Alternative splicing generates secretory isoforms of human CD1

Alternative spliced CD1d transcripts in human bronchial epithelial cells

CD1d is a MHC I like molecule which presents glycolipid to natural killer T (NKT) cells, a group of cells with diverse but critical immune regulatory functions in the immune system. These cells are required for optimal defence against bacterial, viral, protozoan, and fungal infections, and control of immune-pathology and autoimmune diseases. CD1d is expressed on antigen presenting cells but also found on some non-haematopoietic cells. However, it has not been observed on bronchial epithelium, a site of active host defence in the lungs. Here, we identify for the first time, CD1D mRNA variants and CD1d protein expression on human bronchial epithelial cells, describe six alternatively spliced transcripts of this gene in these cells; and show that these variants are specific to epithelial cells. These findings provide the basis for investigations into a role for CD1d in lung mucosal immunity.

Identification and characterization of an alternatively spliced variant of the MHC class I-related porcine neonatal Fc receptor for IgG

The neonatal Fc receptor for immunoglobulin G (IgG) (FcRn) functions to transport maternal IgG to the fetal/neonatal animals and protects IgG from catabolism. The present study identified two pFcRn cDNAs (1.071 and 0.795kb) from intestinal epithelial cells. The corresponding mRNA transcripts were detected in porcine kidney cell line LLC-PK1, peripheral blood mononuclear cells, and porcine tissues by reverse transcription-PCR (RT-PCR) and Northern blot. Sequence analysis showed that the 1.071kb cDNA encodes the full-length pFcRn (pFcRn-L), whereas the 0.795kb cDNA codes for a truncated pFcRn (pFcRn-S) with deletion of 92 amino acids matching the alpha2 domain of pFcRn-L. pFcRn-L was constitutively expressed by epithelial cells; however, pFcRn-S was not detectable in porcine tissues and cell lines although its transcript was abundant. Despite the lack of native pFcRn-S, pFcRn-S was readily detected in transfected cells. Recombinant pFcRn-L was confirmed to bind IgG at pH 6.0, but not at pH 7.5; however, pFcRn-S failed to bind IgG at both pH 5.0-6.0 and 7.5. pFcRn-L was expressed on the cell surface and mainly localized in early endosomes. In contrast, pFcRn-S was absent from cell surface and primarily localized in the lysosome and pFcRn-S trafficking to lysosomes was independent of beta(2)-microglobulin (beta(2)m). The accumulation of pFcRn-S in the lysosome may explain the absence of native pFcRn-S protein expression. In addition, the trafficking of pFcRn-S to the lysosomal compartment suggests that in addition to sorting signals in its cytoplasmic tail, the FcRn structural integrity may be important for proper intracellular trafficking and function.

CD1 expression on antigen-presenting cells

CD1 proteins present self and microbial glycolipids to CD 1-restricted T cells, or in the case of CD1d, to NKT cells. The CD1 family in humans consists of group I proteins CDla, CDlb, CDlc, and CDle and the group II protein CDld. Rodents express only CDld, but as CD1d is broadly expressed and traffics to all endosomal compartments, this single CD1 family member is thereby able to acquire antigens in many subcellular compartments. A complete understanding of the CD 1 family requires an appreciation of which cells express CD1 and how CD1 contributes to the unique function of each cell type. While group I CD 1 expression is limited to thymocytes and professional APCs, CD1d has a wider tissue distribution and can be found on many nonhematopoietic cells. The expression and regulation of CD1 are presented here with particular emphasis on the function of CD1 in thymocytes, B cells, monocytes and macrophages, dendritic cells (DCs), and intestinal epithelial cells (IECs). Altered expression of CD 1 in cancer, autoimmunity, and infectious disease is well documented, and the implication of CD 1 expression in these diseases is discussed.

