Germinal center cells are a major IL-5-responsive B cell population in peripheral lymph nodes engaged in the immune response

Germinal center formation and the development of B cell memory in lymphoid tissue is a T cell-dependent process. The specific B cell-T cell interactions, and/or cytokines, resulting in germinal center cell growth have not yet been identified. Germinal center B cells were separated from other lymph node (LN) B cells by panning on peanut agglutinin (PNA)-coated dishes. Resulting fractions enriched for PNA+ (germinal center) B cells, and the PNA- (other) LN B cells from immune SJL mice were assayed for proliferation in the presence of cytokines. PNA+ and PNA- B cells responded equally to IL-4 in the anti-mu co-stimulator assay. In contrast, PNA+ B cells responded to murine (r)IL-5 or human B cell growth factor in the dextran sulfate (DxS) co-stimulator assay, to a much greater degree than did PNA- B cells. The same results were obtained with PNA+ and PNA- cells from LAF1 mice. Unfractionated LN B cells from nonimmunized SJL or BALB/c mice did not respond to IL-5 with or without DxS. B cell populations from BALB/c mice such as from spleen and peritoneal cavity, which are known to be high in Ly-1+B cells, responded to IL-5 alone, and more dramatically, to IL-5 as a co-stimulator with DxS. Such populations of cells from SJL mice, which are known to contain low numbers of Ly-1+B cells, responded markedly less. These results are consistent with those of others which show that in nonimmunized mice, Ly-1+B cells are a major IL-5 responsive subpopulation. IL-1 enhanced the proliferation of PNA+ cells in response to rIL-5 and had no effect on PNA- cells. IL-4 and IL-5 did not enhance each other's effects as co-stimulators of proliferation. In contrast to PNA+ B cells from immune LN, B cells activated by Escherichia coli endotoxin exhibited no responses to rIL-5. The present results indicate that in immune LN, PNA+, germinal center B cells constitute a prominent IL-5-responsive population.     

Salmonella flagellin induces bystander activation of splenic dendritic cells and hinders bacterial replication in vivo

Bacterial flagellin is a target of innate and adaptive immune responses during Salmonella infection. Intravenous injection of Salmonella flagellin into C57BL/6 mice induced rapid IL-6 production and increased expression of activation markers by splenic dendritic cells. CD11b(+), CD8alpha(+), and plasmacytoid dendritic cells each increased expression of CD86 and CD40 in response to flagellin stimulation, although CD11b(+) dendritic cells were more sensitive than the other subsets. In addition, flagellin caused the rapid redistribution of dendritic cells from the red pulp and marginal zone of the spleen into the T cell area of the white pulp. Purified splenic dendritic cells did not respond directly to flagellin, indicating that flagellin-mediated activation of splenic dendritic cells occurs via bystander activation. IL-6 production, increased expression of activation markers, and dendritic cell redistribution in the spleen were dependent on MyD88 expression by bone marrow-derived cells. Avoiding this innate immune response to flagellin is important for bacterial survival, because Salmonella-overexpressing recombinant flagellin was highly attenuated in vivo. These data indicate that flagellin-mediated activation of dendritic cells is rapid, mediated by bystander activation, and highly deleterious to bacterial survival.     

Cellular cooperation in the expression of murine delayed-type hypersensitivity (DTH). 1. A normal accessory cell population enhances DTH produced by immune peritoneal exudate T lymphocytes

A murine system for local passive transfer of delayed-type hypersensitivity (DTH) has recently been described. It was determined that untreated and T-lymphocyte-enriched (nylon-wool-nonadherent) fractions of peritoneal exudate (PE) cells from immunized donors could be transferred with soluble antigen to normal recipient footpads to efficiently produce a local DTH response. Untreated spleen or lymph node (LN) cell populations were strikingly less capable in this regard. It is now reported that addition of normal untreated PE cell populations to immune T-enriched PE cells markedly enhanced the DTH response transferred by the latter. Specific swelling was dose dependent with respect to each cell type. Removal of T lymphocytes from the normal PE cell population did not affect its enhancement of DTH. By cotransfer of 1 X 10(7) normal PE cells, significant specific swelling was obtained using 1-3 X 10(5) T-enriched immune PE cells. This represented a three- to seven-fold reduction in the requirement for the latter cell type. This scheme of DTH enhancement was employed to evaluate the mechanisms for decreased capability of immune LN and spleen for DTH transfer when compared to PE. No evidence was found that either adherent or nonadherent suppressor cells are operative at the time of DTH expression. Cotransfer of a DTH-enhancing population failed to equalize DTH expression by LN and spleen with that of PE. It is concluded that DTH effector-T-cell activity is enriched in immune peritoneal exudate and that non-T-cell population(s) from that source actively enhance DTH expression.     

