Analysis of T cell signaling by class I MHC molecules: the cytoplasmic domain is not required for signal transduction.

The structural requirements for signal transduction by class I major histocompatibility complex (MHC) molecules were examined. Native or mutant HLA-A2 or HLA-B27 constructs lacking most of their cytoplasmic domains were co-transfected with pSV2neo into Jurkat cells. Transfection of either native or mutant constructs resulted in a comparable expression of the gene products. Stimulation of transfectants expressing either native or truncated A2 or B27 molecules with specific mAb evoked an increase in [Ca2+]i upon crosslinking. Moreover, crosslinking native or truncated A2 or B27 induced IL-2 production upon co-stimulation with phorbol myristate acetate. These results confirm that crosslinking class I MHC molecules transduces an activation signal to human T cells. Effective signaling was observed when all but four of the intracytoplasmic residues were deleted, indicating that signal transduction does not require this portion of the molecule.

Activation of T lymphocytes by immobilized monoclonal antibodies to CD3. Regulatory influences of monoclonal antibodies to additional T cell surface determinants.

The effect of soluble or immobilized MAb directed at various additional surface proteins on the proliferation of highly purified T4 cells induced by two immobilized MAb to CD3, OKT3 and 64.1, was examined. High density 64.1 stimulated nearly all T4 cells to enter and progress through the cell cycle. Maximal T4 cell proliferation required stimulation with immobilized 64.1 throughout the length of the incubation and was not effected by any of the additional soluble or immobilized MAb employed. In contrast, low density immobilized 64.1 and all densities of immobilized OKT3 employed stimulated a minority of the cells to enter the cell cycle and proliferate. Immobilized MAb directed at CD2, class I major histocompatibility complex (MHC) encoded gene products or CD11a (LFA-1) dramatically enhanced the response, whereas soluble MAb directed at these determinants did not. Both immobilized and soluble MAb directed at CD5 and CD28 (Tp44) enhanced responses, but they were less effective than immobilized MAb to CD2, LFA-1 or HLA-A,B,C. Soluble anti-CD4 MAb inhibited responses somewhat, whereas immobilized anti-CD4 enhanced responses. Costimulation was observed when MAb to CD3 and class I MHC molecules but not CD2, LFA-1 or CD4 were immobilized to separate surfaces. The data suggest that when anti-CD3 stimulation is suboptimal, responses can be enhanced by MAb to CD5 or CD28 (Tp44) or by immobilized MAb to CD4, CD2, CD11a (LFA-1), or class I MHC encoded gene products. Although crosslinking of CD4, CD2, or CD11a with CD3 may be necessary for costimulation, immobilized MAb to CD3 and class I MHC molecules appear to deliver independent signals that result in enhanced T4 cell activation and proliferation.

Jun N-terminal kinase/stress-activated protein kinase (JNK/SAPK) is required for lipopolysaccharide stimulation of tumor necrosis factor alpha (TNF-alpha) translation: glucocorticoids inhibit TNF-alpha translation by blocking JNK/SAPK.

The adverse effects of lipopolysaccharide (LPS) are mediated primarily by tumor necrosis factor alpha (TNF-alpha). TNF-alpha production by LPS-stimulated macrophages is regulated at the levels of both transcription and translation. It has previously been shown that several mitogen-activated protein kinases (MAPKs) are activated in response to LPS. We set out to determine which MAPK signaling pathways are activated in our system and which MAPK pathways are required for TNF-alpha gene transcription or TNF-alpha mRNA translation. We confirm activation of the MAPK family members extracellular-signal-regulated kinases 1 and 2 (ERK1 and ERK2), p38, and Jun N-terminal kinase/stress-activated protein kinase (JNK/SAPK), as well as activation of the immediate upstream MAPK activators MAPK/ERK kinases 1 and 4 (MEK1 and MEK4). We demonstrate that LPS also activates MEK2, MEK3, and MEK6. Furthermore, we demonstrate that dexamethasone, which inhibits the production of cytokines, including TNF-alpha, significantly inhibits LPS induction of JNK/SAPK activity but not that of p38, ERK1 and ERK2, or MEK3, MEK4, or MEK6. Dexamethasone also blocks the sorbitol but not anisomycin stimulation of JNK/SAPK activity. A kinase-defective mutant of SAPKbeta, SAPKbeta K-A, blocked translation of TNF-alpha, as determined by using a TNF-alpha translational reporting system. Finally, overexpression of wild-type SAPKbeta was able to overcome the dexamethasone-induced block of TNF-alpha translation. These data confirm that three MAPK family members and their upstream activators are stimulated by LPS and demonstrate that JNK/SAPK is required for LPS-induced translation of TNF-alpha mRNA. A novel mechanism by which dexamethasone inhibits translation of TNF-alpha is also revealed.

