Membrane Ia expression and antigen-presenting accessory cell function of L cells transfected with class II major histocompatibility complex genes

Cell-surface MHC density profiling reveals instability of autoimmunity-associated HLA

Polymorphisms within HLA gene loci are strongly associated with susceptibility to autoimmune disorders; however, it is not clear how genetic variations in these loci confer a disease risk. Here, we devised a cell-surface MHC expression assay to detect allelic differences in the intrinsic stability of HLA-DQ proteins. We found extreme variation in cell-surface MHC density among HLA-DQ alleles, indicating a dynamic allelic hierarchy in the intrinsic stability of HLA-DQ proteins. Using the case-control data for type 1 diabetes (T1D) for the Swedish and Japanese populations, we determined that T1D risk-associated HLA-DQ haplotypes, which also increase risk for autoimmune endocrinopathies and other autoimmune disorders, encode unstable proteins, whereas the T1D-protective haplotypes encode the most stable HLA-DQ proteins. Among the amino acid variants of HLA-DQ, alterations in 47α, the residue that is located on the outside of the peptide-binding groove and acts as a key stability regulator, showed strong association with T1D. Evolutionary analysis suggested that 47α variants have been the target of positive diversifying selection. Our study demonstrates a steep allelic hierarchy in the intrinsic stability of HLA-DQ that is associated with T1D risk and protection, suggesting that HLA instability mediates the development of autoimmune disorders.

Beyond the classical: influenza virus and the elucidation of alternative MHC class II-restricted antigen processing pathways

CD4+ T cells (T(CD4+)) are activated by peptides, generally 13-17 amino acids in length, presented at the cell surface in combination with highly polymorphic MHC class II molecules. According to the classical model, these peptides are generated by endosomal digestion of internalized antigen and loaded onto MHC class II molecules in the late endosome. Historically, this "exogenous" pathway has been defined through the extensive use of purified proteins. However, the relatively recent use of clinically relevant antigens, those of influenza virus in our case, has revealed several additional pathways of peptide production, including some that are truly "endogenous", entailing synthesis of the protein within the infected cell. Indeed, some peptides appear to be created only via endogenous processing. The cell biology that underlies these alternative pathways remains poorly understood as do their relative contributions to defence against infectious agents and cancer, and the triggering of autoimmune diseases.

Dopamine released by dendritic cells polarizes Th2 differentiation

A major neurotransmitter dopamine transmits signals via five different seven transmembrane G protein-coupled receptors termed D1-D5. It is now evident that dopamine is released from leukocytes and acts as autocrine or paracrine immune modulator. However, the role of dopamine for dendritic cells (DCs) and T(h) differentiation remains unclear. We herein demonstrate that human monocyte-derived dendritic cells (Mo-DCs) stored dopamine in the secretary vesicles. The storage of dopamine in Mo-DCs was enhanced by forskolin and dopamine D2-like receptor antagonists via increasing cyclic adenosine 3',5'-monophosphate (cAMP) formation. Antigen-specific interaction with naive CD4(+) T cells induced releasing dopamine-including vesicles from Mo-DCs. In naive CD4(+) T cells, dopamine dose dependently increased cAMP levels via D1-like receptors and shifts T-cell differentiation to T(h)2, in response to anti-CD3 plus anti-CD28 mAb. Furthermore, we demonstrated that dopamine D2-like receptor antagonists, such as sulpiride and nemonapride, induced a significant DC-mediated T(h)2 differentiation, using mixed lymphocyte reaction between human Mo-DCs and allogeneic naive CD4(+) T cells. When dopamine release from Mo-DCs is inhibited by colchicines (a microtubule depolymerizer), T-cell differentiation shifts toward T(h)1. These findings identify DCs as a new source of dopamine, which functions as a T(h)2-polarizing factor in DC-naive T-cell interface.

The molecular makeup and function of regulatory and effector synapses

Physical interactions between T cells and antigen-presenting cells (APCs) form the basis of any specific immune response. Upon cognate contacts, a multimolecular assembly of receptors and adhesion molecules on both cells is created, termed the immunological synapse (IS). Very diverse structures of ISs have been described, yet the functional importance for T-cell differentiation is largely unclear. Here we discuss the principal structure and function of ISs. We then focus on two characteristic T-cell-APC pairs, namely T cells contacting dendritic cells (DCs) or naive B cells, for which extremely different patterns of the IS have been observed as well as fundamentally different effects on the function of the activated T cells. We provide a model on how differences in signaling and the involvement of adhesion molecules might lead to diverse interaction kinetics and, eventually, diverse T-cell differentiation. We hypothesize that the preferred activation of the adhesion molecule leukocyte function-associated antigen-1 (LFA-1) and of the negative regulator for T-cell activation, cytotoxic T-lymphocyte antigen-4 (CTLA-4), through contact with naive B cells, lead to prolonged cell-cell contacts and the generation of T cells with regulatory capacity. In contrast, DCs might have evolved mechanisms to avoid LFA-1 overactivation and CTLA-4 triggering, thereby promoting more dynamic contacts that lead to the preferential generation of effector cells.

Transgenic mice producing major histocompatibility complex class II molecules on thyroid cells do not develop apparent autoimmune thyroid diseases

The expression of major histocompatibility complex (MHC) class II molecules on thyrocytes has been demonstrated in autoimmune thyroid diseases. However, the role of this aberrant MHC class II in disease development is controversial. In particular, it remains unknown whether MHC class II expression on thyrocytes, which are nonprofessional antigenpresenting cells, plays a role in inducing autoimmune processes. To clarify this issue, we have produced transgenic mice harboring an MHC class II gene ligated to the promoter of the rat TSH receptor. We obtained three lines of transgenic mice, and the expression of MHC class II by the thyrocytes was demonstrated by immunofluorescence staining and flow cytometry. Our examination revealed no obvious abnormalities in thyroid histology or in thyroid autoantibody production in these transgenic mice. Although serum-free T(4) levels were slightly lower than those of their nontransgenic littermates, no transgenic mouse suffered from clinical hypothyroidism or hyperthyroidism. Furthermore, thyroid lymphocytic infiltration was absent, and MHC class II-expressing thyrocytes obtained from transgenic mice failed to stimulate the proliferation of autologous T cells in vitro. Taken together, these results show that transgenic mice with MHC class II molecules on their thyrocytes do not develop apparent autoimmune thyroid diseases, suggesting that aberrant MHC class II expression alone is not sufficient to induce thyroid autoimmunity.

Rat RT1.B-transfected fibroblast lines process and present myelin antigens and activate T cells to induce experimental autoimmune encephalomyelitis

The genes encoding the Lewis rat RT1.B molecule (MHC Class II I-A equivalent) were transfected and expressed in mouse DAP.3 fibroblast cells together with the gene encoding the mouse ICAM-1 molecule. Both molecules were stably expressed on the cell surface of DAP.3 cells under longterm culture conditions. The RT1.B/mICAM-1 transfectants presented antigen in a specific manner to a RT1. B-restricted rat T cell hybridoma specific for the 69-89 peptide of myelin basic protein (BP). In addition, the transfectants were able to present antigen to a BP69-89-specific rat T cell line. Presentation to a RT1.D (MHC Class II I-E equivalent)-restricted BP87-99-specific T cell line was minimal. Production of the Th1 cytokine IFN-gamma by BP69-89-specific T cells when stimulated by RT1.B/mICAM-1 transfectants correlated very well with proliferation to specific antigen. Moreover, RT1.B-transfected DAP.3 cells sufficiently stimulated BP69-89-specific T cells such that they were able to transfer experimental autoimmune encephalomyelitis (EAE) to Lewis rat recipients. Thus, the RT1.B molecule is functionally expressed on the surface of transfected Dap.3 fibroblasts and is capable of MHC Class II-restricted, antigen-specific presentation to rat T cells.

