Inhibition of secondary mouse mixed lymphocyte reaction by anti-Ia sera

Secondary mixed lymphocyte reaction (MLR-II) was studied in A.TH anti A.TL and A.TL anti-A.TH combinations in which stimulation was mainly due toH-2I-region differences. In both cases the MLR-II was specifically inhibited by the responder anti-stimulator Ia serum. The level of inhibition was dependent on the ratio of the amount of immune serum to the number of stimulating cells. The inhibitory activity and Ia antibodies were specifically absorbed and eluted together. The results confirm that the lymphocyte-activating determinants of the MLR-II (1) are carried by the Ia molecules and (2) are identical to the serologically defined Ia determinants. —Anti-Ia sera directed against private and public specificities of the stimulating cell induced a higher level of inhibition than anti-Ia sera directed only against public specificities, indicating that both private and public Ia specificities are involved in restimulation during MLR-II. — These results, in connection with others, suggest that the receptor of the proliferating T cell recognizes the same Ia determinant as the combining site of the Ia-recognizing antibody.Abbreviations used in this paper Lad lymphocyte-activating determinant - MLR mixed lymphocyte reaction - MLR-I, MLR-II primary, secondary MLR - PRC primed responder cells - LCT dye exclusion lymphocytotoxicity microtechnique - RR relative response     

Inhibition of secondary mouse mixed lymphocyte reaction by anti-Ia sera

Secondary mixed lymphocyte reaction (MLR-II) was studied in A.TH anti A.TL and A.TL anti-A.TH combinations in which stimulation was mainly due to H-21-region differences. In both cases of MLR-II was specifically inhibited by the responder anti-stimulator Ia serum. The level of inhibition was dependent on the ratio of the amount of immune serum to the number of stimulating cells. The inhibitory activity and Ia antibodies were specifically absorbed and eluted together. The results confirm that the lymphocyte-activating determinants of the MLR-II (1) are carried by the Ia molecules and (2) are identical to the serologically defined Ia determinants. - Anti-Ia sera directed against private and public specificities of the stimulating cell induced a higher level of inhibition than anti-Ia sera directed only against public specificities, indicating that both private and public Ia specificities are involved in re-stimulation during MLR-II. - These results, in connection with others, suggest that the receptor of the proliferating T cell recognizes the same Ia determinant as the combining site of the Ia-recognizing antibody.     

Antigen-binding receptors on T cells from long-term MLR. evidence of binding sites for allogeneic and self-MHC products

Antibody inhibition of radiolabelled stimulator membrane vesicle binding by T blasts activated in the mixed lymphocyte reaction (MLR) was used to identify responder-cell determinants involved in the binding phenomenon. Antisera or monoclonal antibodies against Thy-1, Lyt-1, Lyt-2 and Ly-6 antigens were not inhibitory. However, antibodies against heavy-chain V region (VH) determinants strongly inhibited vesicle binding by both primary and long-term MLR blasts. Anti-Ia (both alloantisera and monoclonal reagents) caused inhibition of antigen binding by primary MLR blasts only. T blasts from long-term MLR lines were neither Ia-positive, nor susceptible to blocking of antigen binding with anti-Ia. However, these cells were capable of specifically absorbing soluble syngeneic Ia material, with the concomitant appearance of vesicle-binding inhibition with anti-Ia sera. Acquisition of syngeneic Ia by T blasts was effectivelly blocked with the anti-VH reagent. Passively bound self-Ia did not interfere with vesicle binding in the absence of anti-Ia. These results strongly suggest the existance of specific self-Ia acceptor sites closely linked to the receptors for stimulator alloantigens on T cells proliferating in MLR. A receptor model based on these findings is briefly discussed.     

