Staphylococcal enterotoxins direct and trigger CTL killing of autologous HLA-DR+ mononuclear leukocytes and freshly prepared leukemia cells

Attempts have been made to induce cytolytic T cells to kill target cells that do not express the appropriate target molecules by crosslinking the T cells and the target cells in various ways. One successful strategy has been to use heteroconjugates or bispecific monoclonal antibodies reacting with T cell molecules with activating properties (e.g., mab directed to CD3/TCR) and target cell surface antigens. In this report we show that Staphylococcal enterotoxins (SE) direct human T lymphocytes to execute cytotoxicity toward MHC class II-expressing Raji cells, but not against MHC class II-deficient Raji mutant RJ 2.2.5. Both HLA-DR+ and HLA-DR- effector T lymphocytes are effective in the killing of Raji cells coated with SE. The Staphylococcal enterotoxin-dependent cell-mediated cytotoxicity (SDCC) is a rapid T lymphocyte-mediated cytolytic mechanism killing the targets within an hour of incubation. HLA-DR+ target cells are sensitized to be killed within minutes of incubation with picomolar concentrations of SE. SE-sensitized Raji cells remain targets for SDCC after overnight culture at 37 degrees C, demonstrating that the sensitive state is relatively stable. SEA- and SEB-selective cytolytic T cell lines were established to illustrate the clonal variability of SDCC effectors with respect to SE specificity. We also demonstrate that autologous monocytes and activated T lymphocytes as well as B lymphocytes and freshly prepared HLA-DR+ leukemic cells are excellent targets in SDCC.     

Differential recognition of tumor-derived and in vitro Epstein-Barr virus-transformed B-cell lines by fetal calf serum-specific T4-positive cytotoxic T-lymphocyte clones

Two interleukin-2 (IL-2)-dependent cytotoxic T-cell clones were obtained by limiting dilution from a lymphocyte culture stimulated in vitro with the autologous Epstein-Barr virus-transformed lymphoblastoid cell line (LCL) in the presence of fetal calf serum (FCS). Both clones uniformly had a T3+, T4+, Dr+ phenotype and lysed autologous B blasts, the autologous LCL, and allogeneic B cell lines sharing major histocompatibility complex (MHC) class II antigens. The cytotoxic function was triggered by FCS-derived components. There was no killing if the sensitive targets were cultured in serum-free medium or in medium supplemented with human serum. Sensitivity to lysis could be restored by exposing the targets to FCS for at least 6 hr at 37 degrees C. Monoclonal antibodies directed to T-cell-specific surface antigens and MHC class II antigens inhibited lysis with different efficiencies depending on the target cell origin. Killing of Burkitt's lymphoma (BL)-derived cell lines was blocked more easily than killing of LCLs. LCLs but not BL lines induced proliferation of the T-cell clones in the absence of exogenous IL-2. The differences were not related to quantitative variations in the expression of MHC class II antigens, indicating that BL lines differ from LCLs in other cell membrane properties that may influence antigen presentation. The results suggest that the affinity of effector/target binding, which is probably influenced by the concentration of antigenic determinants expressed on the target cell membrane, determines whether proliferative responses or cytotoxicity are induced in the antigen-recognizing T cells.     

DR antigens expressed on tumor cells do not contribute to the blastogenetic response of autologous T cells

Summary Tumor cell suspensions prepared from surgical specimens were characterized for cellular composition and reactivity with monoclonal antibodies detecting T lymphocytes, monocytes, and the monomorphic determinants of DR molecules (antigens encoded by the D region of the major histocompatibility complex in man). About half the adenocarcinoma preparations contained tumor cells which expressed DR antigens. Lymphocytes of certain patients were stimulated in vitro by the autologous tumor cells, and this was independent of the expression of DR antigens on the tumor cells. In addition, pretreatment of the stimulator tumor cells with anti-DR Mab (monoclonal antibody) had only marginal effect on their stimulatory potentialIn contrast, when the same tumor cells were used as stimulators of allogeneic lymphocytes, proliferation was more often seen with DR-positive tumors and the reaction was often inhibited by the anti-DR Mab treatment. There were exceptions, however, which suggest that other DR antigens not detected by the reagents used may have been expressed on these cells. The allostimulatory capacity of the tumor cells was usually weak and did not occur with all responder lymphocytes. It is important to note that stimulation of autologous lymphocytes could occur with tumor preparations that did not elicit allogeneic response.Thus, the in vitro stimulation of autologous blood-derived T cells by suspensions of unpropagated cells separated from solid tumors reflects the sensitization state of the patients against their tumor cells.     

