Two phenotypically distinct suppressor T cell subpopulations inhibit the induction of B cell differentiation by phytohemagglutinin

Human B lymphocytes can be induced to differentiate into antibody-secreting plasma cells by Leu-3+ T lymphocytes stimulated with pokeweed mitogen (PWM), a polyclonal T cell activator. In contrast, other polyclonal T cell mitogens, such as phytohemagglutinin (PHA), also activate Leu-3+ T cells but are relatively ineffective inducers of B cell differentiation. We have performed a series of experiments to investigate the mechanism underlying this apparent paradox. When human B cells were cultured with unfractionated T cells and PWM or PHA, only PWM was able to induce plasma cell formation and immunoglobulin (Ig) secretion. However, when the T cells were treated with mitomycin C (MMC) before culture, both PWM and PHA were able to induce significant B cell differentiation. These data indicated that both mitogens were able to activate the helper T cells required for B lymphocyte differentiation and suggested that MMC-sensitive suppressor T cells were responsible for inhibiting the induction of antibody-secreting cells by MMC-untreated T cells stimulated with PHA. Phenotypic analysis of the T cells capable of suppressing PHA-induced B cell differentiation revealed that small numbers of either Leu-2+ or Leu-3+ T cells could profoundly suppress the B cell differentiation induced by PHA. In contrast, significant suppression of PWM-stimulated B cell differentiation was observed only with relatively large numbers of Leu-2+ T cells. These data confirm previous reports that OKT4+/Leu-3+ T cells can suppress human B cell differentiation and indicate that the difference in B cell differentiation induced by PWM and PHA with MMC-untreated T cells is largely a reflection of the relative potency of these mitogens to activate these phenotypically distinct suppressor T cell subpopulations.     

Analysis of two distinct B cell activation pathways mediated by a monoclonal T helper cell. II. T helper cell secretion of interleukin 4 selectively inhibits antigen-specific B cell activation by cognate, but not noncognate, interactions with T cells

A single monoclonal T helper (Th) clone can activate B cells in two distinct pathways; a cognate pathway requiring a major histocompatibility complex (MHC)-restricted T-B cell interaction, and a noncognate pathway not requiring an MHC-restricted T-B cell interaction. The present study was undertaken to investigate whether Th cells mediating a given immune response provide further regulatory function to B cells other than helper function. It was demonstrated that conditions of high antigen concentration which activate a noncognate B cell activation pathway simultaneously inhibit IgG responses. The inhibition is shown to be mediated by the T cell factor interleukin 4, produced by activated cloned Th cells. The inhibitory effect of this factor is directed to B cells and is MHC-unrestricted, antigen-nonspecific, and IgG class-specific. In addition to being susceptible to the effects of augmenting cells and suppressor cells, cloned Th cell populations can therefore themselves function as regulatory cells to inhibit IgG responses when stimulated with high dose of specific antigen. These results indicate that Th cells function to regulate B cells both positively and negatively, depending upon the activation conditions.     

Analysis of two distinct B cell activation pathways mediated by a monoclonal T helper cell. I. MHC-restricted activation of B cells by an IL 2-dependent pathway

The present study was carried out to determine whether the MHC-restricted and MHC-unrestricted B cell activation pathways mediated by a single cloned Th cell are separable, and whether these two pathways are mediated by distinct mechanisms. It was demonstrated that the two B cell activating functions of a single cloned Th cell could be separated by their sensitivity to irradiation. It was shown that MHC-restricted B cell activation is mediated by a radiosensitive Th cell function, whereas MHC-unrestricted B cell activation is mediated by a radioresistant function of the same Th cell. In addition, it was shown that recombinant IL 2 can restore or replace the radiosensitive component of MHC-restricted cognate helper function.     

Localization of human antigen-specific helper and suppressor function in distinct T-cell subpopulations.

Distinct human T-cell subpopulations were isolated and cultured in the presence of B-cells and antigens. After an incubation period of 6 days cells were tested for their capacity to secrete antigen-specific antibodies in the PFC-assay. The results indicate that the T-helper activity for the antigen-induced T-dependent B-cell differentiation is located in the Tμ-subpopulation, whereas the suppressor-cell activity is confined to the Tγ-subpopulation.     