Major histocompatibility complex class II- fetal skin dendritic cells are potent accessory cells of polyclonal T-cell responses

Whereas dendritic cells (DC) and Langerhans cells (LC) isolated from organs of adult individuals express surface major histocompatibility complex (MHC) class II antigens, DC lines generated from fetal murine skin, while capable of activating naive, allogeneic CD8+ T cells in a MHC class I-restricted fashion, do not exhibit anti-MHC class II surface reactivity and fail to stimulate the proliferation of naive, allogeneic CD4+ T cells. To test whether the CD45+ MHC class I+ CD80+ DC line 80/1 expresses incompetent, or fails to transcribe, MHC class II molecules, we performed biochemical and molecular studies using Western blot and polymerase chain reaction analysis. We found that 80/1 DC express MHC class II molecules neither at the protein nor at the transcriptional level. Ultrastructural examination of these cells revealed the presence of a LC-like morphology with indented nuclei, active cytoplasm, intermediate filaments and dendritic processes. In contrast to adult LC, no LC-specific cytoplasmic organelles (Birbeck granules) were present. Functionally, 80/1 DC in the presence, but not in the absence, of concanavalin A and anti-T-cell receptor monoclonal antibodies stimulated a vigorous proliferative response of naive CD4+ and CD8+ T cells. Furthermore, we found that the anti-CD3-induced stimulation of naive CD4+ and CD8+ T cells was critically dependent on the expression of FcgammaR on 80/1 DC and that the requirement for co-stimulation depends on the intensity of T-cell receptor signalling.

Differential Presentation of Glutamic Acid Decarboxylase 65 (GAD65) T Cell Epitopes Among HLA-DRB1*0401-Positive Individuals

Glutamic acid decarboxylase 65 (GAD65) is one of the major autoantigens in type 1 diabetes. We investigated whether there is variation in the processing of GAD65 epitopes between individuals with similar HLA backgrounds and whether the processing characteristics of certain immunogenic epitopes are different in distinct APC subpopulations. Using DR401-restricted T cell hybridomas specific for two immunogenic GAD65 epitopes (115–127 and 274–286), we demonstrate an epitope-specific presentation pattern in human B-lymphoblastoid cell lines (B-LCL). When pulsed with the GAD protein, some DRB1*0401-positive B-LCL, which presented GAD65 274–286 epitope efficiently, were unable to present the GAD65 115–127 epitope. However, all B-LCL presented synthetic peptides corresponding to either GAD epitope. In addition, when pulsed with human serum albumin, all cell lines gave equal stimulation of a DR4-restricted human serum albumin-specific T hybridoma. GAD65-transfected cell lines displayed the same presentation phenotype, showing that lack of the presentation of the 115–127 epitope was not due to inefficient uptake of the protein. Blood mononuclear adherent cells, B cells, or dendritic cells derived from the same individual displayed the same presentation pattern as observed in B cell lines, suggesting that the defect most likely is genetically determined. Therefore, individual differences in Ag processing may result in the presentation of distinct set of peptides derived from an autoantigen such as GAD65. This may be an important mechanism for the deviation of the immune response either into a regulatory pathway or into an inflammatory autoimmune reactivity.

Subsets of HLA-DR1 molecules defined by SEB and TSST-1 binding

Superantigens bind to major histocompatibility complex class II molecules on antigen-presenting cells and stimulate T cells. Staphylococcus aureus enterotoxin B (SEB) and toxic shock syndrome toxin-1 (TSST-1) bind to the same region of human lymphocyte antigen (HLA)-DR1 but do not compete with each other, which indicates that they bind to different subsets of DR1 molecules. Here, a mutation in the peptide-binding groove disrupted the SEB and TSST-1 binding sites, which suggests that peptides can influence the interaction with bacterial toxins. In support of this, the expression of the DR1 molecule in various cell types differentially affected the binding of these toxins.

T cell receptor-major histocompatibility complex class II interaction is required for the T cell response to bacterial superantigens

Bacterial and retroviral superantigens (SAGs) stimulate a high proportion of T cells expressing specific variable regions of the T cell receptor (TCR) beta chain. Although most alleles and isotypes bind SAGs, polymorphisms of major histocompatibility complex (MHC) class II molecules affect their presentation to T cells. This observation has raised the possibility that a TCR-MHC class II interaction can occur during this recognition process. To address the importance of such interactions during SAG presentation, we have used a panel of murine T cell hybridomas that respond to the bacterial SAG Staphylococcal enterotoxin B (SEB) and to the retroviral SAG Mtv-7 when presented by antigen-presenting cells (APCs) expressing HLA-DR1. Amino acid substitutions of the putative TCR contact residues 59, 64, 66, 77, and 81 on the DR1 beta chain showed that these amino acids are critical for recognition of the SAG SEB by T cells. TCR-MHC class II interactions are thus required for T cell recognition of SAG. Moreover, Mtv-7 SAG recognition by the same T cell hybridomas was not affected by these mutations, suggesting that the topology of the TCR-MHC class II-SAG trimolecular complex could be different from one TCR to another and from one SAG to another.

Characterization of a cis-acting regulatory element which silences expression of the class II-A beta gene in epithelium

Class II major histocompatibility complex (MHC) genes encode for alpha/beta chain pairs that are constitutively expressed principally on mature B cells and dendritic cells in mice. These gene products are easily induced on macrophages with cytokines, and may also aberrantly appear on the surface of epithelium during immune injury. The appearance of class II determinants in parenchymal tissue potentially renders these somatic cells capable of antigen presentation to circulating CD4+ T lymphocytes, and their absence may be protective for normal tissues expressing self-antigens. The low surface class II expression observed on parenchymal cells generally correlates with low levels of mRNA, suggesting that transcription rate is a major element in class II regulation. To understand the transcriptional mechanism maintaining low basal surface expression of class II in somatic cells, we transiently transfected mini-gene reporter constructs to study the regulation of the murine A beta promoter in a cultured renal epithelial cell line. We describe here a negative cis-acting regulatory region located between -552 and -489 bp upstream of the A beta cap site that silences the transcriptional activity of the A beta promoter in epithelial cells in an orientation-dependent manner, and is also able to silence a heterologous promoter. This region is not active in class II-expressing B cells (BAL-17) in culture, but is functional in two other murine class II-negative cell lines, fibroblasts and thymoma T cells. Using competition electrophoretic mobility shift assays, we have localized the core protein binding site within this region to an 8-10-bp response element, designated A beta NRE, at -543 to -534 bp. A nuclear extract from BAL-17 cells does not bind to this element. Mutation of this site abrogates the transcriptional silencing activity of the region. We conclude that the transcription of class II-A beta in parenchymal cells, and some lymphocytes, can be actively repressed by an upstream silencing element.

