Role of antigen-specific T cell help in the generation of in vivo antibody responses. I. Antigen-specific T cell help is required to generate a polyclonal IgG1 response in anti-IgD antibody-injected mice.

A system in which injection of mice with an antibody to mouse IgD that they recognize as foreign stimulates a large, T cell-dependent IgG response was used to study whether Ag-specific T cell help is required to stimulate polyclonal (non-Ag-specific) IgG production in vivo. Igha x Ighb allotype heterozygous mice were injected with a conjugate of a foreign Ag coupled to a mAb specific for one of the two IgD allotypes expressed in these mice. This conjugate cross-links mIgD on B cells that express the recognized allotype. These cells process the conjugate and present the foreign Ag to Ag-specific T lymphocytes, which become activated. Thus, B cells of the recognized allotype can be stimulated by cross-linking of their mIgD, Ag-specific T cell help, non-Ag-specific cytokines, and non-Ag-specific contact with activated T cells. In contrast, B cells that express the Igh allotype not recognized by the Ag-anti-IgD antibody conjugate (bystander B cells) can be stimulated in this system only by non-Ag-specific cytokines and non-Ag-specific contact with activated T cells. Although both recognized and bystander B cells in conjugate-injected mice demonstrated substantial increases in size and Ia expression, only the recognized B cells were induced to synthesize DNA and to make a substantial polyclonal Ig response. Bystander B cells still failed to secrete IgG when mice were injected with an anti-IgD-Ag conjugate specific for the other Igh allotype as well as a mAb that cross-linked IgD of the bystander B cell allotype. These observations demonstrate that although non-Ag-specific cytokine and contact-mediated T cell help are sufficient to induce B cells to increase in size and Ia expression in anti-IgD antibody-injected mice, Ag-specific T cell help is required to stimulate the generation of an IgG response in these mice.     

Polyclonal activation of the murine immune system by an antibody to IgD. X. Evidence that the precursors of IgG1-secreting cells are newly generated membrane IgD+B cells rather than the B cells that are initially activated by anti-IgD antibody

Injection of BALB/c mice with an affinity-purified goat antibody to mouse IgD (GaM delta) stimulates T cell-independent B cell activation as well as later T cell activation. Activated T cells then induce polyclonal differentiation of B cells into IgG1-secreting cells, which results in an approximately 100-fold increase in serum IgG1 level. It is not known whether the same B cells that are initially activated by GaM delta are the progenitors of the IgG1-secreting cells. To investigate this issue a system was developed in which CB20 mice, which are congenic to BALB/c mice but express Ig of the beta allotype rather than the BALB/c alpha allotype, were injected with GaM delta and simultaneously or subsequently also received BALB/c B cells. The IgG1 response generated by the donor BALB/c B cells was quantitated by an assay specific for IgG1 of the alpha allotype. Our experiments with this system indicate that: 1) BALB/c B cells transferred 2 days after CB20 mice were injected with GaM delta generate a much larger IgG1 response than do BALB/c B cells transferred simultaneously with GaM delta antibody; 2) B cells that express membrane IgD generate the great majority of this response; 3) differences in the magnitudes of the responses of BALB/c B cells transferred at different times after CB20 mice were injected with GaM delta antibody cannot be explained by differences in homing of the donor B cells to the host spleen or by short survival of donor BALB/c B cells after their transfer; and 4) the response made by donor BALB/c B cells transferred 2 days after CB20 mice were injected with GaM delta is proportionate to donor cell representation in the host spleen 1 day after their transfer, whereas the response made by donor cells transferred simultaneously with GaM delta is disproportionately small. These observations suggest that most of the IgG1 antibody made by GaM delta-injected mice is generated by newly produced, mIgD+ B cells that appear approximately 2 days after GaM delta injection, rather than by those B cells that are present in the spleen at the time of GaM delta injection, and support the view that signals that induce B cell secretion of Ig require an interaction with at least partially activated Th cells.     