Role of the major histocompatibility complex in T cell activation of B cell subpopulations: antigen-specific and H-2-restricted monoclonal TH cells activate Lyb-5+ B cells through an antigen-nonspecific and H-2-unrestricted effector pathway

Monoclonal T helper (TH) cell populations were employed to study the mechanism of activation of the Lyb-5+ B cell subpopulation in T cell-dependent antibody responses in vitro. It was demonstrated that monoclonal T cell populations were sufficient to help rigorously T-depleted unprimed (B + accessory) cells for direct plaque-forming cell responses to trinitrophenyl- (TNP) conjugated keyhole limpet hemocyanin (KLH). The activation of several lines of cloned (H-2b X H-2k)F1 TH cells was antigen (KLH) specific and H-2 restricted. Individual clones were restricted to H -2b, H-2k, or unique (H-2b X H-2k)F1 encoded determinants. Under the experimental conditions employed, responses mediated by cloned TH cells were found to result in the activation of the Lyb-5+ B cell subpopulation. The activation of Lyb-5+ B cells by cloned TH cells did not require covalent linkage of carrier and hapten, and responses could be stimulated in the presence of free KLH plus TNP conjugated to an irrelevant carrier. The H-2 restriction of TH cell function was shown to reflect a requirement for T cell recognition of determinants expressed by accessory cells, whereas no requirement existed for restricted T cell recognition of B cells. These findings suggest that the help provided by monoclonal TH cells, once activated, was both antigen nonspecific and H-2 unrestricted. Consistent with this interpretation, it was found that the supernatant of antigen-stimulated TH cells provided antigen-nonspecific help to T-depleted spleen cells. Thus, these results demonstrate that the activation of Lyb-5+ B cells by antigen-specific and H-2-restricted monoclonal TH cell populations is itself antigen nonspecific and H-2 unrestricted.     

IL 2 restores memory B cell activation by antigen-specific T cell clone variants

It has recently been demonstrated that there are at least two separate pathways by which a single keyhole limpet hemocyanin (KLH) reactive T cell clone can induce B cell differentiation. With the use of the high-dose antigen-driven system (10 micrograms/ml trinitrophenyl (TNP)-KLH), a KLH-specific T cell clone was able to induce a primary anti-TNP response in unprimed B cells. In the presence of aliquots of the same T cell clone, a low-dose of antigen (5 X 10(-2) micrograms/ml TNP-KLH) induced an immunoglobulin (Ig)G response in primed B cells. It has also been demonstrated that there are variant subclones of such KLH-specific helper T cell clones that are unable to provide antigen-specific help in the presence of low-dose antigen but maintain the high-dose antigen-driven helper response. This study was undertaken to investigate whether interleukin 2 (IL 2) had some activity in the low-dose, antigen-driven response induced by the T cell clone. With the use of a variant T cell clone (which lost low-dose, antigen-driven helper activity), it was demonstrated that IL 2 was capable of reconstituting the low-dose, antigen-driven helper activity. To investigate whether accessory cells were required in this system, we removed the adherent cell population from the primed spleen cells added to culture. Interestingly, removal of the G10-adherent cells eliminated the low-dose, antigen-driven response induced by IL 2. Additionally by add-back experiments, we were able to demonstrate that the necessary adherent cell population did not require major histocompatibility complex (MHC) restriction for reconstitution of the IL 2-dependent, low-dose, antigen-driven response. Furthermore, 1% concanavalin A (Con A) supernatant (Sn), but not interleukin 1 (IL 1), could replace this adherent cell function. These data suggest that in this system, IL 2 bypasses the MHC-restricted interaction between T cells and antigen-charged adherent cells; B cells can present antigen to cloned helper T cells efficiently for primary responses but need an added factor(s) to induce IgG production; and adherent cells are essential for IgG production in primed B cells, possibly through the release of soluble factor(s) included in Con A Sn.     

Selective activation by thymus-dependent antigens of distinct B cell subpopulations expressing a major cross-reactive idiotype

