Induction of T15-specific suppressor T cells in mice with the CBA/N defect by neonatal injection with anti-T15 idiotype antibody

Mice with the CBA/N defect (xid) are unresponsive to phosphorylcholine (PC), To determine whether idiotype-specific suppressor T cells can also be generated in these defective mice, defective (CBA/N X BALB/c)F1 male and nondefective (CBA/N X BALB/c)F1 female or (BALB/c X CBA/N)F1 male mice were neonatally injected with antibodies specific for the major idiotype of anti-PC antibody, i.e., anti-TEPC-15 idiotype (T15id) antibody. Suppressor cell activity was examined by co-culturing spleen cells from neonatally treated F1 mice with spleen cells of normal nondefective F1 mice in the presence of antigen. Spleen cells from defective (CBA/NM X BALB/c)F1 mice treated with anti-T15id antibody demonstrated a level of suppressor activity (greater than 83% suppression) comparable to that of similarly treated nondefective F1 mice. This suppression was specific for the T15id of anti-PC response, and a Lyt-1-2+-bearing T cell population appeared to be responsible for the active suppression. These suppressor T cells recognized T15 but not PC, based on a functional absorption test. These results indicate that the CBA/N defects, including the deficiency in the anti-PC response by B lymphocytes and a possible T cell defect, do not influence the generation of T15id-specific suppressor T cells by neonatal injection with anti-T15id antibody.     

Mechanisms of idiotype suppression. V. Anti-idiotype antibody inhibits early B cell triggering induced by antigen

To investigate the relationship between antigen-mediated B cell commitment and induction of idiotype (id) suppression, anti-id antibody directed against the major id (TEPC-15 idiotype or T15id) of the anti-phosphorylcholine (PC) antibody was added at various time intervals to BALB/c spleen cell cultures stimulated with a T-independent PC antigen, R36a. The suppressive effect of anti-T15id antibody on the anti-PC response was rapidly decreased as addition of the antibody was delayed; when anti-T15id antibody was added 6 hr after the initiation of the cultures, only partial suppression was induced, whereas the addition of anti-id antibody after 24 hr did not result in significant suppression of the anti-PC response when compared with similar cultures treated with mock anti-id antibody. This acquisition of resistance to id suppression was completely inhibited by treatment with either sodium azide or colchicine, as well as at temperatures below 20 degrees C. The induction of resistance to id suppression during the preincubation period was dependent on the presence of an immunogenic level of specific antigen. This antigen-mediated B cell commitment did not appear to require macrophages because preincubation of macrophages with antigen did not affect the sensitivity of the B cells to anti-id antibody. These results support the possibility that anti-id antibody inhibits early B cell triggering, which involves an energy-dependent, epitope-mediated, lateral mobility of antigen receptors possibly followed by repolymerization of microtubules.     

Mechanism of neonatal idiotype suppression. II. Alterations in the T cell compartment suppress the maturation of B cell precursors

The cellular mechanism in neonatally suppressed BALB/c mice, which maintains the chronic suppressed state of the TEPC-15 idiotype in the antibody response to phosphorylcholine (PC), was investigated. Cells taken from these suppressed mice cannot transfer suppression to adult BALB/c or affect the in vitro response to PC of adult BALB/c spleen cells. However, spleen cells or T cells from neonatally suppressed mice given to neonatal animals induce chronic suppression of the TEPC-15 idiotype in the anti-PC response. Co-transfer of T cells from neonatally suppressed cells with normal T cells prevented the induction of suppression in neonates. Transfer of T cells from normal or keyhole limpet hemocyanin-primed BALB/c increased the expression of TEPC-15 idiotype in chronically suppressed mice, whereas T cells from neonatally suppressed were ineffective. These findings show that T cells in neonatally suppressed mice can affect the development of immature but not mature cells. The restoration of TEPC-15 expression in neonatally suppressed animals by normal T cells and the failure to induce suppression in neonates by co-transfers of T cells from normal and chronically suppressed mice demonstrate the profound role of an altered T cell compartment in sustaining chronic idiotype suppression.     

