T lymphocyte-enriched murine peritoneal exudate cells. I. A reliable assay for antigen-induced T lymphocyte proliferation.

The in vitro activation of murine thymus-derived (T) lymphocytes by soluble protein and synthetic antigens has been difficult to assess because of the lack of a specific and reliable proliferation assay. The present report describes the development of an assay system which overcomes these problems by making use of a population of nylon wool column-purified T lymphocytes obtained from thioglycollate-induced peritoneal exudates of immunized mice. PETLES (peritoneal exudate, T lymphocyte-enriched cells) were composed mainly of T lymphocytes, eosinophils and small numbers of macrophages. Contamination with bone marrow-derived (B) lymphocytes averaged only 2%. When PETLES from immunized mice were stimulated in microtiter cultures with the immunizing antigen, large degrees of proliferation ensued as measured by incorporation of 3H-methyl-thymidine 5 days after initiation. As few as 1.25 x 10(4) cells and as little as 50 ng/ml of antigen gave significant stimulation. Maximum responses were obtained witn a series of 10 experiments under these optimal conditions, gave a mean incorporation of 70,900 cpm while the controls cultured without antigen showed only 3,600 cpm. PETLES from nonimmunized mice or from mice immunized to other antigens did not respond to DNP5OVA although they did respond to mitogens. The antigen-induced proliferation was shown to require the presence of immune T lymphocytes by two criteria: elimination of the response by treatment with anti-Thy 1.2 serum plus complement and failure to reconstitute the response when the few remaining immune B lymphocytes left after anti-Thy 1.2 treatment were added to nonimmune T lymphocytes. In addition, the system exhibited carrier specificity. Because of the paucity of B lymphocytes in the population, their contribution to the overall magnitude of the proliferative response was negligible as demonstrated by the small response to B cell mitogens. Thus, the assay appears to be a quantitative as well as a qualitative assay for one aspect of T lymphocyte function. This technique should prove useful for the study of murine T lymphocytes in vitro.     

T cell control of the antibody response to the T-independent antigen, DAGG-Ficoll

C57BL/6J nu/nu mice respond to the type 2 TI antigen DAGG-Ficoll, but not to the TD antigen SRC. A comparable difference can also be seen in vitro, but only at high spleen cell density and in the presence of selected batches of FBS. At low spleen cell density and in the absence of FBS, the DAGG-Ficoll-induced B cell response is strictly dependent on soluble helper factors or cloned specific helper T cells. The B cell response so induced requires that the T cell-depleted spleen cells be compatible in the I-A subregion of the H-2 complex. These helper factors, induced by antigen in an I-A-restricted T cell-macrophage interaction, provide helper for T cell-depleted spleen cells irrespective of their H-2 haplotype. Under conventional culture conditions, the stringent requirement for helper factors in the in vitro response to DAGG-Ficoll is obscured by FBS. In vitro culture of low numbers of spleen cells, in serum-free medium instead of FBS, provides a sensitive assay for helper factors. We have compared the helper activity for a B cell response to SRC or DAGG-Ficoll as provided by antigen-induced supernatants of various individual EA-specific T cell clones. There was a remarkable and consistent heterogeneity among individual T cell clones: their helper activity in the response to TI and TD antigens did not correlate, nor was there any correlation between helper activity and antigen-induced TCGF (interleukin 2) activity.     

T cell priming in vivo: a major role for B cells in presenting antigen to T cells in lymph nodes

Previous studies have shown that lymph node (LN) T cells from mice given repeated injections of anti-mu antisera from birth (mu sm) fail to mount secondary T proliferative responses to antigen in vitro after s.c. priming in vivo. This finding raised the possibility that priming of T cells in LN depends on the presence of B cells, Ig+ B lymphocytes being absent in mu sm. In support of this idea, the present paper shows that the priming defect in LN of mu sm can be largely overcome by injecting B cell populations s.c. 1 day before s.c. priming with antigen. Restoration of LN priming was observed with s.c. injection of highly purified populations of small B cells but not with heat-killed or lightly irradiated B cells. Homing studies indicated that approximately 10% of s.c.-injected B cells reached the draining LN. In other studies, irradiated mice injected i.v. with purified T cells manifested poor priming in LN after s.c. injection of antigen. It was reasoned that the LN priming defect in this situation reflected the lack of B cells in irradiated mice, B cells being highly radiosensitive. In support of this notion, it was found that s.c. injection of B cells into irradiated recipients of T cells led to high priming of T cells in LN after s.c. injection of antigen. Although T cells exposed to antigen in B-depleted LN of mu sm and irradiated mice gave negligible T proliferative responses in vitro, low but significant levels of primed T helper function were detected in a sensitive T helper assay in vivo. In light of this finding, our working hypothesis is that the initial induction of T cells to antigen in LN is controlled by resident dendritic cells (or other non-B antigen-presenting cells), the main role of B cells being to control the clonal expansion of activated T cells.     