The application of CD antigen proteomics to pharmacogenomics

The advent of multiplexing technologies has raised the possibility that disease states can be defined using discrete genomic and proteomic patterns or signatures. However, this emerging area has been limited by the ‘content problem’, arising from the uncertainty of which molecules to focus on. The human cluster of differentiation (CD) antigens are expressed on cells of the human immune system (leukocytes) and on other cell types. These heterogeneous molecules perform a host of roles essential to immune function and to the physiology of other lineages. The 339 defined CD antigens and their, as yet, undefined counterparts constitute key components of the expressed human cell surface proteome. We propose that CD antigen expression patterns will form the basis of a rational, discrete and generalized diagnostic and prognostic system. Furthermore, disease-specific CD antigen proteomic signatures are likely to be more robust than corresponding genomic signatures and will also help to identify molecular targets for therapeutic intervention.

Characterization of two avian MHC-like genes reveals an ancient origin of the CD1 family

Many of the genes that comprise the vertebrate adaptive immune system are conserved across wide evolutionary time scales. Most notably, homologs of the mammalian MHC gene family have been found in virtually all jawed vertebrates, including sharks, bony fishes, reptiles, and birds. The CD1 family of antigen-presenting molecules are related to the MHC class I family but have evolved to bind and present lipid antigens to T cells. Here, we describe two highly divergent nonclassical MHC class I genes found in the chicken (Gallus gallus) that have sequence homology to the mammalian CD1 family of proteins. One of the chicken CD1 genes expresses a full-length transcript, whereas the other has multiple splice variants. Both Southern blot and single nucleotide polymorphism analysis indicates that chicken CD1 is relatively nonpolymorphic. Moreover, cross-hybridizing bands are present in other bird species, suggesting broad conservation in the avian class. Northern analysis of chicken tissue shows a high level of CD1 expression in the bursa and spleen. In addition, molecular modeling predicts that the potential antigen-binding pocket is probably hydrophobic, a universal characteristic of CD1 molecules. Genomic analysis indicates that the CD1 genes are located on chicken chromosome 16 and maps to within 200 kb of the chicken MHC B locus, suggesting that CD1 genes diverged from classical MHC genes while still linked to the major histocompatibility complex locus. The existence of CD1 genes in an avian species suggests that the origin of CD1 extends deep into the evolutionary history of terrestrial vertebrates.

Altered expression of CD1d molecules and lipid accumulation in the human hepatoma cell line HepG2 after iron loading

Iron overload in the liver may occur in clinical conditions such as hemochromatosis and nonalcoholic steatohepatitis, and may lead to the deterioration of the normal liver architecture by mechanisms not well understood. Although a relationship between the expression of ICAM-1, and classical major histocompatibility complex (MHC) class I molecules, and iron overload has been reported, no relationship has been identified between iron overload and the expression of unconventional MHC class I molecules. Herein, we report that parameters of iron metabolism were regulated in a coordinated-fashion in a human hepatoma cell line (HepG2 cells) after iron loading, leading to increased cellular oxidative stress and growth retardation. Iron loading of HepG2 cells resulted in increased expression of Nor3.2-reactive CD1d molecules at the plasma membrane. Expression of classical MHC class I and II molecules, ICAM-1 and the epithelial CD8 ligand, gp180 was not significantly affected by iron. Considering that intracellular lipids regulate expression of CD1d at the cell surface, we examined parameters of lipid metabolism in iron-loaded HepG2 cells. Interestingly, increased expression of CD1d molecules by iron-loaded HepG2 cells was associated with increased phosphatidylserine expression in the outer leaflet of the plasma membrane and the presence of many intracellular lipid droplets. These data describe a new relationship between iron loading, lipid accumulation and altered expression of CD1d, an unconventional MHC class I molecule reported to monitor intracellular and plasma membrane lipid metabolism, in the human hepatoma cell line HepG2.

