Reactivity of HTLV-transformed human T-cell lines to MHC class II antigens

T-cell lines established from individuals infected with human T-cell leukaemia virus (HTLV) or generated by co-cultivation of normal human T cells with HTLV-infected T-cells, express class II (HLA-D/DR or Ia) antigens of the major histocompatibility complex (MHC) and interleukin-2 (IL-2) receptors. Because the expression of these markers characterizes the differentiation of immunologically activated T cells, we have now explored the possibility that HTLV- infected T cells might be primed to autologous or allogeneic Ia antigens expressed by the infecting cells. Our studies on the capacity of HTLV-infected T cells to display responses on mixed lymphocyte culture indicate that such T cells as well as single-cell clones derived from them, react non-discriminatively to all known allelic variants of human HLA-D/DR antigens, including those expressed by the responding cells. This reaction is inhibited by antibody to human Ia and is not triggered by Ia-negative T-leukaemia cells. The structure recognized seems to be a common epitope determinant of human Ia antigens, as (HTLV-infected) T cells primed in vitro to one HLA-D/DR specificity display amplified responses to all other HLA-D/DR antigens. We therefore believe that autostimulation by a self-Ia determinant may trigger the clonal expansion of HTLV-infected T cells and potentiate autoimmune processes.     

Essential requirement for major histocompatibility complex recognition in T-cell tolerance induction

The induction of T-cell responses involves the recognition of extrinsic antigen in association with antigens of the major histocompatibility complex (MHC), in mice and man, with different T cells recognizing antigen in association with either class I (H-2K/D, HLA-A, B, C) or class II (Ia, HLA-D/DR) MHC antigens. However, the requirement of MHC recognition in the induction of immunological tolerance remains ill defined. With human T helper clones recognizing synthetic peptides of influenza haemagglutinin (HA-1), we have investigated the nature of antigen-induced stimulation, and antigen-induced antigen-specific unresponsiveness, immunological tolerance. Tolerance is not due to cell death, as the cells remain responsive to interleukin-2 and is associated with the loss of T3 antigen from the cell surface. Using monoclonal antibodies to the non-polymorphic regions of human class II antigens to inhibit the induction of T-cell tolerance we report here that induction of tolerance requires the recognition of MHC antigens.     

Monoclonal antibody identifies a new Ia-like (p29,34) polymorphic system linked to the HLA-D/DR region

The Ia antigens of the mouse are the basis for the genetic control of the immune response. The HLA-D/DR locus is considered to be the human counterpart of the Ia subregion of the murine major histocompatibility complex. The HLA-D/DR antigens are polymorphic, and eight well defined alleles have been identified using alloantisera. More recently, 'supertypic' antigens (MB and MT) have been defined which identify clusters of HLA-D/DR specificities. Little is known about the molecular basis for the cellular and serological polymorphism of the HLA-D/DR antigens, as alloantisera are usually of very low titre and heteroantisera frequently lack monospecificity. We present here the preparation and characterization of a monoclonal antibody which defines a new polymorphic system of the HLA-D/DR region. This and similar antisera should now begin to provide the reagents with which to correlate molecular structure with the functional repertoire of the human Ia-like antigens.     

Epithelial cells expressing aberrant MHC class II determinants can present antigen to cloned human T cells

The first step in the induction of immune responses, whether humoral or cell mediated, requires the interaction between antigen-presenting cells and T lymphocytes restricted at the major histocompatibility complex (MHC). These cells invariably express MHC class II molecules (HLA-D region in man and Ia in mouse) which are recognized by T cells of the helper/inducer subset in association with antigen fragments. Interestingly, in certain pathological conditions, for example in autoimmune diseases such as thyroiditis and diabetic insulitis, class II molecules may be expressed on epithelial cells that normally do not express them. We speculated that these cells may be able to present their surface autoantigens to T cells, and that this process may be crucial to the induction and maintenance of autoimmunity. A critical test of this hypothesis would be to determine whether epithelial cells bearing MHC class II molecules (class II+ cells) can present antigen to T cells. We report here that class II+ thyroid follicular epithelial cells (thyrocytes) can indeed present viral peptide antigens to cloned human T cells.     