T cell regulation of immunoglobulin class expression in the B cell response to TNP-Ficoll: characterization of the T cell responsible for preferential enhancement of the IgG2a response

Syngeneic T cells injected into athymic nu/nu mice cause a preferential enhancement in the amount of IgG2a anti-TNP Ab produced by these mice to TNP-Ficoll. This enhancement appears to be caused by T cell effects on the IgG switching pathway. Through the use of F1----parent chimeras, the helper T cells were shown to affect TNP-Ficoll-responsive B cells in an H-2-unrestricted manner. The ability of T cells to mediate this IgG2a enhancement did not appear to be unique to any particular murine genetic background, because it was observed with T cells and nu/nu mice of C57BL/10, BALB/c, CBA/Ca, and B10.D2 strains. Priming of T cell donors with Ficoll or TNP-Ficoll did not increase the ability of splenic T cells, on a per cell basis, to enhance the IgG2a Ab response to TNP-Ficoll. The T cell population responsible for modulating the isotypic response was found to be sensitive to C-mediated cytotoxicity with both anti-Lyt-2 and anti-Lyt-1 hybridoma Ab. Although T cells from both the thymus and the spleen expressed enhancing activity, splenic T cells were more effective, on a per cell basis, than were thymocytes. The observations suggest that T cells that appear to enhance the switch to IgG2a in TNP-Ficoll-responsive B cells are not effectively primed by the antigen and interact with TNP-Ficoll-activated B cells through an H-2-unrestricted mechanism.     

T-cell responses induced by the parenteral injection of antigen-modified syngeneic cells. II. Mechanisms, specificity, and cellular analysis of 2,4,6-trinitrophenol (TNP)-specific cytolytic response priming by intravenous versus subcutaneous injection with TNP-modified syngeneic cells

We have examined the underlying mechanisms accounting for the enhanced in vitro TNP-specific cytotoxic T-lymphocyte (CTL) response following the parenteral injection of syngeneic hapten-modified lymphoid cells. Augmented CTL activity noted following parenteral injection (iv vs sc) of 2,4,6-trinitrophenol-modified syngeneic spleen cells (TNP-SC) is most apparent when limiting numbers of TNP-modified stimulator cells are used in the in vitro sensitization phase. Enhanced CTL responses seen following sc and iv priming is due to distinct mechanisms. Spleen and lymph node (LN) cells from sc primed mice were found to contain significant levels of radioresistant helper activity upon coculture with either viable normal spleen cells in bulk culture or with thymocytes as the source of precursor CTLs in a limiting dilution assay. The helper activity was found to be mediated by a Lyt 1+2- T cells. In addition, Lyt 2-depleted spleen and LN cells from sc primed BALB/c mice could restore the ability of tolerant spleen cells from 2,4,6-trinitrobenzenesulfonic acid (TNBS)-injected BALB/c mice to generate TNP-specific CTLs. Conversely, Lyt 2-depleted spleen and LN cells from iv primed mice provided no measurable helper activity either in bulk culture or in the limiting dilution assay and did not restore the ability of TNBS-tolerant BALB/c spleen cells to generate TNP-specific CTLs. CTL priming via the iv route was found to be completely antigen specific as iv injection of either 2,4-dinitrophenol (DNP)- or fluorescein isothiocyanatel (FITC)-modified cells caused no enhanced CTL activity. Priming via the sc route exhibited a unique specificity pattern as it was shown that sc injection of both TNP-SC and DNP-SC, but not FITC-SC, resulted in enhanced TNP-specific CTL responses. CTL T-helper (Th)-cell induction via the sc route was correlated with (1) the presence of H-2 I region determinants on the inducer cells as the sc injection of TNP-modified erythrocytes led to no enhanced CTL responses or CTL Th activity (while iv injection of TNP-erythrocytes did lead to enhanced CTL responses without detectable helper activity) and (2) the detection of both hapten-specific T-cell proliferation and Interleukin 2 (IL-2) production upon restimulation in culture. We conclude that the sc injection of TNP-SC leads preferentially to an increase of specific Lyt 1+ helper activity, while iv injection leads preferentially to an apparent expansion of Lyt 2+ prelytic effector CTLs.     