Helper T lymphocytes from xid and normal mice support anti-phosphocholine antibody responses with equivalent T15, 511, and 603 idiotypic composition

We have examined the idiotypic composition of secondary adoptive transfer antibody responses to phosphocholine (PC) supported by KLH-primed helper T cells derived from normal mice or xid mice. CBA/N x BALB/c F1 male xid mice have diminished anti-PC responses and virtually undetectable levels of the T15 idiotype; xid mice do express the 511 and 603 idiotypes. Nonetheless, we find helper T cells derived from such mice are indistinguishable from T cells primed in a normal environment in their ability to cooperate with B cells producing anti-PC antibody bearing the T15, 511, or 603 idiotype markers. This result is in contrast to a previously published report from this laboratory. T cells from xid mice did support more IgG PFC than normal T cells, but serum IgG anti-PC antibody levels were similar in both groups. The IgM anti-PC response was predominantly of the T15 idiotype, whereas the 511 idiotype was associated with a minor fraction of IgG1 antibodies. The majority of the secondary IgG "anti-PC" antibody response bore none of the idiotypic markers associated with PC-binding myeloma or hybridoma antibodies, and was directed against phenyl-PC rather than PC. The phenomenon of T15 clonal dominance in the anti-PC response therefore is largely confined to the IgM response. We would conclude that the idiotype levels in the T cell priming environment do not influence the subsequent ability of such primed T cells to support anti-PC antibody responses.     

Thymus-independent induction and antigen-dependent recovery of idiotype-specific suppression

BALB/c nude (nu/nu) mice and euthymic (nu/+) littermates were treated as neonates with anti-T15 antibody and challenged at various ages with either a thymus-independent, PC-Brucella abortus (PC-BA), or thymus-dependent, PC-keyhole limpet hemocyanin (PC-KLH), form of phosphorylcholine (PC). Nu/nu mice challenged with PC-KLH received KLH-primed splenic T cells prior to immunization. Neither neonatally anti-idiotype-treated nu/+ nor nu/nu mice responded with the production of T15-positive anti-PC antibodies after challenge with either form of PC antigen. It is concluded that neither induction nor maintenance of a state of T15-specific suppression requires thymus-matured T cells. Recovery of anti-PC responsiveness in suppressed nu/+ or nu/nu mice was similar and was found to be related to the form of antigen used to elicit the response. Immunization with PC-KLH revealed a long-lasting unresponsiveness (up to 16 weeks). In contrast, immunization with PC-BA elicited a full anti-PC response as early as at 6.5 weeks of age.     

Perturbation of the idiotypic network. I. Induction with multiple alloantigen stimulation

The effect of hyperimmunization on the immune network with allostimulated syngeneic lymphocytes responding to different haplotypes was analyzed. Ten different haplotypes were used to stimulate syngeneic donor mice. Control mice were multiply immunized with incomplete Freund's adjuvant alone or with syngeneic mixed lymphocyte culture-generated lymphocytes. BALB/c mice were immunized consecutively with alloreactive blasts or allogeneically stimulated spleen cells at 10-day intervals. After a rest period of 2 months, the ratio of T helpers to T suppressors was determined by immunofluorescent staining. The functional network was probed by immunizing the mice with phosphorylcholine (PC) coupled to hemocyanin. The sera were analyzed for anti-PC antibodies and TEPC15 (T15) idiotypic expression. The results demonstrated (i) a decrease in the level of anti-PC antibody titer and T15 idiotypic expression; (ii) a decrease in the number of T helper cells and an increase in the number of T suppressor cells; (iii) a loss of PC epitope specificity; (iv) an increase of IgM antibodies expressing T15 without anti-PC specificity; and (v) an elevated level of preimmune lymphocyte proliferation and Ig secretion. These results reveal a functional network linkage in the regulation of alloreactivity and antigen response and show how repeated exposure to alloantigens can induce a perturbation of the idiotypic network controlling the response of a non-alloantigen-related BALB/c strain dominant idiotype (T15).     

Perturbation of the idiotypic network. II. Transfer of suppression to neonatal mice