The role of non-adhesive T-cell-accessory cell interactions in the induction of T-cell proliferative hyporesponsiveness

We have suggested previously that induction of T-cell proliferative hyporesponsiveness is associated with a defective adhesive T-cell-antigen-presenting cell (APC) interaction. In the previous study, the hyporesponsiveness was allospecific, implying that a T-cell receptor-major histocompatibility complex (MHC) interaction had occurred. Therefore, we hypothesized that this type of non-adhesive T-cell-APC interaction might induce T-cell tolerance rather than activation. This hypothesis has now been tested further in the present study, using two experimental approaches. Firstly, L cells, which express a T-cell receptor ligand, i.e. MHC class II molecules, but lack the capacity to bind to T cells and do not express the crucial receptor/counter receptor lymphocyte function-associated antigen-1 (LFA-1)/intracellular adhesion molecule-1 (ICAM-1) pair, also induced non-allospecific T-cell proliferative hyporesponsiveness; this was not due to any direct inhibitory effect on the T cells. Secondly, monoclonal antibodies (mAb) directed to LFA-1 and ICAM-1 were used to disrupt T-cell-APC adhesion specifically, while allowing for T-cell receptor-MHC interaction to occur. The results of this new study suggest that the non-allospecific T-cell proliferative hyporesponsiveness induced was a function of direct T-cell inhibitory effects of these mAb. Taken together, these experiments add further evidence to support the notion that accessory cells which engage T-cell receptors without providing the necessary co-stimulatory signals induce T cells which are in a state of functional 'paralysis' with respect to the antigen which the T-cell receptor recognizes.

Binding sites for bacterial and endogenous retroviral superantigens can be dissociated on major histocompatibility complex class II molecules

Bacterial and retroviral superantigens (SAGs) interact with major histocompatibility complex (MHC) class II molecules and stimulate T cells upon binding to the V beta portion of the T cell receptor. Whereas both types of molecules exert similar effects on T cells, they have very different primary structures. Amino acids critical for the binding of bacterial toxins to class II molecules have been identified but little is known of the molecular interactions between class II and retroviral SAGs. To determine whether both types of superantigens interact with the same regions of MHC class II molecules, we have generated mutant HLA-DR molecules which have lost the capacity to bind three bacterial toxins (Staphylococcus aureus enterotoxin A [SEA], S. aureus enterotoxin B [SEB], and toxic shock syndrome toxin 1 [TSST-1]). Cells expressing these mutated class II molecules efficiently presented two retroviral SAGs (Mtv-9 and Mtv-7) to T cells while they were unable to present the bacterial SAGs. These results demonstrate that the binding sites for both types of SAGs can be dissociated.

Tumor necrosis factor alpha mediates a T cell receptor-independent induction of the gene regulatory factor NF-kappa B in T lymphocytes

We investigated the molecular basis of the ability of DCEK experimental antigen-presenting cells (APCs) to induce the nuclear form of the transcription factor NF-kappa B in T lymphocytes without engagement of the T cell receptor. We found that NF-kappa B induction did not require contact between the APCs and T lymphocytes and could be achieved by medium conditioned by the APCs. The APCs were found to express low levels of mRNA for TNF alpha. The addition of antibody against TNF alpha blocked the ability of APCs to induce NF-kappa B. These observations were extended by the finding that NF-kappa B was also induced in T lymphocytes separated by a membrane from a mixture of T lymphocytes, splenic APCs and antigen by a TNF alpha-dependent mechanism. Together, these findings suggest that induction of NF-kappa B in antigenically stimulated or 'bystander' T cells may take place through stimulation by TNF alpha as well as in response to T cell receptor occupancy.

Establishment of stable CD8+ suppressor T cell clones and the analysis of their suppressive function

Stable CD8+ suppressor T cell (Ts) clones were established by a relatively simple method. Keyhole limpet hemocyanin (KLH)-primed spleen cells from C3H mice were depleted of B cells and CD4+ T cells by panning and cytotoxic treatment, and the resulting CD8+ T cells were periodically stimulated with antigen and irradiated syngeneic spleen cells followed by manifestation in interleukin-2 (IL-2) containing medium. T cell clones with a definite suppressor function were established by limiting dilution. They were defined as classical effector type Ts of CD8+ phenotype as they had constant and definite suppressor functions in antigen-induced T cell proliferation and specific antibody response against T cell-dependent antigens without detectable cytotoxic activity against both antigen presenting cells (APC) and helper T cells (Th). They showed no helper activity for B cells and produced no detectable helper type lymphokines such as IL-2 and IL-4. CD8+ Ts clones were able to inhibit the antigen-induced IL-2 production of normal and cloned T cells. Their suppressive activity was antigen-nonspecific and major histocompatibility complex-unrestricted. CD8+ Ts clones were also able to suppress the proliferative response of Th clones induced by immobilized anti-T cell receptor (TcR) and anti-CD3 mAbs but not the response induced by concanavalin A (ConA) and IL-2. All the CD8+ T cell clones established independently utilized the TcR V beta 8 gene. Syngeneic antigen presenting cells could induce proliferation of these CD8+ clones, which was blocked by anti-CD8 and anti-I-Ak monoclonal antibody (mAb) but not by anti-class I mAbs. The stimulation of CD8+ Ts clones with immobilized anti-CD3 resulted in the release of a suppressor factor(s) that potently inhibited the antigen-induced proliferation of CD4+ Th clones and the in vitro secondary antibody formation.

Expression and function of the murine B7 antigen, the major costimulatory molecule expressed by peritoneal exudate cells

The murine B7 (mB7) protein is a potent costimulatory molecule for the T-cell receptor (TCR)-mediated activation of murine CD4+ T cells. We have previously shown that stable mB7-transfected Chinese hamster ovary (CHO) cells but not vector-transfected controls synergize with either anti-CD3 monoclonal antibody-induced or concanavalin A-induced T-cell activation, resulting ultimately in lymphokine production and proliferation. We now have generated a hamster anti-mB7 monoclonal antibody. This reagent recognizes a protein with an apparent molecular mass of 50-60 kDa. The mB7 antigen is expressed on activated B cells and on peritoneal exudate cells (PECs). Antibody blocking experiments demonstrate that mB7 is the major costimulatory molecule expressed by PECs for the activation of murine CD4+ T cells. This suggests an important role for mB7 during immune-cell interactions. We have also surveyed a panel of murine cell lines capable of providing costimulatory activity. Our results indicate that mB7 is the major costimulatory molecule on some but not all cell lines and that there may be additional molecules besides mB7 that can costimulate the activation of murine CD4+ T cells.

