Guinea pig T-cell in vitro proliferative responses to tyrosine-azobenzenearsonate-pulsed and azobenzenearsonate-coupled macrophages have different specificities

The cell interactions involved in azobenzenearsonate-N-acetyl-tyrosine (ABA-tyr)-induced delayed hypersensitivity in the guinea pig were studied by in vitro blastogenesis. The ABA-sensitive lymphocyte was demonstrated to be a T lymphocyte and its presence in peritoneal exudate cells was shown to be much higher than spleen or lymph node populations. The secondary response of ABA-sensitized lymphocytes to ABA-tyr in culture is dependent on the presence of an accessory cell, with both splenic and peritoneal macrophages being equally effective. ABA coupled directly to macrophages as an immunogen induced strong responses to itself and not to ABA-tyr-pulsed macrophages or ABA-tyr in solution. The reverse was true in animals, immunized with ABA-tyr. ABA conjugated to thymocytes, L₂C leukemia cells, and guinea pig erythrocytes however, did not elicit significant responses. The results obtained in animals immunized with ABA- or ABA-tyr-modified cells was similar whether or not CFA was used. The difference in specificity shown between ABA-coupled and ABA-tyr-pulsed macrophages favors a single receptor hypothesis for T-cell recognition.     

The requirement of Ia-positive accessory cells for the induction of tumor-specific cytotoxic T lymphocytes in vitro

The mechanism for the induction of cytotoxic T cells specific for tumor-associated antigens was studied by using fractionated responder T cells, tumor cells, and accessory cells in vitro. The tumor-specific cytotoxic T cells were induced by culturing immunized spleen cells with the tumor cells in vitro for 5 days. Nylon-column-purified T cells alone did not induce cytotoxic T cells upon culture with tumor cells, but the addition of normal spleen cells as accessory cells did successfully induce the cytotoxic T cells, suggesting that the presence of accessory cells is required for the activation of tumor-specific cytotoxic T cells in vitro. The accessory function was associated with spleen cell populations adhering to a plastic dish, a Sephadex G-10 column or a nylon wool column, and was sensitive to anti-Ia serum and C treatment, but was resistant to anti-Ig serum or anti-Thy 1 serum and C treatment, suggesting that the accessory cells are Ia-positive macrophages. Not only syngeneic but also allogeneic macrophages had the accessory function and the allogeneic macrophages were also Ia positive. These results suggest that Ia-positive macrophages play a crucial role in the induction of tumor-specific cytotoxic T cells in vitro. The possible role of Ia-positive accessory cells in the induction of tumor-specific cytotoxic T cells is discussed from the standpoint of cellular interactions.     

A novel guinea pig macrophage-specific polymorphic molecule. I. Biochemistry, genetics, and tissue distribution

In the course of studying Ia molecules from strain 2 and strain 13 guinea pig macrophages, with the intent of comparing them to B cell Ia molecules, it was observed that guinea pig alloserum prepared by cross-immunization of guinea pig lymphocyte Ag non-identical inbred guinea pigs immunoprecipitated not only conventional class I and class II molecules, but also a 98,000-Da molecule, termed gp98. Two different forms of the molecule were detected, indicating it is polymorphic. The genes encoding gp98 were shown not to be linked to the guinea pig lymphocyte Ag complex. The molecule gp98 was found on macrophages within populations of peritoneal exudate cells, resident peritoneal cells, bone marrow cells, and spleen. All gp98-bearing macrophages were also Ia-positive. However, only a subpopulation of macrophages bore gp98. The gp98 was not found on Ly-1 or Ig-bearing cells, indicating that B and T cells do not bear Ia. Thus, gp98 appears to be a highly immunogenic polymorphic macrophage-specific molecule that allows the characterization of guinea pig macrophage subsets.     

Genetically restricted immune responses in guinea pigs primed in vivo with antigen-bearing macrophages.

Guinea pigs injected intradermally with antigen pulsed macrophages generate a population of immune T cells that proliferate in vitro on second exposure to antigen. T cells from F1 (2 X 13) guinea pigs immunized with DNP-OVA on one parental macrophage respond in vitro only to DNP-OVA on macrophages identical to those used for immunization and not to DNP-OVA associated with the other parental macrophages. These results demonstrate that the immunogenicity of antigen is dependent upon the macrophages used for priming in that, with this approach, strain 2 or 13 guinea pigs immunized with allogeneic macrophages pulsed with antigen do not respond to either allogeneic or syngeneic antigen-bearing macrophages. However, lysates of antigen-pulsed macrophages can still immunize either allogeneic or syngeneic recipient via their own macrophages. F1 (2 X 13) guinea pigs are immunized by insulin B chain pulsed strain 13 macrophages (responder) but not by strain 2 macrophages (nonresponder) suggesting that whether a F1 (nonresponder X responder) guinea pig recognizes antigen bound to a parental macrophage is genetically restricted before immunization to the same extent as the donor parental macrophages used for immunization.     