Antigen presentation at the inflammatory site.

The introduction of antigen into tissues can induce an inflammatory response initiated by antigen-specific T lymphocytes. Central to this process is the recognition of antigen by specific T cells that cannot respond to intact antigen directly, but rather recognize antigenic fragments in association with gene products of the major histocompatibility complex (MHC) displayed by an antigen-presenting cell. To present antigen effectively, a cell must internalize antigen, process it to the immunogenic moiety, present the antigen in the context of a MHC molecule, and deliver various antigen-nonspecific signals required for T-cell activation. At the initiation of an immune response, the cells with the capacity to perform all of these functions are limited to a few specialized cell types, including monocytes/macrophages, dendritic cells, B cells, and Langerhans cells. Once the immune response has been initiated, however, cytokines and other factors, released by activated cells at the inflammatory site, stimulate a variety of changes in various cell types that alter their capacity to function as antigen-presenting cells and facilitate antigen-induced T-cell activation. Therefore, as the immunologically mediated inflammatory response evolves, a variety of changes occur within the local environment that enhance and/or modulate the capacity of T cells to recognize and respond to the inciting antigen. The purpose of this review is to catalog the changes in the function of antigen-presenting cells at inflammatory sites that might alter the nature of the immune response.

Structural analysis of class I MHC molecules: the cytoplasmic domain is not required for cytoskeletal association, aggregation and internalization.

The role of the cytoplasmic domain in a variety of the functional activities of class I MHC molecules has not been documented. To address this question, Jurkat cells were transfected with genes for either native class I MHC molecules or constructs in which all but four cytoplasmic amino acids were deleted. Antibody-induced aggregation and internalization of class I MHC molecules were examined by flow cytometry, and cytoskeletal association was determined by analysing the detergent-resistant fraction of FITC-labeled mAb to class I molecules. The results indicate that the truncated class I MHC molecules are comparable to native class I MHC molecules in the ability to move in the plane of the membrane and aggregate, to associate with the cytoskeleton and to undergo mAb-induced internalization at 37 degrees C. Thus, the cytoplasmic domain of class I MHC molecules is not required for these functional activities.

Dissection of the antigen presenting function of tissue cells induced to express HLA-DR by gamma interferon.

At sites of inflammation, cells that normally do not express class II products (la antigens) encoded by genes of the major histocompatibility complex such as fibroblasts and endothelial cells have been found to become Ia antigen positive, presumably as a result of the action of the T lymphocyte derived lymphokine gamma interferon (IFN-gamma). These cells may contribute to ongoing immunologically mediated inflammation by functioning as antigen presenting cells (APC). To test this hypothesis, fibroblasts and umbilical vein endothelial cells were treated with IFN-gamma to induce the expression of HLA-DR antigens. Both fibroblasts and endothelial cells became comparably HLA-DR positive in response to IFN-gamma. Despite this, endothelial cells but not fibroblasts became effective APC for resting T cells. HLA-DR positive fibroblasts could present antigen effectively to resting T cells; however, the HLA-DR negative endothelial cells were also present. These results indicate that expression of Ia is necessary but not sufficient for a cell to present antigen. The data also suggest that at inflammatory sites a number of cells may function in concert to promote antigen recognition by T lymphocytes.

Immobilized anti-CD3-induced T cell growth: comparison of the frequency of responding cells within various T cell subsets.