Function of alternative splicing

Alternative splicing is one of the most important mechanisms to generate a large number of mRNA and protein isoforms from the surprisingly low number of human genes. Unlike promoter activity, which primarily regulates the amount of transcripts, alternative splicing changes the structure of transcripts and their encoded proteins. Together with nonsense-mediated decay (NMD), at least 25% of all alternative exons are predicted to regulate transcript abundance. Molecular analyses during the last decade demonstrate that alternative splicing determines the binding properties, intracellular localization, enzymatic activity, protein stability and posttranslational modifications of a large number of proteins. The magnitude of the effects range from a complete loss of function or acquisition of a new function to very subtle modulations, which are observed in the majority of cases reported. Alternative splicing factors regulate multiple pre-mRNAs and recent identification of physiological targets shows that a specific splicing factor regulates pre-mRNAs with coherent biological functions. Therefore, evidence is now accumulating that alternative splicing coordinates physiologically meaningful changes in protein isoform expression and is a key mechanism to generate the complex proteome of multicellular organisms.

Human CD1D gene has TATA boxless dual promoters: an SP1-binding element determines the function of the proximal promoter

CD1d presents lipid Ags to a specific population of NK T cells, which are involved in the host immune defense, suppression of autoimmunity, and the rejection of tumor cells. The transcriptional control mechanism that determines the regulation and the tissue distribution of CD1d remains largely unknown. After investigating 3.7 kb 5' upstream of the coding region, we found that human gene encoding CD1d molecule (CD1D) has TATA boxless dual promoters with multiple transcription initiation sites. The proximal promoter is located within the region of -106 to +24, and the distal promoter is located within the region of -665 to -202 with the A of the translational start codon defined as +1. The longest 5'-untranslated region derived from 5'-RACE and apparently generated by the distal promoter has 272 bp in length covering the genomic sequence of the proximal promoter. The region covering the proximal promoter gave a much higher luciferase activity in Jurkat cells than in K562 cells, whereas it was in reverse for the region covering the distal promoter, indicating a cell type sp. act. of the two promoters. Transcription factor SP1 plays a crucial role in the function of the proximal promoter. The analysis of the CD1D promoter region indicates that IFN-gamma, NF-IL-6, and T cell factor 1/lymphoid enhancer-binding factor 1 are most likely involved in the regulation of CD1d expression. The illustration of the dual CD1D gene promoters will help to reveal the regulatory factors that control CD1d expression and its tissue distribution for a better understanding of the cross-regulation between CD1d and NK T cells.

CD1: antigen presentation and T cell function

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.

Soluble nonclassical HLA generated by the metalloproteinase pathway

Soluble human leukocyte antigens (HLA-A, -B, and -C) proteins can be generated by a membrane-bound metalloproteinase (MPase). The MPase-mediated pathway produces soluble nonconformed HLA proteins susceptible to further degradation, and also HLA proteins with high affinity peptides stable at physiologic temperatures. Accessibility of classical HLA to the MPase cleavage inversely correlates with stability of heavy chain (HC) interactions with beta2-microglobulin (beta(2)m). Whether a MPase is involved in release of soluble nonclassical HLA or CD1 proteins is unknown. We have investigated this question with transfectants expressing full-length HLA proteins. Native surface HLA-E and -G complexes, similar to HLA-A2, were unstable at low pH and dissociated giving rise to beta(2)m-free HC. Furthermore, HLA-E and -G proteins, similar to HLA-A2, were readily released from cell surface into supernatants as soluble 37-kilodalton beta(2)m-free HC. However, the stability of surface CD1d complexes was not affected by pH changes and no soluble CD1d was detected. Because beta(2)m-free CD1d HC were expressed on cells, the lack of cleaved soluble products cannot be explained by high stability of native complexes. Instead, absence of a CD1d-specific MPase in these cells or its impaired interactions with substrate HC may be responsible.

Intracellular pathways of CD1 antigen presentation

Each of the human CD1 proteins takes a different route through secretory and endocytic compartments before finally arriving at the cell surface, where these proteins present glycolipid antigens to T cells. Recent studies have shown that adaptor-protein complexes and CD1-associated chaperones control not only CD1 trafficking, but also the development and activation of CD1-restricted T cells. This indicates that CD1 proteins, similar to MHC class I and II molecules, selectively acquire certain antigens in distinct cellular subcompartments. Here, we summarize evidence supporting the hypothesis that CD1 proteins use separate, but parallel, pathways to survey endosomal compartments differentially for lipid antigens.

