Activation and immunoregulation of antigen-specific human b lymphocyte responses: multifaceted role of the monocyte

The multifaceted role of the monocyte in the induction and modulation of antigen-specific antibody responses by human B cells was delineated. Monocytes were absolutely required for the induction of specific antibody responses to both TT and KLH in an antigen-induced in vitro assay. Monocytes were also required for the PWM induction of specific antibody in immunized subjects. Pulsing monocytes with specific antigen or with PWM consistently stimulated proliferation of T cells in absence of added antigen and could also stimulate specific antibody synthesis although less consistently. Stimulation of specific antibody responses with antigen required fewer numbers of monocytes than did stimulation of specific antibody responses with PWM. Polyclonal antibody synthesis induced by PWM was also dependent on monocytes. However, polyclonal antibody synthesis induced by supraoptimal concentrations of antigen was usually optimal in the absence of monocytes and was actually suppressed when increased numbers of monocytes were added to monocyte-depleted cultures. Monocyte supernatants could not replace the absolute requirements for monocytes in the induction of specific antibody synthesis. However, monocyte supernatants could profoundly modulate the antigen-specific as well as the polyclonal Ig response of lymphocytes to either antigen or PWM stimulation in a manner closely resembling monocytes themselves. Thus, we demonstrated that monocytes and their products play a critical role in the activation and immunoregulation of antigen-specific antibody responses of human B cells.     

In vitro anamnestic immune responses and modulating factors

Summary The term anamnestic refers to the specific and enhanced immune responses of antigen-immunized (primed) lymphoid memory cells to secondary challenge with a foreign substance (antigen). These responses include the accelerated and quantitatively greater syntheses of antibody and other macromolecules than upon primary challenge of such cells. Rabbits were primarily immunized with keyhole limpet hemocyanin (KLH). Six days later their memory lymph node cells (LNC) were removed, and upon culture with KLH, responded with the synthesis of antibody, immunoglobulin (Ig), protein, DNA and RNA, as well as with active transport of dibutryl cyclic AMP (DbcAMP). Purified thymus-derived (T) LNC were prepared on anti-rabbit Ig affinity columns. Bursal-equivalent (B) cells were prepared by binding to a complex of sheep erythrocytes (SRBC)-antibody to SRBC-complement and centrifugation of these complexes on suitable gradients. When these T and B KLH-primed LNC were mixed and challenged with KLH the aforementioned macromolecular syntheses and active transport occurred. Indeed, by a variety of criteria, the reconstituted anamnestic immune responses were indistinguishable from these responses of unfractionated LNC. Antigenic stimulation of KLH-primed T cells induced the synthesis of proteins and DNA, but not antibody, but antigenic challenge of KLH-primed B cells did not evoke these syntheses. However, added KLH induced a mixture of T and B antigen-primed LNC to synthesize more protein, Ig, DNA than either population alone and more antibody than T cells per se; B cells required help for all of these responses. The thymus (T) cell-dependent phase of in vitro anamnestic antibody response lasted the first 24–36 hr.The antibody response was regulated by antigen-concentration. One g KLH evoked maximal antibody synthesis, 10 and 100 g KLH much less. Challenge of the separated T and B cell populations with different KLH concentrations, followed by recombination and eventual assay of antibody synthesis revealed different optima. The optimal concentration for T cell help was 0.01–0.1 g KLH; higher amounts induced much less antibody production. The optimum for B cells was 1–10 g KLH; 100 g inhibited antibody formation.The antibody response to KLH and human serum albumin (HSA) was regulated nonspecifically utilizing LNC from rabbits immunized simultaneously with these two antigens. Thus stimulation of LNC from these rabbits with either antigen induced the synthesis of antibodies to both antigens. HSA and KLH did not cross-react either serologically or cellularly. Cross-stimulation of antibody synthesis also was observed when rabbit LNC were primed with KLH and Mb. However, in this instance, cross-reaction between KLH and sperm-whale myoglobulin (Mb) was observed at the cellular, presumably the T cell, level, although not at the antibody (B cell) level. The antibody response could also be modulated by exogenous cholera enterotoxin (CT), dibutyryl cyclic AMP (DbcAMP) and prostaglandins of the E series. The addition of each substance together with 1–100 g KLH to KLH-primed LNC enhanced the antibody response many-fold. CT-induced non-immunized LNC to produce soluble factor(s) (SF) which, when added to KLH-primed LNC together with KLH, enhanced antibody synthesis significantly. The addition of Indomethacin, an inhibitor of PGE synthesis to KLH-immunized cells together with KLH inhibited antibody production, suggesting that PGE was involved in this response. Evidence was adduced that neither cyclic AMP nor PGE was required for the antibody response: Ca²⁺ was not required for induction of this response by KLH, but only its regulation by cAMP.Moreover, when KLH-primed LNC were fractionated on Nylon columns, the effluent cells were induced by KLH to synthesize antibody, but this synthesis was not enhanced by added DbcAMP or PGE; presumably, regulatory cells were removed on the column. Added KLH induced PGE synthsis in these cultures; this synthesis required macrophages. In all of the LNC cultures — including cultures from rabbits immunized with KLH, HSA, and MB months or a year earlier — much antibody synthesis occurred even when antigen was not added to the cultures. This spontaneous antibody was anamnestic, thymus (T cell)-dependent and involved the interaction of residual immunogen on dendritic cells with T and B memory cells. This spontaneous antibody response provides a model for the study of the factors involved in the longterm maintenance of humoral immunity.Mb was employed as a source of more refined antigenic determinants. Rabbits were immunized with Mb in complete Freunds adjuvant. The addition of small synthetic peptides corresponding to the five antigenic sites of Mb to the Mb-primed LNC induced the synthesis of antibody, Ig, protein, DNA, RNA, and macrophage migration inhibitory factor (MIF). The N terminal 1–6 peptide, which is not antigenic, i.e. does not combine with antibody to Mb, also induced all of these syntheses, except MIF. These peptide-induced responses appeared to be thymus-dependent.Abbreviations AP alum-precipitated - AFab goat IgG antibody to rabbit Fab - ATG goat IgG antibody to rabbit thymocytes - BGG bovine gamma globulin - Bsa bovine serum albumin - BAC bromo acetyl cellulose - B bursalequivalent lymphocytes - CT cholera enterotoxin - CRL complement receptor lymphocytes - DFA complete Freund's adjuvant-, - cAMP adenosine 3:5-cyclic monophosphate - cGMP guanosine 3:5-cyclic monophosphate - DbcAMP N⁶,O²-dibutryl cyclic AMP - EAC sheep erythrocytes sensitized with antibody and complement - FITC fluorescein isothiocyanate - HSA human serum albumin - KLH keyhole limpet hemocyanin - LNC lymph node cells - MEM minimum essectial Eagle's medium - medium; MIF m crophage migration inhibitory factor - Mb sperm-whale myoglobin - PHA phytohemagglutinin - PGE prostaglandins of the E series - PGF prostaglandins of the F series - PGSI inhibitors of prostaglandin systhesis - Slg surface immunoglobulin - T thymus-derived lymphocytes     