Effects of L2C leukemia on macrophage-mediated responses

Summary Preliminary experiments have suggested that guinea pig L₂C B-cell leukemia cells were able to evade macrophage-mediated lysis. To determine whether the L₂C cells were resistant to macrophage cytotoxic activity or whether factors associated with the L₂C leukemia contributed to a generalized inhibition of macrophage cytotoxic activity, pulmonary macrophages from strain 2 guinea pigs with L₂C leukemia were tested for their ability to lyse the susceptible K562 cell line after activation by lipopolysaccharide (LPS) or lymphokines. In addition, the potential presence of soluble inhibitors of macrophage tumoricidal activity in serum-free culture supernatants and in serum from strain 2 guinea pigs terminally ill with the leukemia was tested by determining the effects of leukemic guinea pig serum (LGPS) or L₂C-conditioned medium (CM) on the tumoricidal activity of normal pulmonary macrophages. Macrophages from guinea pigs terminally ill with L₂C leukemia were demonstrated to be depressed in their cytotoxic activity against the K562 cell after stimulation by either LPS or lymphokines when compared to normal macrophages. The lymphokine-stimulated cytotoxic activity of normal macrophages was inhibited in the presence of LGPS or CM. Oxidative burst activity of normal macrophages, as measured by zymosan-stimulated production of superoxide and hydrogen peroxide, was also inhibited under these conditions. The data presented here suggests that soluble factors associated with L₂C leukemia cells can suppress oxidative burst activity of macrophages in vitro and that this effect may contribute to the ability of the leukemia cells to evade macrophage-mediated cytotoxicity.     

Accessory cell function of cells of the mononuclear phagocyte system isolated from mycobacterial granulomas

Epithelioid cells from BCG-induced granulomas and macrophages from Mycobacterium leprae-induced granulomas were examined for their ability to act as accessory cells for T-cell proliferation to mitogen (Con A) and antigen (PPD). The granuloma cells were separated on a FACS using monoclonal antibody specific to guinea pig macrophages. Epithelioid cells (which are Ia negative) were able to support proliferation to Con A but not to antigen. Cultures containing Ia positive granuloma macrophages from M. leprae sensitized animals did not show responsiveness to Con A or to PPD. Oil-induced peritoneal exudate macrophages from BCG or M. leprae immunized animals were able to act as accessory cells for both mitogen and antigen proliferation. The nonresponsiveness of cultures containing epithelioid cells stimulated with PPD or M. leprae granuloma macrophages stimulated with Con A was not due to suboptimal or supraoptimal accessory cell:lymphocyte ratios.     

Immune response gene control of antibody specificity

The expression of the histocompatibility-linked PLL Ir gene was investigated in guinea pig B cells. Strain 2 and F₁ (2 × 13) guinea pigs, immunized with the αDnp-Lys₉, produce both T cells and antibody which are equally discriminatory for αDnp-Lys₉. In contrast strain 13 (PLL Ir gene negative) guinea pigs immunized with αDnp-Lys₉ do not develop specific T-cell responses and the antibody produced while restricted in heterogeneity cannot differentiate the immunizing antigen from Dnp-OH. However, if in a F₁ (2 × 13) environment, PLL Ir gene-negative B cells are provided with F₁ (2 × 13) T cells they express the ability to make antibody as specific and discriminatory as the antibody produced by PLL Ir gene-positive B cells. These findings strongly suggest that in the guinea pigs the PLL Ir gene defect is localized to the T cells and that the repertoire of specificity of B cells is similar if not identical in both responder and nonresponder animals. In addition these observations support the notion that the cellular locus for the PLL Ir gene expression in the guinea pigs is limited to T cells and not to macrophages and B lymphocytes.     

Selective effects of anti-Ia serum and complement treatment upon polyclonal B lymphocyte responses to dextran sulfate and lipopolysaccharide.