Human T cells can be divided into subsets based on the expression of CD29, CD45RA, CD45RO, LFA-3, or CD11a. It has been suggested that the subset of CD4+ T cells that expresses high densities of CD29, CD11a, CD45RO, and LFA-3 contains "memory" T cells, whereas the subset of cells that expresses CD45RA contains "naive" T cells. In order to obtain a more complete picture of the functional capacities of human naive and memory CD4+ and CD8+ T cell subsets, highly purified T cells were activated with a uniform stimulus and responses were examined in bulk cultures and under limiting dilution conditions. T cell activation was achieved with an immobilized mAb to the CD3 molecular complex, 64.1. In bulk cultures, immobilized 64.1 stimulated a vigorous response. Moreover, the number of cells entering the cell cycle, the magnitude of the [3H]thymidine incorporation, and the growth of the cells over 6 days in culture by naive and memory CD4+ T cells was comparable. To delineate the frequency of responsive cells in each subset more precisely, cells were cultured with immobilized 64.1 at limiting dilution and the precursor frequency of responding cells was assessed by examining wells microscopically for visible growth. Immobilized 64.1 was able to induce some T cells from each subset to grow in the complete absence of AC, when exogenous IL2 was present. The number of responding CD4+ and CD8+ cells was comparable. The percentage of naive cells responding in each population was approximately three times greater than the frequency of memory cells. IL4 could also support the growth of immobilized 64.1-activated CD4+ T cells, but the frequency of responding cells was much lower than that supported by IL2. The vast majority of the IL-4 responsive CD4+ cells resided within the naive cell subset. The data indicate that the response of CD4+ and CD8+ naive and memory T cell subsets to immobilized anti-CD3 depends on the density of responding cells. Naive T cells have an enhanced capacity to grow when cultured in the absence of other T cells or accessory cells. This ability may facilitate their expansion during primary immune responses.

MEK1 and the extracellular signal-regulated kinases are required for the stimulation of IL-2 gene transcription in T cells.

TCR engagement stimulates the activation of the protein kinase Raf-1. Active Raf-1 phosphorylates and activates the mitogen-activated protein (MAP) kinase/extracellular signal-regulated kinase kinase 1 (MEK1), which in turn phosphorylates and activates the MAP kinases/extracellular signal regulated kinases, ERK1 and ERK2. Raf-1 activity promotes IL-2 production in activated T lymphocytes. Therefore, we sought to determine whether MEK1 and ERK activities also stimulate IL-2 gene transcription. Expression of constitutively active Raf-1 or MEK1 in Jurkat T cells enhanced the stimulation of IL-2 promoter-driven transcription stimulated by a calcium ionophore and PMA, and together with a calcium ionophore the expression of each protein was sufficient to stimulate NF-AT activity. Expression of MEK1-interfering mutants inhibited the stimulation of IL-2 promoter-driven transcription and blocked the ability of constitutively active Ras and Raf-1 to costimulate NF-AT activity with a calcium ionophore. Expression of the MAP kinase-specific phosphatase, MKP-1, which blocks ERK activation, inhibited IL-2 promoter and NF-AT-driven transcription stimulated by a calcium ionophore and PMA, and in addition, MKP-1 neutralized the transcriptional enhancement caused by active Raf-1 and MEK1 expression. We conclude that the MAP kinase signal transduction pathway consisting of Raf-1, MEK1, and ERK1 and ERK2 functions in the stimulation IL-2 gene transcription in activated T lymphocytes.

Accessory cell-T cell interactions involved in anti-CD3-induced T4 and T8 cell proliferation: analysis with monoclonal antibodies.

The effect of monoclonal antibodies (Mab) directed at T cell and accessory cell (AC) surface molecules on OKT3-induced T4 and T8 cell proliferation was examined. Mab directed at nonpolymorphic class I (W6/32, MB40.5) and class II (L243) major histocompatibility complex (MHC)-encoded gene products, an epitope common to LFA-1, CR3, and the p150, 95 molecule (60.3), and a heterodimer present on monocytes (M phi) and activated T cells (4F2) inhibited M phi-supported OKT3-induced proliferation of both T4 and T8 cells. Moreover, an Mab directed at the CD4 molecule (66.1) inhibited OKT3-induced T4 but not T8 cell proliferation, whereas an Mab directed at the CD8 molecule (OKT8) inhibited T8 but not T4 cell responses. With the exception of 66.1, each inhibited OKT3-induced T cell proliferation when added as late as 15 hr after the initiation of culture. Inhibition could not be explained by competition for Fc receptors on the AC. A variety of other Mab including OKT11 and those directed at other HLA-DR and DQ determinants were not inhibitory. The inhibitory Mab were found to diminish T4 cell IL 2 production and IL 2 receptor expression. Consequently, IL 2 reversed some but not all of the Mab-mediated inhibition of T cell proliferation. In contrast to the effects noted with M phi-supported responses, 60.3 and 66.1 but neither L243 nor 4F2 inhibited OKT3-induced T4 cell proliferation supported by Ia- or IFN-gamma-treated Ia+ endothelial cells. None of the Mab tested inhibited T cell proliferation induced by the AC-independent stimuli OKT3 and phorbol myristate acetate (PMA) or calcium ionophore and PMA in the presence or absence of added AC. The data therefore suggest that the Mab inhibit OKT3-induced activation of T4 and T8 cells by preventing necessary interactions between AC and T cell surface proteins. Moreover, the results suggest that different arrays of interaction molecules are involved in OKT3-induced T cell proliferation depending on the nature of the AC and the responding T cell subset.