Defective intracellular transport as a common mechanism limiting expression of inappropriately paired class II major histocompatibility complex alpha/beta chains

Distinct combinations of class II major histocompatibility complex (MHC) alpha and beta chains show widely varying efficiencies of cell surface expression in transfected cells. Previous studies have analyzed the regions of the class II chains that are critically involved in this phenomenon of variable expression and have shown a predominant effect of the NH2-terminal domains comprising the peptide-binding site. The present experiments attempt to identify the post-translational defects responsible for this variation in surface class II molecule expression for both interisotypic alpha/beta combinations failing to give rise to any detectable cell membrane molecules (e.g., E alpha A beta k) and intraisotypic pairs with inefficient surface expression (e.g., A alpha d A beta k). The results of metabolic labeling and immunoprecipitation experiments using L cell transfectants demonstrate that in both of these cases, the alpha and beta chains form substantial amounts of stable intracellular dimers. However, the isotype- and allele-mismatched combinations do not show the typical post-translational increases in molecular weight that accompany maturation of the N-linked glycans of class II MHC molecules. Studies with endoglycosidase H reveal that no or little progression to endoglycosidase H resistance occurs for these mismatched dimers. These data are consistent with active or passive retention of relatively stable and long-lived mismatched dimers in a pre-medial-Golgi compartment, possibly in the endoplasmic reticulum itself. This retention accounts for the absent or poor surface expression of these alpha/beta combinations, and suggests that conformational effects of the mismatching in the NH2-terminal domain results in a failure of class II molecules to undergo efficient intracellular transport.

Alteration of the T-cell receptor repertoire in A.CA mice expressing an Ead transgene

In an effort to generate an A.CA mouse expressing Ed, the Ead gene has been introduced into A.CA mice which lack the major histocompatibility complex (MHC) class II E molecule. Flow cytometric analysis shows cell surface expression of the E alpha chain on lymphocytes and macrophages in the transgenic mice. Analysis of T-cell receptor (Tcr) genes deleted in some E-expressing mouse strains demonstrates that T cells expressing Tcrb-V5 are partially deleted in these transgenic mice while those expressing Tcrb-V8 and Tcrb-11 are not. In addition, the expressed E alpha d chain can promote Mycoplasma arthriditis mitogen (MAM)-induced T-cell proliferation. The expression of the E alpha chain, presumably as an A beta fE alpha d heterodimer, can alter the peripheral T-cell repertoire and T-cell reactivity to a microbial superantigen.

Invariant chain promotes egress of poorly expressed, haplotype-mismatched class II major histocompatibility complex A alpha A beta dimers from the endoplasmic reticulum/cis-Golgi compartment

Invariant chain (Ii) is a nonpolymorphic, non-major histocompatibility complex (MHC)-encoded glycoprotein that rapidly associates with newly synthesized class II MHC alpha and beta chains in the rough endoplasmic reticulum. This oligomerization of Ii, alpha, and beta and their cotransport within the cell led to speculation that Ii was an essential alpha beta transport protein. However, direct tests failed to show an absolute requirement for Ii in class II MHC molecule transport. More recently, it has become clear that different class II alpha beta chain combinations vary greatly in their efficiency of cell-surface expression, based largely on the allelic origin of the alpha and beta amino-terminal regions. Because the previous tests of Ii for a role in class II molecule expression utilized efficiently expressed alpha beta combinations, we have reexamined this question with several haplotype-mismatched murine A alpha and A beta chain combinations of various potentials for cell-surface expression. Using a transient expression assay in Ii-negative COS cells, we find that many inefficiently expressed alpha beta combinations show marked augmentation of surface expression upon cosynthesis of Ii. This effect is absent or minimal with evolutionarily coselected, haplotype-matched chains that give efficient expression alone. Biochemical studies show that at least one component of the Ii effect is an increased egress of already formed alpha beta dimers from the rough endoplasmic reticulum/cis-Golgi. We suggest that these results reflect the interaction of Ii with the peptide-binding domain of the poorly expressed class II molecules, either aiding in maintenance of a transportable conformation or competing with endoplasmic reticulum retention proteins, and thus enhancing movement to the cell surface. These results suggest a complex and variable role for trans-associated alpha and beta chains in the immune responses of MHC heterozygotes and provide a method for examining Ii interaction with class II MHC molecules independent of measurement of peptide presentation to T cells.

Immunological heterogeneity of autoreactive T lymphocytes against the nicotinic acetylcholine receptor in myasthenic patients

The response of human T lymphocytes against the nicotinic acetylcholine receptor (AChR) was studied in five patients with myasthenia gravis (MG) and in six healthy donors using either native Torpedo AChR or recombinant protein derived from the mammalian AChR alpha subunit (X4, residues 6-216 of mouse AChR alpha subunit). The present study demonstrates that (a) AChR-specific T helper cell lines can be generated from MG patients [either from peripheral blood lymphocytes (PBL) or from thymocytes] as well as from PBL of normal controls, (b) lymphocytes from MG patients, but not from controls, recognize the mammalian AChR but not the Torpedo receptor, (c) in humans, the HLA-DR2-associated T cell epitope is probably located in the region of residues 162-216 of the AChR alpha subunit and (d) there is a considerable heterogeneity of autoreactive T cell responses: (i) T cell lines from different HLA-type donors have distinct epitope profiles; (ii) the epitope specificity of the PBL-derived T cell line is different from that of the thymocyte-derived line; (iii) the epitope specificities of patient-derived T cell lines are different from those generated from normal controls who share the same HLA phenotype.

Accessory cells induce a polyphosphatidylinositol response when cultured with mitogen-activated T lymphocytes

Monocytes (MO) influenced phosphoinositide metabolism when human T lymphocytes, isolated from peripheral blood, were activated by polyclonal mitogens. In the 3 hr immediately following mitogenic challenge, the synthesis of phosphatidylinositol (PI) was augmented and the synthesis of PI-4-phosphate (PIP) and PI-4,5-bisphosphate (PIP2) was induced in cultures of T lymphocytes and MO. In addition, MO induced a rapid and transient degradation of PIP and PIP2 in T cells prelabeled with [32P]PL and subsequently activated by mitogen. Induction of a PIP/PIP2 response correlated well with induction of DNA replication by MO when T cells were activated by phytohemagglutinin or by neuraminidase plus galactose oxidase. MO did not influence polyphosphoinositide metabolism when T cells were stimulated by the nonmitogenic lectin wheat germ agglutinin. Interleukin 1 could not substitute for monocytes in inducing a polyphosphoinositide response. By causing a rapid and transient release of the second messengers diacylglycerol and inositol phosphates and by subsequently increasing their cellular precursors, MO may induce the interleukin 2 responsive state in T lymphocytes.

Mouse B lymphocyte specific endocytosis and recycling of MHC class II molecules

In B lymphocytes, the processing of exogenous proteins and the subsequent binding of antigenic peptides to class II molecules encoded by the major histocompatibility complex (MHC) occurs most likely within endocytic compartments. To examine the endocytic transport of MHC class II molecules, we used (i) surface iodination followed by internalization, pronase treatment and immunoprecipitation, (ii) in situ iodination of endosomal compartments, and (iii) confocal microscopy to visualize the fate of fluorescence coupled Fab fragments. In murine I-Ak, I-Ek positive B lymphoma cells, cell surface MHC class II molecules are partially protected from pronase digestion after 15 min at 37 degrees C and recycled back to the cell surface within the next 30 min. The fluorescence coupled Fab fragments are delivered to juxtanuclear endocytic compartments in 15 min. In contrast to the murine B cells, L fibroblasts transfected with either I-A alpha beta k or I-E alpha k beta k,d fail to internalize their surface class II molecules. A fraction of class II molecules, however, is still present in endosomal compartments as detected after in situ iodination in L fibroblasts. We conclude that the recipient L fibroblasts lack one or several factors needed for the transport of MHC class II molecules from the cell surface to the endosomes. We suggest that in murine B lymphoma cells, antigenic peptides can gain access to a pool of recycling class II molecules whereas in L cells they meet newly synthesized class II molecules targeted to the endosomal compartments.

