The cytolytic T lymphocyte response to trinitrophenyl-modified syngeneic cells. I. Evidence for antigen-specific helper T cells.

Mice were primed subcutaneously with trinitrophenyl (TNP)-modified syngeneic spleen cells. Seven days later, spleen cells from these in vivo primed mice, or spleen cells from naive mice, were co-cultured with TNP-modified syngeneic cells. Spleen cells from the in vivo primed mice demonstrated augmented cytolytic T lymphocyte (CTL) activity. The spleens of these in vivo primed mice contained a population of radioresistant, antigen-specific, helper T cells. Specifically, spleen cells from these mice, after x-irradiation, were able to augment the in vitro CTL response of normal spleen cells to TNP-modified syngeneic cells.     

Regulatory mechanism of delayed-type hypersensitivity in mice. I. Properties of memory cpells and suppressor cells for delayed-type hypersensitivity against ovalbumin.

Delayed-type hypersensitivity (DTH) response in mice induced by sc injection of alum-absorbed ovalbumin (OA) was accelerated and enhanced by priming sc with a low dose of urea-denatured ovalbumin (UD-OA), 2 or more days earlier, whereas it was suppressed by priming sc with a high dose of UD-OA, 0 or more days earlier. The ability in primed mice to accelerate or suppress the DTH response could be transferred antigen specifically into cyclophosphamide (CY)-pretreated recipients or normal recipients by spleen cells from primed mice, but not by the T-cell-depleted spleen cells. Furthermore, the ability of spleen cells to transfer the acceleration or the suppression appeared transiently around 7 or 4 days after priming, although the acceleration or the suppression in donor mice persisted for a much longer time. Pretreatment with CY abolished the suppression of DTH response in high dose-primed mice and resulted in the acceleration of DTH response. These results suggest that the activity of DTH-related memory T cells which accelerate and enhance the response can be inhibited by suppressor T cells for the DTH response.     

Generation of specific helper cells and suppressor cells in vitro for the IgE and IgG antibody responses.

Normal splenic lymphocytes from BDF1 mice were cultured on ovalbumin (OA)-bearing syngeneic peritoneal adherent cells for 5 days and their subsequent helper function was tested by an adoptive transfer technique. Lymphocytes harvested from the culture were mixed with DNP-KLH-primed spleen cells and transferred into irradiated syngeneic mice followed by challenge with DNP-OA. The results showed that the cultured lymphocytes has helper function for both IgE and IgG anti-DNP antibody responses. Depletion of mast cells and T cells in the peritoneal adherent cell preparations did not affect the generation of helper cells in the culture. The helper function of the cultured lymphocytes was abolished by the treatment with anti-theta antiserum and complement and was specific for ovalbumin. The OA-specific helper T cells were generated in vitro by the culture of a T cell-rich fraction of normal spleen on T cell-depleted OA-bearing peritoneal cells. If the normal splenic lymphocytes or T cell-rich fraction were cultured with 10 mug/ml of OA in the absence of macrophages, cultured lymphocytes lacked helper function. The transfer of splenic lymphocytes or splenic T cells cultured with soluble OA to normal non-irradiated mice, however, suppressed both IgG and IgE antibody responses of the recipients to subsequent immunization with DNP-OA. The suppressor cells were sensitive to anti-theta antiserum and complement and their activity was specific for OA. The cultured cells transferred into normal mice did not suppress anti-hapten antibody response to DNP-KLH. Normal lymphocytes cultured on OA-bearing macrophages and had helper function in adoptive transfer experiments failed to suppress antibody response of non-irradiated recipients to DNP-OA. The results indicate that OA-bearing macrophages primed T cells and generated helper T cells, whereas the culture of normal lymphocytes with soluble OA in the absence of macrophages generated suppressor T cells.     

In vitro immune response to the 2,4,6-trinitrophenyl determinant in aged C57BL/6J mice:changes in the humoral immune response to, avidity for the TNP determinant and responsiveness to LPS effect with aging.