H-2-restricted cytolytic T cells specific for HLA can recognize a synthetic HLA peptide

It is generally accepted that T lymphocytes recognize antigens in the context of molecules encoded by genes in the major histocompatibility complex (MHC). MHC class II-restricted T cells usually recognize degraded or denatured rather than native forms of antigen on the surface of class II-bearing antigen presenting cells. It has recently been shown that short synthetic peptides corresponding to mapped antigenic sites of the influenza nucleoprotein (NP) can render uninfected target cells susceptible to lysis by NP-specific class I-restricted cytolytic T cells (CTL). These and earlier experiments that showed specific recognition of NP deletion mutant transfectants suggest that class I-restricted recognition might also involve processed antigenic fragments. One important issue arising from these studies is whether the model applies not only to viral proteins that are expressed internally (such as NP) but also to antigens normally expressed as integral membrane proteins at the cell surface. We have recently isolated class I-restricted mouse CTL clones that recognize class I gene products of the human MHC (HLA) as antigens in mouse cell HLA-transfectants. Here we show that these anti-HLA CTL can lyse HLA-negative syngeneic mouse cells in the presence of a synthetic HLA peptide. These results suggest that the model applies generally.     

CD1b restricts the response of human CD4-8- T lymphocytes to a microbial antigen.

Molecules encoded by the human CD1 locus on chromosome 1 (ref. 33) are recognized by selected CD4-8- T-cell clones expressing either alpha beta or gamma delta T-cell antigen receptors. The known structural resemblance of CD1 molecules to antigen-presenting molecules encoded by major histocompatibility complex (MHC) genes on human chromosome 6 (refs 3, 4, 34, 35), suggested that CD1 may represent a family of antigen-presenting molecules separate from those encoded in the MHC. Here we report that the proliferative and cytotoxic responses of human CD4-8- alpha beta TCR+ T cells specific for Mycobacterium tuberculosis can be restricted by CD1b, one of the four identified protein products of the CD1 locus. The responses of these T cells to M. tuberculosis seemed not to involve MHC encoded molecules, but were absolutely dependent on the expression of CD1b by the antigen-presenting cell and involved an antigen processing requirement similar to that seen in MHC class II-restricted antigen presentation. These results provide, to our knowledge, the first direct evidence for the proposed antigen-presenting function of CD1 molecules and suggest that the CD1 family plays a role in cell-mediated immunity to microbial pathogens.     

Polymorphism of human Ia antigens generated by reciprocal intergenic exchange between two DR beta loci

Class II molecules encoded by the human major histocompatibility complex (MHC) are involved in regulating T-cell response to antigens. The mechanisms for generating polymorphism in products of the MHC have been studied extensively for both the murine H-2 and the human HLA complex. Such studies indicate that point mutations plus selection have a major role in the generation of polymorphisms of class I and class II MHC genes. However, a non-reciprocal gene conversion mechanism has been proposed to explain several examples of clustered sequence variation in MHC genes. In all these examples, the proposed gene conversion event is unidirectional; that is, one of the two interacting genes acts as sequence donor and the other as sequence recipient. No examples of potential reciprocal genetic exchange (as occurs in the fungal system), in which the two interacting genes act as both donor and recipient of gene fragments, have been found in the MHC system or in other multigene families of higher organisms. We sequenced two different HLA-DR beta complementary DNAs from each of two different cells all expressing the same serologically defined determinant (DR2) but different T-cell-recognized (Dw) specificities (Dw12 and MN2). Sequence comparisons of these four cDNA clones (and two DR beta amino-acid sequences from the DR2-Dw2 subtype) suggest that new coding sequences for DR beta molecules in the DR2 haplotypes are potentially generated by reciprocal intergenic exchange.     