Association of various T cell-surface molecules with the cytoskeleton. Effect of cross-linking and activation.

The association of various surface molecules with the cytoskeleton in resting peripheral blood T cells was examined by assaying the capacity of detergent to solubilize them. Cytoskeletal association was assessed by staining T cells with a fluorescein-conjugated mAb, resuspending the cells in buffer with or without the nonionic detergent, NP-40, and determining the capacity of the detergent to remove the mAb from the cell surface by using flow microfluorimetry. MAb to CD3, the TCR, and CD45 were completely removed from the cell surface by detergent. In contrast, 7 to 50% of mAb to CD2, CD4, CD8, CD11a/CD18, CD44, and class I MHC molecules were resistant to detergent solubilization, demonstrating that a fraction of these molecules was constitutively associated with the cytoskeleton. The effect of cross-linking these molecules with a mAb and a secondary goat anti-mouse Ig was also examined. Cross-linking CD3 or the TCR induced cytoskeletal association of these molecules. In addition, cross-linking increased the fraction of CD2, CD4, CD8, CD11a/CD18, CD44, and class I MHC molecules that was associated with the cytoskeleton. In contrast, cross-linking CD45 did not induce an association with the cytoskeleton. The effect of T cell activation on the cytoskeletal association of these molecules was also examined. Stimulation of T cells with ionomycin and PMA greatly increased the expression of CD2 and CD44 without increasing the number of molecules associated with the cytoskeleton. Stimulation with PMA alone had no effect on the expression of CD2 or CD44, but was found to decrease the percentage of these molecules associated with the cytoskeleton. Stimulation with ionomycin and PMA increased both the expression of class I MHC molecules and the number of molecules associated with the cytoskeleton proportionally. Finally, stimulation with ionomycin and PMA decreased CD3 expression, but increased the number of CD3 molecules associated with the cytoskeleton. The data establish a pattern of cytoskeletal association of T cell-surface molecules that is a characteristic of each individual molecule and can be altered by cross-linking. Moreover, the results indicate that the association of various T cell surface molecules with the cytoskeleton is a dynamic process that varies with the state of activation and or differentiation of the cells.

Antigen presentation by interferon-gamma-treated endothelial cells and fibroblasts: differential ability to function as antigen-presenting cells despite comparable Ia expression.

The effect of interferon-gamma (IFN-gamma) on endothelial cell (EC) and fibroblast (FB) class II major histocompatibility complex (MHC) gene product expression and antigen presenting ability was examined. Control FB did not express class II MHC gene products, whereas a small (less than 1%) population of passaged EC expressed class II gene products. IFN-gamma induced a comparable density of HLA-DR expression on nearly all EC and FB. IFN-gamma-treated EC and FB also expressed HLA-DP but at a lower density, whereas HLA-DQ expression was barely detectable on either cell type. Control FB were not able to stimulate allogeneic T4 cell DNA synthesis or function as antigen-presenting cells (APC). Control EC were also unable to stimulate allogeneic T4 cell DNA synthesis unless large numbers of stimulator cells were used. Small numbers of IFN-gamma-treated EC were able to stimulate allogeneic T4 cell DNA synthesis, whereas larger numbers were markedly more effective than control EC. In contrast, IFN-gamma-treated FB were ineffective stimulators of allogeneic T4 cell DNA synthesis. IFN-gamma-treated FB were able to present the exogenous antigen SKSD to autologous but not allogeneic T4 cells, but they were extremely inefficient APC. The inability of IFN-gamma-treated FB to function as APC could not be explained by FB-mediated immunosuppression, Ia density, or HLA-DQ expression. This limited capacity of IFN-gamma-treated FB to participate in Ia-restricted functional interactions with T4 cells correlated with a similar diminished capacity to support nonspecific mitogen-induced proliferation of T4 cells before IFN-gamma-induced Ia expression. This accessory cell function was not enhanced by IFN-gamma treatment. Monocytes syngeneic to the responding T4 cells but not interleukin 1 (IL 1) permitted IFN-gamma-treated FB but not control FB to stimulate allogeneic T4 cell DNA synthesis, but they remained markedly less effective stimulators than monocytes. Moreover, IFN-gamma-treated FB were effective stimulators of alloprimed T4 cells, in contrast to their inability to stimulate fresh T4 cells. Furthermore, monocytes and IFN-gamma-treated FB were comparably effective stimulators of alloreactive T cell lines. These data suggest that accessory cells perform functions unrelated to Ia and IL 1 that are necessary for mitogen-, alloantigen-, and antigen-induced proliferation of freshly isolated T cells. Monocytes and EC effectively perform this function, but FB do not. This accessory cell function does not seem to be as important for the activation of primed T cells.