An in vitro anti-TNP response of the spleen cells from aged C57BL/6J mice showed approximately 4-fold less PFC than did that from young adult mice. Anti-theta serum-treated young spleen cells gave an anti-TNP response that was definitely greater than the response of the anti-theta serum-treated aged spleen cells in the presence of the exogenous activated thymus cells as helper cells. These results suggest that the deficits in B cells may be partly responsible for the imparied anti-TNP response of the aged spleen cells. To examine further the capacity of stem cells in the bone marrow to generate B cells responsible for anti-TNP response in the spleen, we injected i.v. 1.5 to 2.0 times 10(7) bone marrow cells from young or aged mice into lethally irradiated syngeneic recipients that had previously been thymectomized. Four to 6 weeks later, 10(7) spleen cells from the two groups of these recipient mice were immunized with TNP-SRBC in the presence of the exogenous activated thymus cells and assayed for anti-TNP PFC. The response of the aged marrow-derived B cells was approximately one-half of that of the young marrow-derived B cells.The avidity for TNP determinant of the antibodies produced by the PFC was determined by the plaque-inhibition technique. The avidity of the antibodies produced by the aged mice was approximately 33 times lower than that by the young mice. Anti-TNP response of the young spleen cells were markedly enhanced by the addition of LPS to the cultures, whereas no or little enhancement of the response was induced in the aged spleen cells even in the presence of high concentration of LPS. In contrast, DNA synthesis of both the young and aged spleen cells was comparably stimulated by 1 mug/ml and 10 mug/ml of LPS, however, it was rather less in the aged spleen cells at a concentration of 100 mug/ml. Mechanisms responsible for the changes in avidity and responsiveness to LPS with aging are discussed.     

Transition in the character of immunological memory in mice after immunization. II. Memory in T and B cell populations.

Teh immunological memory in antibody response of mice to bovine serum albumin (BSA) was investigated at the level of antibody-producing cells or their precursor B cells and thymus-dependent helper T cells. Spleen cells obtained from mice previously primed with alum-precipitated BSA at various times were transferred to irradiated syngeneic mice. Spleen cells from mice immunized 8 days or 64 days before presented a high degree of adoptive secondary response, whereas the adoptive response of cells from mice immunized 2 days previously was found to be inferior even to that of unprimed spleen cells. Primed spleen cells treated with anti-mouse thymocyte rabbit serum plus complement were supplemented with normal thymus cells and the restoration of the responsiveness was examined. It was suggested that the memory was carried mainly by T cells in the earlier phases of the immunological memory (2 days or 8 days after the primary immunization). On the other hand, the immunological memory in the B-cell population was shown to grow gradually toward the later phase (later than 40 days).     

A requirement for helper T cells in the induction of delayed-type hypersensitivity

This paper describes a model system for studying the role of helper T cells in the induction of delayed-type hypersensitivity (DTH). Cyclophosphamide- (CP) treated mice sensitized with antigen 3 days later develop high levels of delayed-type immunity; however, DTH cannot be demonstrated in mice that are sensitized with antigen 1 day after drug treatment. The inability to respond to antigen 1 day after CP treatment can be restored if either normal or low-dose primed spleen cells are transferred at the time of sensitization. Although irradiated (1500 rad) normal spleen cells are unable to restore DTH, such treatment has no effect on the primed spleen cell population. The lymphocytes responsible for restoring the DTH response were identified as T cells, in that treatment with anti-Thy-1.2 serum and C abrogated their effect. Furthermore, restoration of the DTH response was dependent on the presence of antigen at the time of lymphocyte transfer; irradiated primed cells could not transfer DTH alone. The DTH effector cells in reconstituted mice were identified as originating from the host and not from the transferred cell population. This was accomplished by using anti-H-2 serum to identify the source of the DTH effector cells after transferring parental (H-2b) irradiated primed spleen cells into CP-treated F1 mice (H-2b,k). Thus, the irradiated transferred cells are behaving as helper T cells and promoting the development of DTH effector cells in the host.     

Transition in the Character of Immunological Memory in Mice after Immunization

The immunological memory in antibody response of mice to bovine serum albumin (BSA) was investigated at the level of antibody-producing cells or their precursor B cells and thymus-dependent helper T cells. Spleen cells obtained from mice previously primed with alum-precipitated BSA at various times were transferred to irradiated syngeneic mice. Spleen cells from mice immunized 8 days or 64 days before presented a high degree of adoptive secondary response, whereas the adoptive response of cells from mice immunized 2 days previously was found to be inferior even to that of unprimed spleen cells. Primed spleen cells treated with anti-mouse thymocyte rabbit serum plus complement were supplemented with normal thymus cells and the restoration of the responsiveness was examined. It was suggested that the memory was carried mainly by T cells in the earlier phases of the immunological memory (2 days or 8 days after the primary immunization). On the other hand, the immunological memory in the B-cell population was shown to grow gradually toward the later phase (later than 40 days).     

