Biochemical comparison of the T6 antigen and HLA-A,B antigens

Recruitment of CD1a+ Langerhans cells to the nasal mucosa in seasonal allergic rhinitis and effects of topical corticosteroid therapy

BACKGROUND

Local antigen presentation may be necessary for both primary and recall T-cell responses to grass pollen in hay fever patients. We examined the effect of seasonal allergen exposure on nasal mucosal antigen-presenting cell (APC) populations and the effects of topical corticosteroid therapy.

METHODS

Nasal biopsies were collected from 46 grass pollen-sensitive seasonal rhinitis patients before the grass-pollen season. A second biopsy was collected during the pollen season, when patients had received 6 weeks' treatment with either fluticasone propionate (200 microg, twice daily) or placebo. Cell populations in biopsy sections were quantified by immunocytochemistry.

RESULTS

Significant increases in submucosal and epithelial CD1a+ Langerhans cells, but not CD68 + macrophages or CD20 + B cells, were observed during the pollen season. Seasonal increases in CD1a+ Langerhans cells were inhibited by corticosteroid therapy.

CONCLUSIONS

Recruitment of CD1a+ Langerhans cells to the nasal mucosa during natural seasonal allergen exposure may contribute to local T cell responses. Topical corticosteroids may act, at least in part, by inhibiting effective allergen presentation to T cells through inhibition of recruitment of Langerhans cells to the nasal mucosa.

Cytoplasmic tail-dependent localization of CD1b antigen-presenting molecules to MIICs

CD1 proteins have been implicated as antigen-presenting molecules for T cell-mediated immune responses, but their intracellular localization and trafficking remain uncharacterized. CD1b, a member of this family that presents microbial lipid antigens of exogenous origin, was found to localize to endocytic compartments that included the same specialized subset of endosomes in which major histocompatibility complex (MHC) class II molecules are proposed to bind endocytosed antigens. Unlike MHC class II molecules, which traffic to antigen-loading endosomal compartments [MHC class II compartments (MIICs)] primarily as a consequence of their association with the invariant chain, localization of CD1b to these compartments was dependent on a tyrosine-based motif in its own cytoplasmic tail.

An analysis of the role of skin Langerhans cells (LC) in the cytoplasmic processing of HIV-1 peptides after "peplotion" transepidermal transfer and HLA class I presentation to CD8+ CTLs--an approach to immunization of humans

Skin Langerhans cells (LC) are antigen-presenting cells capable of expressing MHC class I and class II molecules on the plasma membrane. This molecular activity was reviewed to combine the knowledge of peptide presentation by MHC and HLA class I and class II molecules to prime CD8+ cytotoxic T cells (CTLs) and CD4+ T helper cells, respectively. The possible utilization of the skin dendritic cells for the development of antiviral CTLs and antibodies by synthetic peptides modeled according to the motifs of peptides that naturally interact with the peptide binding grooves of the various HLA haplotypes is discussed and evaluated. It may be possible that the introduction of synthetic viral peptides with motifs to fit the HLA class I haplotypes of a human population to the skin dendritic cells will prime selectively the cellular or the humoral immune responses. This approach may provide a new vaccination technique that applies synthetic virus peptides as vaccines for the immunization of humans. The neuropeptide CGRP interacts with LC and modulates antigen presentation.

Corneal and ocular surface histochemistry

In summary, this review has provided information concerning the application of histochemical and cytochemical procedures used to detail the normal versus pathological cornea and ocular surface. Specifically, histochemical analysis has been used to study protein and peptide degradation in cornea, to analyze stromal non-collagenous and collagenous fibers and associated extracellular matrix. Cytochemistry of the ocular surface has been used to detail the morphology of corneal and conjunctival mucin. Use of small cationic probes as well as lectin-gold binding was advantageous to quantitatively demonstrate that ocular mucin contains sialylated residues and that the number of these residues significantly changes (increases) with age. These data are important in that the degree of sialylation has been shown to correlate with the ability of bacterial organisms to adhere to and infect the immature in contrast to the mature corneal surface. The use of lectin analysis of diseased ocular tissue also has shown that there are specific alterations in glycoconjugates which occur in the diseased versus normal human cornea. Wound healing in cornea is an important problem which has been studied at length using combined histochemical and biochemical approaches. Results support the hypothesis that apical cell surfaces of the leading edge of a migrating sheet differ from those of the normal epithelium. During wound healing, alpha 6 integrin expression by corneal epithelial cells has been demonstrated, but another protein, syndecan was only seen in non-migrating epithelium which had restratified. The association of immunoglobulins with the ocular surface epithelium of the cornea, their change with age and kinetics of appearance also has been demonstrated using a cytochemical approach. Histochemical procedures have been used to localize Class I and Class II molecules in cornea and conjunctiva. Class II antigen expression has been shown to be absent on corneal endothelium, but it can be induced by treatment with IFN-gamma. These data are of importance in corneal pathology such as that resulting in rejection of corneal transplants. Langerhans cells (Class II, Ia positive) also are not found in normal central cornea. They are localized in the peripheral cornea and are stained histochemically by ADPase, ATPase and by specific anti-Ia and other antisera. Increased numbers of LC have been demonstrated in cornea following various stimuli and in diseases of the cornea including both bacterial and viral induced keratitis.