A new aspect in glycolipid biology: glycosphingolipids as antigens recognized by T lymphocytes

T cells may recognize a large variety of ligands with different chemical structures. Recently, glycosphingolipids have also been shown to stimulate human T lymphocytes. Recognition of glycosphingolipids is restricted by the nonpolymorphic CD1 molecules, expressed by professional antigen-presenting cells and by macrophages infiltrating inflammatory sites. CD1 molecules have a structure resembling that of classical MHC class I molecules, with the terminal extracellular domains characterized by two antiparallel alpha helices placed on two hydrophobic pockets. The glycosphingolipids bound to CD1 insert the lipid tails in the two pockets and position the hydrophilic head on the external part of CD1. The TCR interacts with aminoacids present in the two alpha helices and with residues provided by the carbohydrate moiety of glycosphingolipids and discriminates their structural variations. T cells recognizing self-glycosphingolipids release proinflammatory cytokines and may have a pathogenetic role in autoimmune diseases such as multiple sclerosis.

Influence of Mycobacterium bovis bacillus Calmette Guérin on in vitro induction of CD1 molecules in human adherent mononuclear cells

Nonpeptide antigens (including glycolipids of microbial origin) can be presented to T cells by CD1 molecules expressed on monocyte-derived dendritic cells. These HLA unrestricted responses appear to play a role in host immunity against Mycobacterium tuberculosis and other pathogenic bacteria. It is known that vaccination with Mycobacterium bovis bacillus Calmette-Guérin (BCG) has limited efficacy in many clinical settings, although the reasons for its inadequacy remain unclear. Here we have investigated the influence of BCG on the induction of CD1b on human monocytes by granulocyte-macrophage colony-stimulating factor (GM-CSF), which is believed to be the principal inducer of this antigen-presenting molecule. Although BCG alone led to a slight induction of CD1b expression, this agent reduced markedly the ability of GM-CSF to induce high levels of CD1b that were typically observed in uninfected cells. Inhibition of CD1b expression in BCG-infected monocytes was apparent at both the mRNA transcript and CD1b protein levels. Down-regulation of CD1b expression by BCG was mediated, at least in part, by one or more soluble factors and could not be reversed with high concentrations of GM-CSF or a variety of other cytokines. The present results suggest that BCG could diminish the efficiency of CD1-restricted T-cell responses against nonpeptide mycobacterial antigens by reducing CD1 expression on antigen-presenting cells. These findings have potential implications for understanding the nature of the immune response elicited by BCG in humans and suggest potential strategies that could be important for the development of better vaccines for the prevention of tuberculosis.

Ligand-independent assembly of recombinant human CD1 by using oxidative refolding chromatography

CD1 is an MHC class I-like antigen-presenting molecule consisting of a heavy chain and beta(2)-microglobulin light chain. The in vitro refolding of synthetic MHC class I molecules has always required the presence of ligand. We report here the use of a folding method using an immobilized chaperone fragment, a protein disulphide isomerase, and a peptidyl-prolyl cis-trans isomerase (oxidative refolding chromatography) for the fast and efficient assembly of ligand-free and ligand-associated CD1a and CD1b, starting with material synthesized in Escherichia coli. The results suggest that "empty" MHC class I-like molecules can assemble and remain stable at physiological temperatures in the absence of ligand. The use of oxidative refolding chromatography thus is extended to encompass complex multisubunit proteins and specifically to members of the extensive, functionally diverse and important immunoglobulin supergene family of proteins, including those for which a ligand has yet to be identified.