Establishment of unresponsiveness in primed B lymphocytes in vivo

As an approach to examine the influence of the state of cellular activation on the ability to tolerize B cells, the induction of unresponsiveness in human gamma-globulin-(HGG) primed B lymphocytes was studied in an adoptive transfer system. In contrast to transferred normal spleen cells, spleen cells from HGG-primed mice are not readily rendered unresponsive when exposed to the tolerogen, deaggregated HGG (DHGG), in irradiated recipients. A kinetic study showed that unfractionated primed spleen cells do not respond to an antigenic challenge given between 6 and 10 days after cell transfer and injection of DHGG, indicating that they are transiently depressed. In contrast, isolated primed B cells are tolerized when transferred to recipients and treated with DHGG in the absence of T cells. Furthermore, primed B cells exposed to tolerogen in the recipients do not recover the ability to respond to HGG either after a secondary challenge with AHGG given up to 14 days after transfer, or after 2 consecutive challenges given on days 14 and 24 after transfer. The presence of primed T cells at the time of tolerization interferes with the induction of unresponsiveness in these primed B cells. These studies suggest that the presence of primed T cells is responsible for the inability to tolerize unfractionated primed spleen cells populations and that primed B cells themselves are not intrinsically resistant to the induction of unresponsiveness.     

Regulation of antibody response in different immunoglobulin classes. II. Induction of in vitro IgE antibody response in murine spleen cells and demonstration of a possible involvement of distinct T-helper cells in IgE and IgG antibody responses.

In vitro induction of anti-DNP IgE as well as IgG1, IgG2a antibody responses was shown in murine spleen cell culture. Spleen cells primed three times with 1 mug of DNP-OA or DNP-Asc produced significant amounts of anti-DNP IgE as well as IgG antibodies by the in vitro stimulation with DNP-OA or DNP-Asc, respectively. Collaboration between DNP-primed B cells and carrier-primed T cells was required for the induction of both IgE and IgG antibodies with DNP-coupled T-dependent antigen. Carrier-specific T cells induced with a low dose of Asc (0.01 mug) showed helper function only on IgE antibody response, whereas T cells primed with a higher dose of Asc (10 mug) cooperated only with IgG-B cells. T cells primed with Asc in CFA showed helper function mainly on IgG antibody response but not on IgE antibody response. The result indicated the presence of a distinct population of T helper cells for IgE and IgG antibody responses. T-independent antigen (DNP-Ficoll) induced both anti-DNP IgE and IgG antibody responses in DNP-primed spleen cell population without the requirement of the collaboration of helper T cells.     

Transfer of agammaglobulinemia in the chicken. II. Characterization of the target of suppression

The T-independent adoptive primary and secondary responses of FP chicken spleen cells to B. abortus (BA) were suppressed by simultaneously transferred histocompatible spleen cells from agammaglobulinemic (Aγ) chickens previously injected with bursa cells. The response of spleen cells transferred with BA 2 days prior to suppressor cells was partially inhibited. Highly significant suppression of both 19 S and 7 S antibody formation was seen during the second week after memory cell transfer. When suppressor cells and primed spleen cells were transferred together and challenged with BA 2 weeks later the secondary responses were more inhibited in recipients that showed persistently decreased serum IgM than in those showing recovery toward normal IgM levels. Transfer of histocompatible suppressor cells into surgically bursectomized (SBX). irradiated, 4-week-old SC and FP strain recipients caused reduction or complete disappearance of serum IgM and lowered IgG levels, which correlated well with a decrease in plasma cell numbers in spleen and trident. Many recipients of both strains, examined 1 to 2 weeks after transfer, completely lacked plasma cells from gut-associated lymphoid tissues and from spleen. When such animals had been sensitized to BA prior to transfer and were challenged after recovery from suppression, they showed good secondary responses. Experiments with serially transferred memory cells using suppressed intermediate hosts also indicated survival of such cells in the face of marked suppression of antibody synthesis. Bursa follicles that were not destroyed by irradiation did not show any effect of the suppressor cells, although plasma cells often disappeared from the interfollicular areas. Intact irradiated recipients showed a greater tendency toward recovery from suppression than did SBX recipients. Although Ig-bearing cells in spleen and peripheral blood of suppressed animals were significantly lower than in irradiated SBX controls, they never disappeared as completely as did plasma cells and serum IgM. The results suggest a direct effect of suppressor cells on antibody-forming cells with a less marked effect on their precursors.     