Requirement for non T-cells in the generation of cytotoxic T lymphocytes (CTL) in vitro. II. Characterization of the active cells in the spleen of nude mice.

Small numbers of LN cells will produce many more cytotoxic lymphocytes on in vitro culture with allogeneic stimulator cells if spleen cells from nu/nu mice are also present throughout the culture period. All cytotoxic cells produced are T cells and arise from precursors in the LN component. The nude spleen component appears to be providing a required non-T cell which has been lost from the LN component through dilution. At least two active subpopulations of cells, differing in sedimentation velocity, adherence properties, radiation sensitivity, and antigen recognition properties can be identified in the nu/nu spleen. The first, the dominant activity in normal nu/nu spleen, is nonadherent, radiation sensitive, and can synergize with either syngeneic or allogeneic LN cells provided both are different from the same alloantigens in the stimulator population. The second, found in nu/nu spleen cells precultured with alloantigen, sediments more rapidly, is adherent, and radiation resistant, and need not be allogeneic to the stimulator cells to synergize with LN cells. The first subpopulation may give rise to the second.     

Role of antigen-specific B cells in the induction of SRBC-specific T cell proliferation

In this study, we ask whether antigen presentation can be effected by antigen-activated B cells. Antigen-dependent in vitro proliferation of T cells from mice primed with SRBC or HoRBC occurs in the presence of B cells primed to the relevant antigen. B cells prepared from lymph nodes of mice primed with irrelevant antigens are not effective antigen-presenting cells for RBC-specific T cell proliferation over a wide range of SRBC doses. This is true even when both RBC and the antigen to which the B cells are primed are included in the culture. In contrast, B cells specific for a hapten determinant coupled to SRBC are able to support proliferation of T cells specific for SRBC determinants. We conclude from these data that antigen-specific B cells play a role in the induction of T cell proliferative responses to SRBC and HoRBC antigens. Two models are proposed: either B cells, upon antigen interaction with surface antibody, are able to act as accessory cells to induce Ia-dependent proliferation of immune T cells; or B cells augment the T cell proliferative response by secretion of antibody, leading to opsonization of the antigen for macrophage uptake and presentation.     

Antigen-induced acceleration of shedding and replacement of B cell antigen receptors requires mature T cells

To determine which early and intermediate events in the response of antigen-binding B cells to a T-dependent antigen (sheep erythrocytes [SRC]) require T help, the antigen-induced changes in receptor turnover and surface IgD loss in BALB/c athymic nu/nu mice were compared with that of nu/+ littermates and +/+ BALB/c mice. Nonimmune SRC antigen-binding spleen B cells (ABC) from +/+, nu/+, and nu/nu BALB/c mice coexpressed IgM and IgD, and 85 to 95% retained receptors well when incubated for 2.5 hr in 100 micrograms/ml cycloheximide (which prevents receptor replacement). Also they were able to regain their ability to bind antigen by 18 hr after pronase treatment, but not by 2 hr. However, 5 days after in vivo immunization, 1) the proportion of ABC expressing surface IgD declined from around 90% to less than 50% in +/+ mice and nu/+ mice but not in nu/nu mice; 2) substantial recovery of antigen-binding occurred by 2 hr after pronase treatment in +/+ and nu/+ ABC but not in nu/nu ABC; and 3) when spleen cells were incubated in cycloheximide, uncompensated receptor shedding reduced +/+ and nu/+ ABC by around 80% but produced only about a 10% reduction in nu/nu ABC. Thus, although the ABC in nonimmune nu/nu mice appeared normal with respect to their surface Ig turnover and expression, they failed to undergo the normal antigen-induced loss of IgD or acceleration of surface Ig shedding and replacement, suggesting that these intermediate activation events require interaction with mature T cells. To determine whether this interaction had to occur during B cell development, during the development of the immune response, or during receptor shedding or replacement itself, cell transfer experiments were carried our wherein nu/+ T cells were transferred i.v. to nu/nu littermates 1 day before immunization with SRC. In the transfer recipients, pronase-treated day 5 ABC were then able to replace and shed their receptors at the accelerated rate, like ABC from +/+ and nu/+ mice. In contrast, the co-incubation of 5-day immune nu/+ T cells with nu/nu B cells did not alter the rate of shedding or replacement.     

