Activated human T cells can present denatured antigen

Enhancement of CD4(+) T cell response and survival via coexpressed OX40/OX40L in Graves' disease

OX40/OX40L pathway plays a very important role in the antigen priming T cells and effector T cells. In the present study, we aimed to examine the involvement of OX40/OX40L pathway in the activation of autoreactive T cells in patients with Grave's disease (GD). We found that OX40 and OX40L were constitutively coexpressed on peripheral CD4(+) T cells from GD patients using flow cytometry analysis. The levels of OX40 and OX40L coexpression on CD4(+) T cells were shown to be correlated with TRAbs. Cell proliferation assay showed that blocking OX40/OX40L signal inhibited T cell proliferation and survival, which suggested that OX40/OX40L could enhance CD4(+) T cell proliferation and maintain their long-term survival in GD by self-enhancing loop of T cell activation independent of APCs. Confocal microscopy and coimmunoprecipitation analysis further revealed that OX40 and OX40L formed a functional complex, which may facilitate signal transduction from OX40L to OX40 and contribute to the pathogenesis of GD.

Role of MHC class II expressing CD4+ T cells in proteolipid protein(91-110)-induced EAE in HLA-DR3 transgenic mice

MHC class II molecules play a central role in the control of adaptive immune responses through selection of the CD4(+) T cell repertoire in the thymus and antigen presentation in the periphery. Inherited susceptibility to autoimmune disorders such as multiple sclerosis, rheumatoid arthritis and IDDM are associated with particular MHC class II alleles. Advent of HLA transgenic mice has helped us in deciphering the role of particular HLA DR and DQ class II molecules in human autoimmune diseases. In mice, the expression of class II is restricted to professional antigen-presenting cells (APC). However, in humans, class II is also expressed on T cells, unlike murine T cells. We have developed new humanized HLA class II transgenic mice expressing class II molecules not only on APC but also on a subset of CD4(+) T cells. The expression of class II on CD4(+) T cells is inducible, and class II(+) CD4(+) T cells can present antigen in the absence of APC. Further, using EAE, a well-established animal model of MS, we tested the functional significance of these class II(+) CD4(+) T cells. DR3.AEo transgenic mice were susceptible to proteolipid protein(91-110)-induced EAE and showed CNS pathology accompanied by widespread inflammation and demyelination seen in human MS patients, suggesting a role for class II(+) CD4(+) T cells in the pathogenesis.

MHC class-II-restricted antigen presentation by myelin basic protein-specific CD4+ T cells causes prolonged desensitization and outgrowth of CD4- responders

T cells express MHC class II glycoproteins under various conditions of activation or inflammation. To assess whether T cell APC (T-APC) activity had long-term tolerogenic consequences, myelin basic protein (MBP)-specific rat T cells were induced to acquire MBP-derived I-A complexes to promote reciprocal antigen presentation. T-T antigen presentation caused extensive cell death among T-APC and MBP-specific T responders and caused long-term desensitization of surviving responders. Addition of the anti-I-A mAb OX6 to activated I-A+ responders inhibited T-APC activity, accelerated recovery from postactivation refractoriness, and prevented long-term loss of reactivity in responder T cells. Antigenic activation of responder T cells with irradiated T-APC induced profound losses in reactivity that lasted for over 1 month of propagation in IL-2 and was associated with preferential outgrowth of CD4- T cells. Antigen-activated CD4- T cells exhibited more rapid IL-2-dependent growth that eventually normalized compared to CD4+ T cells 1-2 months after antigen exposure. In conclusion, expression of T-APC activity by activated T cells represents an important negative feedback pathway that depletes antigen-reactive T cells and causes long-term desensitization of surviving T cells. Hence, T cell APC may be an important mechanism of self-tolerance.

Expression of MHC class II in T cells is associated with increased HIV-1 expression

HIV-1 replicates in activated T cells at significantly higher levels than in resting cells. Thus, certain molecules up-regulated during T cell activation appear to be important for HIV-1 replication. In this study, we present evidence suggesting that expression of MHC class II (class II) molecules on CD4+ T cells facilitate HIV-1 replication. T cells that expressed class II supported greater virus replication than T cells lacking class II. The class II+ cells, when either infected with HIV-1 or transfected with an env-minus HIV-1 provirus plasmid, produced 10-20-fold greater virus expression than class II- cells. Anti-class II antibody markedly inhibited virus expression in class II+ cells (but not class II- cells) and also decreased the nuclear binding activity of AP-1, an inducible transcription factor important in T cell activation and HIV-1 expression. Most importantly, the induction of class II expression by transfection of the MHC class II transactivator (CIITA) stimulated HIV-1 replication in Jurkat T cells. Taken together, these data suggest that expression of MHC class II molecules and/or CIITA in T cells enhances HIV-1 transcription.