We determined the B cell subpopulations that produce the major cross-reactive idiotype (CRIA) associated with the anti-phenylarsonate (ARS) antibody response of A/J mice. Specifically, we examined the B2 subpopulation found in normal mice which, in H-2b mice, bears the I-Ab-encoded determinant Ia.W39; the B1 subpopulation found in mice expressing the CBA/N X-linked immunodeficiency trait (xid); and the B1 subpopulation found in normal mice after the cytotoxic elimination of B2 cells with anti-Ia. W39 and complement. CRIA is expressed in each of these B cell subpopulations. Antigen plays a selective role in the stimulation of distinct B cell sets. ARS conjugates of keyhole limpet hemocyanin (KLH) can activate both the B1 and B2 subpopulations. In contrast, ARS conjugates of synthetic polypeptides under Ir gene control selectively activate the B2 subpopulation in strains that are genetic responders to the carrier. This leads to the establishment of CRIA dominance where CRIA+ anti-ARS antibody is 70 to 95% of the total anti-arsonate antibody response. This class of antigens fails to activate the B1 cells in either normal or xid mice. We compared the CRIA+ antibody produced by selectively activated B2 cells to that produced by the B1 subpopulation in xid mice. For these comparisons, we used competitive radioimmunoassays that employed polyspecific anti-CRIA antiserum or monoclonal anti-CRIA antibodies specific for distinct idiotopes on the heavy chain of CRIA+ antibody. B2 cells produce a CRIA+ anti-ARS antibody that is idiotopically uniform among individual mice, and that closely approximates the hybridoma protein 36-65 (the heavy chain of 36-65 represents the germ line-encoded sequence of the unique CRIA structural gene (25]. In contrast, the CRIA+ antibody produced by the B1 cell subset of xid mice is idiotopically diverse among individual mice, and differs markedly from the 36-65 hybridoma protein. The extent of diversification found in CRIA+ antibody depends on the B cell subpopulation that produces it.     

T cell activation of antigen-specific antibody responses by large B cells is MHC restricted

The activation of small, resting B cells for antibody synthesis by helper T cells has been proposed to require an MHC-restricted interaction between the T and B cells. Large, activated B lymphocytes were, in contrast, thought to be activated by an unrestricted pathway. We re-examined this issue and found that both large and small size fractionated murine B lymphocytes required an MHC-restricted interaction with helper T cells to be activated for specific antibody synthesis. Polyspecific antibody synthesis in the same cultures was not dependent upon an MHC-restricted T-B interaction for any size category of B cell. These results are interpreted as reflecting the ability of antigen-specific B cells to focus and present antigen to T cells, in contrast to B cells of random specificity, which have no effective focusing mechanism for a given experimental antigen. We found that the polyspecific response required much higher antigen concentrations than the antigen-specific response, a result consistent with the antigen-focusing hypothesis.     

Contrasuppressor cells that break oral tolerance are antigen-specific T cells distinct from T helper (L3T4+), T suppressor (Lyt-2+), and B cells

Continuous gastric intubation of mice with the T cell-dependent antigen sheep erythrocytes (SRBC) leads to a state of systemic unresponsiveness to parenteral SRBC challenge, a state termed oral tolerance. The systemic unresponsiveness of mice rendered orally tolerant to SRBC, however, is converted to humoral immune responsiveness by adoptive transfer of effector T contrasuppressor (Tcs) cells. In this study, the authors have isolated and characterized the Tcs cell subset, from the spleens of orally immunized mice, which abrogates oral tolerance. This Tcs cell is a novel cell type, which can be separated from functional T suppressor (Lyt-2+) and T helper (L3T4+) cells, and the effector Tcs cell exhibits a Lyt-1+, 2-, L3T4- phenotype. Furthermore, contrasuppression is not mediated by B cells, including those of the Lyt-1+ phenotype. Adoptive transfer of splenic Lyt-1+, 2-, L3T4- T cells from C3H/HeJ mice given oral SRBC for 21 to 28 days and splenic Lyt-1+, 2-, L3T4- T cells of C3H/HeN mice orally immunized for a shorter interval abrogated oral tolerance. Furthermore, separation of Lyt-1+ T cells into L3T4+ and L3T4- subsets by flow cytometry resulted in Lyt-1+, L3T4+ T cells with helper but not contrasuppressor function, whereas the Lyt-1+, L3T4- T cell fraction abrogated oral tolerance even though it was without helper activity. This Tcs cell subset was also effective when added to cultures of tolerized spleen cells derived from SRBC-fed mice. The effector Tcs cells are antigen-specific, because Tcs cells from SRBC-immunized mice reverse tolerance to SRBC but not to horse erythrocytes (HRBC), and Tcs cells from HRBC-immunized mice reverse tolerance to HRBC but not to SRBC. When splenic T3 (CD3)-positive T cells (Lyt-1+, 2-, and L3T4-) were separated into Vicia villosa-adherent and nonadherent subpopulations, active contrasuppression was associated with the T3-positive and Vicia villosa-adherent T cell fraction. Thus, a distinct Lyt-1+, 2-, L3T4- T cell subset that contains a T3-T cell receptor complex, which can regulate oral tolerance, is present in spleens of orally immunized mice.     

