Investigations into the nature of Igh-V region-restricted T cell interactions by using antibodies to antigens on methylcholanthrene-induced sarcomas. I. Analysis of an Igh-V-restricted suppressor-inducer factor

We have previously demonstrated the relationship between antigens on BALB/c methylcholanthrene (MC)-induced fibrosarcomas and T cell regulatory molecules by using a variety of antisera raised to these sarcomas in BALB/c and BALB/c X C57BL/6 (CB6F1) mice. One such pool of antiserum, a CB6F1 anti-CMS 4 (Pool XIV) serum, was used to investigate the nature of the T cell regulatory structures recognized by these antibodies. Pool XIV antiserum was capable of blocking the induction of feedback suppression by Ly-1 TsiF, an SRBC-specific suppressor T cell factor secreted by Ly-1+, 2- I-J+ T cells. Ly-1 TsiF induces suppression by interacting with an Ly-1+,2+ I-J+ T cell target. Successful interaction of Ly-1 TsiF with its target cell requires genetic homology between inducer and target cells at the variable region of the immunoglobulin heavy chain gene complex (Igh-V). The addition of Pool XIV antiserum to primary in vitro anti-SRBC cultures resulted in blocking the ability of Ly-1 TsiF from Igha (BALB/c) and Ighj (CBA/J) mice to induce suppression on syngeneic cells, whereas suppression induced by Ly-1 TsiF in Ighb (B6), Ighc (DBA/2), Ighd (A/J), and Ighe (AKR) mice are unaffected by addition of the Pool XIV antiserum. The ability of Pool XIV antiserum to block Ly-1 TsiF activity is linked to the Igh region, because Pool XIV antiserum can block Ly-1 TsiF from BALB/c (H-2d, Igha) and the Igh congenic B.C9 (H-2b, Igha) while not affecting Ly-1 TsiF activity on B6 (H-2b, Ighb) or its Igh congenic C.B20 (H-2d, Ighb). In CB6F1 animals, Pool XIV antiserum could block the ability of CB6F1 Ly-1 TsiF to suppress BALB/c spleen cells but not B6 spleen cells. Conversely, Pool XIV antiserum could block the ability of BALB/c Ly-1 TsiF to suppress CB6F1 spleen cells, whereas B6 Ly-1 TsiF showed normal suppressive activity in the presence of Pool XIV antiserum. In contrast, Pool XIV was capable of blocking the ability of Ly-1 TsiF from BALB/c into CB6F1 bone marrow chimeras (BMC) to suppress both BALB/c and B6 mice, whereas the activity of Ly-1 TsiF from B6 into CB6F1 BMC on BALB/c or B6 spleen cells was unaffected by the addition of Pool XIV antiserum. We then investigated the molecular nature of the molecule recognized by Pool XIV antiserum on the Ly-1 TsiF.(ABSTRACT TRUNCATED AT 400 WORDS)     

T cell-induced Ig allotypic suppression in mice. II. Both CD4+ CD8- and CD4- CD8+ T cell subsets from sensitized Igha mice are required to induce suppression of Igh-1b allotype expression

We established the phenotype of T splenocytes (Ts) from Igha/a BALB/c mice sensitized against B splenocytes from the Ighb/b CB20 congenic mice that induce Igh-1b (IgG2a of the Ighb haplotype) suppression. This was achieved by studying the action of anti-T cell subset mAb on the capacity of Ts to induce this chronic allotypic suppression in Igha/b (BALB/c x CB20)F1 mice. The Ts were treated with cytotoxic anti-mouse CD4 or anti-mouse CD8 rat mAb in vitro before their injection into the Igha/b newborns or in vivo after their injection into the Igha/b newborns. Exposure to either anti-CD8 or anti-CD4 mAb in vitro or in vivo leads to loss of the capacity of Ts to induce Igh-1b allotypic suppression. Mixing CD4+-cell-depleted Ts and CD8+-cell-depleted Ts preparations restored the capacity of the cells to induce Igh-1b suppression. Thus, both CD4+ CD8- Ts and CD4- CD8+ Ts are required for the induction of this allotypic suppression. Bone marrow cells and B splenocytes from Igh-1b-suppressed adult Igha/b mice were shown to be able to durably express Igh-1b when transferred into irradiated Igha/a BALB/c hosts whereas whole spleen cells from such donors failed to do it. Abrogation of Igh-1b suppression by in vivo anti-CD8 mAb treatment was achieved in adult Igha/b heterozygotes but with a lower efficiency than in adult Ighb/b homozygotes, all being chronically Igh-1b suppressed. The CD4- CD8+ cell population essential for maintaining this suppression is resistant to in vivo 600 rad irradiation and seems to be slightly inhibited by in vivo administration of free Igh-1b.     