In vivo-induced suppression of T cell proliferation: the relationship between the specificity of induction and control

We have previously shown that sc immunization of C57BL/10 (H-2b) mice with the tobacco mosaic virus protein (TMVP) or with its tryptic peptide number 8, representing residues 93-112 of TMVP, induces T cells which proliferate in vitro in response to TMVP and to peptide 8. In contrast, immunization of B10.BR (H-2k) mice either with TMVP or with peptide 8 induces T cells which respond in vitro to the homologous but not the heterologous Ag. In the present article , we report that in the B10.BR (H-2k) strain, ip prepriming with (TMVP) 7 days prior to sc immunization with peptide 8 causes a drastic reduction in the in vitro proliferative response of peptide 8-specific T cells while no such effect is seen in the congenic C57BL/10 (H-2b) strain. This suppression of T cell responsiveness can be transferred with TMVP-primed spleen cells. Moreover, deleting T cells from the transferred spleen cells abrogates the suppressive effect. In both H-2 haplotypes, ip prepriming with peptide 8 causes suppression of the proliferative T cell response induced by subsequent immunization with peptide 8. This prepriming has no effect on the response to TMVP immunization of B10.BR mice but does effect the response of C57BL/10 mice. Using various synthetic peptides to analyze the specificity of the suppression, we have determined that (1) T cells involved in the suppression of the proliferative T cell response to a single peptide determinant do not suppress the proliferative T cell response to other determinants on the protein antigen and (2) these T cells with suppressor function, and proliferating T cells which are ultimately regulated, can exhibit specificity for the same epitope. These studies suggest that there may exist fundamental differences as to how T cells which participate in suppression an proliferating T cells (which include mainly T helper cells) recognize protein antigens.     

Simultaneous induction of antigen-specific IgA helper T cells and IgG suppressor T cells in the murine Peyer's patch after protein feeding

The effects of feeding the dietary protein antigen, ovalbumin (OVA), on OVA-specific IgG and IgA immune responses involving Peyer's patches (PP) and mesenteric lymph nodes (MLN) were examined. Mice were administered soluble OVA by gastric intubation. One to 3 days later, PP, MLN, or spleen cells from these donor mice were adoptively transferred into normal syngeneic recipients. After two subsequent immunizations, spleens from the recipient mice were assayed for IgA and IgG anti-OVA plaque-forming cell (PFC) responses. None of the tissues from normal (unfed) mice had the inherent ability to alter recipients' IgG or IgA PFC responses. Within 1 day of OVA feeding, however, cells were generated in the PP that could augment recipients' IgA anti-OVA PFC responses and suppress IgG PFC responses. Three days after OVA feeding, these cells were present in MLN as well, and whereas the IgG suppressor cell also appeared to migrate to spleen, the IgA helper cell did not. The cells mediating antigen-specific IgG suppression and IgA help were both T cells but could be distinguished by surface phenotype. We therefore conclude that protein feeding induces differential, isotype-specific immunoregulation in gut-associated lymphoid tissues, part of which is mediated by an antigen-specific IgA helper T cell.     

Suppression of the in vitro secondary response to syngeneic tumor and of in vivo tumor therapy with immune cells by culture-induced suppressor cells.

Mice with advanced disseminated syngeneic tumor can be successfully treated with a combination of chemotherapy and adoptively transferred syngeneic immune cells. We have previously demonstrated that in vivo primed cells secondarily sensitized in vitro became more effective in tumor therapy, whereas primed cells cultured for 5 days without tumor stimulation became less effective than an equal number of uncultured fresh primed cells. Therefore, we examined stimulated and unstimulated cultures of tumor-primed cells for the presence of culture-induced suppressor cells, and determined whether in vivo tumor therapy with immune cells could be inhibited by concurrent inoculation of immune effector cells and cultured normal spleen cells, which contain culture-induced suppressor cells but are devoid of additional effector cells. The in vitro primary allogeneic response was suppressed by cultured normal spleen cells, or tumor-primed spleen cells previously cultured for 5 days with or without tumor stimulation. In vitro secondary sensitization to syngeneic tumor was suppressed by normal or tumor-primed cells that had previously been cultured for 5 days without stimulation. The majority of this suppression was mediated by T cells in the cultured populations. The efficacy of fresh tumor-primed cells, as well as primed cells secondarily sensitized in vitro, in adoptive chemoimmunotherapy of advanced tumor was diminished by concurrent inoculation of cultured normal cells. The cells mediating suppression of in vivo therapy required previous in vitro culture for induction, and were radiation sensitive.     