Group 1 CD1 genes in rabbit

CD1 is an Ag-presenting molecule that can present lipids and glycolipids to T cells. The CD1 genes were first identified in the human, and since then, homologs have been identified in every mammalian species examined to date. Over a decade ago, CD1B and CD1D homologs were identified in the rabbit. We have extended this earlier study by identifying additional CD1 genes with the goal of developing the rabbit as an animal model to study the function of CD1 proteins. We constructed a thymocyte cDNA library and screened the library with CD1-specific probes. Based on nucleotide sequence analyses of the CD1(+) cDNA clones obtained from the library, we have identified two CD1A genes and one CD1E gene as well as determined the complete sequence of the previously identified CD1B gene. The CD1E(+) cDNA clones lacked the transmembrane and cytoplasmic domains and, if translated, would encode for a soluble or secreted CD1E protein. In addition, expression studies demonstrated that the CD1 genes were expressed in peripheral lymphoid tissues as well as in skin, gut, and lung. Of interest is the finding that CD1A2, CD1B, and CD1E genes were found to be expressed by rabbit B cell populations. The rabbit, with a complex CD1 locus composed of at least two CD1A genes, one CD1B gene, one CD1D gene, and one CD1E gene, is an excellent candidate as an animal model to study CD1 proteins.

The molecular biology of CD1

CD1 were the first human differentiation antigens to be identified by monoclonal antibodies. In this review, we summarize some key results from the molecular study of CD1, with particular reference to their relationship to MHC antigens, and to the existence of two distinct groups of CD1 molecules.

Characterization of CD1e, a third type of CD1 molecule expressed in dendritic cells

Dendritic cells express several alternatively spliced CD1e mRNAs. These molecules encode proteins characterized by the presence of either one, two, or three alpha domains and either a 51- or 63-amino acid cytoplasmic domain. Moreover, mRNAs encoding isoforms lacking the transmembrane domain are observed. Several of these CD1e isoforms were expressed in transfected cells, and two of them, with three alpha domains, displayed a particular processing pathway. These latter isoforms slowly leave the endoplasmic reticulum due to the presence of atypical dilysine motifs in the cytoplasmic tail. These molecules are associated with the beta(2)-microglobulin and accumulate in late Golgi and late endosomal compartments. In the latter compartments, they are cleaved into soluble forms that appear to be stable. In dendritic cells, these isoforms are mainly located in the Golgi apparatus, and upon maturation they are redistributed to late endosomal compartments. This work demonstrates the existence of CD1e molecules. As compared with other CD1 molecules, CD1e displays fundamentally different properties and therefore may represent a third type of CD1 molecules.

Differential expression of ovine CD1

was examined using a combination of reverse transcription-polymerase chain reaction (RT-PCR) with sequence-specific primers and Northern and in situ hybridization techniques. The aim of the study was to establish the patterns of CD1 expression at the molecular level and address questions posed by previous studies in other species regarding expression patterns of CD1. A 'pan-CD1' probe based on the exon 4 (alpha 3) region was used in addition to isotype-specific probes for SCD1B (the exon 3 region of clone SCD1B42) and SCD1D (the exon 3 region of clone SCD1D). Widespread expression of CD1 (including thymus, peripheral blood lymphocytes, lung and intestine) was identified using both the exon 4 and SCD1D probe. SCD1B expression was more restricted, being identified in equivalent levels only in the thymus and in scattered populations of dendritic cells. These results highlight the difference in expression patterns between group 1 and group 2 CD1 family members and establish SCD1D as the CD1 family member with the widest pattern of expression, consistent with a differential role for the different CD1 family members.

Alternative splicing forms of the human CD1D gene in mononuclear cells

CD1d is a critical molecule for the presentation of lipid antigens to natural killer (NK) T cells. To investigate the molecular complexity of CD1d, alternatively spliced transcripts in peripheral blood mononuclear cells from three healthy subjects were analyzed by PCR and sequencing methods. We found eight alternatively spliced variants of the CD1D gene (V1-V8), seven of which are newly established variants (V2-V8). V1 and V4 are in-frame; however, the other six variants (V2, V3, V5-V8) are out-of-frame. V1, V2, V4, and V5 lack a beta(2)-microglobulin binding site (alpha3 domain), indicating the unstable presentation of the CD1d molecule on the surface. In V2 and V5, the transmembrane region is absent, supporting a soluble CD1d. In the V3-V8 variants, the antigen binding region (alpha1 and alpha2 domains) is partially defective, suggesting incomplete functional products. In contrast, the V1 and V2 transcripts bear the complete antigen binding site, resulting in functional proteins. Especially, the V2 splicing variant might function as an inhibitory soluble CD1d molecule and regulate the presentation of antigens on APC to NKT cells.