Rapid stimulation of large specific antibody responses with conjugates of antigen and anti-IgD antibody

Injection of mice with goat anti-mouse IgD antibody stimulates a large IgG1 anti-goat IgG antibody response, as well as polyclonal IgG1 production. To determine if this phenomenon could be used to induce large antibody responses to other Ag, covalent conjugates were produced between BSA or other Ag and H delta a/1, a mAb specific for IgD of the a allotype, and between BSA and AF3.33, a mAb specific for IgD of the b allotype. Injection of H delta a/1-BSA into BALB/c mice, which express Ig of the a allotype, or into (BALB/c x CB20)F1 mice (a x b allotype heterozygotes) induced IgG1 anti-BSA antibody responses that peaked 8 to 9 days after injection, and were more than 1000 times larger than those induced by injection of BSA alone, and 100 times larger than those induced by injecting unconjugated BSA plus H delta a/1. H delta a/1-BSA was no more immunogenic than unconjugated BSA when injected into CB20 mice, which express Ig of the b allotype, while AF3.33-BSA greatly enhanced anti-BSA antibody production in CB20, but not in BALB/c mice. Mice serially immunized with three different Ag conjugated to H delta a/1 made large antibody responses to all three Ag, provided that the mouse strain used did not recognize allotypic determinants on H delta a/1 as foreign and produce a neutralizing antibody response. Intravenous and s.c. routes of inoculation produced responses of similar magnitude and relatively low variability; responses to footpad or intramuscular inoculation were more variable, and i.p. inoculation induced smaller responses. Injection of BALB/c mice i.v. with 100 micrograms of H delta a/1-BSA induced an IgG1 anti-BSA response of 5.6 mg/ml, which was approximately 70% of the total IgG1 response. Anti-BSA responses to 30 micrograms of conjugate or less were much smaller, but could be considerably enhanced by adding unconjugated H delta a/1 to the inoculum. This system will be useful for the rapid stimulation of large antibody responses to biologically important Ag, and for investigating mechanisms of Ag processing and B and T cell activation.     

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.     

A syngeneic MLR induced in vivo results in T-cell mediated immune suppression

The proliferation of murine T lymphocytes in response to syngeneic Ia bearing non-T cells (syngeneic mixed lymphocyte reaction, SMLR) has been shown to generate regulatory T cells in vitro. An in vivo regulatory role has therefore been proposed for the SMLR. To study this role more directly, we examined the effects of repeated iv injection of mice with activated syngeneic B cells. Three such weekly injections induced a suppression of the plaque forming cell response to a subsequent injection of trinitrophenylated keyhole limpet hemocyanin (TNP-KLH). The suppression was transient and could not be maintained by additional injections of activated syngeneic B cells. The suppression was transferable to syngeneic recipients with splenic lymphocytes. Continued weekly iv injections of LPS induced blasts, as well as weekly intraperitoneal injections, caused enhancement rather than inhibition of the response to iv injected TNP-KLH. The enhancement was prevented by injection of anti-L3T4. Spleen cells from mice which had received three iv injections of activated syngeneic cells suppressed an in vitro secondary response to TNP-KLH by normal immune spleen cells. The cells responsible for the immune suppression were Thy 1.2+. The results indicate that repeated exposure to activated B cells causes activation of suppressor pathways but does not bring about a chronic state of immune suppression.     

Unidirectional IgG allotype- and isotype-specific suppressor cells in congeneic mice

By the use of allotypic markers on immunoglobulin molecules of isotypes IgG1 and IgG2a, in transfers of spleen cells between Igh haplotype congeneic partner strains BALB/c (Igha) and CB20 (=BALB/c-Ighb), the expression of donor and recipient lymphocytes could be followed differentially. BALB/c donor's allotype a was produced in nonirradiated CB20 recipients for months. By contrast, CB20 donor's allotype b disappeared in nonirradiated BALB/c recipients shortly after transfer. These BALB/c recipients of CB20 spleen cells ("CB20-primed") developed lymphocytes which were able to suppress the autochthoneous allotype b production of CB20 irradiated or CB20 nu/nu or neonatal F1 (BALB/c female X CB20 male) recipients immediately after transfer. Titers decreased with a half life of about 4 days, resembling that of immunoglobulin molecules. The suppression was restricted to the IgG2a isotype of allotype b. Neither the other isotype IgG1 of allotype b, nor, in the reciprocal transfer experiment, IgG1 or IgG2a of allotype a was affected. Analogous transfers between Igh congeneic partners on a C57B1/6 genomic background revealed the same susceptibility of allotype b-producing cells from C57B1/6 donors toward suppression by C57B1/6-Igha mice as recipients. Allotype suppression, induced by cell transfer, is thus unidirectional in that Igha haplotype mice react against allotype b but not vice versa, and it is isotype-specific, only directed against IgG2a, and not IgG1.     