Antigen presentation by T cells: T cell receptor ligation promotes antigen acquisition from professional antigen-presenting cells

The purpose of this study was to determine whether the clonotypic specificity of the T cell receptor influences the specificity of T cell-mediated antigen presentation. We have previously shown that myelin basic protein (MBP)-specific Lewis rat GP2.E5/R1 (R1) T cells cultured with antigen, irradiated syngeneic splenocytes (IrrSPL) and tolerogenic monoclonal antibody become highly effective antigen-presenting cells (APC). In the current studies, we investigated the transfer of specific (MBP) and unrelated (conalbumin) antigens from antigen-pulsed SPL to R1 T cells. R1 T cells cultured with IrrSPL that were pulsed simultaneously with both MBP and conalbumin acquired and presented both antigens to the appropriate T cell responders in a secondary assay. These results suggested a physical transfer of major histocompatibility complex (MHC)/peptide complexes from professional APC to R1 T cells. Transfer of conalbumin from professional APC to R1 T cells required specific recognition of MBP and was optimal when both conalbumin and MBP were presented on the same group of professional APC. Antigens transfer did not occur when allogeneic SPL were used as APC. The anti-I-A mAb OX6 inhibited antigen transfer but only when added during the initiation of culture. OX6 also inhibited antigen acquisition by R1-trans, a variant of the R1 T cell line which constitutively synthesizes high levels of I-A, from MBP-pulsed IrrSPL but blockade of I-A did not inhibit antigen acquisition when soluble MBP was added directly to the culture. Despite constitutive synthesis of I-A, R1-trans T cells did not acquire guinea pig MBP from pulsed allogeneic APC. These studies demonstrate that although T cells of a particular specificity can present unrelated antigens, the cognate interaction of the T cell antigen receptor with the appropriate antigen/self-MHC complex strongly promotes acquisition of these complexes from professional APC.

Antigen presentation by autoreactive proteolipid protein peptide-specific T cell clones from chronic progressive multiple sclerosis patients: roles of co-stimulatory B7 molecules and IL-12

To assess the role of T cell antigen (Ag) presentation in multiple sclerosis (MS), proteolipid protein (PLP) peptide reactive CD4+ T cell clones (TCCs) from MS patients and normal subjects were studied. TCCs derived from chronic progressive (CP) MS patients were able to proliferate and secret cytokines in response to PLP peptide stimulation in the absence of professional antigen presenting cells (APCs), suggesting that these T cells can simultaneously present and respond to Ags. However, they did not respond to total PLP protein, suggesting that PLP-peptide TCCs were unable to process and present the whole PLP molecule. The ability of the different TCCs to act as APCs in response to Ag stimulation did not correlate with expression of HLA-class II molecules. However, the degree of expression of B7-1 and B7-2 co-stimulatory molecules showed a significant correlation with APC capacity. Furthermore, a combination of anti-B7-1 and anti-B7-2 mAbs effectively inhibited proliferative responses as well as secretion of IL-10, IFN gamma and TGF beta induced by antigen presenting T cells. By contrast, IL-4 secretion was not affected. Finally, IL-12 significantly enhanced the efficiency of T cell Ag presentation by a pathway independent of Ag processing, suggesting that IL-12 might act as an additional co-stimulatory signal for T cell activation during T-T cell interactions. Together, these observations suggest that Ag presentation by T cells might amplify and perpetuate an autoimmune response previously initiated by professional APCs. These properties may account for progression of MS into a CP phase.

HLA class II molecules transduce accessory signals affecting the CD3 but not the interleukin-2 activation pathway in T blasts

MHC class II molecules play a central role in the control of the immune response, but their biologic function and mechanism of action on the surface of activated human T lymphocytes are not entirely understood. In our study, the functional role of HLA class II molecules in T-blast proliferation was investigated by analyzing in parallel the IL-2- and CD3-driven activation pathways. The results indicate that the cross-linking of class II and CD3 molecules significantly increased the CD3-mediated T-blast proliferation, while no effect was observed on the IL-2-driven cell activation. This phenomenon was not confined to either CD4+ or CD8+ subsets nor was specifically affected by CD45 triggering. Biochemical studies showed that signaling via MHC class II molecules in T blasts led to PKC membrane translocation and IP accumulation. The simultaneous triggering of CD3 and HLA class II molecules led to a synergistic effect on IP accumulation but did not increase the CD3-mediated PKC membrane translocation. Our data suggest that HLA class II molecules are involved in T-cell-T-cell interactions and can mediate accessory signals, affecting the T-lymphocyte activation state.