Interleukin 1 can replace monocytes for the specific human B-cell response to a particulate antigen

It is shown that the anti-trinitrophenyl (TNP) response of human B cells to trinitrophenyl polyacrylamide beads (TNP-PAA) is monocyte dependent. This response is abolished by extensive adherent cell depletion and restored by the addition of monocytes. The optimal response is obtained with 3% monocytes, higher numbers being suppressive. Supernatants from muramyl dipeptide (MDP)-activated monocytes can restore the response of monocyte-depleted preparations even when cells are cultured at suboptimal concentration. A partially purified preparation of interleukin (IL-1) has a comparable restorative ability. The following arguments suggest that monocytes do not function as antigen-presenting cells for this particulate antigen: (i) anti-genpulsed monocytes induce neither an anti-TNP response nor a specific T-cell proliferative response; (ii) allogeneic monocytes function as well as autologous monocytes to restore the response of nonadherent cells; (iii) HLA-DR-negative cells from the human leukemia cell line K562 can replace monocytes for this response. Monocyte supernatants do not replace T cells for the response of B-enriched lymphocytes, showing that T cells are directly involved in B-cell activation.     

Superantigen-mediated human monocyte-T lymphocyte interactions are associated with an MHC class II-, TCR/CD3-, and CD4-dependent mobilization of calcium in monocytes.

The present study was designed to examine the potential involvement of calcium ions as second messengers in the mediation of the staphylococcal enterotoxin A (SEA)/MHC class II-induced activation of human monocytes. Treatment of monocytes with a monomeric form of SEA failed to induce detectable changes in the level of intracellular calcium in either monocytes or THP-1 cells. However, cross-linking of SEA with biotin-avidin induced a rapid and transient increase in calcium levels in monocytes and in INF-gamma-treated THP-1 cells. This artificial cross-linking system was reproduced by natural physiologic ligands expressed on the surface of T lymphocytes. Delayed, transient, and concentration (cell as well as toxin)-dependent increases in the cytoplasmic level of free calcium in SEA-treated monocytes were observed upon the addition of autologous resting T cells or purified CD4+ cells, but not of CD8+ cells, B cells, or neutrophils. Antibodies against MHC class II Ag, TCR/CD3, and CD4 molecules inhibited the SEA-dependent interaction between monocytes and T cells as indicated by significant decreases in the rise of calcium levels observed in monocytes. Anti-CD8 and anti-class I antibodies did not affect the interaction between the monocytes and the T cells and failed to alter the calcium response. Taken together, these results suggest that the SEA-induced, T cell-dependent calcium mobilization in monocytes requires physical interactions between SEA-MHC class II, TCR/CD3, and CD4 molecules. The ability to mediate a T cell-dependent calcium increase in monocytes was shared by several enterotoxins including staphylococcal enterotoxin B and toxic shock syndrome toxin-1. The characteristics of the SEA-mediated calcium mobilization in monocytes strongly support the hypothesis that this response is an integral part of the signal transducing machinery linked to MHC class II molecules.     

Regulatory role of monomorphic and polymorphic determinants of HLA class I antigens in the proliferation of T cells stimulated by autologous and allogeneic B and T lymphoid cells

Monoclonal antibodies (mAb's) to monomorphic and polymorphic determinants of HLA Class I antigens were shown to inhibit proliferation of T cells stimulated with autologous and allogeneic B and T lymphocytes. Inhibition of proliferative responses was lower when T cells were used as stimulators than when B cells were used. The inhibitory activity was similar for mAb's to monomorphic and polymorphic determinants of HLA Class I antigens, suggesting that the density of antigen-antibody complexes on the cell membrane does not play a major role in the phenomenon. The anti-HLA Class I mAb's exerted their inhibitory effect at the level of both the responding and the stimulating cells. Addition of exogenous interleukin 2 to the mixed cultures did not affect the mAb-mediated inhibition.     