Anti-IgD enhancement of primary antibody responses in rats

The role of membrane IgD in immune responses was examined by treating adult rats with anti-IgD. Anti-IgD when administered to rats in conjunction with optimal or suboptimal doses of either SRBC, a T-dependent antigen, or DNP-Ficoll, a T-independent antigen, enhanced the antibody responses. The greatest enhancement was obtained when anti-IgD was administered before the antigen. The effects of anti-IgD on antibody responses to SRBC were: (i) significant antibody responses to suboptimal antigen concentrations; (ii) greater antibody responses to optimal antigen concentrations; (iii) accelerated antibody responses; (iv) an early shift from IgM to IgG antibodies; (v) prolonged antibody responses. Similar effects on the immune response to DNP-Ficoll were observed with the exception that all antibodies were 2ME sensitive (IgM). These results suggest that an anamnestic type of immune response can be induced in anti-IgD-treated rats when given a primary antigen exposure. Injection of anti-IgD without SRBC or DNP-Ficoll induces B-cell proliferation without detectable antibody production to these antigens, indicating at least two signals are required for the enhanced antibody responses.     

Expression of IgG memory response in vitro to thymus-dependent and thymus-independent antigens

A model is described in which expression of IgG secondary antihapten responses of large magnitude can be initiated in vitro without resorting to in vivo boosting prior to culture. The number of IgG plaque-forming cells (PFC) is frequently as much as 100-fold greater than that of IgM PFC. Spleen cells from mice primed with trinitrophenylated keyhole limpet hemocyanin (TNP-KLH) several months earlier are stimulated in vitro to produce an anti-TNP plaque-forming cell response 7–10 days later. The in vitro IgG response can be elicited with either a thymus-dependent antigen (TNP-KLH) or thymus-independent antigens (TNP-T₄ bacteriophage or DNP-dextran). The kinetics of the responses to these two forms of antigen differ in that the thymus-independent response peaks two days earlier. The IgG response to both forms of antigen requires the presence of 2-mercaptoethanol (2-ME) even though macrophages are not depleted prior to culture. In the absence of the reducing agent both thymus-dependent and thymus-independent IgG responses were diminished ≥90%. The magnitude of the response to thymus-independent antigens emphasizes the ability of these materials to elicit IgG expression in memory B cells provided optimal conditions for memory development and in vitro expression exist.     

Idiotype vaccines against human T cell acute lymphoblastic leukemia. I. Generation and characterization of biologically active monoclonal anti-idiotopes

A murine monoclonal anti-tumor antibody termed SN2 (Ab1), isotype IgG1-kappa, that defines a unique human T cell leukemia-associated cell-surface glycoprotein, gp37 (m.w. 37,000), was used to generate monoclonal anti-idiotype antibodies (Ab2) in syngeneic BALB/c mice. The Ab2 were screened on the basis of their binding to the F(ab')2 fragments of SN2 and not to the F(ab')2 of pooled normal BALB/c mice sera IgG1 or to an unrelated BALB/c monoclonal antibody of the same isotype. Fifteen Ab2, obtained from two fusions, were specific for the SN2 idiotope and not against isotype or allotype determinants. To find out whether these Ab2 are directed against the paratope of SN2, the binding of radiolabeled SN2 to leukemic MOLT-4 and JM cells which contain gp37 as a surface constituent was studied in the presence of these anti-idiotopes. Clone 4EA2 inhibited the binding 100% at a concentration of 50 ng and 4DC6 inhibited 90% at a concentration of 250 ng. A third clone 4DD6 gave about 50% inhibition. Similar was the inhibition of SN2 binding to insolubilized MOLT-4 antigen or cell membrane preparation. The binding of SN2 (Ab1) to 4EA2 and 4DC6 was also inhibited by semipurified preparation of gp37 antigen. These results demonstrate that at least two of the anti-idiotope antibodies are binding either at or near the binding site idiotope of SN2. Next, the purified Ab2 was used to immunize syngeneic mice to induce antibody binding to MOLT-4 cells or gp37. Sera from mice immunized with 4EA2 and 4DC6 coupled to keyhole limpet hemocyanin contained antibodies which bind to semipurified gp37 antigen and MOLT-4 cells. Immune sera inhibited the binding of iodinated Ab2 and Ab1 indicating that an anti-anti-idiotopic antibody (Ab3) in mice shares idiotopes with Ab1 (SN2). Also, the binding of iodinated Ab2 to Ab1 was inhibited by rabbit antisera specific for gp37. Collectively, these data suggest that anti-idiotype antibodies 4EA2 and 4DC6 may be useful in the generation of idiotype vaccines against human T cell leukemia.     