A minimum of four human class II alpha-chain genes are encoded in the HLA region of chromosome 6

The major histocompatibility complex (MHC) in man, also called the HLA region, is located on the short arm of chromosome 6 and encodes antigens involved in immunological processes. The class II HLA antigens consist of two noncovalently associated polypeptide chains, one of molecular weight 34,000 (alpha) and the other of molecular weight 29,000 (beta). The extensive polymorphism of the beta chain(s) has allowed the genetic mapping of the corresponding beta gene(s) to the HLA-DR region. cDNA clones for the HLA-DR alpha chain have been used to map the non-polymorphic DR alpha-chain gene to chromosome 6 using mouse-human somatic cell hybrids. Similarly, the DR alpha-chain gene has been mapped to the short arm of chromosome 6 centromeric to the HLA-A, -B and -C loci by in situ hybridization experiments. We isolated a cDNA clone that is related to the DR alpha chain and encodes the class II antigen DC alpha chain. We describe here how this DC alpha clone was used to find two or three additional alpha-chain genes by cross-hybridization and how HLA-antigen loss mutants of a human lymphoblastoid cell line (LCL) were used to ascertain that these additional class II antigen alpha-chain genes are also located in the HLA region.     

A late-differentiation antigen associated with the helper inducer function of human T cells

T lymphocytes possessing helper function produce soluble factors that greatly augment B-cell proliferation and differentiation into antibody-secreting cells. In humans the subset of T lymphocytes bearing the T4 surface antigen comprises most of the cells that display helper activity and recognize class II antigens of the major histocompatibility complex (MHC), while the subset bearing the T8 antigen comprises T cells recognizing class I MHC antigens and exhibiting cytotoxic or suppressor function. Monoclonal antibodies to T4 or T8 greatly inhibit the cognitive and effector function of cells with the corresponding phenotype. This function/phenotype correlation is not absolute, however, for there are many examples of T8-positive clones that recognize MHC class II antigens and have helper activity, as well as of T4-positive clones with suppressor or cytotoxic function. Recently a family of cell-surface neoantigens, which might be relevant to T-cell function and which are present on activated but not on resting T lymphocytes, has been identified in mouse and humans using monoclonal antibodies. Some of these antibodies block the cytolytic activity of alloreactive T-cell clones, suggesting the possible involvement of such molecules in the activation of cytotoxic T-cell clones or in the lytic process itself. We now describe a similar late-differentiation antigen (LDA1) that is expressed by human T lymphocytes only following activation and is recognized by a monoclonal antibody that inhibits the antibody-inducing helper function of T lymphocytes.     

Genetically restricted suppressor T-cell clones derived from lepromatous leprosy lesions

Leprosy is a spectral disease in which immune responses to Mycobacterium leprae correlate with the clinical, bacteriological and histopathological manifestations of disease, so study of its pathology provides insights into immunoregulatory mechanisms in man. At the tuberculoid pole, patients have few lesions in the skin which contain rare organisms and are able to mount strong cell-mediated immune responses to M. leprae antigens. In contrast, at the lepromatous pole, patients have disseminated skin lesions containing large numbers of acid-fast bacilli and are selectively unresponsive to antigens of M. leprae. M. leprae-induced suppressor cells derived from peripheral blood have been reported to be active in vitro, yet their in vivo significance has remained unclear. Because the focal point of the immune response to M. leprae is the skin lesion consisting of lymphocytes and macrophages, we have recently developed methods for isolating lymphocytes from skin biopsies of leprosy patients. We report here that two T8 clones derived from lepromatous leprosy skin biopsies, in the presence of lepromin, suppress concanavalin A (Con-A) responses both of peripheral blood mononuclear cells and of T4 clones in an HLA-D (HLA, histocompatibility locus antigen)-restricted manner. Moreover, these T8 clones suppressed responses of HLA-D-matched, but not HLA-D-mismatched antigen-responsive T4 clones to M. leprae antigens, indicating that T-cell suppression is major histocompatibility complex (MHC)-restricted at some level in man.     