T cell recognition in the mixed lymphocyte response. II. Ia-positive splenic adherent cells are required for non-I region-induced stimulation

Ia-positive splenic adherent cells (SAC) have been shown to be the predominant stimulators of a mixed lymphocyte response (MLR) to whole H-2 differences, in which most of the proliferative response is directed against I region-encoded determinants. The present studies were undertaken to examine the ability of several purified lymphoid subpopulations to activate T cells in response to the non-H-2-linked MIs products or to products of the K or D regions of H-2. The results demonstrated that adherent cell-depleted populations of T and B cells were nonstimulatory, whereas SAC were potent stimulators for responses involving each of these genetic differences. Treatment of these SAC with anti-Ia and C abrogated their MLR-stimulating ability. In contrast, whereas treatment of SAC with anti-Ia and C abrogated their ability to stimulate an MLR directed against K or D region-encoded determinants, this treatment had no effect on their ability to generate a cytotoxic T lymphocyte response against these same determinants. These findings suggest that in addition to presenting allogeneic I region-encoded determinants, Ia-positive SAC also play a unique role in the presentation of non-I region-encoded alloantigens to proliferating T cells.     

Nature of the antigenic complex recognized by T lymphocytes. IV. Inhibition of antigen-specific T cell proliferation by antibodies to stimulator macrophage Ia antigens.

We have previously demonstrated that nonimmune guinea pig T lymphocytes could be specifically sensitized with TNP-modified allogeneic macrophages after eliminating the alloreactive T cells with bromodeoxyuridine (BUdR) and light treatment. This procedure allowed the unique opportunity to use anti-Ia sera directed against the Ia antigens of only the stimulator macrophages or responder T cells to determine against which cell type anti-Ia would block TNP-specific stimulation. It was found that the TNP-specific DNA synthetic response of BUdR and light-treated T cells stimulated with TNP-modified allogeneic macrophages was totally eliminated by anti-Ia sera directed solely against the allogeneic stimulator macrophage. In contrast, anti-Ia sera directed only against the responder T cells had no effect on their response to TNP-modified allogeneic macrophages. These findings indicate that macrophage Ia antigens are required for efficient T cell-macrophage interactions and raise the possibility that T cell Ia antigens may not be required for collaboration with macrophages. This latter possibility was substantiated by experiments in which we show that treating T cells with anti-Ia sera and complement to remove the Ia-positive cells either before or after priming, or both, had no effect on their ability to be primed and restimulated with TNP-modified macrophages.     

Antigen-binding receptors on T cells from long-term MLR. Evidence of binding sites for allogeneic and self-MHC products

Antibody inhibition of radiolabelled stimulator membrane vesicle binding by T blasts activated in the mixed lymphocyte reaction (MLR) was used to identify responder-cell determinants involved in the binding phenomenon. Antisera or monoclonal antibodies against Thy-1, Lyt-1, Lyt-2 and Ly-6 antigens were not inhibitory. However, antibodies against heavy-chain V region (V_H) determinants strongly inhibited vesicle binding by both primary and longterm MLR blasts. Anti-Ia (both alloantisera and monoclonal reagents) caused inhibition of antigen binding by primary MLR blasts only. T blasts from long-term MLR lines were neither Ia-positive, nor susceptible to blocking of antigen binding with anti-Ia. However, these cells were capable of specifically absorbing soluble syngeneic Ia material, with the concomitant appearance of vesiclebinding inhibition with anti-Ia sera. Acquisition of syngeneic Ia by T blasts was effectively blocked with the anti-V_H reagent. Passively bound self-Ia did not interfere with vesicle binding in the absence of anti-Ia. These results strongly suggest the existance of specific self-Ia acceptor sites closely linked to the receptors for stimulator alloantigens on T cells proliferating in MLR. A receptor model based on these findings is briefly discussed.Abbreviations used in this paper B10 C57BL/10 - Con A concanavalin A - FcR Fc receptor - FCS fetal calf serum - H heavy chain - Ia I-region associated antigen - Ig immunoglobulin - LPS lipopolysaccharide - Lyt T-lymphocyte differentiation antigen - MHC major histocompatibility complex - MLR mixed lymphocyte reaction - PM plasma membrane - T thymus derived - Tcr T-cell receptor - V variable region of Ig     

T lymphocyte-enriched murine peritoneal exudate cells. III. Inhibition of antigen-induced T lymphocyte Proliferation with anti-Ia antisera.