The location of splenic NKT cells favours their rapid activation by blood-borne antigen

Natural killer T (NKT) cells play an important role in mounting protective responses to blood-borne infections. However, though the spleen is the largest blood filter in the body, the distribution and dynamics of NKT cells within this organ are not well characterized. Here we show that the majority of NKT cells patrol around the marginal zone (MZ) and red pulp (RP) of the spleen. In response to lipid antigen, these NKT cells become arrested and rapidly produce cytokines, while the small proportion of NKT cells located in the white pulp (WP) exhibit limited activation. Importantly, disruption of the splenic MZ by chemical or genetic approaches results in a severe reduction in NKT cell activation indicating the need of cooperation between both MZ macrophages and dendritic cells for efficient NKT cell responses. Thus, the location of splenic NKT cells in the MZ and RP facilitates their access to blood-borne antigen and enables the rapid initiation of protective immune responses.     

Identification and characterization of splenic adherent cells forming densely-packed colonies

It is thought that the spleen contains stem cells that differentiate into somatic cells other than immune cells. We investigated the presence of these hypothetical splenic cells with stem cell characteristics and identified adherent cells forming densely-packed colonies (Splenic Adherent Colony-forming Cell; SACC) in the spleen. Splenic Adherent Colony-forming Cell was positive for alkaline phosphatase staining and stage-specific embryonic antigen (SSEA)-1 antigen. However, the self-renewal properties of SACCs were limited because they stopped cell proliferation once colonies visible to the naked eye were formed. Gene expression analyses by semi-quantitative RT-PCR revealed the significant expression of c-Myc and Klf4, whereas faint or no expression was evident for Nanog, Oct3/4, and Sox2. Global expression analyses by DNA microarray and subsequent gene ontology analyses revealed that the expression levels of genes related to the immune system were significantly lower in SACCs than in control splenic cells. In contrast, genes unrelated to the immune system, such as those involved in cell adhesion and axon guidance, were relatively highly expressed in SACCs compared with control splenic cells. Taken together, we identified a novel cell type residing in the spleen that is different from the hypothetical splenic stem cell, but which bears some, but not all, characteristics that represent an undifferentiated state.     

Ability of chicken B cells from different compartments to respond to TNP-Ficoll

The responsiveness of chicken B cells from various compartments to T-independent antigens was studied by immune transfers of spleen and bursa cells into immunosuppressed recipients. Bursa cells from 8- to 10-wk-old donors failed to respond to trinitrophenylated Ficoll (TNP-F) even when thymus cells or splenic T cells were added. Spleen cells from the same donors transferred responses, as judged both by anti-TNP plaque-forming cells (PFC) per spleen and serum anti-TNP titers. In contrast, responses to TNP-Brucella abortus (TNP-BA) were transferred at least as well as by bursa as by spleen cells. Rabbit anti-chicken T cell serum plus complement treatment of the spleen cells reduced their ability to transfer responses to sheep erythrocytes, but either did not affect or enhanced serum antibody responses to TNP-BA and TNP-F. In intact animals, responsiveness to i.v. injected TNP-F was found to develop slowly after hatching in the chicken. At the age of 2 and 3 mo, PFC/spleen on day 4 after TNP-F injection were only 20% and 40%, respectively, of the adult response. Thymectomy at hatching further delayed this development, resulting in 12% and 45% of the adult control response at ages of 3 and 4 mo. It is concluded that responsiveness to the TI-2 antigen, TNP-F, develops slower than that to the TI-1 antigen, TNP-BA, and is restricted to the splenic B cell compartment. In addition, this development appears to be faster in the presence rather than in the absence of the thymus. In view of the previously shown effect of thymus on bursa development, these data suggest that the maturation of TI-1 antigen (TNP-F)-respondent chicken B cells requires residence in both the bursa and spleen before the development of responsiveness to such antigens.     