Transmission of hapten-specific tolerance to an unrelated carrier

The principle of linked recognition is well defined in response and suppression. Yet, to our knowledge, it is not explored in the context of tolerance. To investigate, whether the status of tolerance toward a hapten (TNP) can be transferred to a subsequently introduced carrier, animals which were tolerized by a subimmunogenic dose of hapten (TNP) coupled to syngeneic monoclonal anti-TNP IgG, with the rationale of combining the phenomena of low zone tolerance and syngeneic IgG-induced suppression, were challenged with TNP-horse red blood cells (HRBC). Conjugates of high density (40 mM) TNP-syngeneic IgG (TNP40-IgG) were immunogenic and after challenge with TNP-HRBC, animals responded to TNP and to HRBC. Yet, spleen cells (SC) of mice injected with TNP2.5-IgG and challenged with TNP-HRBC were tolerant against TNP as well as the carrier. Limiting dilution (LD) analysis revealed that subimmunogenic doses of TNP coupled to IgG resulted in diminished activation of help, failure to activate contrasuppressor T cells (TCS), and significantly augmented activation of suppressor T cells (TS). On the other hand, after challenge with TNP-HRBC, activation/expansion of carrier-specific helper (TH), suppressor, and contrasuppressor T cells were not affected by previous immunization with subimmunogenic or immunogenic doses of TNP-IgG conjugates, but HRBC-specific TCS could not interact with TNP-specific TS. Hence, to initiate tolerance it was necessary (and sufficient) that an activated and expanded TS population was not counterregulated by TCS. In this situation, an established status of dominance of suppression for the epitope TNP could not be disrupted by an immunogene carrying a multitude of new epitopes; i.e., tolerization by subimmunogenic doses of the individual epitope TNP resulted in unresponsiveness against any immunogen carrying this epitope.     

Suppressor T cells induced by soluble immune complexes can adoptively transfer inhibition of cytophilic antibody receptors on macrophages.

Immune complexes (soluble antigens of L1210 and antibody to L1210) when given to allogeneic C3H mice generated suppressor cells that inhibited receptors for cytophilic antibody on macrophages. Thymocytes or nylon-nonadherent splenic T cells (4 × 10⁷) from immune-complex-treated mice transferred this suppressive activity when injected into normal syngeneic mice. Maximal suppression of macrophages occurred 4 to 6 days after transfer. In contrast, even 5 × 10⁷ nylon-adherent, non-T spleen cells from immune-complex-treated (“suppressed”) mice failed to induce macrophage suppression in the syngeneic recipients. When T-cell-depleted “B” mice were used as recipients, neither thymocytes nor splenic T cells from suppressed mice were able to transfer suppressive activity. However, the admixture of 2 × 10⁷ normal syngeneic thymocytes with 4 × 10⁷ thymocytes from suppressed mice restored the latter's ability to elicit suppression of macrophages in T-cell-deprived recipients. Peritoneal monocytes from recipients of suppressor thymocytes (to L1210) could not attach cytophilic antibody to L1210 but could attach cytophilic antibody to EL-4 and sheep erythrocytes. Thus, suppressor T cells induced by immune complexes can transfer immunologically specific macrophage suppression (inhibition of cytophilic antibody receptors) to syngeneic recipients. The suppressor cells required the cooperation of normal T cells, suggesting either recruitment of suppressor cells from, or a helper effect by, the normal T cells, in order to produce their effect.     

Regulation of the class of immune response induced by antigen. I. Specific T cells switch the in vivo response from a cell-mediated to humoral mode

Unprimed murine spleen cells, when administered intravenously to irradiated recipients together with antigen for 7 days, are induced to display either DTH reactivity or to mount a humoral (IgM and IgG) response. The class induced depends on the number of spleen cells given to the irradiated host. A low number of cells does not support the induction of any response, a medium number only gives rise to substantial DTH reactivity, whereas a high number only mounts a humoral (IgM and IgG) response. Observations show that the higher number of T cells in a large inoculum of spleen cells, compared to the number present in a medium one, is responsible for the absence of DTH reactivity and the mounting of a humoral response. This finding suggests that the induction of DTH precursor cells may occur when fewer antigen-specific helper-T-cell-dependent signals are generated than the number of signals required to induce B-cell precursors of the IgM and IgG classes. This possibility is favored by further observations. The administration of in situ irradiated, primed helper T cells to mice reconstituted with a medium number of normal spleen cells, results both in the specific suppression of the DTH response that occurs in the absence of these primed cells and in the mounting of a humoral response.     