The recent development of a reliable murine T lymphocyte proliferation assay has facilitated the study of T lymphocyte function in vitro. In this paper, the effect of anti-histocompatibility antisera on the proliferative response was investigated. The continuous presence of anti-Ia antisera in the cultures was found to inhibit the responses to the antigens poly (Glu58 Lys38 Tyr4) [GLT], poly (Tyr, Glu) ploy D,L Ala-poly Lys [(T,G)-A--L], poly (Phe, Glu)-poly D,L Ala-poly Lys [(phi, G)-A--L], lactate dehydrogenase H4, staphylococcal nuclease, and the IgA myeloma protein, TEPC 15. The T lymphocyte proliferative responses to all of these antigens have previously been shown to be under the genetic control of major histocompatibility-linked immune response genes. The anti-Ia antisera were also capable of inhibiting proliferative responses to antigens such as PPD, to which all strains respond. In contrast, antisera directed solely against H-2K or H-2D antigens did not give significant inhibition. Anti-Ia antisera capable of reacting with antigens coded for by genetically defined subregions of the I locus were capable of completely inhibiting the proliferative response. In the two cases studied, GLT and (T,G)-A--L, an Ir gene controlling the T lymphocyte proliferative response to the antigen had been previously mapped to the same subregion as that which coded for the Ia antigens recognized by the blocking antisera. Finally, in F1 hybrids between responder and nonresponder strains, the anti-Ia antisera showed haplotype-specific inhibition. That is, anti-Ia antisera directed against the responder haplotype could completely block the antigen response controlled by Ir genes of that haplotype; anti-Ia antisera directed against Ia antigens of the nonresponder haplotype gave only partial or no inhibition. Since this selective inhibition was reciprocal depending on which antigen was used, it suggested that the mechanism of anti-Ia antisera inhibition was not cell killing or a nonspecific turning off of the cell but rather a blockade of antigen stimulation at the cell surface. Furthermore, the selective inhibition demonstrates a phenotypic linkage between Ir gene products and Ia antigens at the cell surface. These results, coupled with the known genetic linkage of Ir genes and the genes coding for Ia antigens, suggest that Ia antigens are determinants on Ir gene products.     

Macrophage-lymphocyte interaction. III. Site of alloantiserum inhibition of T lymphocyte proliferation induced by allogeneic or aldehyde-bearing cells.

Inhibition by anti-Ia sera of guinea pig T lymphocyte proliferation induced by allogeneic macrophages (MLR) and NaIO4 or neuraminidase-galactose oxidase-treated macrophages has been investigated in order to identify the target cell upon which the antisera act. Anti-2 and anti-13 alloantisera were found to inhibit both MLR and aldehydeinduced T cell reactivity when directed against the specificity of the stimulatory macrophage. Little or no inhibition was observed when these antisera were directed against the T lymphocyte specificity when cultures were harvested at the time of peak proliferation. In addition, anti-2 serum was found to inhibit macrophage-lymphocyte rosett formation at 20 hr between neuraminidase-galactose oxidase-treated strain 2 macrophages and strain 13 lymphocytes. These findings demonstrate that inhibition of T cell proliferation can be produced by anti-Ia sera directed against the macrophage and raise the possibility that Ir gene products may function in part at the level of the macrophage.     

The expression of Ia antigens on immunocompetent cells in the quinea pig. I the differential expression of Ia antigens on T cell subpopulations.