Accessory cell independent proliferation of human T4 cells stimulated by immobilized monoclonal antibodies to CD3.

The capacity of the monoclonal antibodies (Mab) 64.1 and OKT3 directed at CD3 molecules to induce T4 cell proliferation and interleukin 2 (IL 2) production was examined. Each was tested in soluble form or was immobilized by adhering it to the wells of plastic microtiter wells. Soluble anti-CD3 did not induce proliferation of accessory cell (AC)-depleted T4 cells. In contrast, immobilized anti-CD3 induced T4 cell IL 2 production and proliferation in the complete absence of AC. When T4 cells were stimulated with high density immobilized anti-CD3, responses did not require AC, IL 2, or Mab directed at the Tp44 molecule (9.3). In contrast, responses stimulated by lower densities of immobilized anti-CD3 were enhanced by IL 2, AC, and 9.3, and with even lower densities of immobilized anti-CD3 proliferation, required these additional signals. A variety of other immobilized Mab directed at T cell surface proteins including class I major histocompatibility complex encoded gene products, CD2, CD5, 4F2, and Tp44, did not induce proliferation even in the presence of IL 2. Anti-CD4 Mab (66.1) inhibited immobilized anti-CD3-stimulated T4 cell responses, with a greater degree of inhibition noted when lower densities of immobilized anti-CD3 were used to stimulate T4 cells. The data demonstrate that stimulation of T4 cells by anti-CD3 is completely AC independent when the antibody is immobilized onto a surface. Furthermore, the results indicate that maximal stimulation requires multiple interactions with anti-CD3 without internalization of the CD3 molecule. The observation that additional signals are required to support T4 cell proliferation when the density of immobilized anti-CD3 is diminished suggests that these are necessary only when insufficient interactions with the CD3 molecule have occurred to transmit a maximal activation signal to the cell. Finally, the results indicate that anti-CD4 provides a direct inhibitory signal to the T4 cell, the effect of which is inversely proportional to the intensity of the activation signal.

Dissection of defective antigen presentation by interferon-gamma-treated fibroblasts.

The capacity of interferon-gamma (IFN-gamma)-treated HLA-DR expressing human dermal fibroblasts (FB) to function as antigen-presenting cells (APC) was examined. FB were cultured with 250 U/ml IFN-gamma for 4 days to induce HLA-DR expression. Peripheral blood monocytes (M phi), FB, or IFN-gamma-treated FB from the same donor were then cultured overnight with or without the recall antigen streptokinase streptodornase (SKSD), and their capacity to stimulate autologous T4 cell DNA synthesis was examined. SKSD-bearing M phi stimulated T4 cell proliferation, whereas antigen-bearing HLA-DR (+) FB did not. Even after fixation with paraformaldehyde to eliminate metabolic activity, SKSD-bearing M phi, but not FB, were able to function as APC. However, when HLA-DR (-) endothelial cell (EC) or autologous or HLA-D-mismatched M phi were added to the cultures, antigen-pulsed IFN-gamma-treated FB and M phi were comparably effective stimulators of autologous T4 cell DNA synthesis. Antigen recognition by the T4 cell was restricted by the class II major histocompatibility complex (MHC)-encoded gene products expressed by the IFN-gamma-treated FB and was unrelated to the class I or II MHC-encoded gene products expressed by the additional cell type. EC-promoted T4 cell DNA synthesis induced by antigen-bearing IFN-gamma-treated FB was inhibited by 60.3, a monoclonal antibody directed at an epitope common to LFA-1, CR3, and the p150,95 molecule. Inhibition caused by 60.3 was completely reversed by the addition of IL 2 to the cultures. Antigen presentation by IFN-gamma-treated FB was also enhanced somewhat by IL 1, IL 2, or monoclonal antibody directed at Tp44 (9.3). However, each of these additions alone promoted T cell proliferation less effectively than EC and resulted in responses that were smaller than those triggered by antigen-bearing M phi. The data suggest that IFN-gamma-treated FB take up and process antigen effectively, but lack an accessory cell property necessary for antigen-induced T4 cell IL 2 production and proliferation.