Patterns of major histocompatibility complex class II expression by T cell subsets in different immunological compartments. 2. Altered expression and cell function following activation in vivo

This study characterizes antigen-induced phenotypic and functional aspects of major histocompatibility complex (MHC) class II expression on recirculating T cells in efferent lymph. In vivo secondary, but not primary challenge is associated with both kinetic and phenotypic alterations in class II expression by T cells. All three major T cell subsets, CD4+, CD8+ and T19+ (gamma delta T cell receptor), show an approximate four fold increase in the level of MHC class II expression during secondary responses. No changes in B cell expression of class II were seen. Resting efferent lymph T cells are predominantly either class II- or DR+DQ- but this changes to DR+DQ+ after antigenic challenge. The antigen-presenting function of these class II+ T cells was investigated at daily intervals after in vivo antigenic challenge. T cells from non-activated lymph nodes could not induce proliferation of antigen-specific T cells with soluble antigen but were weakly stimulatory in allo-mixed lymphocyte reaction (MLR) at high (> 2:1) stimulator cell ratios. Activated T cells isolated during secondary in vivo responses, and expressing increased quantities of MHC class II, were positive stimulator cells in the MLR. In contrast these cells could not present soluble antigen or trypsin-digested antigen to the T cell lines. In the MLR assays, the relative stimulation by class II+ T cells correlates with the levels of class II expression. We conclude from these experiments that both quantitative and qualitative changes in MHC class II, induced on T cells under physiological conditions, play a role in the regulation of the immune response in vivo but that that role is not simply one of presentation of soluble antigen.

Functional expression of B7/BB1 on activated T lymphocytes

B7/BB1 is a membrane differentiation antigen expressed on activated B cells, macrophages, and dendritic cells that binds to a counter-receptor, CD28, expressed on T lymphocytes and thymocytes. Interaction between CD28 and B7 results in potent costimulation of T cell activation initiated via the CD3/T cell receptor complex. We now report that B7 is also expressed on activated human peripheral blood T cells, CD4 T cell clones, CD8 T cell clones, and natural killer cell clones. B7 appears relatively late after T cell activation, can be detected on both CD4 and CD8 T cell subsets, and is present on antigen-specific, major histocompatibility complex-restricted CD4 and CD8 T cell clones. Expression of B7 on activated T cells was confirmed by immunoprecipitation from 125I-labeled activated T cells and by detection of B7 transcripts. A B7+ CD4+ T cell clone was able to stimulate a primary allogeneic mixed lymphocyte response using small, resting peripheral blood T cells as responders. The alloantigen-induced proliferative response and cytokine production was partially inhibited by anti-B7 monoclonal antibody. Since activated T cells can coexpress both CD28 and its counter-receptor, B7, this suggests that activated T cells may be capable of autocrine costimulation via the CD28 activation pathway.

Current concepts in DRA gene regulation

The purpose of this review is to provide an interpretative view of work from our laboratory on the DRA gene, and incorporate it with work from other laboratories. Specially, we will deal with: (a) the functional roles of transcription factors in DRA gene regulation; (b) the mechanisms of DRA induction by cytokines; (c) the analysis of DRA gene control in primary untransformed cells, and (d) interactions among transcription factors critical for DRA gene expression.

Requirements for lysis of activated T cells by class-II-restricted cytolytic T-lymphocytes

In the present study, we explored the specific requirements for lysis of human activated T cells by CD4+ CTLs. This was achieved by using human CD4+ T cell lines or clones specific for a peptidic fragment of influenza virus as both CTL effectors and target T cells (TTCs). Our results further establish that human activated T cells expressing HLA-DR molecules can present Ag to and be lysed by CD4+ HLA-DR restricted CTLs. This killing is Ag specific and HLA-DR restricted. It can be observed whether TTCs are heterologous or autologous, CD4+ or CD8+. However, we find that in our model: (a) TTCs are able to present artificially processed peptidic fragments of Ag, but not the corresponding natural Ag in the context of class II determinants, even if they can process whole virus in the context of class I determinants; (b) TTCs must express high density of HLA-DR molecules on their membrane; (c) preincubation of TTCs with high concentrations of peptide is required; and (d) interestingly enough, addition of free peptide at similar concentration during the cytolytic assay to replace TTC preincubation inhibits TTC lysis by at least two different mechanisms, i.e., cold-target inhibition in which CTLs serve as their own cold targets and inhibition at the effector cell level. From these results, one can conclude that stringent conditions are required for lysis of activated T cells by class-II-restricted CTLs.