The cellular mechanisms which are responsible for idiotype perturbation induced by repeated stimulation with either allogeneic mixed lymphocyte culture-generated syngeneic blasts or allogeneically stimulated syngeneic spleen cells were investigated as described in the preceding article. Using the splenic fragment culture system, the precursor frequencies of T and B cells for anti-phosphorylcholine (PC) antibodies and T15 idiotypic antibodies were determined in allogeneically challenged mice. Adoptive transfers of T cells to neonatal BALB/c mice induced suppression of the T15+ anti-PC responses. In addition, the effect of immunization with internal image-bearing anti-idiotopes on the level of anti-PC antibodies and T15 idiotype was determined. Results from this study demonstrated (i) a decrease in the precursor frequency in the PC-specific and idiotype-specific B cell repertoire; (ii) a decrease in the precursor frequency of T helper cells, which recognize idiotypes and anti-idiotypes; (iii) the possibility to transfer T15 suppression to neonatal mice; and (iv) the possibility to restore T15 dominance by anti-idiotypic antibody immunization. These data indicate that both the T and B compartments are involved in the maintenance of suppression induced by repeated exposure to alloantigen-sensitized syngeneic cells. Collectively these findings show that a nonspecific general suppression induced by allohyperimmunization can perturb the T15+ anti-PC response.     

Maturation of B cell subpopulations responding to phosphorylcholine

In this study, the order of appearance of B cell precursors responding to different phosphorylcholine (PC) antigens was investigated. Cells from neonatal BALB/c mice were transferred to male (CBA/N X BALB/c)F1 immunodeficient mice, and splenic fragment cultures were set up at different times after transfer. Because Xid F1 mice are unable to mount a primary anti-PC response, the time to prepare fragment cultures after cell transfer could be prolonged. This created an expanded maturation effect in which small differences in the response pattern of different precursor subsets are amplified. Splenic fragment cultures containing neonatal precursors were immunized with PG-TGG-HY (TD antigen), PnC (TI-2 antigen), or PC-TGG-LPS (TI-1 antigen), or with combinations of these antigens. The in vitro responses to these antigens were found to be additive, indicating the existence of different subpopulations. The detected precursors were also analyzed with respect to the T15 idiotype, which is the normally dominant idiotype of the response against PC in BALB/c mice. The analysis demonstrated a distinctly different maturation sequence of the three B cell subsets in which the order of appearance is: TI-1, TD, and TI-2 responding precursors. The T15 idiotype is expressed dominantly in all stages except the early stage of the TI-1 precursors.     

Regulation of T15 idiotype dominance. I. Mice expressing the xid immune defect provide normal help to T15+ B cell precursors

The immune response to phosphocholine (PC) in many strains of mice is dominated by the T15 idiotype family of anti-PC antibodies. By introducing the CBA/N X-linked immune defect (xid gene) into these mice, one profoundly alters their ability to make a T15-predominant, IgM anti-PC response. This loss of T15 dominance in mice expressing the xid gene is not due to the presence of suppressor T cells or the lack of T15 idiotype-specific helper cells in these mice. Thus, one can reconstitute a T15 idiotype-dominant response in immune defective mice with B cells from normal mice, and in adoptive transfer assays the primed T helper cells from immune-defective mice provide qualitatively the same help to normal B cells as the T helper cells from normal mice. T15 idiotype dominance appears to be controlled by the expression and activation of Lyb-5+ PC-specific B cells. Thus, the majority of T15+ B cell precursors are restricted to this B cell subset, whereas the Lyb-5- B cell subset contains predominantly T15-, anti-PC B cell precursors, which produce mainly IgG antibodies after activation by PC-containing antigens.     

Regulation of T15 idiotype dominance. II. Genes unlinked to the Igh locus regulate T15 dominance of the secondary adoptive transfer response to phosphocholine

We have studied the idiotype and fine specificity of the secondary immune response to phosphocholine (PC) in C57BL (B10, B10.D2, and B.C8) and BALB (BALB/c, BAB-14, and C.B20) congenic strains of mice. In vivo IgM responses of mice from these two genetic backgrounds differed in their T15 idiotypic representation. BALB strains expressed the T15 idiotype on greater than 90% of their IgM, PC-specific plaque-forming cells (PFC), whereas C57BL strains expressed the T15 idiotype on approximately 50% of their IgM PFC. All strains examined expressed greater than 75% PC-inhibitable, VHPC idiotype-positive, IgM PFC. The IgG3 and IgA memory responses were similar to the IgM memory response; BALB strains produced a higher proportion of T15+ PFC than C57BL strains; however, the majority of IgG3 and IgA PFC in all strains were VHPC+, and PC-inhibitable. In contrast, the IgG1 memory response was not dominated by T15+, VHPC+, PC-inhibitable PFC in any of the strains tested. The IgG1 PFC required nitrophenylphosphocholine (NPPC) for efficient inhibition. The IgG2 memory response generally mimicked the IgG1 response with respect to idiotype and specificity. These data demonstrate that the representation of the T15 idiotype in the anti-PC immune response is determined by genes outside both the MHC and Igh genetic loci. Control of T15 expression in secondary IgM, IgG3, and IgA anti-PC responses was examined by using a cell-mixing protocol with primed T and B cells from BALB/c and B10.D2 mice. T15 representation in these responses was determined by the genotype of the B cell, not by the genotype of the helper T cell. Similarly, the B cell genotype was responsible for the idiotypic profile of a primary, in vitro, T-dependent, anti-PC response.     

