Expression and regulation of two idiotype families and subsets within an idiotype family among BALB/c antibodies against p-azophenylarsonate

The expression and regulation of the two different idiotype (id) families associated with the anti-p-azophenylarsonate (Ar) antibodies of BALB/c mice were examined. Both families ( 5AF6 and 3C6 ) represented cross-reactive idiotypes (CRI) expressed in the anti-Ar of most individual BALB/c mice. In response to keyhole limpet hemocyanin-Ar, an average of about 28% of BALB/c anti-Ar had 5AF6 family idiotopes, while 3C6 family was expressed on about 16% of BALB/c anti-Ar antibodies. Suppression induced by anti-idiotype treatment against one family did not suppress the expression of the other family, suggesting that the two families were regulated independently. However, the relative expression of one family could influence the expression of the other, because depression of the 5AF6 family tended to increase the expression of the 3C6 family of anti-Ar. Analysis of the 5AF6 family showed that a majority of BALB/c mice produced antibodies bearing most or all of the idiotopes associated with the family, but that a subset of about 35% of the antibodies synthesized lacked idiotopes associated with a monoclonal anti-Ar member of this family, 2.4. Treatment of mice with anti-idiotypes prepared against two different monoclonal anti-Ar of the 5AF6 family produced different effects: one enhanced while the other suppressed idiotype expression, suggesting that there are differences in the idiotopes associated with these two regulatory pathways. Additionally, results indicated that subsets of antibodies within the 5AF6 idiotype family could be regulated independently of each other.     

In situ analysis of antibody-forming cells from the BALB/c CRIc idiotype family: idiotopic heterogeneity among clustered cells

Immunocytochemical staining methods were applied toward defining the in situ expansion of the BALB/c mouse antibody-forming cells (AFC) that express the CRIc idiotype (id) family associated with the antibody response against the p-azophenylarsonate (Ar) hapten. CRIc+ AFC dominated the early primary anti-Ar response but represented a decreased fraction of the anti-Ar AFC during secondary responses. Two subsets of the CRIc family, CRIc1 and CRIc2, differed in their relative expression, with CRIc1 more pronounced during primary responses and CRIc2 better expanded in secondary responses. Idiotopic differences among AFC in very close proximity suggested convergent migration among B cells having similar but not identical V regions or possibly V region mutations among clonally derived cells. The approach also allowed in situ idiotypic analysis of polyclonally activated B AFC.     

Relationship of idiotypes of the anti-p-azophenylarsonate antibodies of A/J and BALB/c mice

It has previously been shown that A/J anti-Ar antibodies contain 2 different families of cross-reactive idiotypes, referred to as the major and minor idiotypes populations. The present report shows that the minor A/J idiotype is related to a major idiotype of BALB/c anti-Ar antibodies. Anti-idiotype directed against the minor A/J idiotype binds 5 to 10% of A/J anti-Ar but an average of about 40% of BALB/c anti-Ar. This BALB/c population corresponds to the major BALB/c anti-Ar idiotype. For individual BALB/c anti-Ar preparations the maximum percentages of antibody bound by anti-id directed to A/J or BALB/c anti-Ar are very similar. Anti-id reactive with the minor A/J idiotypic population suppressed the formation of the BALB/c major idiotype when injected into BALB/c mice. Adsorption experiments showed that only about one-third of the minor A/J population is related to the BALB/c idiotype and that the expression of this idiotype is highly variable in individual A/J sera. Several types of evidence, obtained with hybridoma products expressing the major A/J idiotype, revealed no detectable relationship between the major A/J and BALB/c anti-Ar idiotypes.     

Relation of a cross-reactive idiotype to genetic control of the immune response.