The immunoregulatory role of bone marrow. I. Suppression of the induction of antibody responses to T-dependent and T-independent antigens by cells in the bone marrow.

Bone marrow cells (BMC) from normal mice suppressed the in vitro IgM, but not the IgG, antibody (Ab) response of spleen cells. BMC were inhibitory only when added during the first 24 hr of culture, and inhibition was not due to an induced shift in the kinetics of the response. Addition of specifically activated T cells or nonspecific T-cell-replacing factors to normal or T-depleted spleen cell cultures did not abrogate suppression while the response to the T-independent antigen DNP-polymerized flagellin or lipopolysaccharide was also suppressed. BMC did not inhibit background Ab synthesis by normal or primed cells in the absence of antigen and did not inhibit, but stimulated, DNA synthesis in normal spleen cell cultures. In addition, high-avidity Ab synthesis was preferentially suppressed. A possible role for the bone marrow suppressor cell in the induction of B cell tolerance is discussed.     

In vitro evidence indicating a role for the Fc region of IgG in the mechanism for the long-term maintenance and regulation of antibody levels in vivo

The synthesis of anti-human serum albumin (HSA) antibody was induced spontaneously in cell cultures prepared from the draining lymph nodes of rabbits immunized months earlier with polymerized HSA. Serum from HSA-immunized rabbits suppressed this response. Removal of specific antibody from immune serum eliminated suppression and the addition of specific IgG restored suppression, indicating that the feedback phenomenon may be explained by an effect of specific IgG antibody. Fab and F(ab′)₂ fragments masked antigen as effectively as IgG; however, they were markedly inferior to IgG in mediating suppression. Furthermore, Fab competed with IgG and interfered with IgG mediated suppression. The addition of small amounts of antigen to antibody-suppressed cultures induced an antibody response. The level of induction was proportional to the antigen-antibody ratio. However, 80 to 100 times the antibody concentration needed to mask all antigenic determinants was needed in order to eliminate induction of antibody synthesis. High concentrations of antigen-antibody complexes at equivalence also suppressed the spontaneous response. This suppression was similar to antibody mediated suppression at the spontaneous response in that the Fc region of IgG was required.     