Subpopulations of B lymphocytes have been shown to vary in their expression of Ia alloantigens and polyclonal responsiveness to thymic independent antigens. We have demonstrated that the polyclonal B cell antibody response to dextran sulfate is less sensitive to removal of Ia-positive cells than is the response to LPS. This is a consistent finding whether alloantibody and complement (C) pretreatment is directed toward cells bearing Ia antigens coded for by the entire I region or by the I-A or I-E subregions. Heterogeneity appears to exist within the dextran sulfate-sensitive population in that using high antibody; cell ratios during antibody and C-mediated cell selection results in an inhibition of the proliferative but not the antibody response. This result may indicate a differential expression of Ia antigens on dextran sulfate-sensitive B cells that respond by proliferation versus those cells that produce antibody. Alternatively, proliferative responses to dextran sulfate may be more dependent upon Ia-positive accessory cells than is the polyclonal antibody response.     

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.     

Chemotactic macrophage subpopulations defined by macrophage chemotactic factors from delayed hypersensitivity reaction sites

The chemotactic specificity of ia-positive and -negative macrophages was studied by using three macrophage chemotactic factors (MCF), -a, -b, and -c, isolated from delayed hypersensitivity reaction (DHR) skin sites in guinea pigs. Listeria-elicited macrophages migrated toward MCF-a, -b, and -c. The chemotactic responses suggested responsive subpopulations to MCF. The electronic programmable individual cell sorter (EPICS) was used to separate macrophages with anti-la monoclonal antibodies. Ia-positive subpopulations responded to MCF-c, although they did not migrate toward MCF-a and -b. In contrast, Ia-negative subpopulations migrated toward MCF-a and -b, but not toward MCF-c. Furthermore, MCF-c attracted Ia-positive macrophages, whereas MCF-a and -b were Ia-negative in vitro; MCF did not induce Ia-negative macrophages to express surface Ia-antigens in vitro. MCF-c was able to produce massive Ia-positive macrophage accumulations when injected i.p., whereas MCF-a accumulated Ia-negative macrophages. The data suggest that MCF-a and -b, which mediate initial macrophage reactions, attract Ia-negative macrophages, and that MCF-c, which mediates predominant macrophage reactions, attract Ia-positive macrophages in the DHR.     

Noncytolytic extraction of soluble antigens from leukemic blast cells (L2C-EN)

Summary Lithium 3,5 diiodosalicylate (LIS), a chemical utilized for the noncytolytic extraction of cell surface antigens, was used in this study to extract glycoproteins from the cell membranes of L₂C-EN leukemic blast cells. The crude soluble antigen (LIS-L₂C) preparation was found to confer immunoprotection in syngeneic guinea pigs against a lethal challenge of L₂C-EN. Titration of the crude LIS-L₂C soluble antigen extract revealed that 1 mg antigen gave 100% protection against a 2×10⁵ viable tumor cell challenge 2 weeks after immunization and that immunizing doses of 0.1 mg, 0.25 mg, and 0.5 mg soluble antigen afforded 17%, 66%, and 83% protection, respectively. The specificity of this immune response was demonstrated by the failure of guinea pigs immunized with 1 mg LIS extract prepared from another guinea pig tumor (line 10 hepatoma) to be refractory to a similar L₂C tumor cell challenge. A cell-mediated immune response to the LIS-L₂C soluble antigen was observed in animals, based on a positive delayed hypersensitivity response to the soluble antigen 5 weeks after immunization. Similarly, in vitro testing revealed a specific blastogenic recognition of the soluble antigen by immune leukocytes.     

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.     

Phytohemagglutinin-induced proliferation of guinea pig thymus-derived lymphocytes. I. Accessory cell dependence.

The accessory cell requirement for mitogen-induced T lymphocyte proliferation has been investigated by using a population of guinea pig lymph node lymphocytes enriched in T cells and markedly depleted of macrophages and B lymphocytes. We have found that effective phytohemagglutinin-induced proliferation of T cells is dependent on the participation of accessory cells. Augmentation of PHA responsiveness was noted when cultural conditions were manipulated to increase cell density, suggesting that physical proximity between T cell and accessory cell is required for efficient triggering. Both syngeneic and allogeneic macrophages, as well as syngeneic fibroblasts, serve as accessory cells in this response whereas polymorphonuclear leukocytes or thymocytes do not. Thus, although PHA-induced T lymphocyte proliferation requires accessory cells, the specificity of these cells is strikingly less stringent than for antigen-mediated triggering of immune guinea pig T cells, a response which is dependent upon participation of syngeneic macrophages.     

