Specific suppressive factors produced by hybridomas derived from the fusion of enriched suppressor T cells and a T lymphoma cell line.

A cell fusion technique was used to produce hybridomas between the T lymphoma cell line, EL-4, derived from C57BL (H-2(b)), and an enriched population of human gamma globulin (HGG)-specific suppressor T cells prepared from the spleens of HGG-tolerant CBA mice (H-2(k)). Membrane fluorescence analysis of the hybridoma cells within 6 wk of cell fusion revealed expression of H-2(k) and I-J(k) gene products as well as H-2(b) antigens. Sonicates prepared from hybridomas which contained I-J(k) cells were tested for suppressive activity in vivo in irradiated mice given HGG-primed cells, dinitrophenyl (DNP)-primed cells, HGG-DNP, and horse erythrocytes. Among 18 such hybridoma lines, 6 showed specific suppressive activity, 5 nonspecific suppression, and 7 no suppression. Most lines progressively lost, with time, those properties derived from the normal parent cell. By about 3 mo after fusion few cells expressed CBA markers and only one cell line (number 77) retained some specific suppressive activity. In parallel with the losses was an alteration in chromosome number from near-tetraploid, soon after cell fusion, to near- diploid. Preliminary results with the T lymphoma-sensitive hypoxanthine aminopterin thymidine cell line, L5178, indicate retention of the expression of surface markers derived from the normal parent for 18 wk after hybidization. This suggests that T lymphoma cell lines may have to be screened for their capacity to produce hybridomas with stable properties.

Effect of recent antigen priming on adoptive immune responses. III. Antigen-induced selective recruitment of subsets of recirculating lymphocytes reactive to H-2 determinants.

Information was sought on the reactivity of thoracic duct lymphocytes (TDL) from parental strain mice injected intravenously with large numbers of irradiated semiallogeneic spleen cells. TDL collected at 1 day after spleen cell injection were almost totally depleted of lymphocytes able to produce cell-mediated lympholysis (CML), a graft-versus-host (GVH) reaction, and skin allograft rejection against the H-2 determinants on the injected spleen cells. Normal or near normal responses were observed against third-party determinants. In the case of CML, there was no evidence that the unresponsiveness was due to suppressor cells. In marked contrast, the capacity of TDL to exert a specific mixed lymphocyte reaction (MLR) against the injected determinants was reduced by no more than two to fourfold; this applied whether MLR were measured in vivo or in vitro. Injection of normal rather than irradiated semiallogeneic spleen cells gave similar results. Complete and specific removal of MLR-producing lymphocytes was achieved, however, in a different system in which parental strain T cells were filtered from blood to lymph through irradiated F1 hybrid mice. Since this system presumably provided a much higher concentration of H-2 determinants to the responding lymphocytes, it is suggested that the differing results obtained with these two systems may indicate that certain cells reactive to H-2 determinants are of low affinity, their reactivity being detected in the MLR, but not by other parameters. With both systems, MLR-producing lymphocytes reappeared in the lymph after 2-3 days; the cells collected at this stage gave an MLR of altered kinetics. The present data, in toto, suggest that under certain conditions of antigen presentation, virtually all recirculating lymphocytes reactive to a given set of H-2 determinants can be induced to leave the circulation for a period of 1-2 days. After responding to the injected determinants (presumably in organs such as the spleen), the cells re-enter the circulation in an activated state after 2-3 days.

Effect of recent antigen priming on adoptive immune responses. II. Specific unresponsiveness of circulating lymphocytes from mice primed with heterologous erythrocytes.

When thoracic duct lymphocytes (TDL) or mesenteric lymph node (MLN) cells from mice primed 1 day before with either sheep erythrocytes (SRC) or horse erythrocytes (HRC) were transferred together with both SRC and HRC to irradiated mice, antibody responses measured 7 days later could not be detected to the priming antigen but were high to the other antigen. Furthermore, this unresponsiveness of TDL and MLN to the priming antigen could not be abrogated by delaying antigen challenge of the transferred cells for 1-2 wk. Previous work had shown that short-term priming with antigen also induced specific unresponsiveness in spleen cells on adoptive transfer. Unresponsiveness in these cells, however, was only of temporary duration, full recovery in the reactivity of the cells being observed when challenge with the priming antigen on transfer was delayed for 5 or more days. Since the present work showed that such recovery from initial unresponsiveness on transfer was unique to spleen cells and did not apply to TDL or MLN, it appeared that different mechanisms were responsible for the unresponsiveness in the three populations. It is proposed that the unresponsiveness detected in TDL and MLN cells in the present study resulted from a deficiency of antigen-reactive cells, these cells having been recruited to the spleen, i.e., a region of antigen concentration. This concept of antigen-induced selective recruitment of circulating lymphocytes was supported by evidence that (51)Cr-labeled heterologous erythrocytes indeed localized largely in the spleen after intravenous injection but not in MLN.