Dynamic nature and function of epidermal Langerhans cells in vivo and in vitro: a review, with emphasis on human Langerhans cells

Epidermal Langerhans cells (LC) are Birbeck granule-containing bone-marrow-derived cells, which are located mainly in the suprabasal layer of the epidermis. They can be readily identified by their strong expression of CD1a and MHC class II molecules. In addition to these 'classical' properties, an extensive phenotypic profile of normal human LC, summarized in this review, is now available. The powerful capacity of LC to activate T lymphocytes is clearly documented and, to date, LC are recognized as the prominent antigen-presenting cells of the skin immune system. They are generally believed to pick up antigens encountered in the epidermis and to migrate subsequently from the epidermis to the skin-draining lymph nodes. Upon arrival in the paracortex of lymph nodes, the antigen-laden LC transform into interdigitating cells and they present antigen to naive T lymphocytes in a MHC class II-restricted fashion; this results in the generation of antigen-specific immune responses. It has also been demonstrated that transformation of LC into interdigitating cells occurs when LC are cultured in vitro. Both in vivo and in vitro studies have indicated that properties of LC, such as phenotype, morphology and the stimulatory potential to activate T lymphocytes, are dependent on the local microenvironment in which the LC reside. The essential role of LC in the induction of contact allergic skin reactions and skin transplant rejection is well established.

Langerhans cells in nasal mucosa of patients with grass pollen allergy

Langerhans cells (LC) are known to be present in squamous epithelia of the human body. They are dendritic cells (DC) and characterized by the presence of Birbeck granules (BG). In previous studies, DC positive for CD1a and HLA-DR were found in the cylindrical epithelium and the lamina propria of the nasal mucosa. In our study, more CD1a cells occurred in the allergic patients than in the non-allergic controls. In a combined light microscopy (LM) and electron microscopy (EM) study, biopsies of nasal mucosa in allergic patients were studied. We used monoclonal antibodies against CD1a and HLA-DR, to identify DC in LM cryostat sections. The presence of BG identified most of the intra-epithelial DC as LC on the EM level, whereas a minority of DC in the lamina propria also contained BG. The ultrastructure of LC and DC in the ciliated cylindrical epithelium and the lamina propria is compared.

Recognition of cluster of differentiation 1 antigens by human CD4-CD8-cytolytic T lymphocytes

Human cluster-of-differentiation 1 (CD1) is a family of cell surface glycoproteins of unknown function expressed on immature thymocytes, epidermal Langerhans cells and a subset of B lymphocytes. Three homologous proteins, CD1a, b and c, have been defined serologically, and the CD1 gene locus on human chromosome 1 contains five potential CD1 genes. Analysis of the predicted amino-acid sequences of CD1 molecules reveals a low but significant level of homology to major histocompatibility complex (MHC) class I and class II molecules, and, like MHC class I molecules, CD1 molecules are associated non-covalently with beta 2-microglobulin. These structural similarities to known antigen-presenting molecules, together with the expression of CD1 on cells capable of antigen presentation, suggest a role for CD1 molecules in antigen recognition by T cells. Here we demonstrate the specific recognition of CD1a by a CD4-CD8- alpha beta T-cell receptor (TCR) expressing cytolytic T lymphocyte (CTL) line and the specific recognition of CD1c by a CD4-CD8- gamma delta TCR CTL line. The interaction of CD1-specific CTLs with CD1+ target cells appeared to involve the CD3-TCR complex, and did not show evidence of MHC restriction. These results suggest that for a subset of T cells, CD1 molecules serve a function analogous to that of MHC class I and II molecules.