Regulation of the primary in vitro response to TNP-polymerized ovalbumin by T suppressor cells induced by ovalbumin feeding

Spleen cells from DBA/2 mice that received a single feeding of 20 mg of ovalbumin (OVA) 7 days previously were specifically hyporesponsive to primary in vitro challenge with the thymic-dependent antigen TNP-polymerized ovalbumin (TNP-POL-OVA). The tolerance observed in spleen cells from OVA-fed animals was dependent upon OVA-specific T suppressor cells, because splenic T cells from OVA-fed mice suppressed the primary response to TNP-POL-OVA of cultures containing normal T and B cells. The tolerance and suppression was OVA specific, because spleen cells from OVA-fed animals responded well to other antigens (including TNP on another carrier), and splenic T cells from OVA-fed mice did not affect the response of normal T and B cells to sheep erythrocytes. These data confirm the existence of T suppressor cells after OVA feeding and provide a direct means of assaying their activity in a primary in vitro response.     

Mouse splenic macrophage cell lines with different antigen-presenting activities for CD4+ helper T cell subsets and allogeneic CD8+ T cells.

A panel of seven mouse splenic macrophage cell lines, derived from cloned progenitors, was compared for their ability to present antigen to Th1 or Th2 helper T cell lines and hybridomas, as well as to naive T cells, and to provide accessory cell function for the synthesis of antibody from primed B cells. One of the cell lines expressed MHC class II molecules and was the only line with constitutive antigen-presenting activity for Th1 cells. It may represent a subset of splenic macrophages responsible for the activation of naive Th1 helper cells in situ. The remaining six cell lines responded to INF-gamma by up-regulating their class II expression and acquiring Th1 antigen-presenting activity. They may represent cells which, in situ, lack constitutive antigen-presenting activity but are promoted to presenting status by Th1-derived INF-gamma. Five of the cell lines provided accessory cell function to Th2 cells, as indicated by antibody synthesis in suspensions of spleen cells from primed mice depleted of their antigen-presenting cells. One of the cell lines lacking accessory cell activity had constitutive antigen-presenting activity for Th1 cells. This reciprocal expression of antigen-presenting activity supports the idea that Th1 and Th2 helper cells are activated by different antigen-presenting cells. Finally, the cell lines differed in their ability to constitutively induce an allogeneic response; a response that was limited to CD8+ T cells occurred in a CD4+ helper cell-independent manner and was unaffected by the addition of INF-gamma. The alloantigen-presenting macrophage cell lines also possessed the most efficient accessory cell activity for antibody synthesis. These cell lines, which represent a spectrum of antigen-presenting activities in the spleen afford models for defining the roles of macrophages in the induction of immune responses and for resolving issues concerning their development.     

Adherent Ia+ murine cell lines with characteristics of dendritic cells. II. Characteristics of I region-restricted antigen presentation

The ability of an adherent Ia+, interleukin 1+ (IL-1) tumor cell line (P388AD) to present turkey gamma-globulin (TGG) to primed T lymphocytes was demonstrated and compared with normal antigen-presenting cells (APC) found in mouse spleen. P388AD tumor cells presented TGG to long-term cultures of TGG-reactive T cells (LTTC) and to lymph node-derived T cells which were enriched on nylon wool columns and subsequently depleted of endogenous antigen-presenting cells with anti-Ia antisera and complement. MHC-restricted antigen presentation by P388AD was observed when long-term cultures of TGG-reactive T cells were used as the responding T-cell population. Furthermore, antisera directed against I-region determinants expressed on the P388AD tumor cells inhibited TGG-specific T-cell proliferation in a dose-related fashion, suggesting a functional role for the tumor cell-associated Ia molecules. The kinetics of antigen presentation to LTTC by P388AD were similar to the kinetics observed for splenic APC, although the magnitude of the proliferative response to LTTC to TGG was generally lower when antigen (Ag) was presented by the tumor cells compared to splenic antigen-presenting cells (APC). However, the magnitude of T-cell proliferation of immune lymph node (LN) T cells was comparable when Ag was presented on tumor cells or splenic APC. Several experiments suggested that Ag uptake and/or processing may be less effective in P388AD tumor cells as compared to normal splenic APC. A nonadherent Ia+, IL-1- tumor cell line (P388NA), which was isolated from the same parental tumor as P388AD, was also tested for the ability to present Ag to primed T lymphocytes and Ag-reactive LTTC. In contrast, to P388AD, the nonadherent tumor cell failed to present TGG under identical culture conditions even though Ia molecules were expressed on the tumor cells and Ag uptake had occurred. However, the defect in Ag presentation by P388NA could be corrected if an exogenous source of purified interleukin 1 was supplied to the cultures. A unique opportunity thus exists with both the P388AD and P388NA tumor cell lines to decipher some of the molecular interactions leading to T-cell proliferation during antigen presentation.     