We have examined the effect of negative selection with anti-Ia serum and C on a number of T cell functions and have clearly defined two subpopulations of guinea pig T lymphocytes. One subpopulation is susceptible to the lytic effects on anti-Ia serum and C and includes the majority of the primed T cells which proliferate and which produce migration inhibition factor in response to specific antigen stimulation in vitro. The lytic effects of anti-Ia serum were directed against the antigen-specific T cell and not an accessory cell such as a macrophage or nonantigen-specific T cell. No evidence for allelic exclusion of the Ia antigens of the antigen-responsive cell could be demonstrated. The susceptibility of the mitogen-responsive T cell to lysis by anti-Ia serum and C varied with the mitogen used, anatomic origin of the T cell, and the strain of animals studied. A second subpopulation of T cells is completely resistant to the lytic effects of anti-Ia serum and C and includes the primed T helper cell and the T cell that proliferates in response to alloantigenic stimulation in the MLR.     

The syngeneic mixed leukocyte reaction: the genetic requirements for the recognition of self resemble the requirements for the recognition of antigen in association with self

We have used cells from inbred strain 2 and strain 13 guinea pigs in order to define further the role of Ia antigens in the syngeneic mixed leukocyte reaction (MLR). The guinea pig syngeneic MLR resembled the autologous MLR in man in that it demonstrated both memory and specificity. The Ia antigens appeared to be the proliferative stimuli in that the primary stimulator cell was an Ia-positive adherent peritoneal exudate cell (PEC) and the reaction could be specifically inhibited by anti-Ia sera directed to the stimulator cell. We also demonstrated the existence of two (2 x 13)F1 T cell populations that were capable of reacting to one or the other parental PEC in the absence of any known exogenous antigen. These results suggest that the syngeneic MLR may represent T cell activation mediated through a receptor for self Ia.     

Modulation of natural cytotoxicity by alloantibodies: III. Augmentation of natural killer activity by alloantisera directed against K,D, and I regions of the murine H-2 complex

Natural killer activity of mouse spleen cells toward a human myeloid leukemia cell line, K562, can be enhanced by alloantisera directed against individual antigens in the H-2 region. By using a panel of 13 antisera (8 directed against antigens in the K and D regions and 5 directed against antigens in the I region) and four strains of mice (C57BL/6J, CBA, DBA/2, and A/J) it was found that certain antisera would stimulate target cell lysis by spleen cells only if the antisera had specificity for antigens which were a part of the haplotype represented on the spleen NK effector cells. Anti Ia antisera could stimulate the anti K562 NK activity of nude mouse spleen cells which lack mature T cells. Depletion of B cells and macrophages from nude spleen cells, by passing through a nylon-wool column also did not abolish the effect of anti-Ia antiserum. It appears likely therefore that the anti-Ia antibodies exert this effect directly on NK cells and that Ia antigens may be expressed on NK cells. Since the antisera directed against different antigens in H-2 complex irrespective of subregion specificity (K, D, or I) stimulated the NK activity of mouse spleen cells, the phenomenon offered an interesting method for testing the presence of a given alloantigen on mouse spleen cells. Log-dose response curves for the augmentation of lysis induced by appropriate alloantisera were linear over a dilution range of 1:320 to 1:5120. By using the dose-response curves, potency ratios of two preparations of antisera (directed against antigen 33 of the K region) could be successfully determined. Besides the K562 cell line, many human lymphoblastoid cell lines could also be used as target cells in this assay system.     

Anti-Ia inhibits the activity of B cells but not a T cell-derived helper mediator

The effects of addition of anti-Ia sera to cultures of B cells responding to a number of different stimuli were studied. Anti-Ia sera inhibited the responses of B cells to thymus-dependent and thymus-independent antigens. The effects of antisera directed at different subregions within theI region were examined, using the same anti-Ia serum and mouse strains congenic atI. There was some indication that antisera directed at theI-C region might be more efficient at inhibiting responses to a thymus-independent antigen than to a thymus-dependent antigen. An antiserum to another B-cell surface component controlled by theH-2 complex, the D glycoprotein, had no effect on the response of B cells to a thymus-dependent antigen. By contrast, anti-Ia serum added to cultures had no effect on the activity of a T cell-derived, nonspecific, B-cell helper mediator (NSM). We concluded that the binding of anti-Ia sera to B-cell surfaces inhibited B-cell responses to antigen, either by competing directly with the binding of signal molecules, or by delivering an inhibitory signal to the B cell, such that it was subsequently refractory to stimulatory signals.     