Early signaling defects in human T cells anergized by T cell presentation of autoantigen

Major histocompatibility complex class II-positive human T cell clones are nontraditional antigen-presenting cells (APCs) that are able to simultaneously present and respond to peptide or degraded antigen, but are unable to process intact protein. Although T cell presentation of peptide antigen resulted in a primary proliferative response, T cells that had been previously stimulated by T cells presenting antigen were completely unresponsive to antigen but not to interleukin 2 (IL-2). In contrast, peptide antigen presented by B cells or DR2+ L cell transfectants resulted in T cell activation and responsiveness to restimulation. The anergy induced by T cell presentation of peptide could not be prevented by the addition of either autologous or allogeneic B cells or B7+ DR2+ L cell transfectants, suggesting that the induction of anergy could occur in the presence of costimulation. T cell anergy was induced within 24 h of T cell presentation of antigen and was long lasting. Anergized T cells expressed normal levels of T cell receptor/CD3 but were defective in their ability to release [Ca2+]i to both alpha CD3 and APCs. Moreover, anergized T cells did not proliferate to alpha CD2 monoclonal antibodies or alpha CD3 plus phorbol myristate acetate (PMA), nor did they synthesize IL-2, IL-4, or interferon gamma mRNA in response to either peptide or peptide plus PMA. In contrast, ionomycin plus PMA induced both normal proliferative responses and synthesis of cytokine mRNA, suggesting that the signaling defect in anergized cells occurs before protein kinase C activation and [Ca2+]i release.

Peptide-induced proliferation and lymphokine production in human T cells in the absence of antigen-presenting cells: role of T-cell activation state and costimulatory signals

The role of T-lymphocytes as antigen-presenting cells (APCs) for other T cells was investigated. Activated rabies-virus-specific human T-cell clones were shown to present peptide to class II major histocompatibility complex (MHC)-restricted T cells of a different fine specificity, resulting in lymphokine production and cell proliferation. Furthermore, purified and activated antigen-specific T cells could produce lymphokines and proliferate as a result of the addition of antigenic peptide in the absence of APC. The functional response of T cells to peptide in the absence of APC was amplified by the addition of phorbol ester (PMA) and was inhibited with antibodies specific to class II MHC or to the CD2 molecule. Experiments performed in single-cell suspension cultures using semisolid medium prepared with 1% agar demonstrate that T-cell proliferative and lymphokine responses to peptide both in the presence and absence of APC require the interaction of T-cell antigen receptor (TCR) molecules with class II MHC-peptide complexes on different cell surfaces (cell-cell contact). On the other hand, peptide self-presentation, which occurs by the binding of TCR with class II MHC-peptide complexes on the same cell surface (at the single-cell level), resulted in T-cell activation (i.e., high expression of surface CD2, CD25, and HLA-DR molecules), without proliferation or lymphokine secretion, a pattern observed in the induction of T-cell anergy by antigen. The results are discussed in terms of the role of class II MHC molecules on activated T-lymphocytes, which enable these cells to function as "professional APC" in the development of T-cell regulatory networks.

Transferrin receptor mediates uptake and presentation of hepatitis B envelope antigen by T lymphocytes

Human activated T lymphocytes expressing class II molecules are able to present only complex antigens that bind to their own surface receptors, and thus can be captured, internalized, and processed through the class II major histocompatibility complex processing pathway. We have used the antigen-presenting T cell system to identify the viral receptor used by hepatitis B virus (HBV) to enter cells, as well as the sequence of HB envelope antigen (HBenvAg) involved in this interaction. Results show that both CD4+ and CD8+ T clones can process and present HBenvAg to class II-restricted cytotoxic T lymphocytes and that the CD71 transferrin receptor (TfR) is involved in efficient HBenvAg uptake by T cells. Moreover, we provide evidence that the HBenvAg sequence interacting with the T cell surface is contained within the pre-S2 region. Since TfR is also expressed on hepatocytes, it might represent a portal of cellular entry for HBV infection. This system of antigen presentation by T cells may serve as a model to study both lymphocyte receptors used by lymphocytotropic viruses and viral proteins critical to bind them.