Ia-specific mixed leukocyte reactive T cell hybridomas: analysis of their specificity by using purified class II MHC molecules in synthetic membrane system

This study was undertaken to determine the nature of the antigens recognized in allogeneic and syngeneic mixed leukocyte reactions (MLR). Specifically, we wished to determine whether Ia antigens alone were recognized by MLR-reactive T cells, or whether the specificity was determined by the corecognition of non-MHC antigens together with syngeneic or allogeneic Ia. To do this we used 11 T cell hybrids that were characterized as being specific for Iad and were tested their capacity to respond to isolated I-Ad or I-Ed that had been incorporated into liposomes and had bound to the surface of glass beads. Of nine alloreactive T cell hybrids (five I-Ad-and four I-Ed-specific), seven were shown to be responsive to the relevant isolated Ia antigen on glass beads. Also, two of two syngeneic I-Ad-specific T cell hybrids responded to I-Ad on the glass beads. One of the two alloreactive T cell hybrids that failed to respond to the relevant Ia antigen on glass beads was shown to be specific for an antigen in fetal calf serum (FCS) that was recognized in the context of the allo-Ia antigen (I-Ed), because when intact accessory cells were used, a response by this hybrid was only observed when FCS was present in the assay culture medium or when the accessory cells were pre-pulsed with FCS. The possible involvement of FCS antigens and non-Ia accessory cell antigens in the stimulation of the nine T cell hybrids that responded to isolated Ia on glass beads was evaluated. T cell hybrids that were grown and were tested in serum free medium were still capable of reacting to Ia on beads. The isolated Ia preparations used were greater than 90% pure, and their capacity to stimulate the T cell hybrids did not correlate with the degree of contamination with non-Ia proteins. We conclude from these studies that the majority of T cells that respond to allogeneic or syngeneic Ia bearing stimulator cells are specific for the Ia antigens themselves, and do not require the co-recognition of other non-Ia antigens; nor is there any requirement for Ia antigen processing for this recognition.     

Macrophage-T cell interaction mediated by immunogenic and non-immunogenic forms of a monofunctional antigen

Summary As an approach to the elucidation of the essential steps in the immune pathway, the uptake and retention of immunogenic and non-immunogenic analogs of a monofunctional antigen by guinea pig macrophages and the efficiency of macrophages pulsed with the compounds to present antigen to sensitized T lymphocytes were compared. L-Tyrosine-azobenzene-p-arsonate (RAT) and its non-immunogenic analog, 4-hydroxyphenyl-n-propane-3-azobenzene-p-arsonate (RAN), react similarly with antiarsonate antibody, but RAN, unlike RAT, is unable to induce cellular immunity in guinea pigs. The uptake and retention patterns of the two compounds by macrophages differed in that, at a given time, more RAN than RAT was retained and detectable on cell surfaces by anti-arsonate antibody. Equivalent numbers of T lymphocytes from guinea pigs sensitized to RAT formed antigen-dependent clusters with macrophages pulsed with either RAT or RAN after 24 hr in culture, but not with macrophages pulsed with an azobenzenoid compound of unrelated specificity. On the other hand, T lymphocytes from guinea pigs immunized with RAN showed no significant capacity to bind to macrophages which had been pulsed with any of the compounds. The number of lymphocytes from RAT-sensitized animals which bound to RAT-pulsed macrophages remained relatively stable over a 48 hr period, whereas clusters of the same lymphocytes with RAN-pulsed macrophages dissocitated to background levels within that time. Early cluster formation mediated by RAN, as well as its ability to induce transient specific T cell unresponsiveness to RAT in vivo, indicate that T cells are capable of recognizing (binding) the non-immunogen. However, such early, and perhaps weak, interaction with RAN-pulsed macrophages did not induce DNA synthesis by T cells. Anti-Ia serum completely blocked cluster formation mediated by either RAT or RAN. Thus, the only significant distinction disclosed by these studies between the immunogenic and non-immunogenic compounds was the stability of macrophage-T cell interaction as determined by the persistence of antigen mediated cell clusters in culture, suggesting that this may be a factor in immunogenic discrimination.Abbreviations ABA azobenzenearsonate - BSA bovine serum albumin - CFA complete Freund's adjuvant - IFA incomplete Freund's adjuvant - KLH keyhole limpet hemocyanin - LNC Lymph node cells - MHC major histocompatibility complex - PEC peritoneal exudate cells - PEL peritoneal exudate lymphocytes - RAN 4-hydroxyphenyl-n-propane-3-azobenzene-p-arsonate - RAT L-tyrosine-azobenzene-p-arsonate - TAT L-tyrosine-azobenzene-p-trimethylammonium chloride Aided by USPHS Grant AI 05664.     