Human cytotoxic T cell clones directed against herpes simplex virus-infected cells. I. Lysis restricted by HLA class II MB and DR antigens

In contrast to general findings that mouse and human cytotoxic T lymphocytes (CTL) are restricted in cytotoxic activity by major histocompatibility complex (MHC) class I antigens, we previously found that some herpes simplex virus (HSV) type I-infected cells that shared no HLA class I antigens with the HSV-1-stimulated lymphocytes were lysed. In this study, we addressed the question of the role of HLA antigens in human T cell-mediated lysis of HSV-1-infected cells by generating clones of HSV-1-directed CTL from two HSV-1-seropositive individuals. CTL clones that lysed autologous HSV-1-infected lymphoblastoid cell lines (LCL), but not natural killer-sensitive K562 cells or uninfected or influenza virus-infected LCL, were tested for cytotoxicity against a panel of allogeneic HSV-1-infected LCL. Clone KL-35 from individual KL lysed only HSV-1-infected LCL sharing the HLA class II MB1 antigen with KL. With all four CTL clones isolated from individual PM, only HSV-1-infected LCL sharing DR1 with PM were lysed. Monoclonal antibody s3/4 (directed against MB1 ), but not TS1/16 or B33 .1 (directed against a DR framework determinant), blocked lysis of autologous HSV-1-infected cells by KL-35. In contrast, B33 .1, but not s3/4, blocked lysis of autologous HSV-1-infected cells by the PM CTL clones but not by KL-35. Together, these results indicate that our five human CTL clones which are directed against HSV-1-infected cells, and which are all OKT3+, OKT4+, OKT8-, are restricted in lytic activity by HLA class II MB and DR antigens. These results suggest that the HLA D region-encoded class II antigens may be important in the recognition and destruction of virus-infected cells by human CTL.     

Presentation of Candida albicans and purified protein derivative soluble antigens by Epstein-Barr virus-transformed human lymphoblastoid B-cell lines

Cells other than the macrophage can function as antigen-presenting cells (APCs). These class II-bearing accessory cells include dendritic cells, epidermal Langerhans cells, B cells, murine B-cell tumors, and human Epstein-Barr virus-transformed lymphoblastoid cell lines (EBV-LCL). We investigated the ability of EBV-LCL to present two soluble antigens, Candida albicans and purified protein derivative of tuberculin (PPD). The EBV-LCL derived from B cells of two different individuals can present both antigens to bulk cultures of autologous antigen-primed peripheral blood lymphocytes. The responses of PPD-reactive T-cell clones were weaker to PPD when presented by EBV-LCL than by PBL-APCs, with some clones responding only to PPD presented by PBL-APCs. This suggests that EBV-LCL are not equivalent to PBL monocytes in APC function, and that expression of class II major histocompatibility complex antigen is not sufficient in enabling antigen-presenting capability.     

Accessory cell function of human endothelial cells. I. A subpopulation of Ia positive cells is required for antigen presentation

The expression of class I and class II HLA antigens on preparations of human endothelial cells, isolated from umbilical cord veins, was investigated by immunofluorescence. While virtually all endothelial cells expressed class I antigens, less than 1% were positive for class II antigens, as detected with a panel of 10 different monoclonal antibodies. Antigen specific T cell lines proliferated in response to mumps antigen in the presence of endothelial cells or blood monocytes from HLA-DR matched donors. However, these T cell lines failed to respond in the absence of accessory cells or when accessory cells from HLA-D-region mismatched cord donors were used. The ability of both monocytes and endothelial cells to present antigen was abolished by treatment of the cells with monoclonal antibodies specific for either class I or class II HLA antigens plus complement. Similar treatment with monoclonal antibodies specific for monocytes greatly reduced antigen presentation by endothelial cells. These results indicate that preparations of endothelial cells contain a subpopulation of Ia positive cells, distinct from monocytes, which are required for antigen presentation.     