Induction of HLA class II molecules on human T cells: relationship to immunoregulation and the pathogenesis of AIDS

Human T cells express HLA class II molecules upon activation. The factors that regulate the induction of expression of these molecules are for the most part unknown. Here we report preliminary results indicating that tumor necrosis factor-alpha (TNF-alpha) regulates the induction of cell-surface HLA-DR, DO, and DP molecules in human T cells stimulated with PHA. In contrast, recombinant interferon-gamma (rIFN-gamma), recombinant interleukin-1 alpha (rIL-1 alpha), or rIL-4 appear to have no effect on class II expression. The role of class II molecules on activated T cells is discussed in relationship to immunoregulation and the progression of HIV infection. Three non-mutually exclusive hypotheses are discussed. In the first hypothesis, we consider the role of these class II molecules in antigen presentation of endogenously synthesized HIV envelope by CD4+ cells. The second is a clonal inactivation of virus-specific helper T cells that might occur as a consequence of a direct T cell to T cell interaction and a bypass of the "accessory signal" normally delivered by antigen-presenting cells such as macrophages. The third is a molecular mimicry between HIV envelope proteins and HLA class II molecules, which may lead to the development of autoimmunity against CD4+ T-cell-expressing class II molecules.

Post-transcriptional regulation of MHC class II expression in human T cells

Human T lymphocytes are among those cells which are cell surface class II- in the resting state, but can be induced to express class II following treatment with appropriate stimulators. Although resting T cells do not express detectable surface class II, cell surface class II can be detected on purified T cells as early as 30 min following stimulation with PHA and PMA, well before the initiation of DNA synthesis, and the percentage of positive cells gradually increases with time. One hypothesis explaining this very rapid surface expression of class II is that the genes can be regulated post-transcriptionally in T cells. To test this, we used nuclear run-on assays to measure the transcriptional rate of diverse class II genes in resting and activated T cells. Our results demonstrated that transcripts for DR, DP, and DQ could be detected in cells which were neither dividing nor transcribing mRNA for another marker of T cell activation, the IL-2 gene. Northern blot analysis demonstrated low to moderate steady-state levels of DR beta mRNA in these cells. Moreover, treatment of activated T cells with cycloheximide resulted in superinduction of class II for DR, DQ, and DP. These results suggest that resting T cells can transcribe mRNA for class II genes, but that they do not express the protein product on the cell surface in a detectable way until following activation. In addition, they suggest that there may be a protein factor which negatively influences class II levels in T cells. Thus, the regulation of class II in T cells is complex and involves post-transcriptional regulation, at least in part.

Autoantigen-induced self lysis of human myelin basic protein-specific T lymphocytes

Cytotoxic T cells reactive with myelin basic protein (MBP) may be isolated from most human subjects. Since activated T cells express major histocompatibility complex (MHC) class II antigens, we assessed whether MBP-specific, CD4+ T cells could present MBP or synthetic MBP peptides to themselves and whether this provoked self lysis. We examined two MBP-specific cell lines and eight T cell clones recognizing four different MBP epitopes. All T cell populations presented MBP as well as synthetic peptides to themselves eliciting self lysis of the T cell clones. CD4+ T cell populations recognizing another central nervous system (CNS) protein, proteolipid protein (PLP), or the recall antigen, Candida, did not exhibit this antigen-induced, autocytolytic activity. However, activated, PLP-reactive T cells were susceptible to lysis by cytotoxic MBP-specific T cells in the presence of MBP. These results suggest that antigen-induced self lysis of activated human T cells might limit an autoimmune response within a target organ independent of other immunoregulatory mechanisms.

Signal transduction by HLA-DR is mediated by tyrosine kinase(s) and regulated by CD45 in activated T cells

Recently, it was shown that HLA class II molecules on B cells and activated human T cells can transmit signals involving tyrosine phosphorylation of specific proteins, activation of the inositol phospholipid pathway, and release of cytosolic free Ca2+(Ca2+)i. The regulation of class II induced signals is poorly understood, however, and it remained unknown whether these pathways were coupled or activated independently. Here we show that a specific inhibitor of protein tyrosine kinases (PTK), herbimycin, abrogated DR-induced elevation of (Ca2+)i in activated human T cells. Genistein, belonging to another family of PTK inhibitors, had weaker but significant inhibitory effects on DR-induced (Ca2+)i responses. CD45 crosslinking with DR almost completely abrogated DR-induced (Ca2+)i responses and profoundly changed the PTK profiles. In contrast, CD4 crosslinking with DR enhanced the (Ca2+)i responses, but the inhibitory effect of CD45 dominated over the enhancing effect of CD4. These data indicate that PTK activation is obligatory for DR-induced (Ca2+)i responses, suggesting a linkage between these pathways in class II signal transduction. This conclusion is consistent with our observation that in activated human T cells, class II signals are up regulated by CD4, which is associated with p56lck, and down regulated by CD45, which is a tyrosine phosphatase.