Inhibition of antigen-induced T-cell proliferation by antibodies to endogenous AKR-MuLV

Lymph node cells from BALB/c mice immunized with ovalbumin or human γ-globulin were restimulated in vitro with these antigens and assayed for antigen-induced proliferation. The proliferative response was shown to be antigen specific and T cell dependent. A rabbit antiserum to envelope and core proteins of AKR murine leukemia virus was found to inhibit antigen-induced T-cell proliferation. The IgG fraction and F(ab′)₂ fragments of the antiserum were also inhibitory. The inhibition occurred after the initial step of antigen-T cell interaction and viral absorption studies showed the inhibition to be specific for anti-AKR virus antibodies. A hypothesis for the mechanism of inhibition is discussed in relation to a functional role for endogenous murine leukemia virus.     

Propagation of antigen-specific T cell helper function in vitro.

Antigen-induced proliferation of primed lymph node cells was abrogated by treatment with anti-Ly 1 serum and complement (C) but not with anti-Ly 2 serum and C. Lymph node cells from animals primed to ovalbumin were activated with antigen in vitro, followed by propagation in an antigen-free supernatant fluid obtained from lectin-induced normal spleen cells. T cells processed in this manner displayed a stepwise enrichment of helper activity for antibody production as measured in a secondary hapten-carrier response. The sequential increase in antigen-specific help was paralleled by a rise in the antigen-induced proliferative response, a phenomenon whose expression was dependent on the presence of syngeneic or semi-syngeneic irradiated filler cells.     

Graft-vs-host reactions in F1 mice induced by parental lymphoid cells: nature of recruited F1 cells.

Graft versus host (GVH) reactivity of parental lymph node (LN) cells was assayed by measurements of 3H-thymidine incorporation in vivo. Mitomycin (Mit.) treatment of parental cells abolished their proliferative activity but the combination of such Mit.-treated parental cells with F1 LN cells resulted in much higher proliferation than either one population alone. This recruitment into proliferation of F1 cells was prominent on days 3 and 4 after cell injection and amounted to 35 to 51% of the total activity seen after injection of untreated parental cells alone. The F1 cell sensitive to recruitment was resistant to anti-Thy 1.2 treatment, was not removed by carbonyl iron-magnet separation; and was not present in thymus. The parental cell inducing recruitment was, however, sensitive to anti-Thy 1.2. When spleen cells from hapten immune F1 donors were injected together with Mit.-treated parental LN cells and boosted with hapten on another carrier, a typical "allogeneic effect" was observed in the anti-hapten immune response. It was concluded that Mit.-treated parental T cells exerted a mitogenic effect on F1 B cells resulting in extensive recruitment similar to that seen in murine mixed lymphocyte reactions.     

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.     

Effects of deoxycoformycin in mice. I. Suppression and enhancement of in vivo antibody responses to thymus-dependent and -independent antigens

The effect of 2'-deoxycoformycin (DCF) on the PFC responses of AKR mice to SE, TNP-Ficoll, and TNP-B. abortus was examined. Subcutaneous injection of DCF 4 days before antigen caused suppression of all three responses by 70 to 78%. In contrast, injection of DCF 1 day after antigen caused enhancement of both the anti-SE and the anti-TNP-Ficoll responses. Although a single high dose of cortisone acetate injected 4 days before antigen caused a similar suppression, the effect of DCF was not mediated via a steroid release, inasmuch as DCF also suppressed the immune response in adrenalectomized mice. The response of BALB/c mice to TNP-Ficoll was also inhibited by DCF pretreatment and enhanced by injection of DCF after antigen. In contrast, in athymic mice DCF caused suppression of the anti-TNP-Ficoll PFC response, whether injected before or after antigen. These results are interpreted as suggesting that DCF causes suppression primarily via an effect on B cells. The enhancement seen in normal but not in athymic mice may possibly be ascribed to an effect on suppressor T cells. Apparently the enhancement of both TD and TI responses caused by DCF injected 1 day after antigen in normal mice is the net result of these two opposing effects. The results imply that helper T cells are resistant to DCF.     