Identification of cross-reactive T cell restriction epitopes located on the DR7 beta 1 and DR beta 4 molecules

L cell fibroblasts transfected with HLA class II cDNA clones isolated from a cDNA library produced from a DR7 homozygous cell line were used as antigen-presenting cells (APC) for three HLA DR-restricted, diphtheria toxoid-specific T-cell clones in order to assess the antigen-presenting ability of the transfectants and to define the class II restriction of each clone. Class II-expressing transfectants are capable of presenting antigen to antigen-specific T-cell clones, although the transfectants are less efficient at antigen presentation than conventional APC. Paraformaldehyde fixation of transfectants prior to antigen pulsing abrogated antigen presentation, demonstrating that the transfectants require antigen processing. Antigen presentation by transfectants is completely inhibited by CD4-specific monoclonal antibodies (mAb) and one of four DR-specific mAb, whereas antigen presentation by conventional APC is only partially inhibited. Both the DR alpha:DR7 beta 1 and DR alpha:DR beta 4 (DR omega 53) molecules of the DR7 allotype serve as restriction elements for the diphtheria toxoid-specific T-cell clones. One clone is restricted by the DR7 beta 1 molecule, another clone by the DR beta 4(DR omega 53) molecule, and a third clone by a cross-reactive T cell epitope on DR7 beta 1 and DR beta 4(DR omega 53) molecules. The two DR beta 4(DR omega 53)-restricted clones react, however, differently with a panel of HLA-DR DR omega 53-positive human peripheral blood lymphocytes used as APC. Therefore the data presented here clearly document that the DR beta 4 (DR omega 53) chain may serve as restriction elements for DT-specific T-cell clones. They also provide the first evidence for functional cross-reactivity of the products of two different DR beta loci and in addition emphasize the high complexity of the supertypic HLA-DR omega 53 specificity.

Structure function analysis of in vitro mutated CD4 and major histocompatibility complex class II gene products

The Class II major histocompatibility molecules are implicated in the initiation of antigen-driven autoimmune responses by CD4-positive T cells. In order to study the structure and function of CD4 and MHC Class II molecules, strategies were developed with the intent of generating secreted forms of these molecules by in vitro mutagenesis of the respective genes. A full length cDNA encoding an expressible human CD4 molecule was mutagenized to introduce a premature stop codon corresponding to residue 367 located 8 amino acids amino terminal to the start of the predicted trans-membrane region. Following DNA-mediated gene transfer of the mutant gene, secreted CD4 was detected in the supernatant of transiently transfected COS-1 cells. Surface expression of the membrane-bound form of CD4 was detected under the same conditions. In an attempt to create a secreted form of the mouse Class II molecule I-Ak the exons encoding the connecting stalk, transmembrane and cytoplasmic domains of both the alpha and beta chains were replaced by the corresponding exons from the gene encoding a secreted Class I-like molecule, Q10b. Transfer of these genes into mouse L cells failed to generate detectable secreted I-A molecules. In view of the secretion of CD4 reported in other mutagenesis studies, it is concluded that very subtle differences in the structure of the COOH-terminus can influence the folding, solubility or transport of the CD4 molecule. In addition, the assembly of heterodimeric Class II molecules may require membrane anchorage of the separate chains or some other contribution from the COOH-terminal domains of the alpha and beta chains.

Monoclonal antibodies define the characteristics and cellular distribution of an Ia-associated protein

In a recent report we described the identification of physical associations between Major Histocompatibility Complex (MHC) Class II (Ia) antigens and other structures of Mr 67,000, which were significantly enhanced following brief T-B cell co-culture (1). To further investigate this 67K Ia-associated product, monoclonal antibodies (MAb) were produced against isolated 67K material and their reactivity examined. Cell surface binding by these MAb was detected only after perturbation of the membrane by cellular adherence or following aldehyde fixation, which indicates that the determinant recognized by these mAb is retained in the plasma membrane in a covert fashion. All lymphoid cells tested showed reactivity with the MAb as determined by immunofluorescence and by ELISA, but no binding was detected on bone marrow or peritoneal macrophages. Expression of the antigen reactive with these antibodies followed a similar pattern with established murine cell lines, with T and B cell lines and a pre-B cell line showing reactivity, while no antigen was detected on macrophage-like and fibroblast cell lines. The intensity of antigen expression by normal lymphoid cells was ordered: thymocytes greater than splenic T cells greater than or equal to bone marrow lymphocytes greater than splenic B cells. No correlation was observed between expression of Ia antigens by non-lymphoid cells and expression of the 67K molecule. These observations suggest that this antigen is primarily a marker of lymphoid cells, with the highest expression on cells of the T lymphocyte lineage. Finally, inhibition of antigen-specific, MHC-restricted T-cell activation by the MAb directed against the 67K structure suggests an important functional role for this interesting molecule originally identified by its physical association with Ia following T-B cell interactions.

Preferential restriction of minor alloantigen-specific suppressor T cells to I-E rather than I-A molecules

Suppressor T (Ts) cells specific for minor alloantigens can be generated by intravenous administration of high doses (10(8) cells) of alloantigenic spleen cells. Such Ts cells have previously been shown to inhibit the in vivo induction of CTL responses and are now shown to suppress in vitro proliferative responses to specific minor antigens. This report demonstrates that the activity of such antigen-specific Ts cells in four different strain combinations involving two haplotypes is blocked by anti-I-E antibody. The proliferative helper T cells (Th) in the same strain combinations are restricted to I-A molecules. Whether our results reflect a more general bias of suppressor T cells to be restricted to I-E molecules is discussed.

In vivo expression and function of hybrid Ia dimers (E alpha A beta) in recombinant and transgenic mice

We have found cell surface expression of an E alpha molecule in recombinant and transgenic mouse strains lacking an E beta molecule. Flow cytometry has shown low level expression of E alpha in B10.RQB3 (I-AqEk alpha) and B10.RFB2 (I-AfEk alpha) mice. We have also found that B10.Q (H-2q) mice can express the Ek alpha transgene. Since these strains do not have functional E beta chains, we propose that the E alpha A beta hybrid dimers are formed in low numbers and can be picked up by FACS analysis. So far we have not been able to identify these hybrid molecules by cytotoxicity or immunoprecipitation. The E alpha/A beta molecule can function in vivo during thymic selection in the clonal deletion of two V beta TCR subsets, V beta 11 and V beta 6, which have been shown to interact with the intact I-E molecule.