Structural polymorphism of human DR antigens

DR ANTIGENS are polymorphic cell surface molecules whose expression is controlled by a locus closely linked or identical to the D locus of the major histocompatibility complex (MHC) of man (for reviews see refs 1, 2). They are functionally and structurally homologous to the murine la antigens determined by the I-E subregion of the MHC, a region which has been implicated in the genetic control of immune responses(3,4). Both sets of antigens are mainly expressed on cells associated with immune function (for reviews see refs 1, 2, 5), and are involved in mediating T-cell, B-cell and macrophage interactions required for the generation of immune responses(6-9). In addition, both consist of two non-covalently associated polypeptides, designated alpha and beta, with molecular weights of 34,000 and 28,000, respectively(10). The association of some DR antigens with increased susceptibility to certain diseases (for review see ref. 1) and the genetic restrictions imposed on cellular interactions by the HLA-D region(9,11) may represent the effects of structural variability among DR antigens. The aim of the studies reported here was to examine the nature and degree of structural variation among DR antigens isolated from cultured lymphoid B cells with different DR phenotypes. Such information may provide an understanding of the molecular mechanisms by which DR antigens mediate their function.     

Processing pathways for presentation of cytosolic antigen to MHC class II-restricted T cells.

Antigens presented to CD4+ T cells derive primarily from exogenous proteins that are processed into peptides capable of binding to class II major histocompatibility complex (MHC) molecules in an endocytic compartment. In contrast, antigens presented to CD8+ T cells derive mostly from proteins processed in the cytosol, and peptide loading onto class I MHC molecules in an early exocytic compartment is dependent on a transporter for antigen presentation encoded in the class II MHC region. Endogenous cytosolic antigen can also be presented by class II molecules. Here we show that, unlike class I-restricted recognition of antigen, HLA-DR1-restricted recognition of cytosolic antigen occurs in mutant cells without a transporter for antigen presentation. In contrast, DR1-restricted recognition of a short cytosolic peptide is dependent on such a transporter. Thus helper T-cell epitopes can be generated from cytosolic antigens by several mechanisms, one of which is distinct from the classical class I pathway.     

A novel family of human major histocompatibility complex-related genes not mapping to chromosome 6

Thymocyte antigens CD1 [Thy,gp45,12] are thought to be the human counterparts of mouse thymus leukaemia (TL) antigens. Serological and biochemical analyses indicate that at least three subsets exist, the first of which (HTA 1/T6) was initially identified by the monoclonal antibody NA1/34. Like TL, CD1 are expressed on cortical thymocytes as well as on some lymphoid neoplasias, and resemble in structure major histocompatibility complex (MHC) class I antigens. However HTA 1/T6 is loosely associated with beta 2-microglobulin and is also found linked by a disulphide bridge to CD8(T8). A molecular genetic approach is needed to investigate the CD1 system, to clarify its relationship to TL antigens and to understand its regulation. We report the isolation of complementary DNA (cDNA) clones encoding a CD1 antigen. These clones reveal a novel family of genes which are MHC-related but are neither equivalent to mouse TL antigens nor linked to the MHC.     

Human T-cell clones recognize a major M. leprae protein antigen expressed in E. coli