Critical role for the Val/Gly86 HLA-DR beta dimorphism in autoantigen presentation to human T cells

Helper T lymphocytes recognize fragments of foreign (or self) antigens in the peptide-binding clefts of major histocompatibility complex class II molecules; their activation is a crucial step in the induction of many immune and autoimmune responses. While studying the latter, we raised a T-cell line from the thymus of a myasthenia gravis patient against recombinant alpha subunit of the human acetylcholine receptor, the target of this autoimmune disease. The line responds to the 144-156 region of the human sequence and not to the same region of the electric fish homolog, which differs by only three residues. These CD4+ T cells recognize this epitope only in the context of HLA-DR4 class II molecules, of which the variants with Gly86 are absolutely required. Thus the naturally occurring alternatives Dw14.2 (Gly86) and Dw14.1 (Val86)--which differ only at this one position in the entire antigen-binding region--show an all-or-nothing difference in presenting activity. This dimorphism at position 86 is widespread, occurring in subtypes of DR1, DR2, DR3, DR5, and DR6 alleles as well as DR4. Since other DR4 subtypes with substitutions at positions 70-74 also fail to present this peptide, and glycine residues can be uniquely flexible, we suggest that this replacement at position 86 acts locally or at a distance by altering the conformation of the peptide-binding cleft. Such profound functional consequences for T-cell recognition as we report here may explain this example of conserved major histocompatibility complex diversity.

HLA-DR molecules enhance signal transduction through the CD3/Ti complex in activated T cells

Crosslinking HLA-DR molecules by monoclonal antibodies (mAb) induces protein tyrosine phosphorylation and results in a secondary elevation of free cytoplasmic Ca2+ concentration ([Ca2+]i) in activated human T cells. Here we have studied the effect of DR on CD3-induced signal transduction in allospecific T-cell clones and T-leukemia (HUT78) cells. Co-crosslinking of DR with CD3 produced an enhanced [Ca2+]i response compared to that seen with CD3 alone. In contrast, CD2 responses were not enhanced by co-crosslinking with DR. Co-crosslinking CD45 in a tri-molecular complex of CD45, CD3, and DR completely abrogated the enhancing effects of DR on CD3-induced [Ca2+]i responses. In contrast, the enhancing effect of co-crosslinking CD4 on CD3 responses was not inhibited by co-crosslinking CD45. Thus, the DR-mediated accessory signals appear to be regulated differently from those provided by CD4 accessory molecules. The present data confirm, at the level of second messengers, recent findings suggesting that DR molecules have accessory functions in CD3/Ti-mediated T-cell responses.

Negative signal transmission through class II molecules on activated T cells

Major histocompatibility complex class II antigens are expressed on human T cells following activation, but their functional role remains obscure. We have investigated the effect of anti-class II monoclonal antibodies on T cell proliferation. Our results indicated that antibodies directed against either DR, DQ, or DP were able to decrease 3H-TdR uptake if the cells had been activated by interleukin-2 (IL-2). On the other hand, minimal inhibition resulted when phorbol dibutyrate, a phorbol ester, and ionomycin, a calcium ionophore, were used to activate cells. The specificity of the effect was demonstrated by the observation that anti-class I antibodies inhibited proliferation stimulated by IL-2 and phorbol dibutyrate and ionomycin equally well. Proliferation by the anti-class II monoclonal antibodies was inhibited regardless of whether the monoclonal antibodies were added at the initiation of culture or to actively proliferating cells, suggesting that an early event was not specifically targeted. Our findings are consistent with the interpretation that class II antigens are involved in the transmission of signals to activated T cells.