The suppressor T cell induced by syngeneic splenic cell antigen down-regulates hapten-specific cytotoxic T cells by elaborating a factor inhibitory for IL2-dependent cell replication

An in vitro study has been made of the mechanism by which a suppressor T cell, that is induced in lymph nodes by a syngeneic splenic cell antigen, prevents generation of cytotoxic T cells specific for hapten-altered self antigens. When popliteal lymph node cells exposed in vivo to syngeneic splenic cells were immunized in vitro with heat-treated syngeneic TNP-coupled thymocytes and excess helper factors, the Ts remained inactive. In this condition the exposed popliteal lymph node cells routinely demonstrated approximately twice the CTL response developed by lymph node cells from normal mice. Nevertheless, when triggered in vitro by splenic antigen on either X-irradiated B or T cells, the exposed but not the normal lymph node cells exhibited reduced hapten-altered self-specific CTL responses. Furthermore, T cells within spleen cell-exposed popliteal lymph node cell populations when reexposed to splenic T cells made a factor that was found to be suppressive of CTL generation by normal lymph node cells in vitro. The nondialyzable T-cell suppressor factor (TsF) did not appear to act on lymph node precursor CTLs, nor on helper T cells but instead acted at the level of utilization of helper factors in the development of CTLs. In an examination of the effect of TsF on cellular replication, TsF was found to be nontoxic for CTLL-20, an IL-2-dependent T cell, and it did not hinder the uptake of IL-2 by receptor blockade of this cell. Nevertheless, the replication of CTLL-20 that is IL-2 driven was diminished in the presence of TsF. Similarly, TsF was found to be inhibitory for T-cell proliferation stimulated by mitogen but had no effect on a B myeloma cell proliferative response. Thus, TsF appears to act as an inhibitor of a T cell's capability to replicate despite the presence of the stimulus for replication, namely, IL-2.     

A membrane antigen of rabbit bursal equivalent cells.

Rabbit cells, bearing a specific antigen for bursal equivalent cells, could be detected with a suitably absorbed heterologous antiserum (goat). The antigen, detected with this antiserum, was designated RABELA. In the presence of complement, the RABELA antiserum lysed 80% of appendix cells, 50% of tonsil cells, 50% of spleen cells, and 25% of blood lymphocytes. It did not lyse a significant number of bone marrow or thymus cells.After complement-mediated kill with RABELA antiserum, cell populations lost the ability to respond to B mitogens. The responsiveness to the T mitogen, Concanavalin A, was reduced, but could be restored by addition of B cells which, alone, did not respond to Concanavalin A.RABELA-bearing subpopulations of spleen cells were characterized by velocity sedimentation analysis and were distinguished from subpopulations which took up thymidine after treatment with antibody directed against light chain allotypic specificity.     

Activation of helper T cells by immune complexes.

Spleen cells from mice primed with dinitrophenylated human γ-globulin (DNP-HGG) did not mount a secondary anti-DNP response in diffusion chamber cultures upon stimulation with dinitrophenylated keyhole limpet hemocyanin (DNP-KLH). The same cells, however, responded to stimulation with DNP-KLH complexed with anti-KLH antibody of rabbit or mouse origin. There is an optimal antigen:antibody ratio at which the immune complexes (IC) must be formed for maximal activity. T cells are required for the immunogenic activity of IC, since T-cell-depleted cultures did not respond. It was found that IC made with carrier and anticarrier antibody stimulated the development of carrier-specific helper T cells in cultures of spleen cells, thymocytes, and nylon wool nonadherent spleen cells from nonimmune mice. In contrast, free carrier did not elicit helper T cells. IC made with carrier and the F(ab′)₂ fragment of anticarrier antibody were immunogenic, but those made with carrier and the Fab′ fragment of anticarrier antibody were not, suggesting that helper T-cell activation is triggered by crosslinking of antigen-specific surface receptors.     