Antibodies elicited in strain A mice by immunization with keyhole limpet hemocyanin-p-azophenylarsonate (KLH-Ar) produce anti-Ar antibodies, some of which share a cross-reactive idiotype (CRI); in general, 20 to 70% of the antihapten antibody population carries the idiotype. Large amounts of antibody can be produced by the induction of ascitic fluids, using a 9:1 ratio of complete Freund's adjuvant (CFA) to antigen. Antibodies with the CRI can be isolated by isoelectric focusing from selected mice that have produced a high concentration of the CRI. The H chains exhibit a single homogeneous sequence through the first hypervariable region and, when isolated from a large number of individual mice, appear to be invariant in the first framework region. These findings indicate that somatic mutation is not a significant factor in the determination of framework sequences. Appearance of the CRI can be suppressed in adult A/J mice by administration of rabbit anti-idiotypic antiserum prior to immunization. Such suppressed mice produce normal concentrations of anti-Ar antibodies lacking the CRI. Anti-idiotypic antibodies produced against such antibodies failed to show cross-reactivity with anti-Ar antibodies arising in idiotypically suppressed or nonsuppressed A/J mice. The great sensitivity of the assay indicates that the number of such "private" idiotypes, all present on anti-Ar antibodies of a single strain, must be extremely large; this supports a somatic mechanism for the generation of diversity. The "private" idiotypes arising in suppressed, hyperimmunized mice can be adoptively transferred into multiple, irradiated (200 R) recipients by injections of spleen cells or of cells from ascitic fluids. The use of ascitic fluids permits the rapid production of a colony of mice bearing the idiotype. This should facilitate structural studies of a variety of idiotypically different molecules sharing the same (anti-Ar) specificity, as well as studies of the mechanism of suppression.     

Idiotypic analysis of polyclonal and monoclonal anti-p-azophenylarsonate antibodies of BALB/c mice expressing the major cross-reactive idiotype of the A/J strain

The idiotypic cascade allows the induction of silent idiotypes, and as such, the immune system can be reprogrammed towards predetermined goals. To understand the genetic origin of silent idiotypes, we have used a system in which detailed structural and genetic information is available. The major cross-reactive idiotype (CRIA) of A/J mice (positive strain) immunized with arsonate coupled to a carrier can be regularly induced in BALB/c mice (negative strain) by anti-idiotypic treatment with or without subsequent antigen immunization. By using a panel of monoclonal anti-idiotypic antibodies, we have found that the germline-encoded CRIA displays a mosaic of at least five idiotopes. Polyclonal and monoclonal anti-arsonate antibodies prepared from idiotypically manipulated BALB/c mice have been studied. Four germline idiotopes are shared between the CRIA of the A/J strain and the CRIA-like idiotype induced in BALB/c mice. Furthermore, CRIA-like antibodies can appear "spontaneously" in some BALB/c mice immunized with antigen only. The data suggest that anti-idiotypic treatment in BALB/c mice selects a preexisting subset of antibodies. From the serological analysis, it is predicted that CRIA molecules from A/J and CRIA-like molecules from BALB/c employ different VH subgroups but share some components of the hypervariable regions. These predictions are tested in a forthcoming paper that describes the amino acid sequences of BALB/c monoclonal antibodies displaying the major cross-reactive idiotype of the A/J strain.     

Independent regulation of serologically distinct idiotypes in F1 hybrid mice

We have investigated the regulation of expression of two distinct intrastrain cross-reactive idiotypes, CRI_A and CRI_C, characteristic of anti-p-azophenylarsonate (anti-Ar) antibodies of the A/J and BALB/c strains, respectively, in (BALB/c x A/J)F₁ (CAF₁) mice. Such hybrid mice were found to synthesize antibodies with each idiotype when immunized against the Ar hapten group, although the expression of each was significantly reduced as compared with the parental strain. CAF₁ mice were pretreated with idiotypic-specific antibody reagents and subsequently hyperimmunized against the Ar hapten. Analysis of the idiotypes present in immune sera showed that suppression of either CRI did not concomitantly suppress the expression of the other. Alteration of the expression of one idiotype was not, however, without influence on the other; the expression of CRI_C was markedly enhanced in mice suppressed for CRI_A.Abbreviations used in this paper anti-Id(A/J) idiotypic-specific antibodies against A/J serum Ar-specific antibodies - anti-Id(BALB/c) idiotypic-specific antibodies against BALB/c serum Ar-specific antibodies - Ar p-azophenylarsonate - BGG bovine -globulin - BSA bovine serum albumin - CAF₁ F(BALB/c x A/J) - CFA complete Freund's adjuvant - CRIA the major cross-reactive idiotype of A/J Ar-specific antibodies - CRI_C the major cross-reactive idiotype of BALB/c Ar-speck antibodies - CRI_m the minor cross-reactive idiotype of A/J Ar-specific antibodies - DTH delayed-type hypersensitivity - HP hybridoma product(s) - KLH keyhole limpet hemocyanin     

Structural studies on induced antibodies with defined idiotypic specificities. II. The light chains of anti-p-azophenylarsonate antibodies from A/J mice bearing a cross-reactive idiotype.