Antigen concentration determines helper T cell subset participation in IgE antibody responses.

A recently developed in vitro system for antigen-stimulated primary and secondary murine IgE antibody responses has been used to define (a) the relative participation of the Th1 and Th2 cell-derived lymphokines IFN-gamma and IL-4, respectively, in such responses, and (b) the role of antigen concentration in determining functional helper T cell activity. These studies confirm that IL-4 and IFN-gamma exert regulatory effects on IgE synthesis, but the nature and extent of their respective effects on primary and secondary IgE responses differ. Thus, primary IgE responses are considerably more sensitive to and dependent on IL-4 than are secondary IgE responses since (1) anti-IL-4 monoclonal antibody totally inhibited primary IgE responses, but only partially affected secondary responses; and (2) exogenously added IL-4 could stimulate primary IgE responses to optimal antigen concentrations, but had no effect on secondary IgE production. Likewise, antigen-stimulated primary IgE responses are about eightfold more sensitive than are secondary responses to the inhibitory effects of IFN-gamma. Studying the effect of antigen dose on the quantity of IgE antibody produced revealed that although IFN-gamma could be detected by ELISA in cultures exhibiting high-dose antigen-dependent diminution of IgE production, anti-IFN-gamma monoclonal antibody could not reverse this phenomenon. Thus, IFN-gamma is not solely responsible for decreased IgE synthesis associated with high-dose antigen exposure. IL-4 activity was detected in the fluid from cultures stimulated with low, but not high, levels of antigen. Moreover, addition of exogenous IL-4 restored IgE production to normal levels in cultures exposed to high antigen concentrations. Therefore, it appears that high levels of antigen result in selective stimulation of Th1 cells which produce IFN-gamma, and diminished activation of IL-4-producing Th2 cells. These results help explain observations regarding the influence of antigen dose on the generation of experimental and clinical IgE antibody responses in vivo.     

Studies on the mechanism of suppression by T cells in an adoptive secondary response.

Suppression of antibody synthesis by lymphocytes was studied using an adoptive secondary response model in which human serum albumin (HSA)-primed lymphocytes (memory cells) from the thoracic ducts of inbred rats were inhibited in irradiated recipients by nonimmune lymphocytes after mixed cell transfer. This investigation extended earlier work and formally showed that the suppressor cells were peripheral thymus-derived lymphocytes, which could rapidly recirculate from the blood to lymph, were present in spleen but not in bone marrow, and that primed T cells lacked this property to inhibit. The suppressive effect was independent of antigen dose but was markedly influenced by the form of antigen used for challenge in that suppression was significantly abrogated with aggregated HSA or with soluble HSA in the presence of specific antibody. Suppressor cells were found to exert their effect maximally at the time of antigen injection, but became ineffective by 40 hr following challenge. The results are considered within a larger framework of cellular regulation of antibody synthesis.     

Lectin-induced regulation of human thymus-independent anti-TNP responses in vitro

Recently we showed that human hapten-specific T cell-independent (TI) antibody responses could be elicited in vitro with the antigen trinitrophenylated Brucella abortus (TNP-Ba). Although by definition T cells are not required for TI responses, they have also shown capable of regulating such responses in the mouse. In this study we examine the ability of the T cell lectins Con A and PHA to modulate TI responses of human tonsil cells. Addition of the lectins to cultures on day 0 or day 3 resulted in inhibition (greater than 90%) or enhancement (greater than 150%) of the anti-TNP PFC response, respectively. The inhibition was only apparent if the lectins were added at the onset of culture but not 24 hr later, and was T cell-dependent, because T cell-depleted cultures (less than 0.5% E-rosetting cells) could not be inhibited. The enhancement observed was even greater in T cell-depleted cultures and was antigen-specific because TNP-SRBC but not PC-SRBC targets were lysed and the PFC were inhibited by soluble TNP (greater than 70%). This finding suggested that anti-TNP PFC precursors were proliferating more vigorously or that additional, previously antigen-insensitive cells were being recruited in the presence of lectin.     