Frequent lack of translation of antigen presentation-associated molecules MHC class I, CD1a and Beta(2)-microglobulin in Reed-Sternberg cells

Epstein-Barr virus (EBV) is present in Reed-Sternberg (RS) cells of a substantial proportion of Hodgkin's lymphoma cases. Most EBV-positive cases are also MHC class I-positive, whereas the majority of EBV-negative cases lack detectable levels of MHC class I expression. Application of the SAGE technique has led to the identification of tags corresponding to MHC class I and beta(2)-microglobulin genes in the EBV- and MHC class I-negative L428 Hodgkin's cell line. Further expression studies indicated that single RS cells that do not express HLA class I also lack beta(2)-microglobulins but frequently contain mRNA coding for these proteins. Another tag was identified corresponding to CD1a, a thymocyte and Langerhans cell antigen structurally related to the MHC class I genes. CD1a expression studies revealed mRNA in all cell lines and in several of the single cells, whereas immunostaining showed a cytoplasmic signal in only 2 of the 4 cell lines and in none of the Hodgkin's lymphoma tissue samples. In conclusion, RS cells frequently lack MHC class I, beta(2)-microglobulin and CD1a protein expression but contain mRNA coding for these proteins in some of the RS cells, suggesting a common mechanism affecting the translation of these antigen presentation-associated molecules.

Sheep CD1 genes and proteins

Interest in CD1 genes and proteins was initially stimulated by their close evolutionary and structural relationship to MHC class I molecules. The demonstration that CD1b and c molecules present novel non-peptide antigens to T-cells and play a role in protection against mycobacterial infection then focused attention on the functional role of CD1 proteins. Sheep possess at least seven CD1 genes, including CD1B, D and E, which is the most complex genetic arrangement identified so far in any animal. OvCD1B consists of at least three distinct genes, with the probability of limited polymorphism and the existence of splice variants. Most anti-sheep CD1-specific monoclonal antibodies react with OvCDlb and phenotypic and immunochemical data suggests the existence of two variants. CD1D genes have been identified in all species studied, suggesting a conserved role for CDld proteins across mammalian species. Presumptive evidence for the existence of OvCDIE has been obtained by NH2-terminal sequencing of protein precipitated by the mAb 20.27 (SBU-T6). Confirmatory evidence from gene cloning experiments is currently being sought. Collectively, these factors make the sheep CD1 family a highly relevant model for investigating the in vivo role of CD1 molecules. In this survey, the properties of monoclonal antibodies specific for sheep CD1, the cellular distribution and physicochemical characteristics of sheep CD1 molecules and the current state of knowledge on sheep CD1 genetics are reviewed.

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.

Genomics, Isoforms, Expression, and Phylogeny of the MHC Class I-Related MR1 Gene

A growing number of non-MHC-encoded class I-related molecules have been shown to perform diverse, yet essential, functions. These include T cell presentation of bacterially derived glycolipidic Ags by CD1, transcytosis of maternal IgG by the neonatal Fc receptor, enriched presence and plausible function within exocrine fluids of the Zn-α2-glycoprotein, subversion of NK cytolytic activity by the CMV UL18 gene product, and, finally, crucial involvement in iron homeostasis of the HFE gene. A recently described member of this family is the MHC class-I related (MR1) gene. The most notable feature of MR1 is undoubtedly its relatively high degree of sequence similarity to the MHC-encoded classical class I genes. The human chromosome 1q25.3 MR1 locus gives rise not only to the originally reported 1,263-bp cDNA clone encoding a putative 341-amino acid polypeptide chain, but to many additional transcripts in various tissues as well. Here we define the molecular identity of all human and murine MR1 isoforms generated through a complex scenario of alternative splicing, some encoding secretory variants lacking the Ig-like α3 domain. Moreover, we show ubiquitous transcription of these MR1 variants in several major cell lineages. We additionally report the complete 18,769-bp genomic structure of the MR1 locus, localize the murine orthologue to a syntenic segment of chromosome 1, and provide evidence for conservation of a single-copy MR1 gene throughout mammalian evolution. The 90% sequence identity between the human and mouse MR1 putative ligand binding domains together with the ubiquitous expression of this gene favor broad immunobiologic relevance.