A surface glycoprotein complex related to the adhesive receptors of the VLA family, shared by epidermal Langerhans cells and basal keratinocytes

A murine monoclonal antibody, designated K20, was raised by immunization with a human malignant T-cell line. It reacted specifically with membrane glycoprotein complexes on early haematopoietic cells, T cells, and monocytes. In epidermis, K20 specifically reacted with Langerhans cells and basal keratinocytes, as demonstrated by double labeling experiments. Membrane immunoprecipitation analysis demonstrated that the antigen identified by K20 on lymphoid cells and epidermal cells was different. While on lymphoid cells, K20 recognized glycoprotein complexes made of a constant 130-kD subunit associated with subunits of higher molecular weight ranging from 150 to 200 kD, a complex of 105-145 kD was precipitated from Langerhans and basal cells. Metabolic labeling studies demonstrated that these proteins were synthesized by the basal cells. The antigen identified by K20 was thought to belong to the integrins, a family of cell surface receptors that play a role in cell adhesion, cell interactions, wound healing, and immune defense mechanisms. K20 is the first monoclonal antibody that specifically recognizes a membrane antigen common to Langerhans and basal cells. Additionally, K20 is the first of five reported monoclonal antibodies to have been characterized on the epidermal cells that detect antigens shared by lymphoid subpopulations and normal basal keratinocytes.

CD-1 (T6), HLA-DR-expressing cells, presumably Langerhans cells, in nasal mucosa

In the skin, epidermal Langerhans cells (LC) constitute a major population of antigen-presenting cells. These cells are characterized by the expression of both CD-1 (T6) and HLA-DR on the cell membrane. We wanted to know whether similar CD-1/HLA-DR-positive cells occur in the nasal mucosa of patients with an isolated grass pollen allergy and in non-allergic controls. CD-1/HLA-DR-positive dendritic cells were found in columnar and cuboidal epithelium and the lamina propria of the nasal mucosa. These CD-1/HLA-DR-positive cells presumably correspond with LC in the skin. We also found significantly more CD-1-positive cells in nasal biopsy samples of allergic than in those of the non-allergic controls. In the allergic patients some of the CD-1-positive cells were found to be surface IgE-positive, possibly due to passive adherence of IgE to Fc receptors.

Molecular cloning of CD1a (T6), a human epidermal dendritic cell marker related to class I MHC molecules

To investigate the structure, function, and control of CD1a, we have cloned a 1.6-kbp cDNA which encodes the expressed CD1a protein and includes untranslated 5' and 3' sequences and the poly-A tail. As the protein recognized by the monoclonal antibody OKT6, CD1a is a useful marker for Langerhans cells (LC). CD1a is found on these cells and on thymocytes, suggesting an important immunologic role for this molecule. We constructed a cDNA library in lambda gt10 using mRNA from MOLT-4, a cell line that expresses the CD1a surface antigen. We then screened the library with an oligonucleotide synthesized according to a known partial sequence for CD1a, and subcloned the cDNA and its restriction fragments into pGEM for sequencing and probe production. Based on this sequence the CD1a protein is predicted to consist of three extracellular domains (alpha 1-3), a hydrophobic transmembrane region, and a cytoplasmic tail. DNA 5' to the alpha 1 region may undergo alternative exon splicing. There is high sequence identity between the beta-2 microglobulin binding region of MHC I molecules and CD1a. The secondary structure predicted for CD1a is very similar to the actual structure of HLA-A2, a classical MHC I molecule. The similarity includes the beta pleated sheets and alpha helices which form the antigen binding groove of the alpha-1 and alpha-2 domains. The homology predicted between CD1a and HLA-A2 in these regions appears to exist on the level of secondary structure despite low primary nucleotide and amino acid sequence identity. The structural data and probes we have developed should facilitate studies of the function of CD1a as well as novel investigations of LC.