Depletion of human NK cells with monoclonal antibodies allows the generation of cytotoxic T lymphocytes without NK-like cells in mixed cultures

In vitro stimulation of human mononuclear cells with x-irradiated autologous lymphoblastoid cell line (LCL) or allogeneic normal cells in mixed leukocyte cultures (MLC) was previously shown to result in the generation of OKT3+ OKT8+ cytotoxic T lymphocytes (CTL) lytic for allogeneic and autologous LCLs and also of natural killer- (NK) like cells that are OKT3- and primarily OKT8- and are lytic for HLA- NK-sensitive K562 cells. The origin of the NK-like cells was not previously known because, although the majority of fresh human NK cells react with monoclonal antibodies OKM1 and B73.1, lymphocytes bearing these markers are not detected several days after the onset of MLC, when NK-like cells are present. In this study, experiments were undertaken to determine whether NK-like cells generated after stimulation with x-irradiated pooled allogeneic normal cells (poolx) or with autologous LCL are derived from cells expressing antigens reactive with monoclonal antibodies OKM1 or B73.1, which react with fresh NK cells. Mononuclear cells, depleted of monocytes, were stained with OKM1 or B73.1 and fluorescein-labeled goat anti-mouse IgG. Lymphocytes depleted of OKM1+ or B73.1+ cells, by fluorescence-activated cell sorting, and lymphocytes that were stained but not sorted were stimulated for 7 days with either poolx or autologous LCL. The generation of NK-like activity was decreased at least 90% after depletion of cells reactive with OKM1 or B73.1, whereas the generation of CTL against autologous and allogeneic LCL was minimally affected. These findings show that NK-like cells generated in MLC are derived from cells that express the phenotype of fresh NK cells (OKM1+ or B73.1+) and that CTL can be generated in cultures in which relatively little NK-like activity is concomitantly detected, by depleting NK cells with monoclonal antibodies before stimulation.     

Expression of HLA-DR, MB, MT and SB antigens on human mononuclear cells: identification of two phenotypically distinct monocyte populations

The expression of HLA-DR, SB, MB, and MT antigens in different populations of human mononuclear cells was investigated with the use of monoclonal antibodies that recognize distinct human Ia-like antigens. Our results indicate that in man, as previously reported in other species, two phenotypically distinct populations of monocytes or macrophages can be identified on the basis of expression of Class II MHC antigens. Virtually all circulating monocytes displayed determinants associated with HLA-DR, SB, and MT. In addition, a subpopulation of human monocytes expressed MB/DS-associated antigens, as detected with monoclonal antibodies specific for MB1, MB3, and DS-framework determinants. Most B lymphocytes expressed antigens associated with HLA-DR, and the specificities SB2, SB3, MB1, MB3, MT2, and MT3 were also present. Resting T lymphocytes were unreactive with antibodies that recognize all of the Class II MHC antigens tested. T lymphocytes activated by soluble antigen or alloantigens, and expanded in culture, expressed DR, SB, MB, and MT. The majority of the MB/DS+ cells present in the adherent population were monocytes, because they were phagocytic and had the monocyte-specific marker 63D3. The rest of the cells were not identified. They are likely to include mostly B lymphocytes. The presence of other cells, such as dendritic cells, in this subset needs to be determined.     

The evolution of MHC restrictions in antigen recognition by T cells in a haploidentical bone marrow transplant recipient

We have longitudinally followed the major histocompatibility complex (MHC) restrictions that govern the response of T lymphocytes to specific Ag in a child with severe combined immunodeficiency who was successfully transplanted by using T cell depleted haploidentical maternal bone marrow cells and immunized shortly afterwards with tetanus toxoid (TT) Ag. In the first year post-transplant, monocytes were of both donor and recipient origin whereas T and B cells were of donor origin. Three years after transplant, all monocytes and T and B cells were of donor origin. T lymphocytes taken from the child at that time and depleted in vitro of alloreactivity to paternal Ag proliferated in response to TT presented by maternal as well as paternal monocytes. A TT-specific T cell line established from these cells in the presence of maternal monocytes cooperated with maternal but not with paternal monocytes, whereas a TT-specific T cell line established in the presence of paternal monocytes cooperated with paternal but not with maternal monocytes and with monocytes derived from a paternal uncle who shared the haplotype inherited by the recipient from her father. These results show that long-term memory T cells restricted to recipient MHC Ag not shared with the bone marrow donor continue to circulate long after the disappearance of accessory cells of recipient origin. These T cells could potentially participate in a secondary immune response because they were shown to recognize TT presented by recipient fibroblasts induced to express class II MHC molecules following treatment with IFN-gamma.     