Regulatory role of microfilaments in the induction of T4 cell proliferation and interleukin 2 production.

The role of microfilaments in human T4 cell proliferation and lymphokine production triggered via various pathways of activation was examined by investigating the effects of cytochalasins on these responses. The data demonstrate that the effects of cytochalasins vary depending on the nature of the stimulus and on the concentration of the cytochalasin. Concentrations of cytochalasin that would be expected to bind both the low and high affinity binding sites (5-20 microM), that represent cytosolic and surface actin filaments, respectively inhibited T4 cell proliferation regardless of the stimulus. T4 cell proliferation stimulated by antigen-bearing APC or anti-CD3 was inhibited much more markedly than responses stimulated by ionomycin and PMA. In contrast, concentrations of cytochalasin expected to bind only high affinity binding sites (0.125-1 microM), represented by surface actin filaments, enhanced T4 cell proliferation and interleukin 2 production stimulated by mAb to CD2, CD3, or class I major histocompatibility complex (MHC) molecules, but not those induced by mAb to the T cell receptor, paraformaldehyde fixed, or viable antigen-bearing APC, allogeneic APC, or ionomycin and PMA. The enhancing effect of cytochalasins on responses stimulated by cross-linking class I MHC molecules was studied in detail. Enhancement of T4 cell proliferation induced in this manner required that cytochalasin B was present between 4 and 18 hr of culture, but not before or after. The data demonstrate that T cell microfilaments play a number of roles in determining the magnitude of T cell responses induced by engaging specific cell surface receptors and imply that different components of the microfilament system exert opposing intrinsic regulatory effects on T cell function.

Antigen presentation by cells that are not of bone marrow origin.

T cells do not see antigen directly, but rather recognize antigen only when displayed by an antigen-presenting cell (APC). APC take up, internalize, and degrade antigen and present the relevant antigenic fragment in association with class II major histocompatibility complex (MHC) molecules to antigen-specific T cells. In addition to presenting the antigenic fragment-MHC complex to T cells, APC must also provide a variety of antigen-nonspecific influences to T cells for antigen recognition to result in T-cell activation. These influences include the effects of various cytokines and signals transmitted by a number of nonspecific receptor-ligand interactions. Traditionally, cells of bone marrow origin that express class II MHC molecules, such as mononuclear phagocytes and B lymphocytes, have been regarded as the only APC. Recently, however, it has been suggested that under various physiologic and pathologic conditions, other tissue cells may develop the capacity to express class II MHC molecules and function as APC. The capacity of these cells to function as APC, however, varies widely, depending on the cell type examined. One determinant of the capacity of a cell to function as an APC appears to be its ability to provide antigen-nonspecific signals. Cells with limited abilities to provide these signals have limited APC function. Indeed, it has been suggested that such cells may induce antigen-specific tolerance. In contrast, cells with the capacity to deliver these signals function as fully competent APC. The functional phenotype of the responding T cell may also vary, depending on the nonspecific signals provided by the APC. Some APC may preferentially stimulate antigen-specific T cells that promote the immune response, whereas others promote the activation of suppressor T cells, thereby limiting the response. Thus, it is likely that cells that are not of bone marrow origin play a role in normal immune responses. Moreover, they may also be important in the development of certain forms of autoimmunity.

Engagement of class I major histocompatibility complex molecules by cell surface CD8 delivers an activation signal.

