Complete heavy and light chain variable region sequence of anti-arsonate monoclonal antibodies from BALB/c and A/J mice sharing the 36-60 idiotype are highly homologous

Structural and serologic studies on murine A/J monoclonal anti-arsonate antibodies resulted in the identification of a second idiotype family (Id36-60) in addition to the predominant idiotype family (IdCR). Id36-60, unlike IdCR, is a dominant idiotype in the BALB/c strain but is a "minor" idiotype in the A/J strain. The complete heavy and light chain variable region (VH and VL) amino acid sequences of a representative Id36-60 hybridoma protein from both the A/J and BALB/c strains have been determined. There are only four amino acid sequence differences between the VH of antibody 36-60 (A/J) and antibody 1210.7 (BALB/c). Two of these differences arise from single nucleotide changes in which the A/J and BALB/c Id36-60 VH germline gene sequences differ. The two other differences are the result of somatic mutation in hybridoma protein 36-60. In addition, Id36-60 heavy chains employ the same D and JH3 segments in both strains. The entire Vk2 VL of 36-60 and 1210.7 differ by only two amino acids, suggesting that like the heavy chains, they are derived from highly homologous VL genes. The same Jk segment is used in both antibodies. A comparison of the amino acid sequence data from Id36-60-bearing hybridomas suggests that a heavy chain amino acid difference accounts for the diminished arsonate binding by the 1210.7 hybridoma protein. Because the 1210.7 heavy chain is the unmutated product of the BALB/c VH gene, somatic mutation in VH may be required to enhance Ars affinity in this system.     

Structural characterization of H chain-associated idiotopes of anti-p-azophenylarsonate monoclonal antibodies

The majority of antibodies directed against p-azophenylarsonate (Ars) protein conjugates elicited during secondary immune responses of A/J mice bear a heritable cross-reactive Id (CRIa or IdCR) which corresponds to the utilization of a unique combination of variable region gene segments that can differ by somatic mutations. One such monoclonal anti-Ars antibody, 44-10, bears IdCR as defined by rabbit antisera but does not react with two anti-idiotypic mAb, 5Ci and AD8, which react with all primary (unmutated) IdCR+ antibodies and some secondary response IdCR+ antibodies. We therefore determined the complete sequence of antibody 44-10, which differs from the germline encoded (unmutated) IdCR+ antibody 36-65 at four positions in the H chain V region (VH): position 55 in the second complementarity determining region, 100 and 107 (D-gene junctions) and 110 (in JH2). The 44-10 L chain is unmutated. Sequence analyses of five other secondary immune response anti-Ars IdCR+ antibodies chosen on the basis of sharing one or more of the amino acid substitutions found in 44-10, were correlated with idiotypic expression of this set of antibodies. The results suggest that the mutation at VH position 55 (Asn----Lys) is responsible for loss of the 5Ci idiotope. To substantiate this hypothesis, oligonucleotide-directed mutagenesis of the germline encoded (unmutated) IdCR+ antibody was used to produce two mutants, one with VH Lys 55 and the other containing residues at positions 100, 107 and 110 identical to those found in 44-10. Id binding studies on these mutants confirm that 5Ci idiotope loss is due to conformational changes resulting from a mutation at VH position 55. This mutation also results in loss of the AD8 idiotope in the structural context of antibody 44-10.     

The association of various D elements with a single-immunoglobulin VH gene segment: influence on the expression of a major cross-reactive idiotype

A large fraction of the anti-p-azophenylarsonate antibodies of strain A/J mice share a major cross-reactive idiotype (IdCR). Structural analysis of monoclonal antibodies expressing this idiotype (IdCR+) indicates that a particular combination of variable region gene segments (Vk, Jk, VH, D, and JH) encodes the variable regions of the light and heavy chains of these IdCR+ antibodies. With the use of serologic methods, hybridoma cell lines have been isolated that produce monoclonal antibodies lacking IdCR determinants (IdCR-), but that are derived from most of the same combination of variable region gene segments that encode IdCR+ monoclonal antibodies. Structural analysis of these IdCR- monoclonal antibodies demonstrates that they are very homologous to each other and to IdCR+ monoclonal antibodies with respect to VH and VL sequences, but are markedly different from IdCR+ monoclonal antibodies in their utilization of D region segments. Comparisons of antigen avidity of these IdCR+ and IdCR- antibodies indicates that conservation of D region structure is not crucial for effective antigen binding. These results indicate the importance of the D region in idiotypy in the IdCR system and demonstrate the variation permitted in D region structure while maintaining antigen recognition.     

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.     