HLA-linked nonresponsiveness to Cryptomeria japonica pollen antigen. I. Nonresponsiveness is mediated by antigen-specific suppressor T cell

The objective of this study was to elucidate the cellular mechanism of IgE nonresponse to the Cryptomeria japonica (Japanese cedar) pollen antigen (CPAg), which was shown in our previous study to be HLA-linked (1). We established an assay system for the measurement of small amounts of anti-CPAg IgE antibody, both in an antigen-specific and isotype-specific manner, and a culture system to induce antigen-driven IgE antibody synthesis in vitro. By using these methods, we clarified that the function of the HLA-DR molecule in the CPAg-driven IgE response is similar to that of I-A or I-E molecule in mice, namely the product of immune response genes (Ir-genes), because anti-HLA-DR monoclonal antibody blocked the response, and the interaction between monocyte and monocyte-depleted peripheral blood lymphocytes (PBL) to respond to CPAg was restricted by HLA-DR. Furthermore, PBL from nonresponders revealed a specific IgE response to CPAg when the Leu-2+3- T cell fraction was depleted, thereby suggesting that even nonresponders have Leu-2-3+ T cell and B cell clones specific for CPAg, and they apparently show no response due to the presence of CPAg-specific Leu-2+3- suppressor T cells. This suppressor T cell fraction abolished the IgE response of the autologous B + monocyte + Leu-2-3+ T cell in a CPAg-specific manner. The current cellular analysis together with our previous genetic analysis strongly suggest that the HLA-linked IgE nonresponse to CPAg is mediated by CPAg-specific suppressor T cells. The HLA-linked gene controlling the nonresponsiveness to CPAg is thus designated as the immune suppression gene for CPAg (Is-CPAg). Mapping of Is-CPAg within HLA-DQ subregion is discussed.     

IL-2 secretion and T cell clonal anergy are induced by distinct biochemical pathways.

In Th1 clones, TCR occupancy together with a costimulatory signal from APC results in IL-2 production. TCR occupancy alone results in unresponsiveness (anergy) to antigenic stimulation, a phenomenon that may be important for self-tolerance in vivo. Inasmuch as inositol phosphate production occurs during the induction of anergy other biochemical signals must be necessary for IL-2 production. Here we assess the role of tyrosine-specific protein kinases using the specific inhibitor, genistein. IL-2 secretion and responsiveness were very dependent on tyrosine-specific protein kinase activation and could be completely blocked under conditions where inositol phosphate generation occurred normally. Although anergy induction could also be blocked by inhibition of tyrosine-specific protein kinase activation this probably occurred indirectly via inhibition of inositol phospholipid hydrolysis. The differential susceptibility of IL-2 secretion and anergy induction to inhibition by genistein indicates that positive and negative outcomes of TCR occupancy may be mediated by distinct biochemical pathways.     

Relationships between antigen-specific helper and inducer suppressor T cell hybridomas

Ts1, or inducer suppressor T cells, share many phenotypic and functional characteristics with helper/inducer subset of T cells. In order to evaluate the relationship between these cell types, we made a series of new Ts1 hybridomas by the fusion of Ts1 cells with the functionally TCR alpha/beta-negative BW thymoma (BW 1100). Three Ts1 hybridomas (CKB-Ts1-38, CKB-Ts1-53, and CKB-Ts1-81) were established that express TCR and produce Ag-specific suppressor factors constitutively, thus making it possible to study the nature and specificity of Ag receptors, MHC restriction, and lymphokine production by the Ts1 hybridomas. Results presented in this report demonstrate that all the Ts1 hybridomas described here express CD3-associated TCR-alpha beta. These three Ts1 hybridomas recognize Ag (NP-KLH) specifically in a growth inhibition assay and this recognition is restricted by IE molecules. Two of the hybridomas also produce IL-2 or IL-2 and IL-4 upon Ag-specific activation. Thus, by these three criteria the Ts1 hybridomas appear indistinguishable from Th cells. These three Ts1 hybridomas, however, release suppressor factors (TsF1) in the supernatant that suppress both in vivo DTH and in vitro PFC responses in an Ag-specific manner. Like the TsF1 factors characterized previously, the suppression mediated by these factors are Igh restricted and lack H-2 restriction. These factors mediate suppression when given in the induction phase but not during the effector phase of the immune response. The TsF1 factors are absorbed by Ag (NP-BSA), and anti-TCR affinity columns and the suppressor activity can be recovered by elution. The data are consistent with the interpretation that Ts1 inducer-suppressor T cells are related to Th cells; the feature that distinguishes these cells is the ability to produce Ag-binding factors that specifically suppress immune responses.     