Negative trans-acting factors extinguish Ia expression in B cell-L 929 somatic cell hybrids

Numerous studies have implicated trans-acting factors in the regulation of MHC class II gene expression. Some of these factors have been shown to act by inducing the expression of class II genes while others have been demonstrated to downregulate such expression. These reports have dealt almost exclusively with the role of trans-acting factors in the regulation of class II gene expression in hematopoietic-derived cells. We decided to extend these studies to the role trans-acting factors play in nonhematopoietic-derived (NHD) cells. In order to address this question we made somatic cell hybrids between the NHD Ltk- cell line and normal B cells to determine if the existence of positive trans-acting factors from the B cell would lead to the expression of Ltk- class II genes in the resultant hybrid. Our results clearly indicate that not only was there no induction of Ltk- class II gene expression in the hybrids, but there was a loss of B cell class II gene expression as well. These results suggest that Ltk- cells possess negative trans-acting factors that appear to predominate over the positive trans-acting factors possessed by B cells. We have further extended these studies to test the MHC-inducing activity of IFN-gamma and IL-4 on these hybrids. Our results indicate that the hybrids responded to IFN-gamma with an increase in class I but not class II expression for both fusion partners. Furthermore, neither B cell nor L cell class II genes were induced by IL-4. Taken together, these results indicate that Ltk- cells possess negative trans-acting factors that not only maintain the Ia- phenotype of these cells, but also block the action of positive trans-acting factors from B cells.

Intracellular competition for component chains determines class II MHC cell surface phenotype

Mixed isotype (E alpha A beta and A alpha E beta) dimers are not found on Ia+ hematopoietic cells, although some pairs (e.g., E alpha A beta d) reach the membrane of transfected cells expressing only the two relevant class II genes. To examine the basis for this difference in potential versus actual Ia molecule expression, we utilized an L cell transfection model more closely resembling the normal condition of multiple class II alpha and beta chain synthesis within a single cell, such that competition among alpha and beta chains could occur. The surface expression of individual Ia dimers was compared with the available class II chains in such cells. Our data indicate that 3- to 5-fold preferences in assembly or transport of the predominant A alpha A beta and E alpha E beta species preclude expression of the mixed isotype E alpha A beta pair under physiologic conditions of balanced chain synthesis, but that asymmetric chain synthesis can lead to the expression of such mixed dimers on the cell surface in biologically significant amounts.

Biological response modifier as antigen: OK432-specific T-cell clone as an anti-tumor effector cell

OK432, a Streptococcus preparation, is a biological response modifier that has been used in the treatment of malignant diseases. A cloned Thy 1.2+, L3T4+, Lyt 2.2- T cell (OK2.21), specific for OK432 and restricted to I-Ed, was isolated from BALB/c mice immunized with OK432. OK2.21 not only secreted interleukin 2 but also killed Iad-bearing B-lymphoma cells in an antigen-specific manner. The clone also killed Ia-negative bystander tumor targets, but only in the presence of both OK432 and antigen-presenting cells. Despite the cytotoxicity against tumor cells, OK2.21 did not kill OK432-pulsed normal spleen cells. Injection of this clone together with OK432 to tumor-bearing BALB/c mice prolonged their survival, suggesting that this clone acts as an anti-tumor effector (or effector-inducer) cell in the therapy with OK432.

Two genetically identical antigen-presenting cell clones display heterogeneity in antigen processing

Evidence from various antigen systems suggests that antigen processing can be one factor that determines the repertoire of immunogenic peptides. Thus, processing events may account for some of the disparity between the available and expressed helper T-cell repertoires. In this report, we demonstrate that the immunodominant T-cell determinant in ovalbumin [p323-339; ovalbumin-(323-339) heptadecapeptide] is processed differently by two genetically identical antigen-presenting cell lines, M12 and A20. The ovalbumin-specific T-cell-T-cell hybridomas, DO-11.10 and 3DO-54.8, were used to detect processed antigen. These T-T hybridomas have different fine specificities for the p323-339 determinant. A20 cells presented native ovalbumin well to both T-T hybridomas, whereas M12 cells presented native ovalbumin well to 3DO-54.8 but very inefficiently to DO-11.10. M12 and A20 cells effectively stimulated both T-T hybridomas with the same concentrations of the immunogenic synthetic peptide p323-339. Therefore, M12 cells and DO-11.10 can interact with each other, and both T-T hybridomas have similar sensitivities for the same immunogenic peptide. We conclude that genetically identical antigen-presenting cells can display heterogeneity in the fine processing of an immunodominant T-cell determinant, and synthetic model peptides that represent the minimal stimulatory sequence of a T-cell determinant are not necessarily identical to the structure of in vivo processed antigen. Heterogeneity in antigen processing by individual antigen-presenting cells would serve to increase the repertoire of immunogenic peptides that are presented to T cells.

A monoclonal antibody to murine CD45R distinguishes CD4 T cell populations that produce different cytokines

CD4 T cell clones have been shown to be functionally heterogeneous in the mouse. However, it is not known if normal CD4 T cells are also functionally heterogeneous, or whether functional specialization is a result of cloning and long-term culture. To approach this question, a monoclonal antibody reacting with a subset of CD4 T cells has been prepared by immunization of rats with different cloned T cell lines all sharing the same functional activity. This monoclonal antibody reacts with a subset of CD45 (T200) molecules by binding to a determinant requiring the expression of the second variable exon of the CD45 molecule. Some CD4 T cells bear high levels of this marker, while others react only weakly. This antibody was used to separate CD4 T cells into two subpopulations. The brightly staining population was found to produce interleukin (IL) 2 and not IL 4, while the weakly staining population produced IL 4 and not IL 2. These data demonstrate that CD4 T cells in normal mice are already functionally committed, and that they differentially express forms of CD45 that contain the second variable exon.

A role of Ia-associated invariant chains in antigen processing and presentation

Most native antigens require processing in a cellular compartment for efficient presentation to T helper cells. The cellular elements that permit processing are not known. We investigated a possible role of the class II MHC-associated invariant chains in antigen processing. Fibroblast cells that were transfected with class II genes were compared with fibroblasts supertransfected with the invariant chain gene for their capacity to present the fifth component of complement (C5) to C5-specific class II restricted T cell clones or influenza virus protein to a virus-specific T cell clone. Only fibroblasts supertransfected with the invariant chain gene were able to present native antigen, even at very low antigen concentration, whereas both fibroblast types could present cyanogen bromide-fragmented C5 or the virus peptide. Presentation of intact antigen but not of fragmented antigen was totally abrogated by treatment of fibroblasts with chloroquine. The invariant chain gene encodes two polypeptides, li31 and li41. Expression of either li31 or li41 was sufficient to render class II-expressing fibroblasts capable of presenting intact antigen.

Differential activation of cytokine genes in normal CD4-bearing T cells is stimulus dependent

Studies of cloned CD4+ T cell lines have shown that they can be separated into two distinct subsets with distinctions in their functional capabilities and by the differential release of either interleukin 2 (IL 2) (TH1/inflammatory type) or IL 4 (TH2/helper type) upon activation. To establish if in vivo-derived CD4+ T cells can exhibit distinct subsets we have investigated whether normal CD4+ T cells demonstrate differential expression of IL 2 and IL 4 mRNA, and secretion of IL 2 and IL 4 after primary stimulation in vitro. Utilizing the technique of in situ hybridization IL 2 and IL 4 gene expression in individual CD4+ T cells was readily detectable after concanavalin A (Con A) phytohemagglutinin (PHA) or pokeweed mitogen (PWM)-mediated activation. The frequencies of activated T cells producing IL 2 and IL 4 mRNA after Con A or PHA activation were approximately equivalent (30-40% of cells); however, after PWM activation the number of CD4+ T cells expressing IL 4 mRNA (78%) was more than twofold greater than the number of cells producing IL 2 mRNA (30%). Maximal levels of IL 2 gene expression occurred 24 h after mitogen activation whereas the highest levels of IL 4 mRNA were not detected until 48 h after mitogen activation. Similar distinctions in the kinetics of IL 2 and IL 4 secretion after mitogen activation were also found demonstrating good concordance in the observed expression of IL 2 and IL 4 mRNA and the levels of secreted lymphokines detected by bioassay. Most importantly, we have shown by in situ hybridization analysis that the majority of individual CD4+ T cells produce only IL 2 or IL 4 mRNA, and not both, after primary activation in vitro. By contrast, most CD4+ T cells activated in the presence of PMA and ionophore express both IL 2 and IL 4 mRNA. Our studies demonstrate that in normal, non-clonal populations of CD4+ T cells, the production of IL 2 and IL 4 is independently regulated in the majority of cells and appears to be stimulus dependent.