Signal transduction by HLA class II antigens expressed on activated T cells

Human T cells express HLA class II antigens upon activation. Although activated, class II+ T cells can present alloantigens under certain circumstances, the functional role of class II antigens on activated T cells remains largely unknown. Here, we report that cross-linking of HLA-DR molecules expressed on allospecific, CD4+ T clones and cell lines can function as transduction elements that trigger rapid cellular responses including tyrosine phosphorylation of cellular proteins and mobilization of Ca2+ from internal stores. The proteins phosphorylated on tyrosine were distinct from those observed after cross-linking CD4. Ligation of CD4 and class II molecules generated a synergistic effect of the intracellular free Ca2+ concentration response that required an interaction between the molecules on the cell surface. Since class II is the natural ligand for CD4, the present data suggest that class II is induced on activated T cells to regulate CD4 function, possibly by specific interaction with the CD4-associated p56lck protein tyrosine kinase.

Expression of MHC class II epitopes on human T lymphocyte clones

Twenty-four CD4+ alloreactive helper T cell clones and eight CD8+ cytotoxic T cell clones from five different donors, all of which were dependent on alloantigen and IL 2 for continued growth, were analyzed by FACS for cell surface expression of HLA-DR, -DQ, and -DP epitopes using monoclonal antibodies against monomorphic and polymorphic determinants. Clones were tested early (less than 30 population doublings) and late (greater than 45 population doublings) in their life-spans and at various times (3-5 days) after antigenic restimulation. All clones expressed high levels of HLA-DR at all times, and lower but significant levels of both HLA-DQ and -DP. In contrast, B lymphoblastoid cell lines expressed equivalent amounts of HLA-DR and -DQ, but less HLA-DP. There was no evidence of differential regulation or expression of the three major MHC class II isotypes on different T cell subsets, and neither did antibodies specific for polymorphic epitopes fail to react on clones from donors carrying the appropriate alleles.

Requirement of the T cell receptor for antigen presentation by T lymphocytes. Effect of envelope glycoproteins of HIV-1 on antigen presentation by T cells

We have developed CD4+, tetanus antigen-specific T cell clones that proliferate in the presence of tetanus antigen and autologous irradiated peripheral blood leucocytes (PBL) as antigen-presenting cells (APC). There have been several reports that T cells can present antigen themselves. We have used tetanus antigen-specific T cell clones to examine the effects of envelope glycoproteins of HIV-1 on processing and presentation of antigen to T cells. Cloned T cells were pre-incubated with soluble crude preparation of tetanus antigen for 4 h at 37 degrees C, irradiated, and used as APC (T-APC). These cells could present antigen, as assessed by the ability of the autologous cloned T cells to proliferate. Resting T cells and phytohaemagglutinin-activated T cell blasts from autologous PBL could not present tetanus antigen to the responder cloned T cells. Antigen presentation by T-APC was abrogated by treating cells with anti-HLA-DR but not by anti-HLA-DQ monoclonal antibodies; treatment of tetanus antigen-pulsed T-APC with anti-tetanus antibody also blocked the ability of these cells to induce proliferation in responder T cells. Antigen presentation by cloned T cells was by a chloroquine-resistant pathway. Pretreatment of T-APC with envelope glycoprotein of HIV-1, gp120, did not affect the proliferative responses of the responder T cells. These data suggest that gp120 does not inhibit the antigen-presenting function while suppressing antigen-specific responses.

Selective expression of class II MHC isotypes by MLC-activated human T lymphocytes

Although activated human T cells express class II MHC molecules, the biologic significance of this event is not understood. Using two-color flow cytometry, we have analyzed the expression of HLA-DR, -DQ, and -DP isotypes by T cells following activation by allogeneic lymphoblastoid B-cell lines. Within the CD3+ population, transient expression was observed at 1 day following initiation of culture, which preceded a dramatic and sustained increase around 6-7 days. DR expression was always highest, followed by DP and DQ with DP expression usually somewhat higher than DQ. At day 8, three populations were observed consisting of DR+DP+DQ+ (60%), DR+DP+ (69%), and DR+ (75%) T cells. Interestingly, DQ+ or DP+ but DR- T cells were not observed. These patterns of class II isotype expression were similar in CD2+, CD4+, and CD8+ subgroups and suggest that class II molecules are selectively expressed on T cells and may play a role in the regulation of T-cell responses to alloantigens.