PHA activation of encephalitogenic T cells: in vitro line selection overcomes splenic suppression

In this study we compared myelin basic protein (MBP) and phytohemagglutinin (PHA) for their ability to induce proliferation and experimental autoimmune encephalomyelitis (EAE) transfer activity in mixed cell cultures obtained from spleen and lymph nodes versus highly selected MBP-specific T cell lines and clones. Established MBP-specific cells derived initially from immune lymph nodes attained both proliferative and EAE-transfer activities after in vitro activation with either MBP or PHA. In contrast, PHA was unable to induce immune spleen cells to transfer EAE, in spite of its potent mitogenic activity. On the basis of these results, we evaluated the in vitro proliferation and differentiation responses of MBP-specific T cells during the line selection process using cells derived from both immune lymph node and immune spleen. During the initial selection process with MBP, proliferation of MBP-specific T cell precursors from immunized spleen populations was reduced relative to lymph node cells. After antigen-dependent selection the encephalitogenic cells from either organ exhibited identical in vitro response characteristics. Freshly isolated immune spleen cells were potent suppressors of MBP-specific T cell proliferation suggesting that the in vitro differences between the two organs was due to splenic suppression of the encephalitogenic cells.     

Role of macrophages as modulators but not as autonomous accessory cells in the proliferative response of immune T cells to soluble antigen

The role of murine macrophages (M phi) and that of splenic dendritic cells (DC) were investigated in the antigen-specific proliferative response of memory T cells of mice primed with key-hole limpet hemocyanin (KLH) 6 weeks or more before. Peritoneal M phi, whether expressing Ia antigens or not, did not function as autonomous accessory cells (A cells). A-cell activity of the spleen adherent cell population, which comprised M phi in the majority and DC in the minority, was abolished by eliminating DC with a DC-specific monoclonal antibody and complement, and regained by the addition of a small number of DC. Though M phi did not function as autonomous A cells, they augmented the proliferative response in the presence of a small number of DC. This occurred not only in the presence of free antigen, but also when DC and/or M phi were pulsed with antigen. A culture supernatant of M phi having interleukin-1 activity was effective in enhancing the proliferation of T cells which responded to antigen-pulsed DC. On the other hand, interleukin-2 did not replace DC even in the presence of antigen-pulsed Ia+ M phi. We also investigated recently primed T cells, but no evidence was obtained in favor of the competence of M phi as autonomous A cells.     

Activation requirements of cloned inducer T cells. II. The failure of some clones to respond to antigen presented by activated B cells

Inducer/helper T cells recognize nominal antigen in association with Ia on the surface of the antigen-presenting cell (APC). Recent studies have shown that B cells can effectively function as APC. In the present study we have assessed the ability of cloned inducer T cells to discriminate between activated B cells or splenic macrophages as APC. We found that most of the clones tested demonstrated an equivalent response to antigen presented by activated B cells or splenic adherent cells. Some clones were very efficiently stimulated by antigen presented by activated B cells, whereas other clones failed to respond or responded very poorly when activated B cells were used to present antigen. We attempted to determine the mechanism responsible for the inability of certain clones to proliferate in response to antigen presented by activated B cells.     

Granulocyte-macrophage colony-stimulating factor augments the primary antibody response by enhancing the function of antigen-presenting cells

Purified, recombinant-derived murine granulocyte-monocyte colony-stimulating factor was found to enhance the primary in vitro immune response to SRBC by murine spleen cells. In determining the mechanism of this augmentation, it was found that only splenic adherent cells and neither resting nor activated T cells nor B cells expressed specific receptors for GM-CSF. When splenic adherent cells were pulsed briefly with GM-CSF before addition to macrophage-depleted cultures, they reconstituted the PFC response to a significantly greater degree than did control macrophages. Splenic adherent cells incubated overnight with SRBC plus GM-CSF were also more efficient antigen-presenting cells than splenic adherent cells incubated with antigen alone. The mechanism of this enhanced antigen presentation was found to be due to a GM-CSF-dependent increase in the level of IL 1 secretion and Ia antigen expression. Consistent with these data was the finding that GM-CSF augmented IL 2 production by splenic T cells in response to suboptimal concentrations of Con A. Finally, the day 5 in vivo antibody response (as measured by serum titers) of mice immunized with a low dose of SRBC was enhanced by two daily inoculations of GM-CSF. Thus, the role that GM-CSF plays in augmenting immune responses may not be solely accounted for by its ability to cause the proliferation or differentiation of macrophages, but more than likely includes its ability to enhance the function of antigen-presenting macrophages.     