HLA antigens in ocular tissues. III. Antigen presentation by gamma interferon-treated cultured uveal cells

In previous studies we have shown that normal human uveal cells, with the exception of vascular endothelium, do not express class I or class II HLA antigens in vivo. Class I antigens are induced in vitro by a variety of cytokines, while class II antigens are only induced by gamma interferon. In this study we examine the capacity of cultured uveal cells, rendered class II HLA antigen positive by gamma interferon, to present antigen to T cells. Cultured uveal cells were found to present antigen (tetanus toxoid, PPD, and Candida albicans) to T cells, but only when they were pretreated with gamma interferon. This function of uveal cells was antigen specific and MHC restricted and was blocked by class II-specific monoclonal antibodies, indicating the crucial role of class II HLA antigens in antigen presentation.

Mode of antigen presentation required for triggering of T cell response: analysis by use of azobenzenearsonate-tyrosine derivatives as antigens and L cells transfected with I-Ak genes as antigen presenting cells

Our previous study demonstrated (1) that the presence of charged groups (amino and carboxyl groups) at the alpha-carbon of tyrosine is essential for activation of azobenzenearsonate-L-tryosine (ABA-L-Tyr specific T cells, and (2) that T cells recognizes ABA-L-Tyr in association with macromolecules on syngeneic spleen cells used as antigen presenting cells (APC). The present study was undertaken to confirm that the macromolecules on APC are Ia molecules, by using L cells transfected with A beta k and A alpha k genes as APC. I-Ak restricted ABA-L-Tyr specific cloned T cells, and T hybridoma cells were activated by ABA-L-Tyr in the presence of the L cell transfectants, of which expression of I-Ak molecules had been proven by specific binding of anti-I-Ak monoclonal antibody (MAb) 10.2.16 on the cell surface. The pattern of responses of I-Ak restricted ABA-L-Tyr specific T cells to various ABA-Tyr derivatives presented by the I-Ak expressing L cell transfectants was similar to the pattern obtained by using H-2k spleen cells as APC. Thus, ABA-L-Tyr and ABA-Tyr derivatives, which have both amino and carboxyl groups at the alpha-carbon of Tyr, presented by the L cell transfectants triggered good response of I-Ak restricted ABA-L-Tyr specific T cells. By contrast, ABA-Tyr derivatives, which lack the amino or carboxyl group, or both groups, at the alpha-carbon of Tyr, presented by the L cell transfectants could not activate the ABA-L-Tyr specific T cells at all. Furthermore, anti-I-Ak MAb, but not anti-I-Ek MAb, inhibited completely the response of I-Ak restricted ABA-L-Tyr specific T cells to ABA-L-Tyr presented by the L cell transfectants. These results indicate strongly that the macromolecules on APC which associate with ABA-L-Tyr are A beta k A alpha k gene products, i.e., I-Ak molecules.

Analysis of HLA-DR glycoproteins by DNA-mediated gene transfer. Definition of DR2 beta gene products and antigen presentation to T cell clones from leprosy patients

We have used DNA-mediated gene transfer to express HLA class II molecules in mouse L cells for serological, biochemical, and functional analysis. cDNA clones encoding the DR2 beta a and DR2 beta b products of the DR2Dw2 haplotype were subcloned into a mouse Moloney leukemia virus-based expression vector (pJ4) and transfected separately into mouse L cells together with a HLA-DR alpha/pJ4 construct. These transfectants have allowed differential analysis of the two DR2 beta products in a manner normally prohibited by the concomitant expression seen in B cells. Two-dimensional SDS-PAGE analysis of the transfectants defines the more acidic beta chain as the product of the DR2 beta a sequence, and the more basic chain as the product of the DR2 beta b sequence. The LDR2a transfectants present antigen efficiently to M.leprae-specific T cell clones and are capable of presenting synthetic peptide, 65-kD recombinant mycobacterial antigen and M.leprae. Of the DR2Dw2-restricted T cell clones we have tested, all use the DR2 beta a chain as their restriction element. Inhibition studies with mAbs demonstrate the dependence of presentation by the transfectant on class II and CD4, while mAbs against LFA-1, which substantially inhibit presentation by B-lymphoblastoid cell lines, do not inhibit transfectant presentation.

Insulin-dependent diabetes mellitus induced in transgenic mice by ectopic expression of class II MHC and interferon-gamma

We have produced transgenic mouse strains harboring class II major histocompatibility complex or interferon-gamma genes linked to the human insulin promoter. These experiments were designed to investigate the consequences of the expression of immunological effector molecules by nonimmunological cells. In both of these studies we observed the disappearance from the pancreas of the insulin-producing beta cells coinciding with the development of insulin-dependent diabetes mellitus. Transgenic mice expressing both chains of the I-A gene showed progressive atrophy of the islets of Langerhans, whereas mice expressing interferon-gamma suffered an inflammatory destruction of the islets.

Interferon-gamma treatment of B16 melanoma cells: opposing effects for non-adaptive and adaptive immune defense and its reflection by metastatic spread

The impact of interferon-gamma (IFN) treatment of tumor cells on non-adaptive and adaptive immune defense and its reflection by metastatic spread were evaluated using a weakly metastasizing variant of B16 melanoma (B16-FI). Treatment of B16-FI with IFN resulted in a decrease in binding structures for NK cells and concomitantly in augmented metastasizing capacity. In line with this, activation of NK cells and Mo, which led to reduction of metastatic nodes, was less efficient with IFN-treated B16-FI, while after elimination of non-adaptive immune defense, the number of metastases increased significantly, but irrespective of IFN treatment. On the other hand, IFN-treated B16-FI cells become more prone to killing by cytotoxic T-cells (CTL). This was due to increased lysability by CTL and to increased immunogenicity; i.e., a higher frequency of B16-specific CTL was observed after immunization with IFN-treated than with untreated B16-FI. The reverse phenomenon was observed with anomalous and/or lymphokine-activated killer cells (AK/LAK). The common cause of increased antigenicity and immunogenicity may reside in increased expression of class-I and de novo expression of class-II MHC antigens after IFN treatment. Increased antigenicity and immunogenicity of IFN-treated B16-FI was reflected by significant reduction of metastatic nodes, prolonged survival and increased TD100 in animals immunized with IFN-treated vs. untreated melanoma cells. Comparison of the divergent effects of IFN treatment on B16-FI melanoma cells showed that the benefit of increased antigenicity/immunogenicity clearly outweighed the disadvantage of reduced susceptibility to non-adaptive immune defense.