Role of antigen-specific T cell help in the generation of in vivo antibody responses. II. Sustained antigen-specific T cell help is required to induce a specific antibody response.

The injection of mice with a goat or rabbit antibody to mouse IgD stimulates a large polyclonal IgG response, approximately 10% of which is specific for antigenic determinants on the anti-IgD antibody molecule. The large goat IgG (GIgG)-specific antibody response in mice injected with goat antibody to mouse IgD requires that GIgG-specific B cells undergo much greater clonal expansion than B cells specific for other Ag. One possible explanation for the greater clonal expansion of GIgG-specific B cells is that B cells that lack GIgG specificity can only be stimulated with GIgG-specific T help during the relatively short time that anti-IgD binds to, and is processed and presented by, these B cells before they cease to express membrane mIgD. In contrast, GIgG-specific B cells can continue to bind, process, and present GIgG through mIgM after they lose mIgD. To test the hypothesis that extended stimulation with Ag-specific T help is required to generate a specific antibody response, we determined time requirements for Ag-specific T cell help for the development of such a response. Mice were injected with rabbit antibody to mouse IgD plus one or more daily injections of FITC conjugated to a F(ab')2 fragment of rabbit IgG (FITC-(Fab')2), which has a short in vivo half-life, and IgG1 anti-FITC antibody production was analyzed. In this system, each additional injection of FITC-F(ab')2 extends the period during which FITC-specific B cells can process this Ag and present it to rabbit IgG-specific T cells. Each additional injection of FITC-F(ab')2 stimulated a several-fold increase in IgG1 anti-FITC antibody levels, and injections on 5 consecutive days were required to induce a maximal anti-FITC response. These observations provide evidence that sustained Ag-specific T cell help is required to stimulate the degree of B cell clonal expansion that characterizes a specific antibody response.     

The Effect of IFN-gamma, Alum and Complete Freund Adjuvant on TNP-KLH Induced Ig.G(1), IgE and IgG(2a) Responses in Mice

Adjuvants are considered to play an important role in directing the isotype and amount of antibodies produced upon immunization by conducting the development of either Th-1 or Th-2 cells upon T-cell stimulation. This is based on the different cytokine production patterns that were observed after in vitro resttmulation of T cells isolated from mice immunized with antigen either adsorbed on alum or emulsified in complete Freund adjuvant (CFA). However, other studies suggest that primarily the type of antigen determines which isotypes are produced and to what extent. In these studies, however, IgE was not determined. Therefore, this study examined whether alum and CFA influenced the amount and/or ratio of IgG(1), IgE and IgG(2a) produced after TNP-KLH immunization. Similar levels of IgG(1), IgE and IgG(2a) antibodies were found upon immunization with TNP-KLH either adsorbed on alum or emulsified in CFA. Moreover, administration of IFN-gamma in combination with TNP-KLH adsorbed on alum did not increase the amount of IgG(2a) produced. IFN-gamma treatment resulted in an increased IL-6 and decreased IFN-gamma production by spleen cells upon Con A stimulation, whereas it did not change the IL-4 production in similar conditions. The presented results suggest that upon immunization with TNP-KLH high IL-4 levels are produced, resulting in an antibody response that is dominated by IgG(1), independent of the adjuvant employed. The IL-4 inducing property of TNP-KLH is substantiated by the finding that repeated immunization of mice with TNP-KI, without adjuvant, increases the serum total IgE level. The presented data suggest that the carrier part of TNP-KLH preferentially results in Th-2 cell activity after which the adjuvant merely enhances the antibody responses generated.     