Comparison of antigens recognized by xenogeneic and allogeneic anti-Ia antibodies: Evidence for two classes of Ia antigens

Previously published data suggest that both xenogeneic and allogeneic anti-Ia sera can recognize carbohydrate-defined antigenic determinants on the surface of lymphocytes. There is also evidence, based on studies with allogeneic anti-Ia sera, that protein-defined Ia antigens exist. In this paper the relationship between these two types of Ia antigen was examined. It was found that in capping studies, the allogeneic anti-Ia serum could cap off the antigens recognized by the xenogeneic antiserum, whereas the xenogeneic antibodies could, at least partially, clear the surface of lymphocytes of Ia antigens detected by the allogeneic antibodies. On the other hand, when immunoprecipitates of radioiodinated cell-surface antigens were examined by SDS-polyacrylamide-gel electrophoresis, it was found that the xenogeneic anti-Ia serum did not immunoprecipitate any labeled material. In contrast, the allogeneic antiserum immunoprecipitated a labeled molecule which corresponded to the protein-defined Ia antigen described by others. Finally, it was shown that serum Ia antigens could be bound by either mouse or rabbit anti-Ia antibody, and this binding blocked any further reactivity with either serum. These results were interpreted as suggesting that two separate classes of Ia antigen molecule appear on the lymphocyte surface-one class has carbohydrate-defined antigenic specificities and the other has protein-defined determinants. Allogeneic anti-Ia sera contain antibodies against both these antigenic systems, whereas xenogeneic sera recognize only the carbohydratedefined series. The genetic implications of this interpretation are discussed.     

Nature of the antigenic complex recognized by T lymphocytes. VII. Evidence for an association between TNP-conjugated macrophage membrane components and Ia antigens.

In the present study we examined the effects of anti-sera directed against guinea pig Ia antigens on the ability of TNP-conjugated macrophages to stimulate TNP-specific T lymphocyte proliferation. Treatment of macrophages with anti-Ia sera for 1 hr before, 1 hr immediately after, or as late as 24 hr after TNP-modification resulted in a reduced ability to stimulate the TNP-specific T cell. The inhibition produced by anti-Ia sera was specific and did not result from interference with the ability of macrophages to process TNP-conjugated membrane antigens in a nonspecific manner. Brief treatment with anti-Ia serum did not result in inhibition of Ia-antigen synthesis nor could evidence of carry-over of anti-Ia antibody into the lymphocyte cultures be obtained. These results demonstrate that anti-Ia sera interfere with the development of a TNP-specific immunogen on the macrophage surface and strongly suggest that an association exists between TNP-modified membrane proteins and Ia antigens on the macrophage surface.     

Generation of H-2-reactive T cell lines that bear the 5936 idiotype(s)

The present experiments showed 1) that it was possible to produce mouse T cell lines against MHC determinants with a relatively high success rate by stimulation of purified T cells with allogeneic cells in the presence of irradiated syngeneic spleen cells; 2) that these lines could be led to react against selected H-2 specificities; 3) that only T cell lines established from Ig-1b allotype mice contained 5936-Id+ T cells (5936-Idiotypes are defined by an antiserum against B6 anti-CBA IgG produced in rabbit no 5936, which was tolerant to mouse gamma-globulin); and 4) that antigenic determinants coded by IAk genes induce the 5936-Idiotype(s). The latter data are in accordance with the 5936-idiotype characteristics of primary MLC T blasts. All T cell lines contained both specific MLC-responding cells and cytolytic cells. However, studies on the functional capacity of 5936-Id+ T cells from both primary MLC and the T cell lines showed that neither MLC-responding cells nor cytolytic cells directed against H-2Kk, IAk, or H-2Dk were 5936-Id+. Thus, 5936-Id+ T cells may be regulator cells induced by IAk antigens.     