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.     

In vitro and in vivo immunosuppressive effects of supernatants from human choriocarcinoma cell lines

Local immunosuppression mediated by placental suppressor factors may contribute to the absence of consistently demonstrable cellular immunity against the fetus. In this context, we have investigated the immunosuppressive capabilities of supernatants from human trophoblastic choriocarcinoma cell lines (HCS) by testing the effects of HCS on immune responses in vitro and in vivo in the human and murine systems. HCS suppresses mitogen-induced proliferation and mixed lymphocyte reactions in humans and in mice, as well as antigen-induced T cell proliferation in mice. HCS also suppresses the in vivo response of mice to allogeneic cells. Furthermore, HCS when injected intraperitoneally causes the induction of suppressor cells in mice which in turn prevent the mounting of an allogeneic response in other strains of mice. These results indicate that human choriocarcinoma cell lines secrete a suppressor factor(s) which induces suppression in vitro as well as in vivo through the generation of suppressor cells.     

Adherent cell function in murine T lymphocyte antigen recognition. I. A. macrophage-dependent T cell proliferation assay in the mouse.

The data in this report describe a T cell proliferation assay with nylon wool column-purified murine lymph node lymphocyte from animals immunized by footpad injection of antigen in CFA. It was found that the in vitro immune response of sensitized T cells to soluble protein antigens was functionally dependent on the presence of adherent cells, more specifically macrophages, at all concentrations of in vitro antigen challenge. The response was due to T cells in that cytotoxic treatment of the immune lymphocyte cells with anti-Thy 1.2 serum and complement effectively eliminated the antigen-specific DNA synthetic responses. The antigen-specific proliferation of murine lymphocytes depleted of adhereent cells could not be reconstituted with either guinea pig macrophages nor murine fibroblasts, indicating the existence of species and cell type specificity. In contrast to previous observations in the guinea pig, soluble products of cultured adherent cells could at least partially replace the function of intact macrophages in the response to antigen.     

Production of BSF-1 during an in vivo, T-dependent immune response

BSF-1, a cytokine produced by some T lymphocyte tumors, has been shown to act with anti-Ig antibodies to stimulate B lymphocyte proliferation, to independently induce resting B lymphocytes to increase their expression of surface Ia antigen, and to induce some activated B lymphocytes to differentiate into IgG1- or IgE-secreting cells. To determine whether BSF-1 might be secreted by normal lymphoid cells in the course of a physiologic immune response, BALB/c mice were injected with an affinity-purified goat antibody to mouse IgD (GaM delta), which induces the generation of a large, polyclonal T-dependent IgG1 response; 4-hr culture supernatants of spleen cells from these mice were prepared, and these supernatants were assayed for BSF-1 activity by analyzing their ability to induce BALB/c nu/nu spleen cells to increase their expression of cell surface Ia in vitro. Culture supernatants of unfractionated spleen cells removed from mice 4 to 8 days after GaM delta antibody injection induced substantial increases in B lymphocyte surface Ia expression; these increases were blocked by a monoclonal anti-BSF-1 antibody. Culture supernatants of spleen cells from untreated BALB/c mice or from untreated or GaM delta antibody-treated BALB/c nu/nu mice induced small to moderate increases in B cell surface Ia expression, and GaM delta antibody itself induced large increases in B cell surface Ia expression; however, these increases were not significantly blocked by a monoclonal anti-BSF-1 antibody. A culture supernatant of T cell-enriched spleen cells from untreated mice induced small increases in B cell surface Ia expression that were inhibited by anti-BSF-1 antibody, as was the larger increase in B cell Ia expression induced by a culture supernatant of T cell-enriched spleen cells from mice sacrificed 3 days after GaM delta injection. On the other hand, T cell-depleted spleen cells from BALB/c mice injected with GaM delta antibody 7 days before sacrifice failed to generate culture supernatants with BSF-1 activity. Supernatants prepared from spleen cells taken from untreated mice or mice treated with GaM delta antibody 1 to 3 days before sacrifice did not block the ability of purified BSF-1 to induce an increase in B cell surface Ia expression, and thus did not contain inhibitors of BSF-1 activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

The role of T cells in IgG production; thymus-dependent antigens induce B cell memory in the absence of T cells.