Regulation of macrophage populations. I. Preferential induction of Ia-rich peritoneal exudates by immunologic stimuli

The amounts of Ia-positive and -negative macrophages were studied in peritoneal exudates of normal mice or of mice injected with various inflammatory materials, infected with Listeria monocytogenes, or injected with hemocyanin. Ia-negative macrophages predominated in exudates from normal mice or from mice given mineral oil, peptone, thioglycollate, culture media, or endotoxin. Infection with Listeria caused a very marked increase in Ia-positive macrophages. The induction of Ia-positive macrophages by Listeria inoculation resulted in great part from an immune process. The Ia-positive exudates were more readily generated in immune mice given a secondary challenge with heat-killed organisms. Furthermore, immune T cells transplanted together with heat-killed organisms into normal mice resulted in Ia-rich exudates. Injection of hemocyanin also induced Ia-rich exudates involving an immune process. We conclude that an immune reaction involving T cells regulates the Ia phenotype of the exudate macrophage population. The Ia-positive macrophages were Fc and C3 receptor positive and phagocytized latex particles.     

Identification of the principal cell type yielding immune RNA capable of transferring tumor-specific cellular cytotoxicity

A search was made for the lymphoid cell type(s) which are the source of immune RNA (I-RNA) capable of transferring tumor-specific cell-mediated cytotoxicity (CMC). Hartley guinea pigs were immunized with syngeneic murine fibrosarcomas (BP-10 or BP-11) induced by 3,4-benzo(a)pyrene in C3H/HeJ mice, and the I-RNA was extracted individually from their spleens, lymph nodes, and peritoneal exudate (PE) cells. All three I-RNA preparations were able to convert normal C3H/HeJ mouse lymphocytes to effector cells significantly cytolytic to the specific syngeneic mouse tumor in vitro. Furthermore, lymphocytes and macrophages were purified from the spleens, lymph nodes, and PE cells of tumor-immunized guinea pigs. I-RNA was extracted from these purified cell populations and also from the pooled guinea pig lymphoid tissues. Normal C3H/HeJ lymphocytes were incubated with each type of I-RNA and tested in vitro for CMC against the specific tumor cells. Significant CMC against BP-10 targets was observed with mouse lymphocytes incubated with I-RNA extracted from pooled lymphoid tissues of BP-10 tumor-immunized guinea pigs. There was a reduced but still significant CMC when mouse lymphocytes were incubated with I-RNA extracted from purified guinea pig lymphocytes, whereas there was a markedly increased CMC when the I-RNA was extracted from purified guinea pig macrophages. As indicated by sucrose density gradient analysis, the lesser effectiveness of lymphocyte I-RNA was not due to RNA degradation resulting from lymphocyte purification or I-RNA extraction. Treatment of all types of I-RNA with RNase abrogated the transfer of CMC, whereas treatment of I-RNA with DNase or pronase did not. RNA extracted from the lymphoid tissues of guinea pigs immunized with complete Freund's adjuvant without tumor was ineffective. Mouse lymphocytes incubated with BP-10 macrophage I-RNA destroyed BP-10 but not BP-11 tumor cells, whereas lymphocytes incubated with BP-11 macrophage I-RNA killed BP-11 but not BP-10 tumor cells, thus indicating tumor specificity of the immunity transferred by macrophage I-RNA. Our results suggest that macrophages are the principal source of I-RNA capable of transferring tumor-specific CMC.     

Intraepithelial lymphocytes modulate Ia expression by intestinal epithelial cells