Nature of T lymphocyte recognition of macrophage-associated antigens. IV. Inhibition of peptide antigen presentation by brief treatment of macrophages with anti-Ia serum

To examine the role of macrophage la antigens in T-lymphocyte stimulation, guinea pig macrophages were briefly treated with anti-Ia serum before or after antigen pulsing with the peptide antigen human fibrinopeptide B (hFPB). To assess their antigen-specific stimulatory capacity, the variously treated macrophages were added to culture with hFPB-immune guinea pig T cells and stimulation was determined by the incorporation of [³H]thymidine. Macrophages treated with anti-Ia serum before antigen pulsing stimulated T-cell responses equivalent to those observed with antigen-pulsed macrophages treated with normal serum. By contrast, brief anti-Ia treatment of macrophages immediately following a 2-hr antigen pulse reduced subsequent T-cell responses by 45 to 70%. Similar treatment of macrophages pulsed with antigen for only 1 hr produced only modest inhibition of T-cell responses. However, if macrophages pulsed for 1 hr with antigen were incubated several hours before brief anti-Ia serum treatment, the subsequent T-cell responses were reduced by 40 to 60%. This inhibition was specific for antiserum directed against Ia antigens of the guinea pig MHC, since brief macrophage treatment with antiserum directed against B.1 antigens, the guinea pig equivalent of murine H-2K and H-2D antigens, produced no inhibition of their T-cell stimulatory capacity. These results are discussed with respect to the formation of the immunogen presented by macrophages for T-cell recognition.     

Requirement of Ia-positive accessory cells in the MLR response against class II antigen on human B cell tumor line

In this report we have made a comparative study of the capacity of normal human stimulator cells and Epstein-Barr virus-transformed human B cell line Wa (EBV-Wa) cells to stimulate alloreactive T cells. Class II antigen (presumably HLA-DR4 determinant) on EBV-Wa cells was shown to act as a stimulating molecule in the mixed lymphocyte reaction (MLR) through a blocking study by using anti-Ia antibodies. Furthermore, it was found that HLA-DR-positive accessory cells in the responder population were required to elicit MLR responses against HLA-DR antigen on EBV-Wa cells. In contrast, HLA-DR-positive accessory cells in the responding cell population were not essential for elicitation of MLR responses against HLA-DR antigen on normal allogeneic peripheral blood mononuclear cells, as reported. The cell-cell interaction between responder HLA-DR-positive accessory cells and responding T cells in a major histocompatibility complex (MHC)-restricted manner was required for eliciting MLR responses against class II antigen on EBV-Wa cells such as antigen-presenting cell-T cell interaction in soluble antigen-specific T cell proliferative responses. The function of HLA-DR-positive accessory cells in the responder population could not be substituted for by the presence of interleukin 1. Furthermore, there was no obvious correlation between the degree of surface HLA-DR antigen expression on EBV-Wa cells and its stimulating ability. Thus, two distinct types of allo-class II, antigen-specific T cell activation between normal human stimulator cells and EBV-Wa cells were shown to exist.     

Antigen-presenting cells that induce anti-H-2K T-cell responses: Differences in stimulator-cell requirements for induction of proliferation and cell-mediated lympholysis