Melanoma-associated immunosuppression through B cell activation of suppressor T cells.

Using normal human lymphocytes isolated by sedimentation and cotton column adherence, we have developed a reliable assay of immunosuppression of PHA-induced blastogenesis by serum from selected melanoma patients. These lymphocyte cultures contained both responder cells (subpopulation x) and regulator cells (subpopulation y). Lymphocytes isolated by gradient centrifugation on sodium metrizoate-Ficoll contained responder cells (x) but no regulator cells (y). Cultures of lymphocytes isolated by this method were stimulated by PHA but were not suppressed by the addition of melanoma serum. When lymphocytes were isolated by a cotton column adherence/Lymphoprep centrifugation-double separation, subpopulations (x) and (y) were isolated. We have established that both subpopulations are necessary for suppression to occur, and that (y) operates as the regulator of (x). Finally, by manipulating B cell and T cell populations isolated by nylon column adherence or AET rosette separation, we have determined that the regulator ability of subpopulation (y) is the result of B cell activation of suppressor T cells.     

Production of interleukin 3 and gamma-interferon by an antigen-specific mouse suppressor T cell clone

An interleukin 2 (IL 2)-dependent, keyhole limpet hemocyanin (KLH)-specific, mouse suppressor T cell clone, 3D10, was found to produce interleukin 3 (IL 3) and gamma-interferon (IFN-gamma) in response to T cell mitogens Con A and PHA. Different from KLH-specific suppressor factor (TsF) that was spontaneously released into the medium when cultured in IL 2-containing conditioned medium, the production of IL 3 and IFN-gamma was induced by mitogenic stimuli. IL 3, IFN-gamma, and TsF were separable by gel filtration through a Sephadex G-100 column, being recovered in fractions of m.w. 25,000 to 30,000, 45,000 to 50,000 and 60,000 to 70,000, respectively. On the other hand, minimum size of IL 3 and IFN-gamma were shown to be about 25,000 and 20,000, respectively, by determining the lymphokine activities contained in the extracts from slices of SDS gels. These results indicate that IFN-gamma was present as a homodimer or hetero-complex with another carrier protein(s), whereas IL 3 was present as a monomeric form. A highly positive correlation (a correlation coefficient r = 0.96) between the titers of IL 3 and IFN-gamma produced by seven subclones derived from 3D10 was obtained, suggesting that IL 3 and IFN-gamma are induced by a process with a common mechanism. 3D10 also produced IL 3 and IFN-gamma when cultured with its specific antigen, KLH, in the presence of antigen-presenting cells. When Con A-stimulated 3D10 cells were labeled with L-[35S]methionine, we found that at least three proteins, with m.w. of 35,000, 25,000, and 20,000, were specifically released into medium by the stimulation. The latter two may be IL 3 and IFN-gamma described above, respectively, because of the similarities in m.w.     

Suppression of humoral and delayed hypersensitivity responses by distinct T cell subpopulations.

Immunization of mice with a supraoptimal dose of sheep red blood cells (SRBC) results in splenic T cell populations capable of specifically suppressing recipients' plaque forming cell (PFC) and delayed-type hypersensitivity (DTH) responses to SRBC when tested in an adoptive transfer system. By localization on discontinuous bovine serum albumin (BSA) gradients and relative sensitivity to Cytoxan, two distinct T cell subpopulations suppressing DTH reactivity were identified. One population could not be distinguished from T cells capable of inhibiting direct and indirect PFC responses. However, another population appeared quite distinct and capable of inhibiting DTH, but not PFC responses.     