Allotype-specific immunoregulation of autoantibody production by host B cells in chronic graft-versus host disease

A chronic graft-vs-host (GVH) reaction induced in nonautoimmune mice by the transfer of Ia-incompatible spleen cells results in a syndrome that closely resembles SLE in the spectrum of autoantibodies and immunopathology. We have utilized Ia- and Igh-congenic strains to study the immunoregulation of autoantibody-producing B cells in this model. We have found that the autoantibodies are produced almost entirely by the host B cells. The transferred donor B cells contributed neither to the autoimmune response nor to the total serum Ig, with rare exceptions. The donor cell population did, however, exert an Igh allotype-specific immunoregulatory effect on the host B cells. For example, in allotype-heterozygous recipients, the autoantibodies were preferentially made by those host cells that expressed the donor allotype, whereas those host B cells that expressed nondonor allotype were relatively suppressed. In allotype-homozygous recipients, the donor cells frequently suppressed the host IgG2a allotype completely. This suppression sometimes prevented the IgG antichromatin response, although in other cases the response occurred with the use of a different isotype. In a final set of experiments, a chronic GVH reaction was induced in which both the donors and the recipients were Igh allotype heterozygous and yet differed at Ia. In this case, no donor influence on allotype should be expected; yet the IgG2a autoantibodies were clearly skewed toward the b allotype. These results show that host B cells play a unique role in the GVH autoimmune syndrome. In addition, they are immunoregulated in allotype-specific manners, some of which presumably involve interaction with donor T cells.     

IL-4 suppression of in vivo T cell activation and antibody production

Injection of mice with a foreign anti-IgD Ab stimulates B and T cell activation that results in large cytokine and Ab responses. Because most anti-IgD-activated B cells die before they can be stimulated by activated T cells, and because IL-4 prolongs the survival of B cells cultured with anti-Ig, we hypothesized that treatment with IL-4 at the time of anti-IgD Ab injection would decrease B cell death and enhance anti-IgD-induced Ab responses. Instead, IL-4 treatment before or along with anti-IgD Ab suppressed IgE and IgG1 responses, whereas IL-4 injected after anti-IgD enhanced IgE responses. The suppressive effect of early IL-4 treatment on the Ab response to anti-IgD was associated with a rapid, short-lived increase in IFN-gamma gene expression but decreased CD4+ T cell activation and decreased or delayed T cell production of other cytokines. We examined the possibilities that IL-4 stimulation of IFN-gamma production, suppression of IL-1 or IL-2 production, or induction of TNF-alpha or Fas-mediated apoptosis could account for IL-4's suppressive effect. The suppressive effect of IL-4 was not reversed by IL-1, IL-2, or anti-TNF-alpha or anti-IFN-gamma mAb treatment, or mimicked by treatment with anti-IL-2Ralpha (CD25) and anti-IL-2Rbeta (CD122) mAbs. Early IL-4 treatment failed to inhibit anti-IgD-induced Ab production in Fas-defective lpr mice; however, the poor responsiveness of lpr mice to anti-IgD made this result difficult to interpret. These observations indicate that exposure to IL-4, while T cells are first being activated by Ag presentation, can inhibit T cells activation or promote deletion of responding CD4+ T cells.     

Carrier-induced tolerance to nucleic acid antigens.

BALB/c and SJL mice were treated with nucleosides-IgG1 as a tolerogen, before either primary or secondary immunization with nucleosides-keyhole limpet hemocyanin. Nucleoside-specific responses were measured serologically by a modified Farr assay, with either 14C-labeled denatured DNA or nucleosides-131-I-labeled BSA as test antigen. Specificity of the response was tested by hapten inhition experiments. Multiple doses of nucleosides-IgG1 tolerogen given before the primary or secondary immunization effectively suppressed the secondary and tertiary anti-nucleoside responses. The tolerogen did not suppress the response to an unrelated hapten-KLH conjugate. The IgG alone did not suppress the anti-nucleoside response of BALB/c mice to nucleosides-KLH. Single doses of tolerogen before the primary or secondary immunization were less effective. Residual antibody in partially suppressed BALB/c mice showed changes in specificity as compared to controls. Suppression of the secondary response of SJL mice was measured much more readily by binding of nucleosides-131-I-BSA than by binding of denatured DNA. This reflected an altered specificity of the residual antibody; in control animals, antibodies were directed against all four nucleosides, whereas the antibodies of partially suppressed animals were directed only against guanosine. Suppression of anti-nucleic acid antibody responses may have therapeutic application in the management of systemic lupus erythematosus.     