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.     

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.     

Growth inhibition of a B cell leukemia: evidence implicating an anti-idiotype immune response for protective tumor immunity

BCL1, a spontaneous surface IgM (mu lambda)-positive (sIgM+) B cell leukemia of BALB/c (Igha) origin rarely grows in the Ig heavy chain (Igh) congenic mouse C.B-20 (Ighb) but is highly metastatic and lethal in the host strain of origin. Previous studies indicated that BCL1 tumor immunity in C.B-20 mice was associated with a T cell-mediated immune response against H-40, a minor histocompatibility (H) antigen controlled by a gene linked to the Igh locus. However, we observed that BCL1 leukemia grew progressively in BAB-14 (Igha/b) mice, a strain capable of generating an anti-H-40 immune response. This suggested that anti-H-40 immunity was insufficient for protection and implied that an Igh-V (variable) region gene product was also important for BCL1 growth inhibition. We therefore evaluated the role of two possible Igh-V region-linked gene products in BCL1 growth inhibition; namely, an Igh-V region-linked minor H antigen or alternatively the BCL1 IgM idiotype (Id). We could find no evidence for an Igh-V region-linked minor H antigen because immunosuppressed (500 R) CB-20 mice reconstituted with C.B-20 anti-BAB-14 splenocytes were susceptible to BCL1 growth, whereas recipients reconstituted with C.B-20 anti-BALB/c splenocytes were resistant to BCL1 challenge. In contrast, C.B-20 mice immunized against purified BCL1 IgM protein could adoptively confer BCL1 tumor immunity. C.B-20 mice immunized against other BALB/c IgM myeloma proteins containing either lambda or kappa light chains failed to protect C.B-20 mice suggesting that recognition of a unique determinant (Id) and not an allotype was crucial for tumor immunity. The BCL1 mu-chain appeared to make the major contribution to the idiotypic determinant because a hybridoma product composed of BCL1 mu-chains and BALB/c kappa-chains still elicited BCL1 immunity. Adoptive transfer of C.B-20 anti-BCL1 Id splenocytes into irradiated recipients that prevented an anti-H-40 response due to H-40 tissue expression failed to adoptively confer BCL1 immunity. Thus, these data suggest that BCL1 growth inhibition requires a T cell-mediated response against both H-40 and the BCL1 Id; these responses must be elicited concurrently in the tumor-bearing host to achieve protective BCL1 immunity.     

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.     

Influence of Igh-C- and MHC-linked genes on the activity of immunoglobulin-recognizing T cells

BALB/c Lyt-1+ cells that proliferate in response to NP-modified BALB/c Ig fail to respond to BALB/c Ig modified by a different hapten, TNP. By contrast, when NP-modified BALB/c Ig is used as the immunogen in C.B-20 mice, a strain congenic with BALB/c but expressing the Ighb allotype of C57BL/6 (B6), a partial cross-reaction between NP- and TNP-BALB/c Ig is observed. Similarly, strains expressing different Igh haplotypes also show distinct reactivities toward NP-B6 Ig and NP-modified myeloma proteins. Thus, the proliferative response to NP-modified Ig is regulated by Igh-linked genes. In this paper, we also characterize the T cell proliferative response to IgG2a of the b allotype. We show that allotypic determinants on this molecule are recognized in association with self MHC-encoded gene products and that responsiveness is controlled by MHC-linked Ir genes. Thus, products of MHC-linked genes also influence the activity of Ig-recognizing T cells. Taken together, experiments described in this report suggest that T cells directed against immunogenic determinants on antibody molecules are governed by the same rules as T cells that respond to conventional antigens.     

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.     

Generation in vivo of non-T suppressor cells with the use of anti-allotype antibody

Anti-Igh-1b antiserum induced allotype-specific suppression of adult mouse spleen cells in an adoptive transfer system. Suppression of Igh-1b anti-sheep red blood cell plaque-forming cells was measured as late as 4 wk after the injection of allotype heterozygous (Igha/b) spleen cells, antiserum, and sheep red blood cells. Suppression was maintained on retransfer of the allotype-suppressed spleen cells to further irradiated recipients in the absence of additional exogenous anti-allotype antibody. Mixing experiments were performed to test the putative inhibitory effects of allotype-suppressed spleen cells from the first adoptive transfer (stage I) on the antibody response of normal spleen cells in a second adoptive transfer (stage II). No suppression was observed by using unfractionated stage I spleen cells. In contrast, when these allotype-suppressed spleen cells were depleted of T cells, they strongly inhibited the antibody production of admixed normal spleen cells in stage II. This inhibitory activity of antibody-induced stage I spleen cells was directed primarily toward the target allotype, but some suppression of the Igh-1a plaque-forming cell response and total IgG production also occurred. Although removal of adherent cells did not affect the inhibitory activity of allotype-suppressed spleen cells from stage I, removal of Ig+ cells completely abrogated the inhibitory activity. These results suggest that antibody-induced regulatory B cells may play a role in maintaining long term allotype suppression.     