Generalized systemic and mucosal immunity in mice after mucosal stimulation with cholera toxin

Cholera toxin (CT) has been found to be an extremely potent immunogen for mucosal IgA responses when administered via the intestine. This study has examined both mucosal and systemic immune responses after feeding CT and compared these responses with those obtained after feeding keyhole limpet hemocyanin (KLH), another protein that is strongly immunogenic in mice. Feeding CT to mice resulted not only in IgA antibody in intestinal secretions but also resulted in substantial plasma IgG and IgA antibody levels. Feeding KLH in much larger quantity resulted in little or no antibody response in intestinal secretions or plasma. Lymphoid cells from various tissues of mice fed CT were cultured in vitro for 10 days and the supernatant was tested for antibody to CT. Spontaneous antibody synthesis (no antigen added to cultures) was present in cultures of each cell type, but IgG anti-CT was found mainly in cultures of spleen and mesenteric lymph node cells and IgA anti-CT mainly in cultures of Peyer's patch and lamina propria cells. Peyer's patch cells cultured with CT as antigen synthesized both IgG and IgA anti-CT, suggesting that the antibody response to both isotypes originated in this site. Helper T cell activity for both IgA and IgG anti-CT was detected in spleens, mesenteric lymph nodes, and Peyer's patches. Lastly, when KLH and CT were fed to mice at the same time, an intestinal IgA anti-KLH and plasma IgG anti-KLH response was stimulated, a response pattern similar to that occurring to CT after CT was fed alone. We conclude that mucosal stimulation by CT generates both a systemic IgG and mucosal IgA response to this antigen, and that CT can cause a similar pattern of response to an unrelated protein antigen when both are administered into the intestine at the same time. The data favor the idea that both the IgG and IgA responses originate in GALT and then disseminate to other tissues. We propose that CT accomplishes these effects by altering the regulatory environment within GALT.     

Monoclonal antibodies that inhibit activation and proliferation of lymphocytes. II. Requisite role of the monoclonal antibody-defined antigen systems in activation and proliferation of human and rat lymphocytes

A murine monoclonal antibody (MoAb) B3 to rat cells and MoAb HBJ127 and HBJ98 to human cells were found previously to recognize the homologous antigen systems (gp130 in the rat and gp125 in the human) which are predominantly distributed on the cell surface of proliferating cells of the respective species, and the expression of the antigen systems in lymphocytes were indicated previously to correlate closely with the activation and proliferation of the lymphocytes. In this respect, the in vitro effects of these MoAb on the nucleic acid synthesis, cell cycles, or proliferation of stimulated rat and human lymphocytes were examined by use of T cell-enriched and B cell-enriched cell populations. The addition of B3 MoAb to cultures diminished Con A-induced or allogeneic mixed lymphocyte culture-induced rat T cell proliferation and lipopolysaccharide-induced rat B cell proliferation, whereas B31 MoAb, which is unreactive with the gp130 antigen, did not inhibit these lymphocyte responses. Similarly, both HBJ127 and HBJ98 MoAb could inhibit the human lymphocyte proliferation in vitro, although HBJ127 MoAb showed about eight times greater inhibitory activity than did HBJ98 MoAb; HBJ127 MoAb almost completely inhibited the DNA synthesis of the Con A-stimulated lymphocytes at concentrations higher than 13 micrograms/ml. The flow cytometric analysis of the cellular nucleic acid contents with acridine orange-stained cells showed that when B3 MoAb and Con A were simultaneously added to unstimulated rat T cells, progression of the cell cycle was blocked at the G0 to G1 transition. In this culture condition, the appearance of the B3-defined antigen was arrested in a moderate level, as determined with fluorescein-stained cells. On the addition of B3 MoAb to the culture of the T cells after 24-hr Con A stimulation, the MoAb also strongly inhibited the cellular DNA synthesis, but it did not arrest the cell cycle at a certain phase and did not modulate the corresponding antigen. These data suggest that the B3 MoAb-defined antigen on the rat lymphocytes and the HBJ127/HBJ98 MoAb-defined antigen on the human lymphocytes may play some requisite roles not only in lymphocyte activation but also in the subsequent progression through the cell cycle to proliferate.     