Demonstration of phosphorylcholine-specific IgE B cells in CBA/N mice.

CBA/N mice, which did not make anti-PC IgM or IgG antibody against PC-conjugated T-dependent or T-independent antigens, produced IgE antibody to PC-determinant when they were immunized with PC-KLH. PC-specificity of IgE antibody produced in CBA/N mice was determined by inhibition of PCA reaction with free PC-hapten or C-polysaccharide or by absorption of reaginic activity in the serum with C-polysaccharide. The presence of T15 idiotype on anti-PC IgE antibody produced in CBA/N x BALB/c F1 males also showed that anti-PC IgE antibody in defective mice was PC-specific. The results suggest that PC-specific B epsilon cells may belong to a subpopulation distinct from PC-specific precursors for IgM and IgG responses.     

Modulation of SLE induction in naive mice by specific T cells with suppressor activity to pathogenic anti-DNA idiotype.

T cells (CD8+) with specific suppressor activity against anti-dsDNA antibody (16/6 Id+) were generated in vitro. The cells were established from BALB/c-enriched T cells exposed in vitro to silica beads coated with the pathogenic anti-DNA idiotype, 16/6. The idiotype specificity of the suppressor cells was demonstrated by (a) specific induction of a decrease in proliferative response of T helper cell lines specific for the pathogenic idiotype (16/6 Id), when exposed to the idiotype, with no effect on T cell lines with other specificities, e.g., against human IgM or synthetic polypeptide. (b) Effectively suppressing in vitro antibody production of anti-16/6 antibody, employing 16/6-primed B cells and specific helper T cell line. The 16/6 Id-specific Ts cells were found to be MHC restricted. Weekly intravenous injections of 10(7) 16/6 Id-specific Ts cells given to BALB/c mice at different stages of experimental SLE disease prevented the clinical, serological, and pathological manifestations. This effect was characterized by decreased titers of autoantibodies (e.g., anti-DNA, anti-Sm antibodies) in the sera, by abolishment of the proteinuria, leukopenia, and the increased ESR, followed by decreased immunoglobulin deposition in the kidneys. Treating the mice with control IgM-specific T cells did not affect the above parameters. These studies demonstrate the ability to generate Ts cells specific for pathogenic idiotypes. The method might be employed therapeutically to modulate the course of autoimmune conditions.     

Immunologic memory to phosphocholine. VII. Lack of T15 V1 gene utilization in Xid anti-PC hybridomas

CBA/N mice carrying the Xid defect fail to make antibodies expressing the T15 idiotype in response to immunization with PC-KLH. Antibodies predominating in the Xid response have binding properties characteristic of group II antibodies that emerge in the memory response in BALB/c; the prototype group II antibody utilizes a VH gene product distinct from the V1 gene product expressed by T15 idiotype-positive antibodies. To examine VH gene usage in the anti-PC response of Xid B cells, hybridomas were produced from Xid mice immune to PC-KLH. Four hybridomas possessing properties typical of the predominant group II antibody response in Xid mice and two representing minor components of the response were studied. Analysis of DNA by Southern blot hybridization revealed that none of the hybridomas utilized the T15 V1 gene segment, nor did they share use of a common VDJ gene product. These results indicate that Xid group II antibodies either make use of different VH gene segments or use the same VH in combination with various D and JH segments.     