An immunocytochemical study of MHC class I expression on human Langerhans cells and melanocytes

Classical MHC class I glycoproteins (HLA-A, B, and C) present endogenous cytosolic peptide antigen fragments to CD8-positive T-cells. CD8-positive T-cell recognition and destruction of virus-infected cells are dependent on adequate cellular MHC class I expression. Constitutive MHC class I expression is ubiquitous, but known to be deficient on specific differentiated cell types which include hepatocytes, neurones, chondrocytes and myocytes. Although enabling assessment of MHC class I expression on individual cells, limitations of immunocytochemistry were encountered with this assessment on Langerhans cells and melanocytes. These dispersed intraepidermal cells were obscured by adjacent keratinocytes in sections immunostained for MHC class I glycoproteins. Initiatives designed to resolve the issue have included immunoelectron microscopy, cell culture techniques, and animal bone marrow chimera models. Despite the elegance of these techniques, the issue of MHC class I expression on Langerhans cells and melanocytes remains unresolved. In this immunocytochemical study, an alternative strategy was based upon the recognized deficiency of epithelial MHC class I expression within pilosebaceous adnexal units. Langerhans cells and melanocytes were therefore studied within this microenvironment of deficient MHC class I expression, using monomorphic and polymorphic MHC markers. Langerhans cells and melanocytes were demonstrated within pilosebaceous units of scalp skin by immunocytochemistry. Differentiation markers OKT6 (CD1a) and TMH1 defined Langerhans cells and melanocytes, respectively. Monomorphic MHC markers W6/32 and TAL IB5 defined invariant epitopes of HLA class I and II, respectively. Polymorphic MHC class I markers defined the HLA-Bw4 and HLA-Bw6 supertypic determinants. Constitutive MHC class I expression was shown to be deficient on Langerhans cells and melanocytes.

IFN-gamma modulates CD1d surface expression on intestinal epithelia

In vivo, epithelial cells that line the intestine are intimately associated with lymphocytes, termed intestinal intraepithelial lymphocytes (iIEL). A putative ligand for iIEL on intestinal epithelial cells is CD1d, and recent studies demonstrate a surface form of this molecule exists on intestinal epithelia. At present, it is not known whether CD1d expression is regulated by cytokines in the intestinal microenvironment. Thus we examined the impact of relevant cytokines on CD1d at the level of mRNA and cell surface expression. Using a sensitive whole cell enzyme-linked immunosorbent assay, we assessed the impact of relevant cytokines on CD1d expression on intestinal epithelial cell lines. We were readily able to detect CD1d on the surface of T84 cells, a cryptlike intestinal epithelial cell line. Epithelial cell exposure to human recombinant interferon-gamma (IFN-gamma) resulted in increased CD1d expression in a dose- and time-dependent manner. Polymerase chain reaction amplification of CD1d cDNA revealed a time-dependent induction after exposure to IFN-gamma. This IFN-gamma effect on CD1d expression was cytokine specific and was evident with epithelial cell lines other than T84, including Caco-2 and HT-29 cells. Finally, we were not able to detect significant surface expression of CD1a, CD1b, or CD1c on intestinal epithelial cell lines in the presence or absence of relevant cytokines. These results indicate that CD1d cell surface protein and cellular mRNA, like other major histocompatibility complex-related molecules, is cytokine regulated in intestinal epithelial cell lines.