Leprosy is a chronic infectious disease caused by Mycobacterium leprae. As with other intracellular parasites, protective immunity is dependent on T cells and cell-mediated immunity. In animal models, immunization with killed armadillo-derived M. leprae elicits strong T-cell responses, delayed-type hypersensitivity and protection against viable challenge. We have recently shown that killed M. leprae can induce delayed-type hypersensitivity in healthy human volunteers. Identification of the M. leprae antigens that are recognized by T cells and may be involved in protection has been hampered by the inability to cultivate the organism in vitro and by difficulties in antigen purification from limited quantities of armadillo-derived bacillus. Because genes for the major protein antigens of M. leprae as seen by mouse monoclonal antibodies have been isolated, it has become possible to test whether these individual antigens are recognized by T cells. We screened crude lambda gtll phage lysates of Escherichia coli containing individual M. leprae antigens using M. leprae-specific T-cell clones isolated from M. leprae-vaccinated volunteers. Using this method, we find that nearly half of the M. leprae-specific T-cell clones are stimulated to proliferate by lysates containing an epitope of a M. leprae protein of relative molecular mass 18,000 (18K).     

Structural relationship of the SB beta-chain gene to HLA-D-region genes and murine I-region genes

The major histocompatibility complex (MHC) regulates several aspects of the immune response. Class II antigens of the MHC control cellular interactions between lymphocytes. In man, at least three class II antigens (DR, DC and SB), consisting of distinct alpha- and beta-chains, are encoded in the HLA complex. Sequence analysis has established that the DR and DC antigens are the respective structural counterparts of the murine I-E and I-A antigens. Molecular cloning of the SB beta-chain gene has now enabled us to define its relationship to other class II genes. The DR, DC and SB beta genes have diverged from each other to the same extent. In murine DNA and in cloned genes from the I region, the best hybridization of SB beta DNA is with the E beta 2 sequence. E beta 2 may belong to a complete gene (E' beta) because first domain sequences were found adjacent to it.     

Developmental regulation of T-cell receptor gene expression

In contrast to B cells or their antibody products, T lymphocytes have a dual specificity, for both the eliciting foreign antigen and for polymorphic determinants on cell surface glycoproteins encoded in the major histocompatibility complex (MHC restriction). The recent identification of T-cell receptor glycoproteins as well as the genes encoding T-cell receptor subunits will help to elucidate whether MHC proteins and foreign antigens are recognized by two T-cell receptors or by a single receptor. An important feature of MHC restriction is that it appears to be largely acquired by a differentiating T-cell population under the influence of MHC antigens expressed in the thymus, suggesting that precursor T cells are selected on the basis of their reactivity with MHC determinants expressed in the host thymus. To understand this process of 'thymus education', knowledge of the developmental regulation of T-cell receptor gene expression is necessary. Here we report that whereas messenger RNAs encoding the beta-and gamma-subunits are relatively abundant in immature thymocytes, alpha mRNA levels are very low. Interestingly, whereas alpha mRNA levels increase during further development and beta mRNA levels stay roughly constant, gamma mRNA falls to very low levels in mature T cells, suggesting a role for the gamma gene in T-cell differentiation.     

T cells can distinguish between allogeneic major histocompatibility complex products on different cell types

In the response of T cells to foreign antigens, the ligand for the T cell alpha/beta receptor is presented on a cell surface as a fragment of antigen complexed to one of the membrane molecules encoded in the major histocompatibility complex (MHC). The receptor apparently interacts via its variable elements (V beta, D beta, J beta, V alpha and J alpha) with residues within both the antigen and MHC portion of the ligand. The frequency of T cells responding to a conventional antigen plus self MHC is usually quite low, presumably reflecting the relative rarity of receptors with the particular combination of variable elements to match the antigen/MHC ligand. T cells also respond to allogeneic forms of MHC molecules in the absence of added antigen. In this case the frequency of responding T cells is very high. One hypothesis to explain this observation is that, in the absence of foreign antigen, MHC molecules are complexed to a large array of peptides derived from self-proteins. In this case the combination of the polymorphic MHC amino acid residues and many different self peptides presents so many possible ligands that the likelihood of recognition by a given T cell receptor is quite high. The recent crystallography experiments which revealed a dramatic binding cleft on the face of a human MHC molecule have given impetus to this view, but as yet there is no direct supporting evidence. We have recently described a close association between murine T cell receptors utilizing the V beta 17a element and reactivity to various allogeneic forms of the murine MHC molecule, I-E (ref. 8). In this paper, we show that this I-E ligand is detected on B cells, but not on I-E+ macrophages or fibroblasts expressing a transfected I-E gene. These results strongly suggest a B cell specific product combines with I-E to form the allogeneic ligand for V beta 17a+ receptors and thus support the concept of alloreactivity described above.     