Cloned human cytotoxic T lymphocyte (CTL) lines reactive with autologous melanoma cells. I. In vitro generation, isolation, and analysis to phenotype and specificity

Activation of peripheral blood lymphocytes (PBL) from a melanoma patient either in secondary MLC in which EBV-transformed B cells from the cell line JY were used as stimulator cells, or by co-cultivation with the autologous melanoma cells in a mixed leukocyte tumor cell culture (MLTC) resulted in the generation of cytotoxic activity against the autologous melanoma (O-mel) cells. From these activated bulk cultures four cloned cytotoxic T lymphocyte (CTL) lines were isolated. The CTL clone O-1 (T3+, T4+, T8-, OKM-1-, HNK-, and HLA-DR+), and O-36 (T3+, T4-, T8+, OKM-, HNK-, and HLA-DR+) were obtained from MLC, whereas the CTLC clones O-C7 (T3+, T4+, T8-, OKM-1-, HNK-, and HLA-DR+) and O-D5 (T3+, T4-, T8+, OKM-1-, HNK, and HLA-DR+) were isolated from autologous MLTC. All four CTL clones were strongly cytotoxic for O-mel cells but failed to lyse autologous fibroblasts and autologous T lymphoblasts. Moreover, the CTL clones lacked NK activity as measured against K562 and Daudi cells. Panel studies indicated that the CTL clones also killed approximately 50% of the allogeneic melanoma cells preferentially, whereas the corresponding T lymphoblasts were not lysed. Monoclonal antibodies against class I (W6/32) and class II (279) MHC antigens failed to block the reactivity of the CTL clones against O-mel and allogeneic melanoma cells, indicating that a proportion of human melanoma cells share determinants that are different from HLA antigens and that are recognized by CTL clones. In contrast to the CTL clones isolated from MLTC, the clones obtained from MLC also lysed JY cells, which initially were used as stimulator cells. The reactivity of O-36 against JY could be inhibited with W6/32, demonstrating that this reactivity was directed against class I MHC antigens. These results suggest that the lysis of O-mel and JY cells by O-36 has to be attributed to two independent specificities of this CTL clone. The specificity of the other cross-reactive CTL clone (O-1) could not be determined. The notion that individual CTL clones can have two specificities was supported by the following observations. The cytotoxic reactivity of both O-1 (T4+) and O-36 (T8+) against JY was blocked by monoclonal antibodies directed against T3 and human LFA-1, and against T3, T8, and human LFA-1, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

Dissociation of autologous and allogeneic mixed lymphocyte reactivity by using a monoclonal antibody specific for human T helper cells

A monoclonal antibody defining a population of human T helper cells was developed and shown to specifically block the autologous mixed lymphocyte reaction (AMLR). This antibody, termed KT69-7 (IgG1), recognized 62% of peripheral blood E rosette-positive (E+) cells while demonstrating negligible reactivity with E- cells, monocytes, granulocytes, EBV-transformed B cell lines, and mouse splenocytes. Separation of E+ cells into KT69-7+ and KT69-7- populations revealed that KT69-7+ T cells provided helper function in PWM-driven B cell differentiation, whereas KT69-7- T cells provided no help and may suppress this response. Modulation of membrane moieties by using KT69-7 or OKT4 plus goat anti-mouse IgG removed reactivity to both these antibodies, suggesting an association between these molecules recognized by these antibodies. In functional studies, KT69-7 selectively blocked the AMLR while demonstrating minimal or no effect on the allogeneic MLR (allo-MLR). Blocking of the autoreactivity occurred when either autologous B lymphocytes or macrophages were used as stimulators. The failure of KT69-7 to block the allo-MLR was not attributable to excessive allogeneic stimulus; KT69-7 failed to block even under conditions of limiting numbers of stimulator cells. KT69-7 thus appears to recognize a molecule on the surface of T helper cells required for recognition of autologous class II antigens.     