The importance of different murine cell types in the immunopotentiation produced by amphotericin methyl ester.

Amphotericin R (AmB) or its methyl ester (AME) are potent stimulants of humoral and cell-mediated immunity in mice. When AME is injected simultaneously with antigen, it augments humoral immunity by expansion of the primary as well as the memory B cell pool. The most consistent and dramatic effect of amphotericin on humoral immunity is the enhancement of secondary IgG responses. This effect on the IgM-IgG switch mechanism depends on T cells and is reduced following thymectomy on adult mice. The route and timing of amphotericin administration also have dramatic quantitative, effects on immunopotentiation. Neither polyclonal B cell activation nor stimulation of antigen uptake in vitro by peritoneal macrophages was observed following intraperitoneal injection of AME. A tentative hypothesis is that antigen-stimulated T cells are important sites of the immunostimulant effects of AME on murine immune responses.     

Autoimmunity after induction of neonatal tolerance to alloantigens: role of B cell chimerism and F1 donor B cell activation

BALB/c mice rendered tolerant by the neonatal injection of semiallogeneic (C57BL/6 X BALB/c)F1 spleen cells develop features of autoimmune disease. The possible mechanisms involved in autoantibody production, particularly anti-DNA antibodies, were investigated. In the first 5 wk, there was polyclonal B cell activation, as indicated by marked hypergammaglobulinemia, with a predominance of IgG1 and an increased production of antihapten antibodies. IgG1 anti-SSDNA and anti-DSDNA antibodies were detected with similar kinetics, but at higher titers than the anti-hapten antibodies. Also, there was a correlation between the effective induction of tolerance, as evaluated by the measurement of alloantigen-specific cytolytic T lymphocyte precursors, the persistence of B cell chimerism, and the production of anti-DNA antibodies. Anti-DNA antibodies were observed only in mice exhibiting a persistence of immunoglobulins bearing the donor's allotype. To determine the origin of anti-DNA antibodies, experiments were conducted whereby newborn BALB/c (Igh-1a) mice were injected with F1 cells from mice resulting from a crossing between Igh congenic BALB/c mice bearing the IgCHb allotype and conventional C57BL/6 mice (Igh-1b). All anti-DNA and anti-hapten antibodies exhibited the Igb allotype and thus were produced by the F1 donor B cells. The initial phase of tolerance induction was apparently associated with an allogeneic helper effect, because DNP-KLH-primed F1 donor cells transferred to newborn BALB/c could be stimulated after challenge with DNP-BGG. The triggering of persisting auto-reactive F1 donor B cells may reflect an activation by "incompletely" tolerant semiallogeneic T cells.     

Primed lymphoid cell tolerance. II. In vivo tolerization of highly tolerogen-sensitive hapten-primed, potentially IgG-producing B cells

The relative ease of tolerizing IgM-bearing versus IgG-bearing B cells was investigated. Previous work had shown that IgG-bearing trinitrophenyl (TNP)-specific B cells from mice primed and boosted with TNP-keyhole limpet hemocyanin (TNP-KLH) are highly susceptible to tolerization in vitro by TNP presented on an unrelated carrier. TNP-OVA was used as tolerogen, as it may represent a more general class of tolerogens than those which are nonmetabolizable or immunoglobulin containing. This study showed that highly primed B cells are tolerizable in vivo using TNP-OVA, with the IgG response to TNP-KLH easier to tolerize than the IgM response. To determine if the ease of tolerization of the IgG response in vivo was due to intrinsic differences in B-cell precursors of the IgM and IgG responses, tolerance was performed in vitro with B cells of defined surface isotypes. A T-independent antigen, TNP-endotoxin, was employed to minimize T-cell effects. At least 10 times as much TNP-OVA was required to tolerize B cells bearing the IgM surface isotype than those with the IgG surface isotype. Thus, the ease of inhibition of the IgG response as compared to the IgM response in vivo by preexposure to TNP-OVA may be at least partially explained by inherent differences in IgM and IgG B-cell precursors.     