Influence of the Ig H chain locus on autoantibody production in autoimmune mice.

Autoimmune disease is influenced by multiple genes. In this study, we investigated the role of one genetic locus, Ig H chain. IgG2a antichromatin, anti-ssDNA, and antihistone autoantibodies (autoAb) from (MRL/Mp-lpr/lpr x C57BL/6-lpr/lpr), (Ighj/b); (C57BL/6-lpr/lpr x C57BL/6-lpr/lpr-Igha), (Ighb/a); and (MRL/Mp-lpr/lpr x MRL/Mp-lpr/lpr-Ighb), (Ighj/b) mice were determined using allotype-specific ELISA. Strikingly, antichromatin and antihistone antibodies (Ab) were comprised of significantly more b allotype than either a or j allotype in all cohorts of F1 mice examined. In mice that produced anti-Sm Ab, the b allotype was used preferentially for these autoAb as well. However, no allotype skewing was observed in IgG2a Ab directed against TNP or DNA, or for total IgG2a. An Igh recombinant locus was utilized to examine the genetic control of b allotype skewing in lpr mice and in chronic graft vs host disease. In both models, the VH region did not appear to be responsible for the preferential use of b allotype. These results indicate a contribution to autoimmunity by the Igh locus and raise the possibility that Ig allotype may influence autoimmune disease by its effect on the production of certain autoAb.     

Quantitative measurement of mouse IgG subclasses with the use of heteroantisera: the importance of allotype considerations.

Double antibody radioimmunoassays have been used to determine the quantities of IgG1, IgG2a and IgG2b in samples of normal serum IgG from BALB/cJ, AKR/J and C57BL/6J inbred mice. The assays employed subclass-specific goat antisera which had been prepared with BALB/c myeloma proteins as immunogens and as immunoabsorbents. 125I-labeled BALB/c myeloma proteins were used as probes. Results indicate that partial resolution of mouse IgG subclasses was achieved by ion exchange chromatography on DEAE-Sephadex. Nearly all of the protein in BALB/cJ and AKR/J IgG fractions could be accounted for as IgG1, IgG2a and IgG2b, and IgG2a was the predominant species observed. However, considerably less protein in C57BL/6J IgG fractions of purity similar to the BALB/cJ fractions could be accounted for as these three subclasses, and virtually no IgG2a was detected. Furthermore, an IgG2a myeloma protein bearing the C57BL/6 allotype failed to inhibit the IgG2a-specific assay significantly. Thus the IgG2a-specific antibody in the goat heteroantiserum employed appeared to consist nearly exclusively of antibody to BALB/c Ig-1a allotypic determinants. These findings point to the importance of allotype considerations in the use of heteroantisera to quantitate IgG subclasses.     

In vitro T cell-mediated killing of Pseudomonas aeruginosa. III. The role of suppressor T cells in nonresponder mice

T lymphocytes from immune BALB/c mice can adoptively transfer protection against infection with the extracellular Gram-negative bacterium Pseudomonas aeruginosa to nonimmune recipients, and in vitro, immune T cells are able to kill these bacteria. Earlier studies indicated that this killing is mediated by a bactericidal lymphokine. The current studies demonstrate that T cells from immunized CB.20 mice, a strain congenic with BALB/c, fail to kill Pseudomonas aeruginosa in vitro. This nonresponsiveness is attributable to the activity of suppressor T cells of the Lyt-1-, 2,3+, I-J+ phenotype. CB.20 mice are known to differ from BALB/c mice only at a single locus, which includes the Igh-1 allotype CH genes. These results suggest a critical role for this locus or closely linked genes in the control of T cell killing of this extracellular bacterium.     

Regulation of the anti-alpha(1----3) dextran IgG antibody response of BALB/c mice by idiotype-specific T suppressor lymphocytes.