Immunologic function of endothelial cells: guinea pig aortic endothelial cells support mitogen-induced T lymphocyte activation, but do not function as antigen-presenting cells

The possibility that vascular endothelial cells (EC), like macrophages (M phi), can function as accessory cells necessary for mitogen- and antigen-induced T cell activation was examined. EC were enzymatically detached from the luminal surfaces of guinea pig aortas and then propagated in culture. Lymph node T lymphocytes were rigorously depleted of adherent cells, such that they completely lost the capacity to respond to mitogenic stimulation with phytohemagglutinin or concanavalin A. In this system, EC restored mitogen-induced T cell DNA synthesis as effectively as did M phi. This effect could not be explained by a facilitation of residual accessory cell activity within the responding T cell population, because EC restored mitogen responsiveness to T cells that had been treated with anti-Ia antibody and complement. Support of mitogen responsiveness could not be accounted for by secreted products of M phi or EC in the absence of intact accessory cells. In addition to the capacity to serve as fully sufficient accessory cells for the induction of mitogen-stimulated T cell proliferation, EC exerted a number of modulatory influences on T lymphocyte responses in cultures supported by M phi. When such cultures were supplemented with small numbers of EC, responses were dramatically augmented; larger numbers of EC resulted in marked suppression. At least part of these immunomodulatory effects could be accounted for by the activity of secreted products of EC. EC did not express detectable Ia antigens assayed either by indirect immunofluorescence, with the use of the fluorescence-activated cell sorter, or by complement-mediated cytotoxicity. Moreover, treating the EC population with anti-Ia antibody and complement had no effect on its capacity to support mitogen-induced T cell DNA synthesis. As would be expected from the lack of Ia antigen expression, EC were incapable of presenting antigen to primed T cells. They did, however, carry enough antigen into the cultures such that effective antigen presentation could occur when the cultures were supplemented with M phi that were syngeneic but not allogeneic to the responding T cells. Moreover, EC were capable of dramatically augmenting antigen-specific responses stimulated by antigen-pulsed M phi. There was no genetic restriction for this EC-mediated augmentation of antigen responsiveness. These results indicate that EC are capable of functioning as completely sufficient accessory cells for mitogen-induced T cell DNA synthesis and, in addition, are able to modulate ongoing M phi-supported T lymphocyte responses in both a positive and negative manner.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antigen presentation by macrophage-enriched cells from the mouse Peyer's patch

Macrophage-enriched cells derived from Peyer's patches were prepared with or without preincubation of whole patches in collagenase-containing medium. The cells thus obtained were pulsed with ovalbumin (OVA), added to OVA-primed whole lymph node (LN) cells or LN T cells and proliferative responses stimulated in the latter cells were assessed after 5 days by thymidine incorporation. Macrophage-enriched cells obtained from Peyer's patches (PP) preincubated with collagenase presented antigen as well or better than macrophage-enriched cells obtained from spleens. In contrast, macrophage-enriched cells obtained from PP which were not preincubated with collagenase were frequently unable to function as antigen-presenting cells. In further studies, macrophage-enriched cells obtained from mice which had been fed OVA were found to be capable of stimulating antigen-primed LN T cells in an antigen-specific manner without further exposure to antigen in vitro. These results indicate PP macrophage-enriched cells are fully capable of supporting the induction of immune responses in vitro and that macrophages from PP of orally primed mice may present antigen without further antigen exposure. Thus macrophages in PP may participate in the induction of immune responses to gastrointestinal antigens in vivo.     

Production of IL 2 and IFN-gamma by T cells from malaria patients in response to Plasmodium falciparum or erythrocyte antigens in vitro