Heterogeneity in the B1 (CD20) cell surface molecule expressed by human B-lymphocytes

The B1 molecule (CD20) is a phosphoprotein expressed only by B-lymphocytes. In this study, analysis of B1 immunoprecipitated from surface iodinated B-cell lines and B-lymphocytes has shown that there are several expressed forms of B1. A predominant species of Mr 33,000 represents 75-80% of the iodinated cell surface B1 and a Mr 35,000 species represents 20-25%. Limited proteinase digestion of these two species generated similar peptide maps demonstrating that the different forms of B1 shared common peptides. Biosynthetic labeling with [35S]methionine revealed that the Mr 35,000 B1 species may actually represent two bands of Mr 34,500 and 36,000. Endoglycosidase digestion studies and metabolic labeling in the presence of tunicamycin indicated that neither the Mr 33,000 or 34,500-36,000 forms of B1 were glycosylated. The Mr 33,000 and 34,500-36,000 forms of B1 were constitutively phosphorylated in B-cell lines. However, exposure of B-cells to PMA resulted in a significant increase in the phosphorylation of the Mr 34,500-36,000 form. Exposure to PMA also resulted in an increase in the amount of Mr 34,500-36,000 protein immunoprecipitated from 35S labeled cells. These results suggest that there are multiple forms of the B1 molecule expressed by B-lymphocytes and that this heterogeneity may result from phosphorylation of the B1 protein.

Monomeric and dimeric IgG1 as probes for assessing high-affinity and low-affinity receptors for IgG on human monocyte-derived macrophages and on activated macrophages

From a panel of IgG1 myeloma proteins, only one was found to interact with human monocyte FcR in a manner similar to that of polyclonal IgG. This protein was used in binding studies involving human macrophage Fc receptors. A monomeric fraction depleted of dimeric and polymeric IgG1 was crosslinked with bis-diazonium benzidine, and a fraction highly enriched in cross linked IgG1 dimers was radiolabeled. Labeled monomeric and dimeric IgG were allowed to interact with monocytes that had matured to macrophages in vitro. The association with macrophages at 4 degrees C, in the presence of cytochalasin B, reached a plateau after 6 hr. The dissociation induced by excess unlabeled IgG followed similar kinetics as the association, but 20-30% of the bound IgG could not be dissociated. Under equilibrium conditions, evidence for a single FcR population binding monomeric IgG was obtained, the Kd being in the range of 12-42 nM. In contrast, the binding of dimeric IgG was more consistent with a model assuming two populations of binding sites when appropriate curve-fitting calculations were applied. The high-affinity FcR population had a Kd in the range of 0.8-3.5 nM, whereas the Kd of the low-affinity FcR population was in the range of 28-85 nM. When macrophages had been pre-treated with recombinant interferon-gamma, the expression of high-affinity sites was increased by a factor of 1.5-3, but the number of low-affinity sites was not augmented. Cytofluorographic analyses confirmed the increased expression of high-affinity FcR, binding fluoresceinating murine IgG2a. The expression of CD16, a low-affinity FcR expressed on neutrophils, NK cells and macrophages, as well as the expression of the complement receptor type III was little influenced by the rIFN-gamma pretreatment.

Evidence for specific association between class I major histocompatibility antigens and the CD8 molecules of human suppressor/cytotoxic cells

Human T lymphocytes, metabolically labeled with 35S-cysteine and 35S-methionine, were reacted with the homobifunctional cross-linking reagent, dithiobis (succinimidyl propionate) (DSP). When detergent lysates from these cells were immunoprecipitated with a monoclonal antibody reactive with the CD8 antigen, a radiolabeled protein of approximately 44 kd was coprecipitated with the CD8 molecule. Immunoprecipitates from detergent lysates prepared without prior chemical cross-linking contained only the 33 kd CD8 molecule. Similar results were obtained when T lymphocytes or a cytotoxic T cell clone (T4T8Cl) were radiolabeled with 32P-orthophosphoric acid. The 44 kd CD8-associated protein was identified as the heavy chain of the class I major histocompatibility antigen by depletion in preclearing experiments with anti-class I MHC antibody and by peptide mapping. Further analyses indicated that the CD8-class I MHC association is due, in part at least, to disulfide bonding, which may be susceptible to cleavage during processing of cell lysates.