Induction of parasite-specific helper T lymphocytes during Trypanosoma cruzi infections in mice

Development of parasite-specific T helper cells was examined in mice infected with Trypanosoma cruzi. At various times during the course of infection mice were challenged with TNP conjugated to fixed culture forms of T. cruzi (TNP-TC), and the resultant splenic plaque-forming cells (PFC) against TNP were determined. By day 10 post-infection significant responses against TNP-TC were observed but not against TNP-BSA. Infected mice that were not challenged with TNP-TC did not produce anti-TNP PFC, which demonstrated that the TNP-TC response was not the result of nonspecific B cell activation. Treatment of spleen cells from infected mice with anti-theta antiserum plus C ablated the anti-TNP-TC response when these cells were transferred to normal mice that were subsequently challenged with TNP-TC, whereas treatment of the cells with anti-Ig plus C prior to transfer had no effect on the TNP-TC response. These results demonstrate enhancement of parasite-specific Th activity of mice infected with T. cruzi and that cell-cell interaction in development of responses to neoantigens is fully functional when sensitized Th are present, even though the animals are unresponsive to heterologous antigens.     

Peptic fragments of bovine serum albumin bind antigen-specific T suppressor cells from orally tolerized mice

The antigenic structures capable of binding immunoregulatory T cells have been investigated. The functional properties (suppression or help) of BSA-specific T cells from primed or orally tolerized mice with capacity to adhere to bovine serum albumin or its peptic fragments were examined in reconstitution experiments in which splenic T-cell populations together with naive B cells were transferred into irradiated syngeneic recipients. Antigen-specific T suppressor cells isolated from mice tolerized to BSA adhered to peptic fragments of BSA as well as to the intact antigen. BSA-specific T helper cells adhered only to the intact antigen. Our data suggest that the preferential activation of T suppressor cells following administration of peptic fragments may be due to their ability to adhere to such fragments. These findings offer a novel approach of separation and identification of T suppressor cells and may be useful in further studies of immunosuppression.     

Ongoing hapten-specific delayed-type hypersensitivity prevents generation of cytolytic T lymphocytes to the same hapten

Cytolytic T lymphocytes (CTL) specific for trinitrophenyl (TNP)-altered self antigens can be generated in vivo through the simultaneous injection of TNP-modified syngeneic spleen cells and H-2-compatible, minor histocompatibility locus (Mls)-disparate auxiliary spleen cells into the footpads of mice. The latter stimulates host helper cells to produce differentiative and proliferative signals required for the generation of CTL. Advent of this protocol allowed investigation of the initiation of two different cell-mediated immune responses, delayed-type hypersensitivity (DTH) and the generation of CTL, in the same experimental animal. Mice presensitized for CTL were able to develop DTH as well as normal controls. However, when mice were first sensitized for DTH, they were thereafter incapable of generating CTL. This effect was hapten specific, relatively long lasting, and preventable by treating mice with cyclophosphamide before sensitizing for DTH. Adoptive transfer of lymphoid cells from DTH-immune mice conferred DTH reactivity upon naive recipients but not a suppressed CTL response. Therefore, cells mediating DTH were not responsible for suppression of CTL. The mechanism for suppression has been discussed from the viewpoint of the suppressor-T-cell circuits that are known to be generated when animals are sensitized for DTH and which are susceptible to treatment with cyclophosphamide.     

Long-term effects of in vitro sensitization on immune reactivity of lymphocytes: generation of suppressor and helper T cells.

Mouse spleen cells were cultured for 5 days with or without HRBC. Cultured cells were 'parked' in irradiated syngeneic recipients for 3 weeks and then tested for their immunologic reactivity in vitro. We found that spleen cells from recipients of HRBC-sensitized cells (S) as well as spleen cells from recipients of control unsensitized cells (U) possessed radiosensitive suppressor and radioresistant helper activities. Suppressor activity was observed by the capacity of unirradiated S and U spleen cells to inhibit the in vitro generation of IgM and IgG PFC by spleen cells primed in vivo to HRBC or to LacKLH. Helper activity was shown by the capacity of the irradiated S and U cells to restore IgM and IgG PFC responses of in vivo primed, T-depleted spleen cells to HRBC, LacHRBC, and LacCRBC. Both suppressor and helper activities were mediated by T cells. The possibilities that immunologically specific or nonspecific mechanisms account for these phenomena are discussed.