Cell-to-cell interaction in the immune response. VI. Contribution of thymus-derived cells and antibody-forming cell precursors to immunological memory.

Collaboration between thymus-derived lymphocytes and nonthymus-derived antibody-forming cell precursors occurs in the primary antibody response of mice to heterologous erythrocytes and serum proteins. The purpose of the experiments reported here was to determine whether collaboration took place in an adoptive secondary antibody response. A chimeric population of lymphocytes was produced by reconstituting neonatally thymectomized CBA mice soon after birth with (CBA x C57BL)F(1) thymus lymphocytes. These mice could be effectively primed to fowl immunoglobulin G (FgammaG) and their thoracic duct lymphocytes adoptively transferred memory responses to irradiated mice. The activity of these cells was impaired markedly by preincubation with CBA anti-C57BL serum and to a lesser extent by anti-theta-serum. Reversal of this deficiency was obtained by adding T cells in the form of thoracic duct cells from normal CBA mice. Cells from FgammaG-primed mice were at least 10 times as effective as cells from normal mice or from CBA mice primed to horse erythrocytes. These results were considered to support the concept that memory resides in the T cell population and that collaboration between T and B cells is necessary for an optimal secondary antibody response. Poor antibody responses were obtained in irradiated mice given mixtures of thoracic duct cells from primed mice and of B cells from unprimed mice (in the form of spleen or thoracic duct cells from thymectomized donors). In contrast to the situation with T cells, the deficiency in the B cell population could not be reversed by adding B cells from unprimed mice. It was considered that memory resides in B cells as well as in T cells and that priming probably entails a change in the B cell population which is fundamentally different from that produced in the T cell population.

Effect of recent antigen priming on adoptive immune responses. I. Specific unresponsiveness of cells from lymphoid organs of mice primed with heterologous erythrocytes.

When spleen, mesenteric lymph node, or Peyer's patch cells from mice primed 24 h before with either sheep erythrocytes (SRC) or horse erythrocytes (HRC) were transferred together with both SRC and HRC to irradiated mice, antibody responses measured 7 days later were very low to the priming antigen but high to the other antigen. This was demonstrated either by measuring numbers of antibody-forming cells in spleen or levels of hemagglutinins in serum. Specific unresponsiveness of the transferred cells was evident in both the 19S and 7S responses. It was observed only when strict experimental conditions were followed: (a) the cell donors had to be primed with not less than 10(9) erythrocytes given intravenously; (b) the cells had to be transferred between 1 and 2 days after antigen priming; (c) antibody responses in the recipients were measured within 7 days of cell transfer, i.e., partial recovery was evident by 11 days; (d) the transferred cells had to be challenged in the recipients within 1 day after cell transfer: when challenge was delayed for 5 days or longer, responsiveness returned. The failure of cells from recently primed donors to respond to the priming antigen on adoptive transfer could be overcome by supplementing with normal spleen cells, but not with thymus alone or bone marrow alone. This implied that unresponsiveness occurred at the levels of both T and B lymphocytes, and was not due to a suppressive influence exerted by T cells. Further work is in progress to determine the mechanism of this transient state of specific unresponsiveness.

Cell-to-cell interaction in the immune response. IX. Regulation of hepten-specific antibody class by carrier priming.

Mice primed to horse erythrocytes (HRBC) produced greatly enhanced 3,5-dinitro,4-hydroxyphenylacetic (NNP)-specific indirect plaque-forming cell (7S PFC) responses when given NNP.HRBC but no difference in hapten-specific direct (19S PFC) responses in comparison to non-carrier-primed mice. The effect was carrier specific and could not be produced by simultaneous challenge of rabbit erythrocyte (RRBC)-primed mice with RRBC and NNP.HRBC. When spleen cells from HRBC-primed mice were transferred to irradiated recipients, there was again an enhanced 7S response to NNP.HRBC. The primed spleen cells could be replaced by giving activated thymus cells to HRBC together with normal spleen as a source of B cells. It is concluded that T cells influence not only the amount but also the class of antibody formed by hapten-sensitive B cells.

Enrichment of specific suppressor T cells and characterization of their surface markers.

