune defense to the host for combating pathogens.
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PMID:CD1 antigen presentation and infectious disease. 1253 Mar 26

Langerhans cells are a critical component of skin immunity, capable of capturing protein antigens in the epidermis and presenting them to specific T cells in the context of major histocompatibility complex class II molecules. Recently, a major histocompatibility complex independent pathway of lipid antigen presentation has been identified and is mediated by molecules of the CD1 family (CD1a, CD1b, CD1c, and CD1d). Because Langerhans cells are professional antigen-presenting cells and express CD1a molecules prominently, we hypothesized that Langerhans cells might play a role in T cell responses directed against not only peptide antigens but also lipid antigens. Here, we show that freshly isolated immature Langerhans cells as well as mature Langerhans cells that have migrated from the epidermis are efficient in presenting foreign microbial lipid antigens to specific T cells whereas dermal dendritic cells express much less CD1a molecules and function inefficiently. Further, we found that Langerhans cells migrating from epidermal sheets that were exposed to microbial lipid antigens expressed lipid-antigen-loaded CD1a molecules on the cell surface, resulting in activation of specific T cells. These results underscore an outstanding ability of Langerhans cells to mediate CD1a-dependent lipid antigen presentation. Thus, Langerhans-cell-mediated skin immunity may involve T cell recognition of both peptide and lipid antigens.
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PMID:Epidermal Langerhans cells efficiently mediate CD1a-dependent presentation of microbial lipid antigens to T cells. 1292 10

The presentation of lipid and glycolipid Ags to T cells is mediated through CD1 molecules. In the mouse and rat only a single isoform, CD1d, performs these functions, while humans and all other mammals studied have members of both group I (CD1a, -b, and -c) and group II (CD1d) isoforms. Murine CD1d contains a cytoplasmic tyrosine-based sorting motif that is similar to motifs recognized by adaptor protein complexes that sort transmembrane proteins. Here we show that the adaptor protein complex, AP-3, directly interacts with murine CD1d and controls its targeting to lysosomes. AP-3 deficiency results in a redistribution of CD1d from lysosomes to the cell surface of thymocytes, B cell-depleted splenocytes, and dendritic cells. The altered trafficking of CD1d in AP-3-deficient mice results in a significant reduction of NK1.1(+)TCR-beta(+) and CD1d tetramer-positive cells, consistent with a defect in CD1d self-Ag presentation and thymocyte-positive selection. The AP-3 complex has recently been shown to associate with the human CD1b isoform, which has an intracellular distribution pattern similar to that of murine CD1d. We propose that lysosomal sampling may be so critical for efficient host defense that mice have evolved mechanisms to target their single CD1 isoform to lysosomes for sampling lipid Ags. Here we show the dominant mechanism for this trafficking is mediated by AP-3.
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PMID:Lysosomal localization of murine CD1d mediated by AP-3 is necessary for NK T cell development. 1453 Mar 37

The CD1 family consists of lipid antigen-presenting molecules, which include group I CD1a, CD1b, and CD1c and group II CD1d proteins. Topologically, they resemble the classical peptide antigen-presenting MHC molecules except that the large, exclusively nonpolar and hydrophobic, antigen-binding groove of CD1 has evolved to present cellular and pathogen-derived lipid antigens to specific T lymphocytes. As an approach to understanding the biochemical basis of lipid antigen presentation by CD1 molecules, we have characterized the natural ligands associated with mouse CD1d1 as well as human CD1b and CD1d molecules. We found that both group I and II CD1 molecules assemble with cellular phosphatidylinositol (PI), which contains heterogeneous fatty acyl chains. Further, this assembly occurs within the endoplasmic reticulum. Because the structures of the antigen-binding grooves of CD1a and CD1c closely resemble those of CD1b and CD1d, we conclude that the assembly of CD1 molecules with PI in the endoplasmic reticulum is evolutionarily conserved. These findings suggest that PI plays a chaperone-like role in CD1 assembly, possibly to preserve the integrity of the antigen-binding groove until CD1 binds antigenic lipids in the endocytic pathway.
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PMID:Lipid-protein interactions: biosynthetic assembly of CD1 with lipids in the endoplasmic reticulum is evolutionarily conserved. 1472 59

Recent studies of CD1 structure and intracellular trafficking have demonstrated significant differences among the CD1 isoforms (CD1a, CD1b, CD1c and CD1d). The molecular and structural basis for the differential trafficking of CD1 molecules has also been delineated. These observations broaden our understanding of why the immune system has evolved multiple CD1 isoforms to survey different cellular compartments for lipid antigen presentation, to provide host defense against the microbial world and to offer immunoregulation with relevance to tumor immunity and autoimmunity.
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PMID:New insights into pathways for CD1-mediated antigen presentation. 1473 15

Although T cells were previously believed to recognize only peptide antigen associated with the major histocompatibility complex (MHC), recent studies have shown that there are unique T cells specialized for recognition of lipid or glycolipid antigens bound to the MHC class I-like CD1 molecules (CD1a, b, c or d). Among these lipid-specific T cells, CD1d-restricted T cells, also referred to as natural killer (NK) T cells, are of special interest as a target of drug development, since their role in immunoregulation has been indicated in various physiological or disease conditions including autoimmunity. They are unique in their homogeneous ligand specificity for alpha-glycosylated sphingolipid and secrete large amounts of regulatory cytokines shortly after T cell receptor (TCR) engagement. The first glycolipid identified as an NKT cell ligand was alpha-galactosylceramide (alpha-GalCer) derived from marine sponges. alpha-GalCer exhibits significant immunomodulatory effects by stimulating NKT cells. However, we found that an altered analogue of alpha-GalCer with a shorter sphingosine chain (OCH), is more useful than alpha-GalCer for treatment of autoimmune disease models, because of its ability to selectively induce IL-4, a key cytokine for control of autoimmunity. As such, altered glycolipid ligands (AGL) of alpha-GalCer appear to be promising reagents for treatment of human autoimmune diseases.
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PMID:NKT cell-stimulating synthetic glycolipids as potential therapeutics for autoimmune disease. 1496 7