The immune response of BALB/c mice against the so-called thymus-independent bacterial Ag alpha(1----3) dextran (Dex) is restricted to the expression of few major idiotypes (Id). It is furthermore under the control of T lymphocytes which regulate the isotype expression in such a way that they prevent anti-Dex IgG antibody production upon immunization. At the same time these T cells are part of a regulatory system for Dex-specific B cell memory formation. The underlying Ts cell activity has previously been analyzed by using euthymic and athymic congenic animals. Now we have isolated CD4-positive Id-specific T cell lines and clones which by several criteria are representatives of the above Ts cells. They inhibit in vitro proliferation and antibody secretion of Dex-specific hybridoma B cells. They prevent Id-restricted in vivo IgG anti-Dex antibody formation in T cell-reconstituted BALB/c nu/nu mice. At the same time they enforce, again Id-specific, accumulation of Dex-specific B memory cells. As has been shown previously under the influence of splenic Ts cells, these B memory cells are arrested in the original host but can be expanded and activated for anti-Dex IgG antibody formation upon adoptive transfer into X-irradiated allotype congenic nonresponder BALB.Ighb mice. The data show that the regulatory influence of T cells on the anti-Dex response is Id specific. It can now be studied by means of cloned Ts cells.     

IgA allotype suppression in mice: A cellular implication for the IgA preponderance in the gut

Paternal IgA allotype suppressions were induced in (A/HeJ x SJL/J)F₁, (BALB/cJ x CB-20) F₁, and (BALB/cJ x SJL/J)F₁ mice by perinatal exposure of the neonates to antibody against paternal IgA allotype (Ig-2b). All the Ig-2b allotype suppressions were temporary and were prominently seen at the age of 4–10 weeks. These transient Ig-2b allotype suppressions were manifested by a suppression of Ig-2b allotype in the serum and a suppression of Ig-2b allotype-producing cells in the gut lamina propria. During the suppression, no replacement of the Ig-2b allotype by IgM and IgG plasma cells was seen in the gut lamina propria. The transient IgA allotype suppression was primarily due to a depletion of IgA allotype precursors in Peyer's patches; suppressor T cells were not actively involved. These results suggest that IgA preponderance in the gut is due to the migration of the patch IgA precursors and their accumulation and maturation in the gut lamina propria.     

H-40, an antigen controlled by an Igh-linked gene and recognized by cytotoxic T lymphocytes. II. Recognition of H-40 as a tumor antigen in leukemic animals

C.B-20 (Ighb) but not (C.B-20 X BALB/c)F1 mice reject BCL1, a sIg+ tumor that spontaneously arose in an Igh congenic BALB/c (Igha) mouse. C.B-20 immune T cells from mice immunized with either BCL1 or BALB/c splenocytes adoptively transfer tumor protection to sublethally irradiated C.B-20 but not BALB/c or (BALB/c X C.B-20)F1 mice. These data suggest that BALB/c and BCL1 share an antigen, which if present in the host prevents the immune cells from eradicating the tumor. The antigen is controlled by H-40, a gene that maps to the C end of the Igh complex, telomeric to Tsu and in the region of Pre-1. The ability of H-40 to act as a tumor antigen for other BALB/c tumors inoculated into C.B-20 hosts was investigated. H-40 did not elicit rejection of P1798 (T lymphoma), Meth A (fibrosarcoma), or MOPC-315 (alpha, lambda myeloma) tumor cells. C.B-20 mice that previously rejected BCL1, however, showed partial resistance to a low challenge dose of the MOPC-104E (mu, lambda myeloma) tumor. These data suggest that H-40 has a differential degree of expression on BALB/c tumor cells. The ability of the adoptively transferred cells to confer protection against BCL1 is abrogated by pretreatment of the cells with anti-Lyt-1 or anti-Lyt-2 antibodies. However, an admixture of anti-Lyt-1- and anti-Lyt-2-treated cells provided protection. These data, together with the results detected by cytotoxic T lymphocyte (CTL) activity in vitro, indicate that H-40 can serve as a target antigen for tumor rejection by CTL in allogeneic hosts. The implications of the results for allogeneic bone marrow transplantation into leukemic individuals who benefit from a graft vs leukemia effect are discussed.     