A simple method is described which allows antigen-specific suppressor T cells to be enriched by greater than 100-fold. The enriched cells have the following characteristic markers: Ig-, Thy-1+, Ly-1-, Ly-2,3+, and I-J+. More than 30% of this population could be killed directly by an antiserum specific for the I-J subregion gene product in the presence of complement.

Expression of two alpha chains on the surface of T cells in T cell receptor transgenic mice.

CD8+ T cells taken directly from mice expressing a Kb-specific T cell receptor (TCR) transgene expressed the transgenic TCR in a bimodal profile as detected by flow cytometric analysis using a clonotype-specific monoclonal antibody. Those cells expressing the lower density of the transgenic TCR expressed the transgenic beta chain and two different alpha chains on their surface. One alpha chain was the product of the alpha transgene, whereas the other was derived by endogenous rearrangement. This report provides the first demonstration that T cells isolated directly from mice may express two different TCR clonotypes on their surface. The potential consequences of this finding for studies using TCR transgenic mice and for the induction of autoimmunity are discussed.

Suppression of T cells specific for the nonthymic parental H-2 haplotype in thymus-grafted chimeras.

The mechanism of restriction of T-cell specificity by the genotype of the thymus in allogeneic and semiallogeneic chimeras was investigated. Lack of induction of delayed-type hypersensitivity (DTH) directed against antigen in association with the nonthymic parental haplotype in naive cells adoptively transferred into chimeras suggests the existence of an in vivo suppressive mechanism. However, it was not possible to suppress the expression of DTH in sensitized cells transferred into chimeras, or to transfer this suppression to normal naive recipients.

Delayed-type hypersensitivity to allogeneic cells in mice. III. Sensitivity to cell-surface antigens coded by the major histocompatibility complex and by other genes.

DTH could be induced to cell-surface antigens coded by either H-2 or non-H-2 genes. Sensitivity was more readily induced across I region than across K- or D-region differences. The presence of an I-region difference during sensitization did not significantly increase the DTH response to K- or D-region-coded antigens. Macrophage processing appeared to be the major route of sensitization to background antigens. Thus, high levels of sensitivity were achieved equally well using viable or disrupted cells, the response was independent of the H-2 haplotype of the allogeneic cells, and transfer was restricted to the K end of the host H-2 complex. Although sensitization to H-2 antigens was obtained with disrupted cells, transfer of sensitivity against viable cells was unrestricted. This suggests a minor role for macrophage processing in sensitization to H-2 antigens.

Cell to cell interaction in the immune response. I. Hemolysin-forming cells in neonatally thymectomized mice reconstituted with thymus or thoracic duct lymphocytes.

An injection of viable thymus or thoracic duct lymphocytes was absolutely essential to enable a normal or near-normal 19S liemolysin-forming cell response in the spleens of neonatally thymectomized mice challenged with sheep erythrocytes. Syngeneic thymus lymphocytes were as effective as thoracic duct lymphocytes in this system and allogeneic or semiallogeneic cells could also reconstitute their hosts. No significant elevation of the response was achieved by giving either bone marrow cells, irradiated thymus or thoracic duct cells, thymus extracts or yeast. Spleen cells from reconstituted mice were exposed to anti-H2 sera directed against either the donor of the thymus or thoracic duct cells, or against the neonatally thymectomized host. Only isoantisera directed against the host could significantly reduce the number of hemolysin-forming cells present in the spleen cell suspensions. It is concluded that these antibody-forming cells are derived, not from the inoculated thymus or thoracic duct lymphocytes, but from the host. Thoracic duct cells from donors specifically immunologically tolerant of sheep erythrocytes had a markedly reduced restorative capacity in neonatally thymectomized recipients challenged with sheep erythrocytes. These results have suggested that there are cell types, in thymus or thoracic duct lymph, with capacities to react specifically with antigen and to induce the differentiation, to antibody-forming cells, of hemolysin-forming cell precursors derived from a separate cell line present in the neonatally thymectomized hosts.

Cell to cell interaction in the immune response. II. The source of hemolysin-forming cells in irradiated mice given bone marrow and thymus or thoracic duct lymphocytes.