T cells from patients acutely infected with malaria exhibit a disease-related stimulation of DNA synthesis in response to Plasmodium falciparum antigen in vitro. This response is weak and short-lived, suggestive of induction of suppressor mechanisms. Exogenous T cell growth factor (IL 2) that was added to antigen-stimulated T cell cultures enhanced proliferation in antigen-responsive cultures, indicating that the lymphocytes expressed IL 2 receptors. In contrast, the addition of IL 2 to cultures that did not respond to antigen had no effect. Antigen-responsive cultures contained endogenous IL 2 as well, and the antigen-induced lymphocyte proliferation was correlated with IL 2 production. However, the results suggested that IL 2 production by the patients' T cells was insufficient or actively shut off, and that this was responsible for the premature cessation of their DNA synthesis. Supernatants from 60% of the T cell cultures treated with malaria antigen and from 30% treated with RBC ghost antigen contained interferon-gamma (IFN-gamma), as determined by a cytopathic effect inhibition assay combined with acid treatment and antibody neutralization or by an IFN-gamma-specific ELISA. There was no obvious correlation between antigen-induced lymphocyte proliferation and the presence of IFN-gamma in the culture supernatants. A high IFN-gamma activity was also seen in antigen-treated cultures from P. falciparum-immune donors living in highly endemic malaria areas. In contrast, no IFN-gamma was found in supernatants of antigen-treated T cells from healthy donors or patients with Plasmodium vivax malaria. Thus, the IFN-gamma activity of these cultures appears to reflect the presence of antigen-reactive T cells and may be useful as a sensitive indicator of cellular immunity in P. falciparum malaria.     

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

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

Trypanosoma cruzi: maintenance of parasite-specific T cell responses in lymph nodes during the acute phase of the infection

Mice infected with 5 x 10(3) forms of Trypanosoma cruzi showed a transient, but severe impairment of in vitro spleen cell responses to parasite antigens and to Concanavalin A (Con A). In contrast, inguinal and periaortic lymph node (LN) cells displayed high parasite-specific proliferative responses and only a partial reduction of the Con A-induced proliferation during the acute and chronic phases of infection. Lymphocytes that underwent blastic transformation in T. cruzi-stimulated cell cultures were of the L3T4+ phenotype. Suppression of spleen cell responses occurred in the acute phase whether mice were infected with high (3 x 10(5] or low (5 x 10(3] doses of T. cruzi by intraperitoneal or subcutaneous route. Suppression of the T. cruzi-specific proliferative response of LN cells was only observed in mice infected with high subcutaneous inocula. This suppression, however, was restricted to the LNs draining the site of inoculation without affecting distant LNs. Supernatants from parasite-stimulated proliferating LN cells displayed low or undetectable T cell growth factor (TCGF) activity, in contrast with the high TCGF levels found in supernatants of the same cells stimulated with Con A. Low levels of TCGF were also detected in cultures of LN cells from mice immunized with T. cruzi extracts. Neither the T. cruzi antigen used for in vitro stimulation nor the LN cell supernatants from infected mice inhibited TCGF activity. These findings indicate that (1) parasite-specific responses are present in the LN compartment throughout the acute phase of T. cruzi infection in mice and (2) the proliferative response of L3T4+ LN cells from infected mice to T. cruzi antigens is not associated with a high TCGF secretory response.     

Induction of apoptosis in activated T cell blasts by suppressive macrophages: a possible immunotherapeutic approach for treatment of autoimmune disease

Large suppressive macrophages (LSM) were induced by restimulating spleen cells from rats with experimental autoimmune myasthenia gravis (EAMG) in vitro, with the autoantigen acetylcholine receptor (AChR) in the presence of cyclosporine A. LSM, purified from these cultures, are extremely potent suppressors of AChR-stimulated lymphoproliferative responses and antibody responses in vitro. In the present study, we have analyzed the factors that determine susceptibility of primed lymph node cells (pLNC) to suppression by LSM and examined the fate of these cells. We found three characteristics of pLNC that influenced their susceptibility to suppression. First, pLNC were required to be activated (by antigen in these experiments) in order for suppression to occur. Resting lymphocytes were not affected, even when they were present in cultures where antigen-activated lymphoblasts were being actively suppressed. Second, antigen specificity of the responder cells influenced their susceptibility to suppression by LSM. AChR-specific cells were relatively more susceptible to suppression by AChR-induced LSM than pLNC primed to an unrelated antigen, keyhole limpet hemocyanin. Third, T cell proliferation was suppressed by LSM to a far greater extent than antibody production by B cells. Using enriched T cell blasts generated from AChR-stimulated T cell lines, we found that LSM rapidly suppressed [3H]TdR uptake and induced DNA fragmentation assessed by the TUNEL assay (within 8 h of coculture) and induced morphological signs of apoptosis of T cells (within 24 h). Few, if any, blasts remained by 48 h of coculture. The ability to suppress an activated immune response permanently, without affecting nonactivated, bystander lymphocytes, holds promise that LSM, or their cellular products, could be used for immunotherapy of autoimmune diseases such as myasthenia gravis.     