Activated human T cells can present alloantigens but cannot present soluble antigens

Human T cells, when activated by antigen or mitogen, express Ia antigens. We have examined the capacity of activated T cells to stimulate autologous and allogeneic T cells and their ability to present soluble antigen. Interleukin 2-dependent T-cell lines (TCL), free of accessory cells, were used for antigen-presenting cells. These activated T cells were potent stimulators in an autologous mixed lymphocyte reaction (AMLR), more so than autologous irradiated non-T mononuclear cells. Activated T cells were also able to stimulate proliferation of allogeneic T cells in the absence of any other accessory cells, and this stimulation was blocked by anti-Ia antibodies. Resting unstimulated T cells were unable to stimulate autologous or allogeneic responses. Thus, activated T cells were able to present self antigens and alloantigens. However, activated T cells could not present soluble antigens to autologous T cells or to antigen-specific TCL even if exogenous interleukin 1 was added to cultures. The ability of activated T cells to stimulate an AMLR in vitro may reflect an important immunologic amplification mechanism in vivo. The ability of activated T cells to present alloantigens but not soluble antigens suggests an inability to process antigen, and this may provide further insights into the complexities of antigen presentation.     

Liver sinusoidal lining cells express class II major histocompatibility antigens but are poor stimulators of fresh allogeneic T lymphocytes

Guinea pig liver sinusoidal lining cells (LSLC), a mixture of Kupffer cells (KC) and sinusoidal endothelial cells (EC), were examined for their capacity to function as antigen-presenting cells (APC). LSLC were extremely poor stimulators of freshly isolated allogeneic T lymphocytes even though a large number of them expressed class II major histocompatibility complex (MHC) antigens (Ia). This deficiency could not be explained by a lack of soluble factor production by LSLC, because an interleukin 1-containing macrophage (M phi) supernatant could not restore the capacity of LSLC to stimulate allogeneic T cells. Moreover, LSLC were able to promote mitogen-induced proliferation of accessory cell-depleted T lymphocytes. No evidence of suppression was apparent in experiments in which LSLC were added to cultures of T cells stimulated by allogeneic peritoneal exudate M phi (PEM). The Ia expressed by LSLC was functional because they were able to stimulate an alloreactive T cell line. When LSLC were mixed and co-cultured with either PEM syngeneic to the responding lymphocytes or Ia-negative fibroblasts, the allostimulatory ability of LSLC was greatly augmented. In contrast, the addition of mitogen-activated T cell supernatants had only a minimal effect on the capacity of LSLC to stimulate allogeneic T cells. The data suggest that LSLC lack a biologic property that is necessary for recognition of class II MHC determinants by fresh but not primed allogeneic T cells and that is not required to support T cell activation induced by nonspecific mitogenic lectins. These findings may be important in understanding the reason that antigen introduced into the portal blood appears not to initiate an immune response.     

Stimulation of human lymphocytes with irradiated cells of the autologous Epstein-Barr virus-transformed cell line. I. Virus-specific and nonspecific components of the cytotoxic response

Peripheral blood lymphocytes were cocultivated with irradiated cells of the autologous EB virus-transformed cell line at different responder:stimulator (R:S) ratios and the cytotoxic response was assayed up to 12 days later. In cocultures set up at a R:S ratio of 4:1, the response from both EB virus antibody-positive (seropositive) and negative donors was dominated by a broad-ranging NK-like cytotoxicity which did not segregate within the E-rosette-forming subpopulation of effector cells. In contrast, cocultures set up at a R:S ratio of 40:1 and harvested after 10 to 12 days gave rise, in the case of seropositive donors only, to effector T-cell preparations which appeared to be both EB virus specific and HLA-A and B antigen restricted. Strong lysis of the autologous virus-transformed cell line and demonstrable activity against certain allogeneic HLA-A and/or B antigen-related virus-transformed lines occurred in the absence of any significant killing either of the corresponding lines from HLA-unrelated donors or of a variety of EB virus genome-negative target cells (K562, HSB2, BJAB) particularly sensitive to NK-like cytotoxicity; furthermore, lysis of the autologous cell line by these effector T cells was specifically inhibited by monoclonal antibodies binding to HLA-A, B, and C antigens on the target cell surface. This work demonstrates that an HLA-restricted EB virus-specific cytotoxic T-cell response can indeed be induced in vitro by stimulation of fresh lymphocytes with autologous EB virus-transformed cells providing cocultures are set up at the correct R:S ratio.     