The number of discrete hemolytic foci and of hemolysin-forming cells arising in the spleens of heavily irradiated mice given sheep erythrocytes and either syngeneic thymus or bone marrow was not significantly greater than that detected in controls given antigen alone. Thoracic duct cells injected with sheep erythrocytes significantly increased the number of hemolytic foci and 10 million cells gave rise to over 1000 hemolysin-forming cells per spleen. A synergistic effect was observed when syngeneic thoracic duct cells were mixed with syngeneic marrow cells: the number of hemolysin-forming cells produced in this case was far greater than could be accounted for by summating the activities of either cell population given alone. The number of hemolytic foci produced by the mixed population was not however greater than that produced by an equivalent number of thoracic duct cells given without bone marrow. Thymus cells given together with syngeneic bone marrow enabled irradiated mice to produce hemolysin-forming cells but were much less effective than the same number of thoracic duct cells. Likewise syngeneic thymus cells were not as effective as thoracic duct cells in enabling thymectomized irradiated bone marrow-protected hosts to produce hemolysin-forming cells in response to sheep erythrocytes. Irradiated recipients of semiallogeneic thoracic duct cells produced hemolysin-forming cells of donor-type as shown by the use of anti-H2 sera. The identity of the hemolysin-forming cells in the spleens of irradiated mice receiving a mixed inoculum of semiallogeneic thoracic duct cells and syngeneic marrow was not determined because no synergistic effect was obtained in these recipients in contrast to the results in the syngeneic situation. Thymectomized irradiated mice protected with bone marrow for a period of 2 wk and injected with semiallogeneic thoracic duct cells together with sheep erythrocytes did however produce a far greater number of hemolysin-forming cells than irradiated mice receiving the same number of thoracic duct cells without bone marrow. Anti-H2 sera revealed that the antibody-forming cells arising in the spleens of these thymectomized irradiated hosts were derived, not from the injected thoracic duct cells, but from bone marrow. It is concluded that thoracic duct lymph contains a mixture of cell types: some are hemolysin-forming cell precursors and others are antigen-reactive cells which can interact with antigen and initiate the differentiation of hemolysin-forming cell precursors to antibody-forming cells. Bone marrow contains only precursors of hemolysin-forming cells and thymus contains only antigen-reactive cells but in a proportion that is far less than in thoracic duct lymph.

Cell to cell interaction in the immune response. IV. Site of action of antilymphocyte globulin.

In this series of papers it has been shown that the immune response of mice to sheep erythrocytes requires the participation of two classes of lymphoid cells. Thymus-derived cells initially react with antigen and then interact with another class of cells, the antibody-forming cell precursors, to cause their differentiation to antibody-forming cells. Antilymphocyte globulin depressed the ability of mice to respond to sheep erythrocytes. This effect was more marked when the antigen was injected intraperitoneally than intravenously, and occurred only when the antilymphocyte globulin was given before or simultaneously with antigen. Injection of thymus cells restored to near normal the ability to respond to an intravenous injection of sheep erythrocytes. Spleen cells from antilymphocyte globulin-treated mice gave a weak adoptive immune response in irradiated recipients. The addition of thymus cells however enabled a response similar to that given by normal spleen cells. When thymectomized irradiated recipients were used, normal spleen cells continued to give a higher response to a challenge of sheep erythrocytes at 2 and 4 wk postirradiation than did spleen cells from ALG-treated donors. This result is more consistent with the notion that thymus-derived target cells are eliminated, rather than temporarily inactivated, by antilymphocyte globulin. These findings suggest that, in vivo, antilymphocyte globulin acts selectively on the thymus-derived antigen-reactive cells.

Relationship between Fc receptors, antigen-binding sites on T and B cells, and H-2 complex-associated determinants.

The relationship between H-2 complex-associated determinants, Fc receptors, and specific antigen-recognition sites on T and B cells was examined by binding and functional assays. The Fc receptor was detected by radiolabeled immune complexes or aggregated human IgG. Both these reagents selectively bound to B cells, not to T cells. When spleen cells, from mice primed to several antigens, were exposed to highly substituted radioactive aggregates, their capacity to transfer both a direct and indirect plaque-forming cell response to these antigens was abrogated. Addition of B cells, but not of T cells, restored responsiveness. Complexed Ig binding to Fc receptors was prevented by pretreatment of mixed lymphoid cell populations with antisera directed against membrane components on the same cell (e.g., H-2) and on other cells (e.g., theta). The lack of specificity of inhibition was thought to be due to the formation on cell surfaces of antigen-antibody complexes which would then attach to the Fc receptor during the incubation precedure. Specific blockade of the Fc receptor during the incubation procedure. Specific blockade of the Fc receptor however occurred when B cells were pretreated with the Fab fragments of anti-H-2 antibody. This was demonstrated autoradiographically and by inhibition of aggregate-induced suicide. The blocking activity of ante-H-2 Fab was removed by absorption with spleen cells from thymectomized irradiated mice but not with thymus cells of appropriate specificity. This suggested that the antibodies involved had specificity for determinants on the B-cell membrane distinct from those coded by the K or D end of the H-2 complex, and either absent from, or poorly represented on, thymus cells. Specific antigen-induced suicide of B cells was achieved simply by incubating the cells with radioactive antigen in the cold. T-cell suicide on the other hand required that the 125I-labeled antigen be presented to the T cells at 37 degrees-C on the surface of spleen cells from antigen-primed mice. Pretreatment of T cells with the Fab fragment of anti-H-2 antibody protected them from the suicide effect. By contrast no such protection of B cells could be achieved by this procedure. In other words H-2 (? Ir)-associated determinants may not only be in close proximity to the antigen-binding site on T cells but, in addition, may be involved in the effective operation of the receptor.