Interleukin 2 responsive T cell clones from rheumatoid and normal subjects: proliferative responses to connective tissue elements

In vivo-activated interleukin 2 responsive T cell clones were generated from peripheral blood (PB) and synovial fluid (SF) of rheumatoid arthritis (RA) patients and from normal control PB. The specificity of these clones was assessed by measuring proliferation induced by the connective tissue elements (CTE) collagen types I and II, native and denatured, proteoglycans, and irrelevant control antigens. The cloned T cells from RA patients but not from normal subjects responded in vitro with proliferation to all CTE but not to control antigens purified protein derivative, ovalbumin, or lysozyme. Proliferation occurred in the presence and absence of accessory cells (AC), but the responses were consistently higher in the presence of AC. Antibodies to HLA-DR abrogated the proliferative response to CTE suggesting that DR expression was necessary for the induction of proliferation. These findings demonstrate the existence of clonable T cells responsive to CTE in PB and SF of RA patients. Expression of reactivity to CTE may contribute to the chronicity of the inflammation in RA.

Regulation of HLA-DR, DP, and DQ expression in activated T cells

Class II expression following restimulation of a population of T cells which had first been activated and then allowed to revert to small resting cells via IL-2 deprivation was followed on the cell surface and mRNA levels. Our interest was to determine the kinetics of class II expression during in vitro growth, the triggers which can induce them, and also whether similar or different patterns are observed for the three class II antigens, DR, DQ, and DP. The cells responded rapidly to restimulation with conditioned medium containing IL-2 as assessed by increased incorporation of [3H]TdR into DNA. Cell surface expression of HLA-DR reached peak levels by Day 1, and greater than 90% of the cells continued to express DR until Day 4, when the number of positive cells gradually began to decline. The expression of DP also increased, though maximum levels were not reached until Day 3, when it began to decline. The percentage of cells positive for DP was, however, consistently lower than that of DR. DQ was expressed by very few cells, but appeared to increase until Day 4 and then decline. Tac expression was dramatically up-regulated following IL-2 stimulation, remaining high until Day 4, and then declining more precipitously than any of the other antigens. Class I antigen expression was relatively constant during the entire culture period, though a slight decline was noted between Day 5 and 6 when proliferation and viability were at their lowest levels. On the molecular level, DR beta mRNA accumulation peaked at Day 3, then rapidly declined. Reculture in IL-2 on Day 4 resulted in transient reaccumulation of message. Study of DP beta and DQ beta mRNA demonstrated strong expression on Days 3 and 4 and no obvious up-regulation after restimulation with IL-2 on Day 4. The kinetics of Tac mRNA accumulation and the response to restimulation with IL-2 closely resembled that of DR. Finally we compared the ability of different signals to up-regulate class II mRNA and surface expression and to restimulate proliferation. Our results indicated that PHA was more effective then medium alone, but far less effective than was IL-2. PMA was essentially no different than medium alone.

T cells can present antigens such as HIV gp120 targeted to their own surface molecules

To trigger class II-restricted T cells, antigen presenting cells have to capture antigens, process them and display their fragments in association with class II molecules. In most species, activated T cells express class II molecules; however, no evidence has been found that these cells can present soluble antigens. This failure may be due to the inefficient capture, processing or display of antigens in a stimulatory form by T-cells. The capture of a soluble antigen, which is achieved by nonspecific mechanisms in macrophages and dendritic cells, can be up to 10(3) times more efficient in the presence of surface receptors, such as surface immunoglobulin on B cells that specifically bind antigen with high affinity. We asked whether T cells would be able to present soluble antigens that bind to their own surface molecules. Here we show that such antigens can be effectively processed and presented by both CD4+- and CD8+-bearing human T cells. This indicates that T cells are fully capable of processing and displaying antigens and are mainly limited in antigen presentation by their inefficiency at antigen capture.

HLA DPw1 class II molecules on human T cells

Human T cells express HLA class II antigens when activated by mitogens, alloantigens, or nominal antigens such as influenza virus. However, little is known about why they are expressed and the extent to which subsets of class II molecules (DR, DQ, and DP) are expressed. From studies with allocytotoxic antisera it is clear that DR and DQ molecules are expressed by T cells; cell surface expression of DP is more ambiguous because cellular typing methodologies are required. Alloreactive T-cell clones, specific for DPw1-associated antigens, were derived by limiting dilution in the presence of DPw1-positive stimulator PBLs and IL-2 and screened on panels of DPw1-positive and DPw1-negative PBL's in proliferation assays. Clones that recognized DPw1-associated determinants were then assayed for responses using as stimulators, irradiated T-cell clones derived from a DPw1-positive donor. Of seven DPw1-specific clones, one (TLC 56.26) was highly responsive to the alloantigens expressed on the stimulator T-cell panel. Six such clones gave a range of lower responses to T cells although capable of recognizing DP-associated determinants on PBL stimulators.