N-terminal amino acid sequence analyses have been performed on three preparations of light chains of A/J mice. Light chains derived from the IgG of unimmunized animals were compared to light chains of anti-p-azo-phenylarsonate (anti-Ar) antibodies possessing a cross-reacting idiotype (CRI); the latter were derived from the ascites fluid of a single A/J mouse, or from the pooled ascites fluids of 18 A/J mice. The heavy chains of these same two antibody preparations had previously been shown to comprise a single, homogeneous sequence to position 40. With few exceptions, the first 26 positions of light chains derived from unimmunized animals were extremely heterogeneous; the heterogeneity is comparable to that observed in a composite of sequence data on light chains of BALB/c myeloma proteins. Although the light chains obtained from anti-Ar antibodies possessing the CRI (whether from the pool of 18 A/J mice or from a single mouse) were more restricted in their sequence, at several positions as many as four alternative amino acids were detected. These studies indicate that an antibody population with defined idiotypic specificity, and very possibly identical heavy chain sequences, may contain at least four distinct light chains. The feasibility of structural studies on antibodies induced in individual mice is further demonstrated.     

Structural studies on induced antibodies with defined idiotypic specificities. I. The heavy chains of anti-p-azophenylarsonate antibodies from A/J mice bearing a cross-reactive idiotype.

Amino acid sequence analysis has been performed on three groups of heavy (H) chains of A/J mice. H chains derived from unimmunized animals were compared to anti-p-azophenylarsonate (anti-Ar) antibodies which were further subdivided into those possessing and those depleted of a cross-reacting idiotype (CRI). It was found that anti-Ar antibodies bearing the CRI are homogeneous through the first hypervariable region of the H chain. The same sequence was obtained for pooled antibody isolated from the ascites fluid of 18 A/J mice or from a single mouse. The H chains appear to belong to a minor V-H subgroup. In the first 30 positions Anti-Ar antibodies depleted of the CRI had the same sequence as those containing the CRI (with small amounts of heterogeneity at some positions), but contained a mixture of sequences in the first hypervariable region of the H chain. These studies indicate that antibodies with similar specificity and with identical framework sequences, but which differ in their hypervariable regions, contain different idiotypic determinants, and support the concept that the idiotypic determinants reside primarily within hypervariable regions.     

Characteristics of two idiotypic subfamilies of murine anti-p-azobenzenearsonate antibodies

A family of antibodies bearing a common or cross-reactive idiotype, termed CRIC, predominates in the response of most BALB/c mice to the p-azobenzenearsonate (Ar) hapten, but represents a minor component of the anti-Ar response of most A/J mice. Previous results have suggested that the VH region of CRIC is encoded by two different germ-line genes in both strains. We have determined extensive mRNA sequences for VH and VL, developed specific idiotypic reagents and measured affinities for two subfamilies of CRIC, designated CRIC1 and CRIC2. Both were found to be minor components of A/J anti-Ar antibodies, and CRIC1, but not CRIC2, is a major component of the BALB/c response. The two subfamilies utilize different VH germ-line genes but the same, or nearly identical V kappa genes. The VH nucleotide sequences of CRIC1 and CRIC2 exhibit approximately 90% homology. The D regions of both families are short (one or two amino acid residues) and some can be accounted for on the basis of known JH sequences alone. Affinity differences may account for the dominance of CRIA over CRIC1 and CRIC2 in A/J mice, but results obtained with allotype-congenic mice indicate that background (non-V region) genes are also important in controlling levels of expression of the CRIC1 idiotype. Our data suggest that the A/J germline VH gene that gives rise to the CRIC2 family of antibodies may be identical with a previously sequenced BALB/c germ-line VH gene. On the basis of these and earlier data it is suggested that extensive differences between inbred strains of mice in their complements of VH genes do not result from the accumulation of many mutations in these genes. An alternative possibility is that the differences arise from deletions and/or duplications of VH genes.     

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.     

Regulation of the BALB/c anti-p-azophenylarsonate antibody response by monoclonal anti-idiotype. II. Idiotope expression in serum and its regulation