Evidence of alternative or concomitant use of perforin- and Fas-dependent pathways in a T cell-mediated negative regulation of Ig production

To study the possible involvement of perforin (Pfp)- and/or Fas-dependent cytotoxicity pathways in a T cell-mediated negative regulation of Ig production, we used the T cell-induced Ig-allotype suppression model. T splenocytes from Igha/a mice, when neonatally transferred into histocompatible Igha/b F1 or Ighb/b congenic hosts, are intrinsically able to totally, specifically, and chronically suppress the production of IgG2a of the Ighb haplotype (IgG2ab). It has not been established whether the suppression effectors, which are anti-IgG2ab MHC class I-restricted CD8+ T cells, cytolyse IgG2ab+ B targets or whether they only silence Ig production. In this study, using T cells from Igha/a Pfp+/+ or Pfpo/o mice, the latter obtained by crossbreeding, and B cells from Ighb/b Fas+/+ or Faslpr/lpr (lymphoproliferation) mice in appropriate adoptive transfer models, we demonstrated that: 1) under blockage of the Pfp-mediated pathway, Igha/a T cells were still able to induce suppression against wild-type IgG2ab+ B cells, 2) IgG2ab+ B cells with impaired Fas expression were also subjected to suppression by WT Igha/a T splenocytes, and 3) the suppression establishment was totally inhibited when both Pfp- and Fas-dependent mechanisms were simultaneously blocked, i.e., when Igha/a Pfpo/o T cells were used to induce suppression against Ighb/b Faslpr/lpr B cells. These results provide the first demonstration of the existence of alternative or simultaneous use of the major cytotoxic mechanisms in a T cell-mediated down-regulation of an Ig production.     

Allotype suppression in the chicken. V. Abnormal isotype ratios of chronically suppressed IgM and IgG allotypes

Chronic allotype suppression was generated in M-1 (C mu), G-1 (C gamma) heterozygous B14 line chickens either by embryonal injection or by maternal transfer of anti-M-1b allotype antibodies. Using a sensitive radioimmunoassay to detect the suppressed IgM-1b, a striking disparity was observed between the degree of suppression of the IgM-1b allotype and that of the genetically linked IgG-1i allotype. The amount of suppressed IgM-1b ranged between 0.2 and 3% of total serum IgM in chronically suppressed birds. The levels of the genetically linked IgG-1i, however, comprised 5 to 25% of total serum IgG in such birds. The allotypes measured in suppressed chickens were qualitatively identical to those in normal, nonsuppressed birds by serological criteria. These results are discussed within the context of isotype regulation in the chicken.     

From cell biology to immunology--a short trip

Immunologic memory and immunoglobulin allotype suppression are discussed as problems in Cell Biology. Memory, the ability of an animal after a first antigenic exposure to give a heightened and faster immune response upon a second exposure to the same antigen, is shown to be a property of bone marrow-derived cell lines. Expression of this memory depends on interaction with thymus-derived cells from either non-immunized or immunized mice. Chronic allotype suppression is described for the first time. It is initiated by in utero or neonatal exposure of (SJL × BALB/c)F₁ mice, allotype a/b, to anti b antibody. Suppression lasts for long periods and continues in irradiated recipients which have received lymphoid cells from suppressed donors. Selection against b allotype producing cell precursors can explain suppression.     

Igh-C allotype-linked control of anti-DNA production and clonotype expression in mice infected with Plasmodium yoelii

The infection of nonlethal strain of Plasmodium yoelii induces the formation of IgG anti-DNA antibodies as a result of polyclonal B cell activation. By using various nonautoimmune strains of mice including H-2 or Igh congenic or recombinant mice, the levels and clonotypes of anti-DNA antibodies elicited by the malaria infection were analyzed in relation to the expression of the MHC or Igh gene. Our results showed there were little, if any, differences in serum anti-DNA levels and their clonotypes among B10 and B6 H-2 congenic mice. In contrast, malaria-induced IgG anti-DNA responses markedly differed quantitatively and clonotypically between murine strains bearing the Ighb allotype and those bearing the Igha, Ighj, Ighd, or Ighn allotype. The latter group of mice produced approximately 5 to 10 times more IgG anti-DNA antibodies than the former group of mice. Clonotypically, mice bearing the Ighb allotype developed high alkaline anti-DNA antibodies of pH 8.0 to 8.5, whereas non-Ighb mice failed to express such alkaline anti-DNA spectrotypes, and exhibited more neutral spectrotypes (pH 7.0 to 8.0). Studies on the Igh recombinant mice indicated that the observed quantitative and clonotypical differences in IgG anti-DNA production was not associated with the variable region, but with the constant region of the Igh gene complex. Our results have suggested that IgG anti-DNA responses occurring as a result of polyclonal B cell activation during the course of malaria infection markedly differs quantitatively and clonotypically among murine strains and appear to be controlled at least in part by the Igh-C gene or gene(s) closely linked to it.     

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.