We have demonstrated that although intestinal epithelial cells in fetuses and young rats do not express Ia antigens, in adult rats intestinal epithelial cells do express Ia antigens, as indicated by immunoperoxidase staining with monoclonal antibodies. Ia expression by intestinal epithelial cells appeared to be related to an increase in the number of intraepithelial lymphocytes (IEL). Most of the IEL were T cells and expressed the phenotype associated with cytotoxic/suppressor T cells, and a large number contained cytoplasmic granules. To directly study a possible modulating effect of IEL on intestinal epithelium, an Ia-negative intestinal epithelial cell line (IEC 17) of rat origin was cultured in the presence of supernatants obtained from Con A- or PHA-stimulated lymphocytes. IEL, as well as spleen cells but not bone marrow cells, were able to secrete a factor(s) capable of inducing Ia antigens on IEC 17 cells, as judged by immunoperoxidase staining and radioimmunoassay. Ia-positive IEC 17 cells were detectable after 12 hr and maximum Ia expression was obtained by 48-hr incubation. Persistence of Ia expression by intestinal epithelial cells required the continued presence of Ia-inducing factor in the medium. Lymphocyte proliferation was not essential for the secretion of the Ia-inducing factor(s). The characteristics and the kinetics of secretion of the Ia-inducing factor were similar to that of an interferon-like activity, but not of interleukin 2. Con A-induced supernatants from IEL and spleen cells were also capable of suppressing the growth of IEC 17 cells. The results of this study indicate that IEL, because of their close association with intestinal epithelial cells, may be involved in modulating a variety of epithelial cell functions, including the expression of Ia antigens. This leads us to speculate that Ia-positive epithelial cells, like Ia-positive macrophages and dendritic cells, may be involved in antigen presentation to T lymphocytes.     

The role of B lymphocytes in cell-mediated immunity II. Delayed hypersensitivity induced by dinitrophenyl-ficoll in dinitrophenyl-keyhole limpet hemocyanin-immunized guinea pigs.

Dinitrophenyl (DNP)-Ficoll will elicit typical delayed hypersensitivity skin reactions in guinea pigs immunized with DNP-keyhole limpet hemocyanin (KLH). We observed that lymph node cells (LNC) from these animals produced the lymphokine, monocyte chemotactic factor (MNL CTX) when stimulated by DNP-Ficoll in vitro. This response was antigen and hapten specific since LNC from nonimmune guinea pigs or those immunized with nonDNP containing antigens were not stimulated by DNP-Ficoll. Lymph node cells were fractionated into T- and B-cell-enriched populations to determine the nature of the DNP-Ficoll-responsive cell. Only the B-lymphocyte-enriched population produced MNL CTX in response to DNP-Ficoll. The purity of the B-cell population was demonstrated by its failure to respond to PHA and by the fact that B cells derived from DNP-although they could no longer respond without T-cell help to the T-dependent antigen, DNP-OVA. These findings suggest that the hapten-specific response of guinea pigs to DNP-Ficoll may be a form of B-cell-mediated delayed hypersensitivity.     

Dissection of the functions of antigen-presenting cells in the induction of T cell activation

The functions of antigen-presenting cells (APC) in the initiation of T cell activation was examined by culturing antigen-bearing guinea pig macrophages (M phi) with T cells obtained from antigen-primed animals. Although such antigen-bearing M phi stimulated primed syngeneic T cell DNA synthesis, as assessed by tritiated thymidine incorporation, paraformaldehyde fixation (0.15% for 1 min at 37 degrees C) abolished this capacity. Analysis with acridine orange staining indicated that fixed antigen-bearing M phi could not trigger primed syngeneic T cells to progress from the G0 to the G1 phase of the cell cycle. The addition of control non-antigen-bearing syngeneic or allogeneic M phi but not interleukin 1 or 2 to cultures of T cells and fixed APC permitted a proliferative response. Although the interaction between fixed antigen-bearing M phi and responding T cells was genetically restricted, there was no similar restriction for the supplemental control M phi. In fact, completely Ia-negative endothelial cells (EC) and fibroblasts (FB) could restore antigen responsiveness to cultures of fixed antigen-bearing M phi and syngeneic responding T cells, although they could not directly present antigen. Moreover, metabolically intact accessory cells, including Ia-negative EC and FB, could take up and process antigen to an immunogenic moiety, which fixed Ia-positive M phi could present to primed T cells. These data indicate that recognition of the antigen-Ia complex on an APC is necessary but not sufficient to trigger proliferation of freshly obtained primed T cells. The results additionally support the conclusion that APC carry out at least two separate functions necessary for the initiation of antigen-induced T cell activation. Not only must the APC display the antigen-Ia complex, but it must also convey another required effect. This influence, which apparently involved the establishment of cell to cell contact, was neither Ia nor antigen dependent and could only be provided by a metabolically intact cell. By contrast, genetically restricted antigen presentation could be accomplished by a fixed Ia-positive cell. Only when both the antigen-Ia complex and the influence of an intact accessory cell were provided by the same or different accessory cell were T cells triggered to enter the cell cycle.