This review summarizes the major features of CD1 genes and proteins, the patterns of intracellular trafficking of CD1 molecules, and how they sample different intracellular compartments for self- and foreign lipids. We describe how lipid antigens bind to CD1 molecules with their alkyl chains buried in hydrophobic pockets and expose their polar lipid headgroup whose fine structure is recognized by the TCR of CD1-restricted T cells. CD1-restricted T cells carry out effector, helper, and adjuvant-like functions and interact with other cell types including macrophages, dendritic cells, NK cells, T cells, and B cells, thereby contributing to both innate and adaptive immune responses. Insights gained from mice and humans now delineate the extensive range of diseases in which CD1-restricted T cells play important roles and reveal differences in the role of CD1a, CD1b, and CD1c in contrast to CD1d. Invariant TCR alpha chains, self-lipid reactivity, and rapid effector responses empower a subset of CD1d-restricted T cells (NKT cells) to have unique effector functions without counterpart among MHC-restricted T cells. This review describes the function of CD1-restricted T cells in antimicrobial responses, antitumor immunity, and in regulating the balance between tolerance and autoimmunity.
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PMID:CD1: antigen presentation and T cell function. 1503 98

The cytotoxic activity of NK cells can be inhibited by classical and nonclassical MHC molecules. The CD1 system is formed by a family of glycoproteins that are related to classical MHC. CD1a, b, and c molecules present lipids or glycolipids to T cells and are involved in defense against microbial infections, especially mycobacteria. It has been shown recently that these molecules can inhibit target cell lysis by human NK cells. It has also been shown that mouse CD1d molecules can protect cells from NK cell-mediated cytotoxicity. In the present study, we describe how human CD1d, orthologous to murine CD1 molecules, can inhibit NK cell-mediated cytolysis. We have expressed CD1d in the HLA class I-deficient cell lines L721.221 and C1R. The inhibitory effect is observed when effector NK cells from different donors are used, as well as in different cell lines with NK activity. The inhibitory effect was reversed by incubating the target cells with a mAb specific for human CD1d. Incubation of target cells with the ligands for CD1d, alpha-galactosylceramide (alpha-GalCer), and beta-GalCer abolishes the protective effect of CD1d in our in vitro killing assays. Staining the effector cells using CD1d tetramers loaded with alpha-GalCer was negative, suggesting that the putative inhibitory receptor does not recognize CD1d molecules loaded with alpha-GalCer.
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PMID:Expression of human CD1d molecules protects target cells from NK cell-mediated cytolysis. 1518 5

Little is known of the transcriptional events controlling the differentiation and function of dendritic cells (DC). We found that the ligand-activated transcription factor Peroxisome Proliferator Activated Receptor gamma (PPARgamma) is immediately upregulated after the induction of monocyte-derived DC differentiation. Activation of PPARgamma changed the expression pattern of cell surface receptors and enhanced the internalizing activity of DC. Unexpectedly, we found that CD1 glycoproteins, a class of molecules responsible for the presentation of self and foreign modified lipids, were coordinately regulated by PPARgamma activation. CD1a levels were reduced, while CD1d expression was induced. Enhanced expression of CD1d was coupled to the selective induction of invariant natural-killer T cell (iNKT cell) proliferation in the presence of alpha-GalCer. These results suggest that PPARgamma orchestrates a transcriptional response leading to the development of a DC subtype with increased internalizing capacity, efficient lipid presentation, and the augmented potential to activate iNKT cells.
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PMID:Activation of PPARgamma specifies a dendritic cell subtype capable of enhanced induction of iNKT cell expansion. 1534 23

This study reports the molecular characterization and tissue expression of the non-human Aotus nancymaae primate CD1b isoform in the search for an experimental animal model to be used in evaluating the role of non-peptide antigen-presentation molecules in the immune response to infectious agents. CD1b expression on the surface of A. nancymaae peripheral blood monocyte-derived dendritic cells, shown by flow cytometry, was made possible by using human CD1b isoform antibodies. Studying the expression of CD1b-encoded transcripts revealed this molecule's broad distribution in several tissues. The A. nancymaae CD1b transcript-encoded amino-acid sequence showed 95.5% identity with the human sequence. Such high sequence homology was reflected in the identical structural conservation of how pockets A', C' and F' and tunnel T' conforming the antigen's binding site are organized, the similar arrangement of those amino-acids interacting with the T-cell receptor (TCR) during antigen presentation, and the conservation of YQNI-motif sequence in the cytoplasmatic tail (responsible for the molecule's intracellular trafficking in humans). Comparing the structure of human CD1a and CD1b and mouse CD1d proteins with CD1b structure in A. nancymaae obtained by minimization revealed that changes in the latter molecule's alpha1 and alpha2 domains imposed a narrowing of the antigen-binding groove in A. nancymaae CD1b. The high structural similarity between A. nancymaae CD1b and that from humans presented in this study leads to A. nancymaae being proposed as a suitable experimental animal model for analyzing CD1b in vivo, mainly in bacterial and parasite infections such as tuberculosis and malaria, respectively.
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PMID:Identifying and structurally characterizing CD1b in Aotus nancymaae owl monkeys. 1536 47


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