B cell memory was shown to develop in congenitally athymic (nu/nu) mice after injection with small amounts of thymus-dependent antigens, in particular heterologous serum proteins, such as fown gamma-globulin (FGG) or DNP-bovine-serum albumin (DNP-BSA). Large doses of proteins (10 mg) tended to produce a specific B cell unresponsiveness, although there was still some evidence of B cell priming. The antigen did not have to be in a multivalent form to interact with B cell so as to induce immunologic memory or tolerance. In contrast to the induction of B cell memory, the production of IgG antibody in this system was found to be strongly T cell dependent. Thymus-independent antigens like LPS or POL with pronounced adjuvant effects on IgG production in normal or surgically thymectomized mice, could not replace T cells in allowing an IgG response against thymus-dependent antigens in congenitally athymic mice. However, the action of T cells once activated is likely to be non-antigen-specific, since it was shown that supernatants of antigen-activated-syngeneic T cells stimulated IgG production in cultures of primed B cell populations non-antigen-specifically.     

The T lymphocyte response to cytochrome c. IV. Distinguishable sites on a peptide antigen which affect antigenic strength and memory

The murine T cell proliferative response to the carboxyl terminal cyanogen bromide cleavage fragment 81-104 of pigeon cytochrome c (cyt) has been studied. Two interesting properties of this response have been previously described. First, T cells from B10.A mice primed with pigeon cyt 81-104 show more vigorous proliferation when restimulated with moth cyt 81-103 than when stimulated with pigeon cyt 81-104; that is, the B10.A T cell response to pigeon shows heteroclitic restimulation by moth. Second, T cells primed with the acetimidyl derivative (Am) of pigeon cyt 81-104 did not cross-react with the unmodified cyt fragments, but Am-moth cyt 81-103 still stimulated Am-pigeon cyt 81-104 primed T cells better than the Am-pigeon cyt 81-104 fragment. These results raised the issue of whether the antigenic sites on the fragments responsible for the specificity of T cell priming in vivo differed from the residues that contributed to the heteroclitic response of pigeon (or Am pigeon)-primed T cells to moth cyt c fragments. In this paper, synthetic peptide antigens were tested in order to identify which residues caused the heterocliticity of the moth fragment and which residues were involved in the antigenic differentiation of native and derivatized fragments. The heterocliticity of the T cell response to moth fragment 81-103 was found to be due to the deletion of the penultimate residue (Ala103) from the pigeon fragment. However, the ability to cause heterocliticity was not uniquely a property of this deletion. T cells from animals primed with peptides containing substitutions at positions 100 or 102 were also heteroclitically stimulated by the moth-like antigen. The observation that T cells could not be primed for recognition of the changes in peptide sequence that caused heteroclitic stimulation suggests that T cells do not directly recognize determinants in this region. The antigenically significant site of derivatization for T cell priming was found to be Lys99. Furthermore, substitution of a Gln at position 99 also resulted in elicitation of yet a third set of T cell clones specific for the presence of that residue. That is, the specificity of the primed T cell population was found to be altered by changes at residue-99, but no such alterations in specificity were demonstrable when T cells primed with peptides altered at residue-103, residue-102, or residue-100 were compared. Overall, the results demonstrate that the antigen can be divided into two functionally distinct sites that are in close physical proximity.     

Suppressor T cell mechanisms in contact sensitivity. II. Afferent blockade by alloinduced suppressor T cells.

We investigated the mechanism(s) by which MHC-restricted suppressor T cells (Ts) induced by i.v. injection of allogeneic DNP-modified lymphoid cells (alloinduced Ts) suppress the DNFB contact sensitivity response. It was shown that alloinduced Ts acted only during the early phases (afferent limb) of sensitization. They were incapable of suppressing previously sensitized recipients or of inhibiting the expression of DNFB-immune LN cells when co-transferred into normal recipients. The target of alloinduced Ts seems to be cell proliferation, i.e., inhibition of antigen-induced cell proliferation (DNA synthesis) in Ts recipient mice. The failure of recipients of alloinduced Ts to generate DNFB-immune LN cells capable of transferring contact sensitivity to normal recipients also suggests that these Ts act by preventing the development of an expanded clone of mature immune T cells. The suppressive effects of alloinduced Ts also were inhibited by prior in vitro treatment with anti-TNP serum. The data are discussed in terms of current models of suppression, and are compared to mechanisms of suppression in other contact sensitivity models.