T cells in B cell chronic lymphocytic leukemia. II. Lack of antigen-specific T suppressor cells and their progenitors

Nylon wool-purified T cells (Tn) of two patients with chronic lymphocytic leukemia of the B cell type were phenotyped and tested in various assays for antigen-specific T helper (Th), T suppressor effector (Tse), T suppressor precursor (Tsp), and T suppressor inducer (Tsi) function. Antigen-specific Th as well as Tsi activity could be effectively generated. Although phenotypically CD8+ T cells, carrying the receptor for the Fc part of IgG, were present in mononuclear blood cells and Tn fractions, no antigen-specific Tse cell activity could be induced. In addition, Tsp cells were found to be functionally absent. These findings are discussed in relation to a tumor-induced limited heterogeneity within the T suppressor (Ts) cell compartment.     

T helper cell-dependent, microbial superantigen-induced murine B cell activation: polyclonal and antigen-specific antibody responses.

Microbial superantigens (SA), bound to human B cell surface MHC class II molecules, have been shown to promote direct, "cognate" interaction with SA-reactive autologous Th cells, resulting in polyclonal Ig production. To investigate the potential for microbial SA to support Th cell-dependent, Ag-specific antibody responses, we have extended our studies to the murine system. BALB/c Th cell lines (TCL), specific for either the Mycoplasma arthritis-derived SA or the Staphylococcus aureus-derived toxic shock syndrome toxin-1) were generated. These TCL cells are SA-specific, functionally noncross-reactive, and utilize distinct TCR V beta gene families. Coculture of SA-reactive TCL cells and syngeneic B cells bearing the relevant SA results in B cell proliferation and polyclonal IgM and IgG production. In contrast, Ag-specific (SRBC-specific) antibody-forming cells are only generated in cultures that also contain SRBC. Thus, microbial SA-mediated Th-B cell interactions induce both polyclonal B cell activation and provide selective help for the proliferation and/or differentiation of B cells that have encountered specific Ag. In additional studies, we determined that the in vivo administration of toxic shock syndrome toxin-1 to young, athymic (nude) BALB/c mice results in SA binding to splenic B cells, rendering these B cells effective stimulators of and targets for SA-reactive helper TCL cells. Taken together, these results demonstrate that microbial SA mediate productive Th-B cell interactions analogous to those that occur during allospecific Th-B cell interactions in vitro and GVHD in vivo. These findings are consistent with the hypothesis that microbial SA represent environmental factors that may trigger autoimmune disease in the genetically susceptible host.     

Induction of polyomavirus-specific CD8(+) T lymphocytes by distinct dendritic cell subpopulations

Dendritic cells are pivotal antigen-presenting cells for generating adaptive T-cell responses. Here, we show that dendritic cells belonging to either the myeloid-related or lymphoid-related subset are permissive for infection by mouse polyomavirus and, when loaded with a peptide corresponding to the immunodominant anti-polyomavirus CD8(+) T-cell epitope or infected by polyomavirus, are each capable of driving expansion of primary polyomavirus-specific CD8(+) T-cell responses in vivo.     

Activation of B cells by autoreactive T cells: cloned autoreactive T cells activate B cells by two distinct pathways

Although the existence of autoreactive T cells has been widely reported, the functional capacities of these populations have been less well defined. Studies were therefore carried out to characterize the relationship of autoreactive T cells to antigen-specific major histocompatibility complex (MHC)-restricted T cells in their ability to act as helper cells for the induction of immunoglobulin synthesis by B cells. A number of autoreactive T cell lines and clones were isolated from antigen-primed spleen and lymph node cell populations. Autoreactive T cells were found to proliferate in response to direct recognition of syngeneic I-A or I-E subregion-encoded antigens in the absence of any apparent foreign antigen. It was shown that cloned autoreactive T cells were capable of activating B cell responses through two distinct pathways. After appropriate stimulation by syngeneic cells, autoreactive T cells polyclonally activated primed or unprimed B cells to synthesize IgM antibodies. These activated T cells functioned in these responses through an MHC-unrestricted pathway in which polyclonal responses were induced in both syngeneic and allogeneic B cells. These cloned autoreactive T cells were also able to activate IgG responses by primed B cells through a different activation pathway. In contrast to the polyclonal activation of IgM responses, the induction of IgG antibodies by the same cloned T cells required primed B cells and stimulation with the priming antigen. The activation of B cells to produce IgG was strongly MHC restricted and required the direct recognition by the autoreactive T cells of self MHC determinants expressed on the B cell surface, with no bystander activation of allogeneic B cells. These results indicate that cloned autoreactive T cells resemble antigen-specific MHC-restricted T cells in their ability to function as T helper cells through distinct MHC-restricted and MHC-unrestricted pathways.