Five murine monoclonal antibody (mAb) anti-idiotypes (id), shown in the accompanying report by binding studies to be reactive with five different id on a single member of the 5AF6 family of BALB/c antibodies against the p-azophenylarsonate (Ar) hapten, were used to examine the distribution of their recognized id among anti-Ar in BALB/c and other mouse strains immunized with keyhole limpet hemocyanin-Ar (KLH-Ar). Differences in id expression in BALB/c and other strains substantiate that all five monoclonal anti-id reacted with different id. This suggests that the anti-id repertoire for a single antibody molecule may be extensive. Two of the anti-id reacted with id that were found in virtually all KLH-Ar immunized BALB/c mice, but constituted only a subset (approximately 33%) of the antibodies representing the 5AF6 family. The other three anti-id reacted with id infrequently expressed among BALB/c anti-Ar. Other mouse strains producing 5AF6 family anti-Ar antibodies also produced antibodies recognized by mAb 2CB8 and 6BA1; however, the three id infrequently expressed in BALB/c mice were produced in higher quantities and in a greater percent of mice. Monoclonal anti-id were capable of suppressing a portion but not all of the 5AF6 family of anti-Ar antibodies. Four of the five anti-id suppressed a greater fraction of the 5AF6 family than that id represented in a normal immune response, suggesting that suppression was mediated via an id other than that recognized by these monoclonal anti-id. Overall, the results indicate that an extensive repertoire of anti-id can be produced against a single id antibody, but suppression induced by treatment with these anti-id in this model is presumably mediated via another as yet unidentified id determinant(s).     

Analysis of the cellular basis of idiotype-specific suppression.

We have investigated the ability of B and T lymphocyte subclasses from donor mice that produce high levels of anti-Ar antibody but have been suppressed for one idiotypic component (CRI) to induce and maintain idiotypespecific suppression. Our studies indicate: 1) Memory B cells from such mice can preempt virgin CRI+ B cells present in the host from contributing to the anti-Ar response. 2) T cells can also adoptively transfer idiotypespecific suppression. 3) B and T cells do not act synergistically in this transfer of idiotype-specific suppression. 4) Extremely small numbers of Ly23 cells transfer suppression of idiotype and most probably represent true Ts cells. 5) Ly1 cells from hyperimmune idiotypically suppressed donors can induce idiotype-specific suppression. This latter result most likely reflects the induction of idiotype-specific suppressor cells in the host.     

Analysis of the idiotypic network in tumor immunity

Herein we have analyzed the expression of idiotopes associated with a monoclonal anti-tumor-associated antigen (TAA) antibody in DBA/2 mice which have progressively growing tumors or resist tumor growth. A panel of eight monoclonal antiidiotypic antibodies raised against a monoclonal antibody which reacts with a mouse mammary tumor virus cross-reactive qp52 envelope protein (TAA) of the L1210/GZL lymphoma was used to measure the expression of idiotopes in sera from different treatment groups. Significant correlations between the expression of certain idiotopes and the growth of the tumor or the establishment of anti-tumor immunity are seen. 1) Idiotypes detected by anti-idiotype D11 are high in anti-idiotype immunized progressor or tumor-susceptible mice and low or absent in regressor mice, i.e., the mice immunized with the protective 2F10 anti-idiotype; 2) the 3A4-detected idiotypes are less frequent or absent in irradiated tumor-immunized regressor mice than in untreated mice challenged with live tumor or progressor mice; 3) no difference in the anti-TAA titers is seen in mice in which the tumor growth is inhibited and in mice in which the tumor grows; 4) no difference in 11C1 idiotype + anti-TAA titer was observed between regressor and progressor mice; and 5) mice with normal or accelerated tumor growth have higher titers of idiotypes detected by a polyclonal anti-idiotype. These findings provide evidence for a regulatory idiotype network induced by the growing L1210/GZL tumor or by anti-idiotypic immunization. The titer of anti-TAA antibody does not correlate with the biology of tumor growth, but certain idiotopes correlate with either progressive or regressive tumor behavior. Therefore, the target of the idiotype regulation is likely to be anti-tumor T effector cells. Effective idiotype therapy of tumors must deal with the complexity of idiotype regulation induced by the tumor itself and is unlikely to be successful if anti-idiotypes are used only as internal mimicry of a TAA.     

Contribution of the erythrocyte matrix to the formation of rosettes by idiotype-specific lymphocytes.