Recent evidence has demonstrated that cross-linking class I major histocompatibility complex (MHC) molecules on human T cells with monoclonal antibodies (mAb) triggers T cell activation. The only known natural ligand for MHC class I molecules is CD8. Therefore, the possibility that CD8+ T cells might provide activation signals to other T cells by engaging MHC class I molecules was examined by culturing CD4+ peripheral blood T cells with Chinese hamster ovary cells (CHO) cells that had been transfected with the alpha chain or alpha and beta chains of CD8 and assessing interleukin (IL)-2 production. CD4+ T cells did not secrete IL-2 when cultured alone, with control or CD8+ CHO cells. In contrast, CD4+ T cells produced IL-2 when cultured with CD8+ CHO cells and co-stimulated with phorbol myristate acetate (PMA) or mAb to CD3 or CD28. PMA stimulated substantially less IL-2 when control CHO cells were employed and the mAb to CD3 and CD28 did not stimulate IL-2 production in the presence of control CHO cells. The co-stimulatory activity of CD8+ CHO cells was completely eliminated by mAb to CD8 or MHC class I molecules. The data demonstrate that CD8 can interact with MHC class I molecules expressed on T cells and deliver a costimulatory signal that increases IL-2 production. Thus, engagement of MHC class I molecules by its natural ligand, CD8, provides an activation signal to T cells. Under some circumstances, such interactions may amplify the responses of T cells.

T4 cell activation by immobilized phytohemagglutinin: differential capacity to induce IL-2 responsiveness and IL-2 production.

Soluble mitogens, such as PHA induce accessory cell (AC)-dependent T cell proliferation. One function of the AC is to create a stimulatory matrix. Therefore, experiments were carried out to determine whether PHA immobilized onto microtiter plates could stimulate T cells in the absence of AC. Peripheral blood T4 cells were cultured under limiting dilution conditions with either soluble or immobilized PHA with or without rIL-1 beta, rIL-2, r-TNF-alpha, an anti-CD28 mAb (9.3), or irradiated EBV-transformed B cells as AC. The frequency of proliferating T4 cells was assessed by examining wells microscopically, and the frequency of T4 cells producing IL-2 was assessed by examining the ability of supernatants to support CTLL-2 proliferation. The percentage of T4 cells growing and producing IL-2 was determined by a maximum likelihood procedure. Immobilized, but not soluble, PHA induced a mean of 20.0 +/- 2.6% of T4 cells to grow in the complete absence of AC in medium supplemented with rIL-2. Whereas rIL-1 beta, rTNF-alpha, and 9.3 were unable to support T4 cell growth in the absence of rIL-2, each enhanced the percentage of T4 cells responding to immobilized PHA in the presence of rIL-2. In contrast, both soluble and immobilized PHA were unable to induce T4 cell IL-2 production in the absence of AC, even when cultures were supplemented with rIL-1 beta or 9.3. In the presence of AC, a small percentage of T4 cells (5.4 to 11.7%) was stimulated to produce detectable amounts of IL-2 by either immobilized or soluble PHA. Moreover, in the presence of AC, a very small population (approximately 1%) of PHA-stimulated T4 cells proliferated without supplemental rIL-2. The data indicate that a matrix of immobilized PHA is sufficient for some T4 cells to be activated to respond to IL-2, whereas others require additional signals provided by rIL-1 beta, rTNF alpha, 9.3, or AC. In contrast, neither soluble nor immobilized PHA is sufficient to induce T cell IL-2 production. This response requires signals provided by intact AC.

Enhancement of antigen- and mitogen-induced human T lymphocyte proliferation by tumor necrosis factor-alpha.

The capacity of human recombinant tumor necrosis factor-alpha (rTNF alpha) to modulate human T cell proliferation was examined. To examine the effect of rTNF alpha on the responding T cell directly, T cell activation was studied in the absence of viable accessory cells (AC). Highly purified AC-depleted peripheral blood T4 or T8 cells were stimulated with immobilized monoclonal antibodies to the cluster of differentiation (CD)3 molecular complex, an AC-independent stimulus. rTNF alpha augmented anti-CD3-stimulated T4 and T8 cell proliferation. The capacity of rTNF alpha to enhance T cell proliferation varied inversely with the density of immobilized anti-CD3 and the number of responding cells in each culture. The capacity of rTNF alpha to enhance antigen-induced T4 cell proliferation was also examined. Antigen-bearing paraformaldehyde-fixed antigen-presenting cells induced modest T4 cell proliferation when cultured in flat-bottomed wells; this response was enhanced by rTNF alpha. The results demonstrate that rTNF alpha has direct effects on T cells, facilitating their capacity to proliferate in response to mitogens and antigens. These data indicate that rTNF alpha may play an immunoregulatory role, enhancing the proliferation of T lymphocytes.