Splenic T or B cells, which have been depleted of adherent cells by passage through Sephadex G10 columns, fail to stimulate allogeneic lymph-node cells (LN) in primary mixed lymphocyte reactions (MLR) both when the stimulating antigens are H-2 plus Ia and H-2K only. This failure cannot be ascribed to lack of viability of G10-passed cells, since by dye exclusion they are 95 percent viable and can be induced to proliferate in vitro by exposure to LPS or allogeneic cells. Stimulation of MLR activity could be restored by addition of small numbers of plastic-adherent spleen cells (SAC) which had to be syngeneic with the G10-passed stimulator cells. Further, SAC alone without G10-passed cells induced MLR activity which was, on a cell-for-cell basis, 40 times more effective than that induced by unfractionated spleen cells. If the SAC were first depleted of Ia⁺ cells, no stimulation was obtained. This result was observed both in cases where responder and stimulator strains differed across the entireH-2-gene complex and in a mutant-wild type combination (CBA and H-2^km1) in which the difference between the two strains has been mapped to theK region only. These results indicate that Ia⁺ SAC contain a subset(s) of cells which are responsible for stimulation in MLR, regardless of whether the alloantigenic differences involve either Ia or H-2K. In contrast to the inability of G10-passed splenic cells to stimulate MLR activity, these cells were able to stimulate CTL from cytotoxic T lymphocyte precursors (CTL.P) in combinations where the antigenic differences between responder and stimulator were at the entireH-2 complex or atH-2K only. However, SAC were more potent stimulators of cell-mediated lympholysis (CML) activity on a cell-for-cell basis. Thus, either CTL.P can be stimulated by nonadherent spleen cells or they are specifically sensitive to a small subpopulation of contaminating cells that cannot readily be removed by G10 passage.     

Cell-mediated immunity to chemically xenogenized tumors. II. Evidence for accessory function and self-antigen presentation by a highly immunogenic tumor variant

To determine whether antigen-presenting ability might be involved in the superior immunogenicity of chemically xenogenized tumors over that of parental cells, we tested a murine lymphoma line xenogenized by a triazene derivative for expression of Ia antigens, ability to present soluble antigen in vitro, and production of factor(s) active in a mouse thymocyte assay. Results showed that Ia antigens, absent on nonimmunogenic parental L5178Y cells, were expressed on a xenogenized, highly immunogenic tumor variant (clone D), as detected by immunofluorescence. While the ability of parental cells to stimulate lymphocyte proliferation in vitro was lost on removal of Ia+ cells from the responder population, considerable augmentation of reactivity was observed upon depletion of Ia+ cells from the population of splenocytes responding to the xenogenized cells. Under these conditions, stimulation was blocked by anti-Ia antibodies, or an anti-L3T4 reagent or antibodies to the novel antigenic determinants induced by xenogenization. In addition, no stimulating activity was observed following exposure of clone D cells to glutaraldehyde or lysosomotropic agents such as chloroquine and ammonia. When the ability of clone D cells to present ovalbumin in vitro was assayed, it was found that the xenogenized cells could present the soluble antigen to specifically primed lymphocytes. Moreover, clone D cells could substitute for splenic adherent cells in the proliferative reaction of splenocytes to concanavalin A. Finally, when the supernate from clone D-cell culture pulsed with phorbol myristic acetate was tested in a mouse thymocyte assay, considerable IL-1-like activity was disclosed.     

Synergistic interactions between lymph node and thymus cells in response to antigenic differences limited to selected regions of the H-2 complex.

Thymus and lymph nodes from the A.TL recombinant line were utilized as sources of responding cells in MLR (mixed lymphocyte response) assays to MHC-determined (major histocompatibility complex) antigenic differences. Cells from both sources were stimulated to proliferate by antigenic determinants controlled by the H-2K region alone, H-2D region and the H-2I-H-2S regions. Nylon-fiber-adherent splenic cells from each of the stimulating cell strains stimulated T-cell-dependent responses. Synergistic interactions between A.TL thymus and lymph node cells were initiated by antigenic products limited to single H-2 regions. Antigenic differences determined within the H-2I region were not required for synergistic responses to H-2K-controlled products or for the generation of cytotoxic killer cells to H-2D-associated antigens. The H-2I-region-associated products also were very effective in stimulating T-cell synergy. These data demonstrate that the two responsive T-cell subpopulations can both be stimulated by alloantigens coded within a single known H-2 region.