Membrane oligosaccharides: structure and function during differentiation

Recent results gathered by normal light microscopy, immunocytochemistry, fluorescent-analog cytochemistry, and electron microscopy have allowed an improved interpretation of ameboid movement and related phenomena. 1. The contractile system responsible in Amoeba proteus for the generation of motive force for protoplasmic streaming and a large variety of dynamic activities is represented mainly by a thin cortical filament layer at the cytoplasmic face of the cell membrane (Fig. 18I). During normal locomotion this layer exhibits a distinct structural and physiological polarity with three different zones: a zone of reformation at the front (A), a zone of contraction in the intermediate cell region (B), and a zone of destruction at the uroid (C). 2. Two types of filaments participate in the formation of the cortical layer: (1) randomly distributed thin (actin) filaments exhibiting a parallel orientation in the anterior (Fc1) and a disordered arrangement in the intermediate and posterior cell region (Fc2; see also Fig. 17b), and (2) thick (myosin) filaments in close association with F-actin and mostly restricted to the intermediate and posterior cell region (Fc2). 3. The internal hydraulic pressure generated by localized active contraction of the cortical layer is transmitted to the endoplasm via the cell membrane and converted into directed streaming by a gel-sol gradient of decreasing viscosity between the uroid and the front. Calcium ions, ATP, and regulative proteins (profilin and a kinase) play an essential role in controlling both the interaction of actin and myosin and the sol-gel state of the cytoplasmic matrix. 4. Any alterations externally induced in the polarity of the cortical filament system by chemical or physical stimulation and inhibition cause immobilization of the amebas (Fig. 18II) with characteristic changes in (1) cell shape (spherulation and cell flattening), (2) membrane dynamics (cytotic and cytokinetic activities), and (3) cytoplasmic organization (hyalogranuloplasmic separation). pseudopodial tip (Fig. 18III, b----c, d----e), (3) destruction of the old layer at the hyalogranuloplasmic border (Fig. 18III, c,e), and (4) alternate solation (Fig. 18III, b and d) and gelation (Fig. 18III, c and e) of the hyaloplasm between the layer and the plasma membrane. The retraction of pseudopodia is accomplished by a local contraction of the cortical layer in conjunction with a simultaneous gel-sol transformation of the ectoplasmic cylinder. 6. The expression of a rather complex cytoskeleton which is composed not only of microfilaments and associated proteins, but also of intermediate- and microtubularlike structures has to be considered in future

Human epidermal Langerhans cells internalize by receptor-mediated endocytosis T6 (CD1 "NA1/34") surface antigen. Birbeck granules are involved in the intracellular traffic of the T6 antigen

Using immunogold staining of a suspension of living human epidermal cells to identify the Langerhans cell membrane-associated antigen T6 (revealed by the monoclonal antibody BL6), we have observed internalization of T6 antigen in Langerhans cells. This phenomenon is at least partly due to receptor-mediated endocytosis involving coated pits, coated vesicles, endosomes, the smooth endoplasmic reticulum, and lysosomes. These ultrastructural results suggest that T6 antigen may be part of a receptor site. Following receptor-mediated endocytosis, the appearance in the cell center of the first labeled Birbeck granules suggests that Birbeck granules could represent T6 intracellular transport organelles carrying T6 from the central part of the cell to an unknown destination.

Human epidermal Langerhans cells cointernalize by receptor-mediated endocytosis "nonclassical" major histocompatibility complex class I molecules (T6 antigens) and class II molecules (HLA-DR antigens)

HLA-DR and T6 surface antigens are expressed only by Langerhans cells and indeterminate cells in normal human epidermis. We have previously demonstrated that T6 antigens are internalized in Langerhans cells and indeterminate cells by receptor-mediated endocytosis. This process is induced by the binding of BL6, a monoclonal antibody directed against T6 antigens. In the present study, using a monoclonal antibody directed against HLA-DR antigens, on human epidermal cells in suspension, we show that the surface HLA-DR antigens are also internalized by receptor-mediated endocytosis in Langerhans and indeterminate cells. Moreover, using immunogold double labeling, we demonstrate that T6 and HLA-DR antigens are internalized through common coated regions of the membrane of Langerhans or indeterminate cells. The receptor-mediated endocytosis that is induced involves coated pits and vesicles, receptosomes, lysosomes, and also, in Langerhans cells, the Birbeck granules. Thus, T6 antigens, which are considered to be "unusual" or "nonclassical" major histocompatibility complex class I molecules, and the major histocompatibility complex class II molecules, HLA-DR, are internalized in Langerhans and indeterminate cells through common receptor-mediated endocytosis organelles.