Immunosuppression of a cross-reactive idiotype associated with anti-p-azophenylarsonate (anti-Ar) antibodies of A/J mice, followed by hyperimmunization, causes the appearance of substantial percentages of T cells with anti-idiotypic specificity. The T cells were identified through their capacity to form rosettes with autologous (A/J) erythrocytes coated with Fab fragments bearing the idiotype. We report here that the RBC are a significant factor in determining the capacity of the lymphocytes to form rosettes. Relatively low numbers of rosettes were observed when the RBC were derived from species other than the mouse or from certain strains of mice. The property is not determined by the H-2 haplotype but is controlled by one or more genes that are closely linked to the H-2 locus, as shown by data obtained with RBC of several congenic strains. In an F₁ hybrid the property is dominant, suggesting a positive contribution of the RBC rather than the effect of an inhibitor. Also, idiotype-specific lymphocytes from C.AL-20 mice, which possess the allotype of the AL/N strain on a BALB/c genetic background, form rosettes much more efficiently with coated RBC from C.AL-20 or BALB/c mice than with A/J RBC; the opposite is true of idiotype-specific lymphocytes from A/J mice. This provides further evidence for complementary interaction between the lymphocytes and RBC.     

A common VH marker relating BALB/c alpha 1-3 dextran-binding and A/J P-azophenylarsonate-binding antibody families

Antibodies that define the idiotypic marker 104E-MPC11 were purified from rabbit anti-M104E sera. The expression of this marker was searched for in a panel of representative myeloma and hybridoma proteins differing in antigen-binding specificities and idiotype expression. By radioimmune competition assays, the marker was distinguished from the IdX Dex idiotype of BALB/c alpha 1-3 dextran-binding proteins (alpha 1-3 Dex-BP) in that it was expressed on both IdX Dex-positive and IdX Dex-negative proteins on the one hand, and on A/J p-azophenylarsonate-binding proteins (Ar-BP) on the other. Among the later, six of eight of the proteins also expressed the major cross-reactive idiotype (CRI). The marker was expressed weakly or not at all on A/J Ar-BP, which did not express the CRI, as well as on a number myeloma and hybridoma proteins of different antigen-binding specificities, and normal IgG. The marker was localized in VH, but its full expression required the light chain, and was influenced by quaternary structure.     

The VK gene expressed by BALB/c ABPC48 cross-reactive idiotypes induced by anti-idiotypic immunization is identical to that of BALB/c anti-oxazolone and A/J anti-arsonate antibodies

Anti-idiotypic immunization triggers the production of antibodies that are structurally related to the idiotype. We have shown that the heavy chain variable regions of antibodies produced after anti-ABPC48 (A48) anti-idiotypic immunization of BALB/c mice are homologous to that of A48, except for the third hypervariable region. We present here partial light chain sequences of A48 and of antibodies induced by anti-idiotypic immunization. Nearly perfect homology is found, suggesting that these chains are the products of genes derived from a unique VK germ-line gene. These observations indicate that the H and L hypervariable regions contribute to define the structure of A48 idiotopes. Remarkably, the VK sequence we identify is the same as that described for anti-arsonate and anti-oxazolone antibodies. We discuss the relative importance of particular amino acids for idiotype expression and antigen-binding activity.     

Complete amino acid sequence of the heavy-chain variable region from an A/J mouse antigen-nonbinding monoclonal antibody bearing the predominant arsonate idiotype

The 1F6 hybridoma protein, exhibiting the predominant cross-reactive idiotype (CRI) associated with the immune response to p-azophenylarsonate in A/J mice but failing to bind the hapten arsonate, was elicited following immunization with rat anti-CRI [Wysocki, L.J., & Sato, V. (1981) Eur. J. Immunol. 11, 832-839]. The dissociation of idiotype and antigen binding in this hybridoma provides an opportunity to determine structural features involved in antigen binding and idiotypic sites. The complete heavy-chain variable region (VH) amino acid sequence was obtained by automated Edman degradation of the intact chain and fragments due to CNBr cleavage, trypsin digestion, mild acid hydrolysis, and carboxypeptidase A digestion of a CNBr fragment. Comparison of the CRI+ arsonate-nonbinding 1F6 sequence with the CRI+ germ-line VH gene sequence reveals that the 1F6 heavy chain differs from the germ-line-encoded amino acid sequence at seven positions within VH [Siekevitz, M., Gefter, M. L., Brodeur, P., Riblet, R., & Marshak-Rothstein, A. (1982) Eur. J. Immunol. 12, 1023-1032]. The 1F6 VH appears to arise from the CRI+ germ-line VH by somatic mutation at at least seven amino acid residues, each of which could be due to a single nucleotide base change. The diversity (D) gene-encoded segment of 1F6 is similar to that of the CRI+ antigen-binding hybridoma 36-65 except for two amino acid substitutions. Further, the idiotype (CRI) is preserved despite use of a JH4 gene segment in 1F6 as compared to JH2 in all CRI+ arsonate-binding hybridomas examined to date.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of syngeneic antiidiotypic monoclonal antibodies to murine anti-human high molecular weight melanoma-associated antigen monoclonal antibodies