Cell to cell interaction in the immune response. V. Target cells for tolerance induction.

Collaboration between thymus-derived lymphocytes, and nonthymus-derived antibody-forming cell precursors occurs during the immune response of mice to sheep erythrocytes (SRBC). The aim of the experiments reported here was to attempt to induce tolerance in each of the two cell populations to determine which cell type dictates the specificity of the response. Adult mice were rendered specifically tolerant to SRBC by treatment with one large dose of SRBC followed by cyclophosphamide. Attempts to restore to normal their anti-SRBC response by injecting lymphoid cells from various sources were unsuccessful. A slight increase in the response was, however, obtained in recipients of thymus or thoracic duct lymphocytes and a more substantial increase in recipients of spleen cells or of a mixture of thymus or thoracic duct cells and normal marrow or spleen cells from thymectomized donors. Thymus cells from tolerant mice were as effective as thymus cells from normal or cyclophosphamide-treated controls in enabling neonatally thymectomized recipients to respond to SRBC and in collaborating with normal marrow cells to allow a response to SRBC in irradiated mice. Tolerance was thus not achieved at the level of thelymphocyte population within the thymus, perhaps because of insufficient penetration of the thymus by the antigens concerned. By contrast, thoracic duct lymphocytes from tolerant mice failed to restore to normal the response of neonatally thymectomized recipients to SRBC. Tolerance is thus a property that can be linked specifically to thymus-derived cells as they exist in the mobile pool of recirculating lymphocytes outside the thymus. Thymus-derived cells are thus considered capable of recognizing and specifically reacting with antigenic determinants. Marrow cells from tolerant mice were as effective as marrow cells from cyclophosphamide-treated or normal controls in collaborating with normal thymus cells to allow a response to SRBC in irradiated recipients. When a mixture of thymus or thoracic duct cells and lymph node cells was given to irradiated mice, the response to SRBC was essentially the same whether the lymph node cells were derived from tolerant donors or from thymectomized irradiated, marrow-protected donors. Attempts to induce tolerance to SRBC in adult thymectomized, irradiated mice 3-4 wk after marrow protection, by treatment with SRBC and cyclophosphamide, were unsuccessful: after injection of thoracic duct cells, a vigorous response to SRBC occurred. The magnitude of the response was the same whether or not thymus cells had been given prior to the tolerization regime. The various experimental designs have thus failed to demonstrate specific tolerance in the nonthymus-derived lymphocyte population. Several alternative possibilities were discussed. Perhaps such a population does not contain cells capable of dictating the specificity of the response. This was considered unlikely. Alternatively, tolerance may have been achieved but soon masked by a rapid, thymus-independent, differentiation of marrow-derived lymphoid stem cells. On the other hand, tolerance may not have occurred simply because the induction of tolerance, like the induction of antibody formation, requires the collaboration of thymus-derived cells. Finally, tolerance in the nonthymus-derived cell population may never be achieved because the SRBC-cyclophosphamide regime specifically eliminates thymus-derived cells leaving the antibody-forming cell precursors intact but unable to react with antigen as there are no thymus-derived cells with which to interact.

Induction of a primary antihapten response in vivo by a graft-vs.-host reaction.

A primary anti-NIP PFC response can be elicited by a GVH reaction provided certain structural requirements of the NIP-carrier are met. NIP-coated F(1) erythrocytes and NIP-coated parental erythrocytes give rise to substantial anti-NIP PFC responses in F(1) mice after the injection of parental spleens. These conjugates do not of themselves give rise to an anti-NIP PFC response and, in fact, normally give rise to NIP-specific tolerance. In contrast the GVH reaction is not able to enhance the primary anti-NIP PFC response to immunogenic NIP-conjugates.