Isolation and purification of the human thymocyte antigens T6 and M241

T6 and M241 antigens are products of the Class I major histocompatibility complex. The T6 and M241 antigens can be detected on human cortical thymocytes and on dendritic cells in the skin by monoclonal antibodies. Here we report a method of purification of the T6 and M241 antigens. Amino acid sequence data of purified antigens indicate that the heavy chains are blocked at their N-termini, whereas the partial N-terminal amino acid sequence of the light chains is identical to that of the human beta 2-microglobulin. In order to obtain sequence data from the heavy chains a method is described for isolation of purified cyanogen bromide fragments by electrophoretic methods.

An immunohistologic study of the epithelial and lymphoid components of six thymomas

Six thymomas were classified histologically and studied immunohistochemically with a panel of mouse and rat monoclonal antibodies directed against thymic epithelial and lymphoid components. The antibodies included monoclonal antibodies directed against cytokeratin, medullary epithelial cells (ER-TR5), and HLA-DR and HLA-ABC antigens, as well as antibodies with specificity for thymocytes. Histologically, one thymoma was characterized by epithelial predominance (EP type), two showed lymphoid predominance (LP type), and two showed mixed lymphoid/epithelial composition (MLE type); one thymoma was a malignant pure epithelial thymoma (PE type). In the thymomas of the MLE and EP types the major populations of cells consisted of HLA-DR-negative, cytokeratin-positive epithelial cells with large ER-TR5-positive subpopulations (i.e., the phenotype of medullary epithelium). In the thymomas of the LP type, the neoplastic population was composed of cytokeratin-positive, ER-TR5-negative cells that expressed the HLA-DR antigen (i.e., the phenotype of cortical epithelium). The thymoma of the PE type consisted of cytokeratin-positive cells, some of which were ER-TR5- and HLA-DR-positive. Double immunofluorescence studies revealed the presence of varying numbers of additional nonepithelial (nonlymphoid) HLA-DR-positive cells in thymomas of the LP, MLE, and EP types. The intervening lymphoid population in the thymomas of the LP, MLE, and EP types consisted largely of cortical thymocytes, as defined by immunologic characterization. These results suggest that thymomas can be classified as medullary or cortical epithelial neoplasms on the basis of their immunologic phenotypes.

Clonospecific structural heterogeneity in the Thy-1 molecule from mouse T lymphocytes

The Thy-1 molecule immunoprecipitated from detergent-solubilized, 125I-labeled cell-surface proteins was shown to be processed in two distinct ways by mouse T lymphocytes: one leading to the expression by thymocytes, concanavalin A-activated spleen blasts, and six of nine T-cell clones of a molecule of 25-28 kd, and another, observed in three other T-cell clones, leading to the expression at their surface of a so far undescribed low Mr (23 kd) form of Thy-1. The results of two-dimensional gel electrophoresis and neuraminidase, endoglycosidase H, and endoglycosidase F treatment revealed that the observed heterogeneity of Thy-1 molecules from peripheral cloned T cells was due to major differences in the maturation and sialylation of their N-linked complex-type oligosaccharide residues. It was also found that a given T-cell clone could express T200, LFA.1, and transferrin receptor molecules with a low or high Mr. Furthermore, and in contrast to previously reported results, this study revealed that the differences in cell-surface glycoprotein profiles could not be correlated with the Lyt-2,3/T4 phenotypes, the specificity for allo-H-2, allo-I-A, allo-I-E, or GAT + I-Ak determinants, nor with the cytolytic or helper/amplifier potential of the various T-cell clones examined. The possible implications of these findings are discussed.

Anti-MHC immunity detected prior to intentional alloimmunization. III. Natural autoreactive H-2-specific antibodies

Cell fusion was performed between spleen cells from young BALB/cBy (H-2d) mice which have never been immunized and SP2/0 mouse plasmacytoma cells. A monoclonal H-2 specific cytotoxic IgM antibody was obtained (By-1) which detected a new public biregional H-2 specificity, H-2.m210. The mcAb By-1 reacted strongly with H-2Kd, Dd, and H-2s antigens, gave weak cross-reactions with H-2Kk, Dq, H-2r, and H-2v antigens and was negative with H-2b, H-2f, H-2p, and H-2Ld antigens. A polymorphic reaction pattern was also observed on a panel of lymphocytes from B10.W strains. The intriguing finding on this reaction pattern was the reactivity on H-2d cells, including the syngeneic BALB/cBy and truly autologous cells. As shown by capping and immunoprecipitation experiments on H-2d cells and by studies on H-2d-transfected mouse L cells, the target molecules for McAb By-1 were H-2Kd and H-2Dd molecules. The BALB/cBy mouse, from whose spleen cells the McAb By-1 was obtained, survived after the fusion experiment, and serum was examined for the presence of cytotoxic H-2-specific antibodies during the rest of its life. At the time of the fusion, no autoreactive serum antibodies were found, but about 4 months later, we found in the serum of this mouse autoreactive H-2-specific cytotoxic IgM antibodies. The serum antibodies followed the same reaction pattern as that of the McAb By-1. As far as we know, this is the first report of autoreactive H-2-specific antibodies in serum of a mouse which has never been immunized and of the first natural autoreactive H-2-specific monoclonal antibody.