HLA-A2 peptides can regulate cytolysis by human allogeneic T lymphocytes

The class-I and class-II molecules encoded by the major histocompatibility complex (MHC) are homologous proteins which allow cytotoxic and helper T cells to recognize foreign antigens. Recent studies have shown that the form of the antigen recognized by T cells is generally not a native protein but rather a short peptide fragment and that class-II molecules specifically bind antigenic peptides. Furthermore, the three-dimensional structure of the human MHC class-I molecule, HLA-A2, is consistent with a peptide-binding function for MHC class-I molecules. An outstanding question concerns the molecular nature and involvement of MHC-bound peptides in antigens recognized by alloreactive T cells. In this study the effects of peptides derived from HLA-A2 on cytolysis of alloreactive cytotoxic T cells (TC) cells are presented. Peptides can inhibit lysis by binding to the T cell or sensitize to lysis by binding an HLA-A2-related class-I molecule (HLA-Aw69) on the target cell. Thus, allospecific TC cells can recognize HLA-derived peptides in the context of the MHC.     

Thymic selection process induced by hybrid antibodies

Thymus-derived (T) lymphocytes using the alpha beta T-cell antigen receptor (TCR) recognize fragmented antigen in conjunction with surface molecules encoded by genes of the major histocompatibility complex (MHC). Peripheral T lymphocytes preferentially see antigen presented by self rather than by foreign MHC molecules, and autoreactive T lymphocytes are deleted. Thus, the peripheral T-lymphocyte repertoire is skewed towards recognition of antigen in the context of self-MHC and towards tolerance to self-antigens. During T-lymphocyte development in the thymus, this repertoire is formed by the interaction of TCR with MHC molecules resulting in positive and negative selection phenomena. Hybrid antibodies (HAbs) that carry binding sites to the TCR and to a surface marker on another cell can engage all T lymphocytes regardless of their specificity. It should be possible to mimic selection processes in normal animals with HAb that specifically link members of a TCR family to MHC molecules on the thymic stroma. We have probed T-lymphocyte development with HAbs linking V beta 8-positive TCR to either class I or class II MHC products in thymic organ culture. Thymocytes exposed to either HAb in an early stage of maturation respond with a significant increase in the frequency of V beta 8-carrying cells. At a later stage of development V beta 8-positive thymocytes are depleted. These results illustrate the succession of positive and negative selection in the developing thymus of normal mice.     

Cytotoxic T lymphocytes against a soluble protein

Thymus-derived (T) lymphocytes recognize antigen in conjunction with surface glycoproteins encoded by major histocompatibility complex (MHC) genes. Whereas fragments of soluble antigens are presented to T helper lymphocytes (TH), which carry the CD4 antigen, in association with class II MHC molecules, CD8-bearing cytotoxic T lymphocytes (CTL) usually see cellular antigens (for instance virally-encoded proteins) in conjunction with MHC class I molecules. The different modes of antigen presentation may result from separate intracellular transport: vesicles containing class II molecules are thought to fuse with those carrying endocytosed soluble proteins. Class I molecules, in contrast, can only pick up degradation products of intracellular proteins (see refs 7 and 8). This makes biological sense; during an attack of a virus, class I-restricted CTL destroy infected cells and class II-restricted TH guide the humoural response to neutralize virus particles and toxins. But here we provide evidence that CTL specific for ovalbumin fragments can be induced with soluble protein, and that intracellular protein degradation provides epitopes recognized by these CTL. These findings suggest the existence of an antigen presenting cell that takes up soluble material and induces CTL.