T15 dominance in BALB/c mice is not controlled by environmental factors

The effects of the environment on the expression of T15 in the in vivo anti-PC response of BALB/c mice were analyzed. T15 dominance in young BALB/c mice was independent of the expression of T15 dominance in either parent, because the offspring of parental mice that were suppressed for T15 production presented antibody responses dominated by the T15 idiotype. Also, dominant T15 expression was independent of living microorganisms; mice raised in conventional, specific pathogen-free or germfree conditions mounted similar T15 dominant antibody responses. Furthermore, T15 expression was independent of the conventional diet, because mice raised on a synthetic diet produced T15-dominant antibody responses. Moreover, mice that received a synthetic diet under germfree conditions also produced T15 dominant antibody responses. Thus, the generation of T15 dominance in BALB/c mice appears to be independent of environmental factors and within the context of the present and earlier results, originates at the level of B cell-mediated clonal selection/regulation, genetic mechanisms concerning Ig gene rearrangement and expression and/or the fine specificity of the combining site for antigen on the B cell.     

Differences in T15 expression of primary and secondary anti-PC responses with T cells from T15+ and T15- donors

The expression of T15 idiotype dominance with T cells from T15- mice was investigated. It was found that T15 dominance in the T-dependent response to phosphorylcholine (PC) could be generated by unprimed BALB/c B cells with T cells from T15+ and xid T15- mice. T15 dominance was also expressed when T15 neonatally suppressed BALB/c were used as T cell donors. With PC-primed B cells, however, T15 dominance was not established until 3 wk after adoptive co-transfer with T helper cells from xid NBF1 mice. To further study the different efficiencies of T cells for T15 dominance, limiting dilution analysis was performed. The data demonstrate that T15-specific T cell populations in BALB/c mice and NBF1 male mice differ in their precursor frequencies. In BALB/c mice, a frequent set of T15/M167-recognizing T helper cells is present; a corresponding frequent set of cells is absent in NBF1 males. This difference is likely to be one of the reasons why dominance is not immediately established after transfer of T cells from xid mice.     

Suppressor T cells: presence in mice rendered tolerant by neonatal treatment with anti-receptor antibody or antigen.

Specific tolerance to phosphorylcholine (PC) was induced in BALB/c mice by two methods. Neonatal mice received a single injection of either: 1)PnC, the C-polysaccharide from S. pneumoniae, R36a vaccine which has PC as a major antigenic determinant or 2) ARA, an homologous antibody directed against the receptor for PC. Spleen cells from animals treated as neonates with either PnC or ARA were specifically suppressed for the response to PC antigens in vitro. In addition, cells from either group of unresponsive animals co-cultured with spleen cells of normal BALB/c mice markedly suppressed the response of the normal cells to PC. Greater than 90% inhibition of the plaque-forming cell response was obtained when unresponsive cells were mixed with normal cells in ratios of 1:1 or greater. Equal numbers of cells from animals made unresponsive by PnC or ARA produced an equivalent degree of suppression. Neither supernatants of cultures nor sera of animals of either unresponsive group suppressed the response of normal spleen cells to PC. Suppression by cells from both groups of tolerant mice was eliminated by treatment with anti-Thy 1.2 serum and C. Presumably, a common cell is responsible for suppression caused by cells from mice made unresponsive by either procedure.     

Detection of the dominant expression of the TEPC-15 idiotypic determinant(s) on phosphorylcholine-specific suppressor T lymphocytes in vitro

Phosphorylcholine-(PC) specific suppressor T lymphocytes, induced by immunization with PC-coupled syngeneic spleen cells and capable of suppressing antibody production in an in vitro system, were successfully obtained by removal of a PC-nonspecific, i.e., diazo-phenylstructure-directed, suppressor cell population using an immunoadsorbent column coupling an unrelated hapten with a diazo phenyl structure such as azobenzene arsonate (ABA). Column-purified PC-specific suppressor T cell activity was completely abrogated by treatment of the cells with anti-TEPC-15 (T-15) anti-idiotypic antibody and complement, or by the continuous presence of that antibody in the culture, whereas nonpurified suppressor cell activity was resistant to such treatment. Thus, the column-purified PC-specific suppressor T lymphocytes in BALB/c mice have a very homogeneous T-15 idiotypic determinant(s) on their functional receptors for antigen similar to those present on PC-specific antibody and/or B lymphocytes. Because of these results, we envision the growing importance of analysis of the fine specificity of the idiotype repertoire of T lymphocytes after purification of a hapten-specific population.     

A study of autologous anti-idiotypic antibody-forming cells in mice of different ages and genetic backgrounds.