Transformation of LMTK- cells with purified HLA class I gene. VI. Serological characterization of HLA-B7 and AW24 molecules

Serological characterization of HLA-B7 and HLA-AW24 class I molecules following transfection of murine LMTK- cells with purified HLA class I genes was performed using human alloantisera. Induction by murine alpha interferon of the expression of class I molecules was required to obtain unambiguous identification of these molecules which appear serologically identical to the HLA-B7 and HLA-AW24 molecules expressed at the surface of human peripheral blood lymphocytes of 20 unrelated individuals. Analysis of the transformed cells with 8 different anti-HLA class I monoclonal antibodies results in the definition of 3 separate clusters of antigenic determinants shared by all HLA class I molecules. These studies further suggest the existence of locus-specific serological reactivities associated either with the HLA-A or with the HLA-B and C gene products.

Beta 2-microglobulin from serum associates with MHC class I antigens on the surface of cultured cells

Beta 2-microglobulin (beta 2-m) is a highly conserved polypeptide (12,000 molecular weight; 12K) noncovalently associated with the heavy chain (45-48K) of the major histocompatibility complex (MHC) class I antigens. Its synthesis is required for expression of the HLA-A/B and H-2K/D heavy chains at the cell surface; beta 2-m is also associated with the human cell-surface antigens T6 and M241 isolated from thymocytes. However, on the T leukaemic cell line MOLT-4 some of the T6 antigens contain a different 12K subunit, termed beta t (refs 3, 7, 8). Purified human beta 2-m can exchange partially both with human beta 2-m associated with HLA-antigens, and with mouse beta 2-m associated with murine alloantigens. As MOLT-4 cells were grown in the presence of fetal calf serum (FCS) and as serum is known to contain some free beta 2-m, we examined whether beta t was bovine beta 2-m which had replaced endogenous beta 2-m on the surface of the cell. Here we show both that beta 2-m from FCS or human serum (HuS) used in cell culture can exchange with beta 2-m on the cell surface, and that beta t is in fact bovine beta 2-m.

Human cutaneous dendritic cells express two glycoproteins T6 and M241 which are biochemically identical to those found on cortical thymocytes

Monoclonal antibodies anti-T6 and anti-M241 define unique cell populations within different lineages: cortical thymocytes and dendritic cells in the skin. T6 positive cutaneous dendritic cells are located predominantly in the epidermis and belong to the Langerhans/indeterminate lineage, whereas, most of the M241 positive cells are located in the perivascular regions of the dermis. Biochemical analysis of thymocytes and cutaneous dendritic cells was performed in order to determine whether the reactivity of these antibodies with these cell types is due to sharing of antigenic determinants by two unrelated proteins, or whether similar proteins are present on cells of different lineages. Our results indicate that T6 antigens are borne by the same glycoprotein (49K) on cortical thymocytes and Langerhans/indeterminate cells. Similarly, M241 antigens isolated from thymocytes and cutaneous dendritic cells are found on the same glycoprotein (43K).

Two distinct TL-like molecular subsets defined by monoclonal antibodies on the surface of human thymocytes with different expression on leukemia lines

Monoclonal antibodies reacting with TL-like class I antigens expressed on the surface of human thymocytes and some T leukemia lines were found to define three independent epitopic clusters, two of which could be shown to reside on serologically distinct molecular subsets by a solid-phase radioimmunoassay as well as by sequential immunoprecipitation. Both molecular subsets consist of a 49-K heavy chain associated with a beta-2 microglobulin light chain. Thymocytes expressed similar amounts of the two molecular subsets, while on T leukemia lines the amount of these two molecular subsets varied from line to line.