A suppressor cell which interferes with antiallotype stimulated DNA synthesis of rabbit B cells

Responsiveness of rabbit spleen cells to anti-allotype antibody was measured in terms of increased thymidine incorporation. Incorporation was enhanced after removal of cells which had ingested or had adhered to magnetic particles. B lymphocytes, prepared from spleen cells by the removal of adherent cells and of RTLA bearing T cells, were more responsive to anti-allotype antibody than were the original spleen suspensions. This increase could not be explained by enrichment in B cells. It was concluded that an adherent cell suppressed B cell transformation. The addition of 2-mercaptoethanol to the cell cultures stimulated with mitogen augmented the incorporation of thymidine. Adherent cells interfered with 2-mercaptoethanol potentiation in the response to anti-allotype antibody but not in the response to Con A. Fractionation of spleen cells, over glass bead columns, yielded nonadherent and adherent cell populations. The responsiveness of nonadherent cells to anti-allotype induced thymidine incorporation was two to six times that of unfractionated cells. The responsiveness of nonadherent cells to stimulation by anti-allotype antibody was reduced after addition of adherent cells. Findings were discussed in terms of the inhibitory role played by adherent cells on anti-allotype antibody induced responsiveness of rabbit B cells and of the possible participation of a third cell type which functions as a promotor of mitogenic T cell stimulation.     

The regulatory role of sialic acids in the response of class II reactive T cell hybridomas to allogeneic B cells

Two different kinds of alloreactive T cell hybridomas were established in previous experiments. One is reactive and the other is nonreactive to allogeneic I-A region-associated membrane antigen (mIa) on B cells. In the present experiments the difference between these hybridomas were analyzed by using representative clones, B cell mIa-reactive clone CB-11.4, and nonreactive clone HTB-9.3. Unresponsiveness of HTB-9.3 clone to allogeneic B cells could not be due to the inability of B cells in interleukin 1 production or the density of mIa molecules on B cells. HTB-9.3 clone could respond to C57BL/6 mouse B cells treated with neuraminidase (Nase), and Nase-treated HTB-9.3 clone could respond to normal B cells from C57BL/6 mouse, indicating that sialic acid on both B cells and HTB-9.3 clone plays a regulatory role in the alloreactivity of the clone. In response to B cells from C57BL/6 mouse, T cells from C3H/He mouse spleen showed similar reactivity to HTB-9.3 clone; that is, T cells could respond to Nase-treated B cells, and Nase-treated T cells to B cells, and T cells primed with C57BL/6 spleen cells in vitro showed similar reactivity to CB-11.4 clone. These results suggest that HTB-9.3 clone represents virgin T cells and CB-11.4 clone-primed T cells at least in alloreactivity. Anti-L3T4a was shown to block alloreactivities of both T cell hybridomas and splenic T cells against B cells more efficiently than against splenic adherent cells. These results suggest that L3T4a on T cell plays more important role in allogeneic response to B cells than to splenic adherent cells.     

Response of mouse splenic lymphocytes to timothy pollen antigens in a microculture system.

Spleen cells from LAF1 mice were stimulated in a microculture system with T and B cell mitogens or antigens of timothy pollen. Only cells from mice immunized with crude timothy pollen extract (WST) or a major antigen of timothy pollen conjugated to Ascaris (antigen B-Ascaris) responded to timothy antigens in vitro. Optimum responses were obtained at 120 to 144 hr of culture with 5 to 10 mug WST per culture and ranged from three to 10 times greater than cell background. No correlations could be found between the optimum antigen concentration or the maximum response and the immune status of the spleen cell donor. Response could be inhibited by a dialyzable fraction of timothy pollen, antigen D, which is a monovalent form of a major antigen of timothy pollen.     

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.