Antibody response to phosphorylcholine, an immunodominant epitope of Streptococcus pneumoniae R36a (Pn), is characterized by a public idiotype, T15, that is expressed on a large proportion of antibody molecules produced by all mouse inbred strains. The ability of the immune system to produce an autologous antibody to T15 upon immunization with Pn vaccine was investigated using a modified ELISA plaque assay for detection of single antibody-forming cells (AFC). The limit of ELISA assay for detection of specific anti-T15 AFC is approximately 300 cells/spleen. However, our studies failed to detect any autologous anti-T15 AFC in the course of the primary antibody response to Pn vaccine in young/adult (2-4 months) BALB/c and C57BL/6 mice. Aged mice (20-22 months) also failed to develop any specific auto-anti-T15 AFC upon the primary Pn immunization, despite the fact that the anti-Pn response in these animals changes both quantitatively and qualitatively. In order to generate specific anti-T15 AFC, BALB/c mice had to be immunized repeatedly with Pn vaccine (four weekly injections) or immunized directly with T15 protein in CFA. Different results were obtained with D1.LP mice that are low responders to Pn and express lower levels of T15 Id as compared to BALB/c. Young D1.LP mice produced high numbers of auto-anti-T15 AFC of both IgM and IgG isotypes following a single immunization with Pn vaccine. The kinetics of auto-anti-T15 response in D1.LP mice was similar to that of the antigen-specific response. These results demonstrate that the ability of the immune network to produce autologous antibody to a shared Id depends on the genetic makeup of the host, and that this response may be regulated by the level of Id expression.     

Regulation of the BALB/c anti-p-azophenylarsonate antibody response by monoclonal anti-idiotype. I. Anti-idiotope fine specificity

Five monoclonal anti-idiotype antibodies were prepared against the IgG1 monoclonal antibody, 5AF6, the prototype molecule representing the BALB/c 5AF6 idiotype family of antibodies specific for the p-azophenylarsonate (Ar) hapten. Three were of BALB/c origin and two were derived from allotype congenic strain CB.20. All five anti-idiotopes (id) reacted with the 5AF6 immunogen but not with four other BALB/c anti-Ar sharing other id with 5AF6. Four of the five showed some reactivity with three monoclonal anti-Ar derived from A strain mice that represent a minor component of the anti-Ar from that strain. Reactivity patterns of these anti-id indicated that all five reacted with different id on the 5AF6 molecule, yet all five were sufficiently close to the Ar-binding site for their binding to be blocked by the Ar hapten alone. Furthermore, all five anti-id could compete with each other for binding to 5AF6, indicating that the five id detected by these anti-id were in close proximity. Four of the five anti-id reacted with id produced by conformations requiring both the appropriate heavy and light chains. The fifth anti-id reacted with a heavy chain id stabilized by the presence of any light chain. The implications of such a diverse anti-id response against a single antibody molecule on anti-id network interactions are discussed.     

Alteration of the B cell surface phenotype, immune response to phosphocholine and the B cell repertoire in M167 mu plus kappa transgenic mice

M167, mu plus kappa, transgenic mice have been analyzed for the expression of the transgene product as a cell surface, Ag-specific receptor and for their ability to respond to Ag. The vast majority of B cells in these H + L transgenics (97 to 99%) express large amounts of the transgene product on their surface and are capable of binding phosphocholine. A total of 4 to 30% of the B cells also express endogenous IgM and IgD H chain products. After immunization with phosphocholine (PC)-conjugated keyhole limpet hemocyanin, more than 1000 micrograms/ml of anti-PC antibody bearing the transgene IgMa allotype marker are produced. Surprisingly, significant amounts of anti-PC antibodies that express the endogenous, IgMb allotype, are also produced; however, these antibodies lack the T15-idiotype which dominates the anti-PC response in their nontransgenic littermate controls. The B cells producing these endogenous anti-PC antibodies also fail to switch to IgG anti-PC synthesis, whereas B cells producing anti-keyhole limpet hemocyanin antibodies readily undergo class switching. These last two observations may be due to the fact that the endogenous anti-PC antibody actually results from mixed mu a + mu b molecules in which the transgene encoded H and L chains are most likely responsible for the binding of PC. Thus, a switch of the endogenous isotype from mu b to IgG would result in a loss of specificity for PC in the IgG molecules produced using the endogenous VH-gene product(s), and mu a + gamma b hybrid molecules are not likely to be formed. This hypothesis is supported by the fact that the majority of (mu a + mu b) hybridomas have the mu b-allotype joined with a VH region other than the VH1 gene which is required for PC-binding and T15 idiotype expression.