Hybridization with murine myeloma cells P3-X63-Ag8.653 of splenocytes from BALB/c mice immunized with syngeneic anti-human high molecular weight melanoma-associated Ag (HMW-MAA) mAb 149.53, 225.28, 763.74, and TP41.2 has resulted in the formation of antiidiotypic antibody-secreting hybridomas with a frequency ranging between 1.2% and 5.2%. No marked difference was detected in the frequency of antibody secreting hybridomas in the fusions generated from mice immunized with the four anti-HMW-MAA mAb, suggesting that the idiotopes expressed by each of them display similar immunogenicity in a syngeneic combination. The number of antiidiotypic mAb that did not inhibit the binding of immunizing mAb to melanoma cells was higher than that of those that died, suggesting that idiotopes not associated with the Ag-combining site are more immunogenic than those that are. The idiotopes recognized by mAb were not detected on a large panel of anti-HLA Class I mAb, anti-HLA Class II mAb, and anti-human melanoma-associated Ag mAb. The latter included also mAb that cross-inhibit the immunizing anti-HMW-MAA mAb. The idiotopes recognized by mAb were not detected on the isolated H and L chain of the immunizing anti-HMW-MAA mAb. Cross-blocking experiments with a selected number of antiidiotypic mAb identified three distinct idiotopes on mAb 149.53, 225.28, and TP41.2 and two on mAb 763.74. Three, 5, 2, and 5 antiidiotypic mAb to idiotopes within the Ag-combining site of mAb 149.53, 225.28, 763.74, and TP41.2, respectively, were tested for their ability to induce anti-HMW-MAA antibodies. Serological and immunochemical assays detected anti-HMW-MAA antibodies only in sera from BALB/c mice immunized with mAb MK2-23. Therefore, mAb MK2-23 can be classified as beta, while the remaining 14 can be classified as gamma.     

Adoptive transfer of resistance to growth of an idiotype-secreting hybridoma by T cells from idiotypically suppressed mice

A/J or CAF1 mice that are suppressed with respect to an idiotype, CRIA, associated with anti-Ar antibodies, and hyperimmunized develop high concentrations of idiotype-suppressor T cells. In this paper we show that such CAF1 mice are resistant to the growth of a CRIA-positive hybridoma that is lethal in normal or in immunized non-suppressed mice. No resistance was observed to the growth of a hybridoma secreting anti-Ar antibodies that lack CRIA. The state of resistance could be adoptively transferred to naive syngeneic recipients with spleen cells or T-enriched spleen cells from suppressed hyper-immunized mice; B-enriched cells were ineffective.     

Study of idiotopic suppression induced by anti-cross-reactive idiotype monoclonal antibody in the anti-p-azophenylarsonate antibody response

A/J mice immunized with p-azophenylarsonate coupled to keyhole limpet hemocyanin produce antibodies expressing a cross-reactive idiotype (CRIA). The pretreatment of A/J mice with anti-idiotypic polyclonal or monoclonal antibody directed against the major cross-reactive idiotype (CRIA) borne by p-azophenylarsonate-specific antibody can lead to idiotypic suppression. In this study, we investigate this idiotypic suppression by using four mAb2 (E4, H8, E3, 2D3) recognizing distinct idiotopes whose expression is related to the presence of particular gene segments of the heavy chain V region. 2D3 expression has been related to the presence of some amino acid in the CDR2 region of the VH gene segment derived from the germ line VH IdCR11. So far, the latter is the only germ-line gene coding for CRIA+ antibody that has been identified in the A/J genome. E4 and H8 expression has been related to the use of a particular D segment, whereas E3 expression has been attributed to certain combinations of D and JH segments. Therefore, we might expect independent regulation of the expression of those various idiotopes in relation to the mechanism of gene recombination. Indeed, we observed that 2D3-suppressed A/J mice still produce the three other idiotopes, suggesting the recombination of those particular D and J segments with a different VH gene. Such a gene has been identified in the genome of BALB/c mice. A/J mice pretreated with one of the other three mAb2 are generally cosuppressed for the expression of E4, H8, and E3, but they still produce 2D3+ antibody. In this case, the IdCR11 VH germ-line gene is most probably recombined with different D and J segments. Molecular evidence for the existence of such molecules has also been presented in the literature. So our serologic data on idiotopic suppression in the arsonate system can be compared with recent data provided by molecular genetics.