Placental expression of HLA class I genes

This article presents an overview of the more recent data dealing with the constitutive, transcriptional, and translational expression of classical class Ia and nonclassical HLA-E and -G class Ib products in the different trophoblast cell subpopulations that constitute the maternofetal interface during human pregnancy. Of particular interest is the expression of alternatively spliced HLA-G transcriptional isoforms that may be translated in membrane-bound or soluble protein products. Molecular regulatory mechanisms that may control the differential expression of class Ia and class Ib molecules, according to the cell types, state of differentiation, and stages of gestation are also examined. They may operate at the levels of transcription, translation and/or transport of proteins to the cell surface. Functional significance of the absence of detectable cell surface expression of class Ia molecules in all trophoblast cell subpopulations, and of the presence of membrane-bound HLA-G products in extravillous cytotrophoblast cells is finally questioned.

Detection of membrane-bound HLA-G translated products with a specific monoclonal antibody

A monomorphic anti-HLA-G monoclonal antibody (mAb) was obtained by immunization of HLA-B27/human beta 2-microglobulin double-transgenic mice with transfected murine L cells expressing both HLA-G and human beta 2-microglobulin. This mAb, designated BFL.1, specifically recognizes, by flow cytometry analysis, the immunizing HLA-G-expressing cells, whereas it does not bind to parental untransfected or to HLA-B7- and HLA-A3-transfected L cells, suggesting that it distinguishes between classical HLA-A and -B and nonclassical HLA-G class I molecules. This was further assessed by the absence of BFL.1 reactivity with a number of human cell lines known to express classical HLA class I proteins. In addition, we showed that the BFL.1 mAb also labels HLA-G-naturally-expressing JEG-3 and HLA-G-transfected JAR human choriocarcinoma cell lines as well as a subpopulation of first-trimester placental cytotrophoblast cells. Further biochemical studies were performed by immunoprecipitation of biotinylated membrane lysates: BFL.1, like the monomorphic W6/32 mAb, immunoprecipitated a 39-kDa protein in HLA-G-expressing cell lines, a size corresponding to the predicted full-length HLA-G1 isoform. However, in contrast to W6/32, which immunoprecipitates both classical and nonclassical HLA class I heavy chains, BFL.1 mAb does not recognize the class Ia products. Such a mAb should be a useful tool for analysis of HLA-G protein expression in various normal and pathological human tissues and for determination of the function(s) of translated HLA-G products.

Structure and function of the CD1 family of MHC-like cell surface proteins

The CD1 family of proteins are structurally related to MHC class I proteins, but are only distantly related to the class I proteins or other MHC-linked class I-like proteins. Sequence comparisons indicate that the CD1 proteins have evolved into two subfamilies, those which are similar to human CD1a, b, and c and those which are similar to human CD1d. The CD1A-, B-, and C-like genes were deleted from rodents and the CD1D gene was duplicated. CD1a, b, and c are expressed by thymocytes, dendritic cells, activated monocytes, and B cells (CD1c), a tissue distribution which strongly suggests a role in antigen presentation. In contrast, CD1d and its murine homologues are expressed by many cells outside of the lymphoid and myeloid lineages. The CD1 proteins are in most cases expressed as beta 2mg-associated membrane glycoproteins, but may associate with additional proteins. CD1d is expressed on the surface of intestinal epithelial cells in a nonglycosylvated form without beta 2mg. Whether the CD1 proteins function as antigen-presenting molecules is unresolved, but it is unlikely that they present conventional peptide antigens. Strong evidence indicates that murine CD1 proteins are recognized by a population of NK1.1+, CD4+ or CD4-CD8- (double negative, DN) T cells which express an invariant TCR alpha chain. CD1d is most likely recognized by the homologous T cell population in humans. DN alpha beta T cells which recognize CD1a, b, or c have been isolated, including clones which recognize a lipid antigen from mycobacteria presented by CD1b. A third potential population of CD1 reactive cells are CD8+ T cells in the intestinal epithelium. Taken together, these observations indicate that CD1 proteins interact with several specialized populations of T cells. The precise biological functions mediated through these interactions remain to be determined.