Ia-restricted interaction between normal lymphoid cells and SJL lymphoma (RCS) leading to lymphokine production. I. Enhancement and suppression of antibody formation to TI antigens by supernatants and cells from cocultures of RCS and lymphoid cells

Addition of gamma-irradiated reticulum cell sarcoma (RCS) cells causes suppression of the antibody response to trinitrophenyl (TNP)-keyhole limpet hemocyanin (KLH)-primed syngeneic SJL spleen cells to TNP-polyacrylamide (PAA) in vitro. The response of anti-brain antigen (BAT) + C-treated spleen cells is not suppressed by gamma-RCS, but is suppressed by cells from 48-hr SJL lymph node or thymus + gamma-RCS cultures. Addition of as few as 2.5 x 10(5) cultured (anti-I-A + C treated to remove gamma-RCS) cells causes significant inhibition of the responses of both syngeneic and allogeneic spleen cells. Treatment of gamma-RCS-induced suppressor cells with anti-BAT + C reduces their suppressive activity. In contrast to the cells, supernatants (SN) from (lymph node (LN) + gamma-RCS) cultures greatly enhance, in an antigen-dependent fashion, the responses of untreated or anti-BAT + C-treated Sephadex G10-passed spleen cells to TNP-PAA. TNP-SIII polysaccharide, or TNP-Ficoll, but not as much to TNP-KLH. Addition of SN as late as Day 3 of culture still causes about half as much enhancement as leaving SN in throughout the culture period, but it has no effect if left with the spleen cells for only the first day of culture. SN contains high levels of IL-2 and IFN-gamma; absorption with cells from an IL-2-dependent cytotoxic T-cell line removes the enhancing activity, while treatment with pH 2 to remove the IFN-gamma has no effect. SN from an IL-2-producing T-cell line (LBRM-33) has a similar effect on antibody production to TI antigens as does SN of (LN + gamma-RCS). The results suggest a marked dependency of PFC responses to TI antigen on IL-2 in all strains examined, including SJL, LAF1, DBA/2Ha, and CBA/N, probably through a direct activation of B cells. The findings also suggest that suppressor T cells, induced by gamma-RCS in syngeneic lymphoid cells, absorb the IL-2 needed for responses to TI antigens in vitro.     

Effect of bacterial lipopolysaccharide on the in vitro secondary antibody response in mice. II. Abrogation of the suppressive capacity of endotoxin

Previous experiments have shown that bacterial endotoxin (ET) can be highly inhibitory to the in vitro secondary IgG antibody response when added 1–2 days after antigen. This paper examines the capacity of ET and another adjuvant, poly(AU), to circumvent the suppressive capacity of ET. It was found that ET or poly(AU) given simultaneously with antigen prevented any subsequent inhibition by ET added later to the cultures. Poly(AU) was effective in amounts as low as 1 μg/ml and ET in amounts as low as 0.1 μg/ml. Poly(AU) in greater amounts (50–100 μg/ml) also suppressed antibody synthesis when added 1–2 days after antigen, similar to ET. As with ET suppression, both ET and poly(AU) when added simultaneously with antigen were capable of overcoming the suppressive capacity of poly(AU). The capacity of small amounts of poly(AU) and ET to circumvent suppression in vitro by ET may help to explain why suppression by ET given after antigen has not been routinely observed in vivo. Lymphoid cells in vivo are most likely constantly exposed to either nuclear material released upon natural cell turnover or to ET from bacteria habitating the gut, resulting in an abrogation of any subsequent suppression by ET.     

Cell-mediated immune responses to syngeneic tumors. I. Identification of two distinct CTL effector pathways which differ in antigen specificity, genetic regulation, and cell surface phenotype