Antigen presentation to HLA class II-restricted measles virus-specific T-cell clones can occur in the absence of the invariant chain

A human fibroblast line expressing HLA-DR1 antigen on its surface was generated by transfection with DR alpha and DR beta cDNAs. Expression of the invariant chain gene was not detectable in the transfected fibroblasts and was not induced by infection with measles virus. Lysis of measles virus-infected cells occurred with DR1- but not with DR4-restricted measles virus-specific cytotoxic T-lymphocyte (CTL) clones and was inhibited by a monoclonal antibody specific for DR antigen. Therefore, the invariant chain is not required for DR-restricted presentation of measles virus antigens by this fibroblast line. Transfected fibroblasts were lysed as efficiently as an autologous B-cell line even though they expressed much less surface DR antigen. Lysis of both the transfected fibroblasts and the B-cell line was insensitive to treatment with chloroquine. These results demonstrate that expression of a DR alpha beta heterodimer at the surface of this fibroblast line is necessary and sufficient for presentation of measles virus antigens to specific CTL clones.

Predominant role of amino-terminal sequences in dictating efficiency of class II major histocompatibility complex alpha beta dimer expression

Cell surface expression of class II major histocompatibility complex-encoded (Ia) molecules depends on association of the component alpha and beta chains into a stable heterodimer. In the mouse, two isotypes of class II molecules have been identified, A beta A alpha and E beta E alpha. However, experiments from this laboratory have shown that, following DNA-mediated gene transfer into murine L cells, an A beta E alpha-mixed-isotype molecule can be assembled and expressed at the cell surface. In the present study, we have investigated the structural features of the beta chain that control the extent of association and level of membrane expression of A beta E alpha interisotypic pairs. The use of intact allelic A beta genes demonstrated that only A beta d chains, but not A beta b or A beta k chains, can be coexpressed on the surface membrane with E alpha chains. Transfection of recombinant A beta genes that encode all or half of the beta 1 domain from one allele and the rest of the chain from another allele revealed that the 5-7 polymorphic residues in the amino-terminal 50 residues of the A beta chain completely controlled this variation in expression with E alpha. Isotypically mixed beta genes encoding the A beta 1 domain of either A beta d or A beta k chains and the beta 2, transmembrane, and intracytoplasmic portions of E beta chains were used to assess the role of isotypically conserved structures in alpha beta pairing and expression. In marked contrast to the major alterations in expression accompanying changes in the amino-terminal polymorphic residues, exchange of these carboxyl-terminal isotypic segments had no detectable influence on the efficiency of expression with either A alpha or E alpha chains. These results argue strongly that variations in the efficiency with which distinct Ia alpha beta dimers assemble and are transported to the membrane is determined almost exclusively by a critical chain interaction involving the amino-terminal domains of the molecules.

Ia antigen expressed by keratinocytes can be the molecule of antigen presentation in contact sensitivity

Immune response-associated (Ia) antigens are important as molecules in antigen recognition by T cells. Keratinocytes can express Ia antigens in many inflammatory dermatoses and by action of gamma interferon (IFN-gamma). A keratinocyte cell line, Pam 212 cells, expressed Ia antigens at maintaining culture. They also expressed Ia antigens under the influence of IFN-gamma. Liposomes carrying molecules from trinitrophenylated-Pam cells did not stimulate lymphnode cells (LCs) of contact sensitivity; however, liposomes carrying a large amount of those molecules stimulated LCs. This stimulation was attributable to contaminated Ia antigens in those molecules. Liposomes with a small amount of those molecules or trinitrophenylated-proteins from Pam cells were prepared. Into them were inserted Ia antigen-rich proteins from Pam cells, spleen cells, IFN-gamma-treated Pam cells, or epidermal cells containing Langerhans cells. Thus prepared liposomes stimulated the LCs significantly. The Ia antigens obtained from IFN-gamma-treated Pam cells worked as well as Ia antigens from epidermal cells that contained Langerhans cells as the molecule of antigen presentation in contact sensitivity.

Allele-specific control of Ia molecule surface expression and conformation: implications for a general model of Ia structure-function relationships

Sequence polymorphism of class II major histocompatibility complex-encoded molecules (Ia) not only accounts for the allelic variability in Ia structure relevant to T-lymphocyte responses but also seems to result in differential quantitative expression of particular Ia heterodimers. The contributions of different allelically variable regions of Ia molecules to both of these processes were analyzed by transfection of L cells with various A beta and A alpha gene pairs. The results show that, with regard to quantitative and qualitative aspects of Ia expression, the polymorphisms in the A beta chain segregate into two groups. Those in the NH2-terminal half of A beta 1 have a consistent role in controlling beta-alpha chain interactions, efficiency of dimer expression, and Ia conformation and probably are in the interior of the Ia molecule at the site of beta-alpha domain interaction. Polymorphisms in the COOH-terminal half of A beta 1 contribute to those structures that directly interact with antibodies, antigen, and/or T-cell receptors, consistent with their presence on the surface of the Ia heterodimer. This analysis provides a model for understanding both overall class II molecular structure and the relationship between this structure and immune recognition. It also suggests an explanation for the evolution of certain features of class II genes.

The basis for the immunoregulatory role of macrophages and other accessory cells

Macrophages handle extracellular proteins and secrete diverse bioactive molecules and, therefore, influence the physiology of many tissues. They also have an important immunoregulatory role. The immune response to proteins involves the activation of the T helper subset of lymphocytes. The T helper cell is activated only when it interacts with the protein displayed on the surface of a macrophage or other accessory cell. This interaction involves restrictive proteins encoded in the major histocompatibility gene complex as well as growth-differentiating proteins.

Cloned protein antigen-specific, Ia-restricted T cells with both helper and cytolytic activities: mechanisms of activation and killing

Myoglobin-specific, Iad-restricted cloned helper T cells and T hybridomas were found to directly kill Iad-bearing, myoglobin-pulsed B lymphoma targets and could also kill bystander targets, but only in the presence of antigen-pulsed antigen presenting cells (APC). The induction of the killing requires recognition of processed antigen in the context of class II major histocompatibility complex (MHC) molecules. Despite the specificity of induction, the bystander killing suggests a nonspecific lytic mechanism. The direct killing can be inhibited only by cold specific targets, whereas the bystander killing can be blocked by both specific and nonspecific targets. The cold target inhibition seems to be due to interference with effector-to-target contact or proximity rather than due to high-dose suppression of T-cell activation. Experiments using T-cell supernatants or cyclosporin A suggested that the helper T cells kill targets by synthesizing short-range soluble factor(s) with nonspecific killing activity de novo during the effector phase, but only while antigen-specific signal transduction is occurring. The mechanism of cold target inhibition appears to be absorption or consumption of a short-acting cytotoxic lymphokine by cells which must be able to interact closely with the effector cell. Normal spleen B cells, despite their capability for activating the helper T cells, cannot inhibit specific killing or be killed by helper T cells, even after lipopolysaccharide stimulation. Thus, although killing by helper T cells may play a negative feedback role in the normal immune response, our data raise the possibility that the helper T-cell-mediated killing may contribute to the immune surveillance against malignancy by virtue of the preferential killing of tumor cells either directly or indirectly.