Cell-to-cell interaction in the immune response. 8. Radiosensitivity of thymus-derived lymphocytes.

The helper function of carrier-primed T cells was found to be radiosensitive in vivo. The results could not be attributed to interference with the spleen-seeking properties of the irradiated cells. It is suggested that T cell division is essential for the induction of 7S antibody responses in vivo.

The frequency of clones of cytotoxic lymphocytes generated by H-2 antigens.

By using a culture system that allows the segregation of individual precursors of cytotoxic lymphocytes, the number of clones generated by cells from different combinations of congenic mice have been measured. It has been found that 0.3% of the total anti-H2d clones are generated by stimulators which differ predominantly at the H-2 locus. The contribution of non-H-2 antigens to anti-H-2 responses is discussed.

Cell to cell interaction in the immune response. 3. Chromosomal marker analysis of single antibody-forming cells in reconstituted, irradiated, or thymectomized mice.

Two new methods are described for making chromosomal spreads of single antibody-forming cells. The first depends on the controlled rupture of cells in small microdroplets through the use of a mild detergent and application of a mechanical stress on the cell. The second is a microadaptation of the conventional Ford technique. Both methods have a success rate of over 50%, though the quality of chromosomal spreads obtained is generally not as good as with conventional methods. These techniques have been applied to an analysis of cell to cell interaction in adoptive immune responses, using the full syngeneic transfer system provided by the use of CBA and CBA/T6T6 donor-recipient combinations. When neonatally thymectomized mice were restored to adequate immune responsiveness to sheep erythrocytes by injections of either thymus cells or thoracic duct lymphocytes, it was shown that all the actual dividing antibody-forming cells were not of donor but of host origin. When lethally irradiated mice were injected with chromosomally marked but syngeneic mixtures of thymus and bone marrow cells, a rather feeble adoptive immune response ensued; all the antibody-forming cells identified were of bone marrow origin. When mixtures of bone marrow cells and thoracic duct lymphocytes were used, immune restoration was much more effective, and over three-quarters of the antibody-forming mitotic figures carried the bone marrow donor chromosomal marker. The results were deemed to be consistent with the conclusions derived in the previous paper of this series, namely that thymus contains some, but a small number only of antigen-reactive cells (ARC), bone marrow contains antibody-forming cell precursors (AFCP) but no ARC, and thoracic duct lymph contains both ARC and AFCP with a probable predominance of the former. A vigorous immune response to sheep erythrocytes probably requires a collaboration between the two cell lineages, involving proliferation first of the ARC and then of the AFCP. The results stressed that the use of large numbers of pure thoracic duct lymphocytes in adoptive transfer work could lead to good adoptive immune responses, but that such results should not be construed as evidence against cell collaboration hypotheses. Some possible further uses of single cell chromosome techniques were briefly discussed.

Cell-to-cell interaction in the immune response. X. T-cell-dependent suppression in tolerant mice.

Specific immunological tolerance was induced in CBA mice by a single injection of deaggregated fowl immunoglobulin G (FgammaG). The unresponsive state was stable on adoptive transfer and irreversible by pretreatment of tolerant cells with trypsin. Tolerant spleen cells could suppress the response of normal syngeneic recipients. They also suppressed the adoptive primary response of spleen cells to FgammaG in irradiated hosts. The inhibitory effect was on the indirect (7S) plaque-forming cell (PFC) response. Incubation of the tolerant cell population with anti-theta serum and complement reversed the suppressor effect. Furthermore, the addition of purified T cells from normal donors restored the capacity of the anti-theta serum-treated tolerant cells to transfer an adoptive response to FgammaG. The existence of FgammaG-reactive B cells was supported by the demonstration of normal numbers of antigen-binding cells in the spleen and thoracic duct lymph from tolerant animals. Moreover, the formation of caps by these cells implied that they could bind antigen normally. These experiments provided direct evidence for the existence of suppressor T cells in the tolerant population. Further evidence was derived from examination of the effect of antigen "suicide". Tolerant spleen cells were treated with radioactive FgammaG under conditions known to abrogate T-cell helper function. When these cells were transferred together with normal spleen cells into irradiated hosts, suppression of the primary adoptive response to FgammaG was no longer observed. Inhibition of an adoptive secondary response to FgammaG was obtained by transferring tolerant spleen cells with primed B cells provided high doses of tolerant cells were used. By contrast low doses exerted a helper rather than a suppressor effect in this system.