Differential ability of fixed antigen-presenting cells to stimulate nominal antigen-reactive and alloreactive T4 lymphocytes

The capacity of paraformaldehyde-fixed human antigen-presenting cells (APC) to induce responses by autologous, freshly isolated peripheral blood T4 cells was examined and was compared with their ability to stimulate allogeneic T4 cell DNA synthesis. Fixation of glass-adherent cells (AC) with as little as 0.06% paraformaldehyde abolished leucine incorporation, whereas fixation with 0.75% paraformaldehyde caused death of greater than 98% of the AC. Control APC were able to take up and present the soluble antigens streptokinase-streptodornase (SK-SD), tetanus toxoid, or tuberculin-purified protein derivative to autologous Ia-depleted T4 cells. Fixation with greater than 0.06% paraformaldehyde eliminated such ability. When AC were incubated with antigen overnight and were then fixed, however, they were able to present nominal antigen to autologous T4 cells in a genetically restricted manner that was blocked by monoclonal antibodies directed against monomorphic determinants on class II major histocompatibility complex (MHC) molecules. Despite the ability to present nominal antigen, paraformaldehyde-fixed AC were unable to induce allogeneic T4 cell proliferation. Similar results were observed when non-T cells or spleen cells were used as stimulators. The inability of fixed APC to stimulate allogeneic T4 cell DNA synthesis was not reversed by increasing the number of fixed APC or by the addition of control AC autologous to the responding cells. Moreover, interleukins 1 and 2 either alone or in combination also failed to permit maximal T cell proliferation in response to fixed allogeneic APC. The differential effects of fixation on nominal antigen and alloantigen presentation could not be explained by the loss of membrane thymocyte stimulatory activity on fixed AC. These results indicate that antigen-bearing fixed APC are competent to stimulate proliferation by antigen-reactive T4 cells, but are deficient at inducing allogeneic T4 cell DNA synthesis. The differential sensitivity of these two Ia-restricted functions of APC to chemical denaturation (reductive methylation) by paraformaldehyde suggests that the allodeterminants and restriction elements for nominal antigen on MHC class II molecules can be functionally dissociated.     

Allogeneic T cell activation triggering by MHC class I antigens

The role of MHC-encoded class I molecules in allogeneic activation and proliferation of human T lymphocytes was investigated. The study was performed by using primary mixed culture of lymphocytes from MHC recombinant siblings identical for MHC class II Ag (DR, DP, DQ) and displaying MHC class I disparity. The results indicate that such allogeneic combination is sufficient to trigger early activation steps within responder T cells without promoting a significant proliferation. After MHC class I allosensitization, a significant proportion of cells entered the cell cycle (G0----G1). The stimulatory potential of MHC class I Ag was further stressed by the specific induction on responder cells of IL-2R (22% T cell activation Ag positive). Under the same experimental conditions, transferrin receptor expression and IL-2 activity were not detectable. This is consistent with the low T cell proliferation. Exogenous rIL-1 did not improve IL-2 production and the subsequent T cell proliferation indicating that these two events were not associated with a defective accessory cell function involving IL-1 release. MHC class I disparity can also prime precursor CTL to differentiate into IL-2-dependent functional MHC restricted cytotoxic T cells. Conversely IFN-gamma had no effect. Addition to the culture of W6/32, a mAb specifically directed against a monomorphic determinant on human class I HLA-A, -B, and -C Ag was able to block all these activation events. These data clearly indicate a role of HLA class I Ag involvement in the early events triggering allogeneic T cell activation.     

Immunochemical and functional analysis of Ia-like antigens on human monocyte-macrophages with monoclonal antibodies

The distribution, structural profile and functional properties of Ia-like antigens synthesized by human monocyte-macrophages have been analyzed using monoclonal antibodies to common determinants of these antigens. Up to 45 and 70%- of monocyte-macrophages isolated from the fluid of blisters induced with cantharidin and from peripheral blood, respectively, react with monoclonal antibodies to human Ia-like antigens. The level of Ia-like antigens on monocytes-macrophages appears to be similar to that on cultured B lymphoid cells. Monoclonal antibodies to common determinants of Ia-like antigens specifically block antigen presentation by monocyte-macrophages to T lymphocytes as well as proliferative response of T lymphocytes to autologous and allogeneic monocytes-macrophages. These results indicate that common determinants of Ia-like antigens play a role in the interaction of monocytes-macrophages with T lymphocytes.