Functional relationships between B-cell subsets: evidence for an antigen-induced B1 leads to B2 switch

Priming of mice with the TI-2 antigen TNP-Ficoll results in an increased secondary anti-TNP response to the TD antigen TNP-KLH. Spleen cells obtained from mice primed with TNP-Ficoll or TNP-LPS, but not TNP-KLH, gave augmented responses to DNP-Dextran, TNP-LPS, or LPS. In vitro treatment of spleen cells with DNP-Dextran results in an increased anti-TNP response to TNP-LPS. This effect is also obtained if mitogenic doses of Dextran and LPS are used to induce cell proliferation. We conclude that the B_i2 subset (responding to TNP-Ficoll and DNP-Dextran) switches to the B2 subset (responding to TNP-KLH) after antigen activation. The B_i1 subset (responding to TNP-LPS) may represent an intermediate stage of B-cell differentiation.     

Different effects of the capsular polysaccharide of Klebsiella pneumoniae on the functions of various subpopulations of B cells in the immune response of mice to T-dependent antigen.

Using the capsular polysaccharide of Klebsiella pneumoniae (CPS-K) as a polyclonal B-cell activator (PBA) and sheep red blood cells (SRBC) as a T-dependent antigen, we studied the effects of PBA on the functions of various subpopulations of B cells in the immune response of mice to T-dependent antigen. Antibody-forming cells (AFC) of IgM and IgG types were estimated as anti-SRBC direct and indirect plaque-forming cells (PFC), and the B cells with precursor activities involving generation of AFC and supplementing new B cells as rosette-forming cells (RFC) of the B-cell type. Stimulation of normal mice by CPS-K caused a definite increase in the number of direct PFC but not in that of indirect PFC and RFC in the spleens. The responsiveness of spleen cells of CPS-K-treated mice to generate PFC and RFC responses to a subsequent injection of SRBC was lower than that of CPS-K-untreated normal mice. In this case, the responsiveness to generate RFC and indirect PFC was inhibited more strongly by CPS-K than that to generate direct PFC. When CPS-K was injected into normal mice simultaneously with SRBC, CPS-K never decreased but increased the levels of PFC and RFC responses to SRBC. In the spleens of SRBC-primed mice, the number of RFC was markedly decreased following injection of CPS-K, the number of direct PFC was increased only slightly and the number of indirect PFC was increased very slightly. The responsiveness of spleen cells of these CPS-K-treated SRBC-primed mice to generate secondary PFC and RFC responses to a subsequent injection of SRBC was much lower than that of CPS-K-untreated SRBC-primed mice. In this case, the responsiveness to generate the secondary RFC and indirect PFC responses was more strongly inhibited by CPS-K than that to generate the secondary direct PFC response. When CPS-K was injected into SRBC-primed mice simultaneously with the secondary injection of SRBC, there were marked decreases in the level of the secondary RFC response and slight decreases in that of the secondary indirect PFC response, but little change in that of the secondary direct PFC response. From these results it has been concluded that CPS-K provides the positive signal (the minor action) and the negative signal (the major action) to various subpopulations of B cells functioning at various stages of the immune response to T-dependent antigen in different ways, and acts to regulate the levels of B-cell responses to the antigen-mediated positive signal.     

IgA anti-dextran B1355 responses.

Injection of mice bearing the Ig-1a allotype with dextran B1355 results in an IgM antibody response that is generally regarded as thymus independent. Moreover, the antibody is directed to alpha[1,3] determinants on dextran B1355 and shares cross-reacting idiotypic determinants with a lambda 1 IgA (J558) myeloma protein as well as a lambda 1 IgM (MOPC 104E) myeloma protein. In this study, we show that BALB/c (Ig-1a) mice injected with dextran B1355 produced highly significant IgA anti-dextran responses with specificity directed to the alpha[1,3] epitope. Kinetics of the IgA anti-dextran response in BALB/c mice paralleled kinetics of the IgM response. However, the magnitude of the IgA response was markedly T cell dependent and age dependent.