It has been demonstrated previously that draining lymph nodes (DLN) from tumor-immunized mice contain a population of lymphoid cells that are capable of differentiating into functional antitumor cytotoxic T lymphocytes (CTL) during in vitro culture. In the present studies, it was observed that DLN cells from either C57BL/10 (B10) or C3H mice that had been footpad-immunized with syngeneic tumor cells differentiated into CTL during a 4-day in vitro culture in the absence of added antigen. The specificity patterns of the CTL thus generated, however, were quite different in the two strains. DLN from B10 mice immunized with ultraviolet light-induced fibrosarcoma cells of B10 origin differentiated into CTL which were only capable of lysing target cells from the tumor used for immunization. Thus, the antitumor CTL which differentiate from B10 DLN appeared to be specific for the tumor-specific antigen (TSA) expressed by these tumor cells. In contrast, DLN from C3H mice immunized with a syngeneic ultraviolet light-induced fibrosarcoma differentiated into CTL which effectively lysed not only target cells from the immunizing tumor, but several other fibrosarcomas of both B10 and C3H origin, and which did not lyse normal nontumor targets. These C3H effectors thus appeared to be specific for a tumor-associated antigen (TAA) which is widely shared by a number of tumors. Cold target-blocking studies demonstrated that the CTL generated by C3H DLN cells contained a subpopulation of TSA-specific cells in addition to cross-reactive TAA-specific effectors. (B6 X C3H)F1 (B6C3F1) mice generated cross-reactive TAA-specific CTL in response to in vivo challenge with either B10 or C3H tumors, indicating that the ability to generate a TAA-specific CTL response behaves as a dominant trait of the responding mouse strain and not as a function of the tumor used for immunization. TSA-specific CTL and cross-reactive TAA-specific CTL were distinguishable on the basis of their cell surface phenotypes, because the TSA-specific CTL generated by B10 DLN cells were Thy-1.2+ Lyt-2.2+, whereas TAA-specific B6C3F1 CTL were Thy-1.2+ Lyt-2.2-; alloantigen-specific CTL generated from the same B6C3F1 lymph nodes were Thy-1.2+ Lyt-2.2+.(ABSTRACT TRUNCATED AT 400 WORDS)     

A mannoprotein constituent of Candida albicans cooperates with antigen in the induction of a specific primary antibody response in cultures of human lymphocytes

The effects of Candida albicans mannoproteins on the induction of a primary antibody response to a T-dependent antigen, sheep erythrocytes (SRBC), in cultures of human blood lymphocytes, were investigated. Two experimental systems (bulk and limiting dilution cultures) allowing the detection of both enhancing and inhibitory effects, were used. In bulk cultures, antigen alone elicited a small number of specific antibody forming cells, unless IL-2 was supplied. Addition of the fungal mannoprotein extract or of a purified constituent of it increased 5 to more than 10 times the specific response. When limiting dilution analysis was performed, we observed that: a) a similar number of specific precursor cells was induced by antigen and either IL-2 or mannoprotein; b) the plot of the number of seeded cells versus the log of the fraction of negative cultures was linear in antigen and IL-2 triggered cultures but constantly deviated from linearity when the candidal stimulant was added. Thus, more than one type of precursor cell was limiting in these cultures, and the immunoenhancing effect of mannoprotein may involve multiple cellular interactions.     

The 'co-delivery' approach to liposomal vaccines: application to the development of influenza-A and hepatitis-B vaccine candidates

DNA vaccination with mammalian-expressible plasmid DNA encoding protein antigens is known to be an effective means to elicit cell-mediated immunity, sometimes in the absence of a significant antibody response. This may be contrasted with protein vaccination, which gives rise to antibody responses with little evidence of cell-mediated immunity. This has led to considerable interest in DNA vaccination as a means to elicit cell-mediated immune responses against conserved viral antigens or intracellular cancer antigens, for the purpose of therapeutic vaccination. However, almost all current vaccines are used prophylactically and work by producing antibodies rather than cell mediated immune responses. In the present study we have therefore explored the combination of DNA and protein forms of an antigen using two exemplary prophylactic vaccine antigens, namely inactivated influenza virion and hepatitis-B surface antigen. We studied the effects of various combinations of DNA and protein on the antibody response. Co-administration of soluble forms of DNA and protein representations of the same antigen gave rise to the same level of antibody response as if protein were administered alone. In contrast, we found that when these antigens are entrapped in the same liposomal compartment, that there was a strong synergistic effect on the immune response, which was much greater than when either antigen was administered alone, or in various other modes of combination (e.g. co-administration as free entities, also pooled liposomal formulations where the two materials were contained in separate liposomal vehicles in the same suspension). The synergistic effect of liposomally co-entrapped DNA and protein exceeded, markedly, the well known adjuvant effects of plasmid DNA and liposomes. We have termed this new approach to vaccination 'co-delivery' and suggest that it may derive from the simultaneous presentation of antigen via MHC class-I (DNA) and MHC class-II (protein) pathways to CD8+ and CD4+ cells at the same antigen presenting cell--a mode of presentation that would commonly occur with live viral pathogens. We conclude that co-delivery is a very effective means to generate protective antibody responses against viral pathogens.