Complete amino acid sequences of the heavy and light chain variable regions from two A/J mouse antigen nonbinding monoclonal antibodies bearing the predominant p-azophenyl arsonate idiotype

The immune response to p-azophenyl arsonate (Ars) in A/J mice is dominated by a cross-reactive idiotype (CRI or IdCR). IdCR+ hybridoma proteins 1F6 and 3D10 produced in a single mouse by immunization with a monoclonal anti-IdCR antibody did not bind Ars [Wysocki, L., & Sato, V. (1981) Eur. J. Immunol. 11, 832-839]. The preservation of idiotype coupled with lack of antigen binding in the same molecules provoked an examination of their primary structures in order to localize sites involved in binding to antigen and to anti-idiotypes. The VH sequence of antibody 3D10 was determined by Edman degradation of intact chains and fragments generated by CNBr, hydroxylamine, and o-iodosobenzoic acid cleavage, by trypsin and V8 protease digestion, and by sequence analysis of mRNA. The 1F6 VH sequence was reported previously [Smith, J. A., & Margolies, M. N. (1984) Biochemistry 23, 4726-4732]. The VL sequences of 1F6 and 3D10 were determined by Edman degradation of intact chains and peptides generated by cleavage with o-iodosobenzoic acid and digestion with trypsin and chymotrypsin. Both 1F6 and 3D10 are encoded by the same VH, VK, D, and JK gene segments as are IdCR+ Ars-binding antibodies. However, 1F6 and 3D10 employ the JH4 gene segment rather than JH2. Antibodies 1F6 and 3D10 share several somatic mutations, suggesting a common clonal origin, but manifest individual mutations as well. By comparison with Ars-binding IdCR+ molecules, the substitutions in 1F6 and 3D10 likely responsible for the lack of Ars binding are localized to the heavy chain D-JH junction and/or to a substitution in light chain CDR 3.     

Immunologic memory to PC-KLH: participation of the Q52 VH gene family

BALB/c mice immunized with phosphocholine-conjugated keyhole limpet hemocyanin respond with two major groups of antibodies that differ with respect to fine specificity and idiotype. Group I antibodies predominantly bear the T15 idiotype, and show appreciable affinity for the haptens PC and nitrophenyl PC (NPPC), whereas group II antibodies have appreciable affinity for NPPC only and are T15 idiotype negative. Previous studies indicated that group II binding characteristics may derive from the use of novel V gene segments not observed in group I antibodies. To determine the nature of VH gene usage in the group II antibody response, we examined the VH region of a prototype group II hybridoma, PCG1-1. The nucleotide sequence obtained from the VDJ region indicates that PCG1-1 utilizes a VH gene not observed in the group I response, one that belongs to the Q52 VH family. The PCG1-1 VH nucleotide sequence shares 97% identity with the myeloma M141 VH gene. In addition, PCG1-1 utilizes a D segment most closely related to DSP2.6 rearranged to JH-3. These data indicate that M141, a VH gene not seen in group I anti-PC antibodies is utilized by PCG1-1 to generate a PC-protein-binding group II antibody. PCG1-1 was previously shown to express the V kappa 1-3 light chain, a characteristic shared by several group II hybridomas. Furthermore, here we examined the VH gene rearrangements in four lambda 1-bearing group II hybridomas that share a common JH rearrangement with PCG1-1 by Southern blot analysis. A VH-specific probe that detects M141 VH rearrangements revealed that all four lambda 1 hybridomas as well as PCG1-1 share an identical VH gene rearrangement to JH-3. Thus the M141 VH gene product is able to utilize two distinct light chains to generate group II-like combining sites.     

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.     

Molecular analysis of heavy and light chains used by primary and secondary anti-(T,G)-A--L antibodies produced by normal and xid mice

The primary (1 degree) antibody response to (T,G)-A--L shows limited heterogeneity, consisting mostly of side chain-specific antibodies that bind GT and that express the TGB5 idiotype (Id). The secondary (2 degrees) response is very diverse: antibodies that bind the backbone A--L constitute a third of the response, and a high proportion of the side chain-specific antibodies do not bind GT and are TGB5 Id-. To provide a molecular basis for understanding this difference in repertoire expression, we analyzed the Ig genes used by heavy and light chains of 1 degree and 2 degrees side chain-specific anti-(T,G)-A--L hybridoma antibodies (HP). Southern blot restriction analysis and nucleotide sequence analysis of the expressed genes used by three TGB5 Id+ 2 degrees HP showed usage of three different VH genes in two VH gene families (36-60 and J558), different D segments, and two different Vk1 genes (the Vk1A and Vk1C subgroups). Thus, antibody heterogeneity in the 2 degrees response is contributed by combinatorial diversity of distinct germ-line genes. Nucleotide sequence analysis of the expressed genes used by TGB5 Id+ 1 degree HP showed use of highly homologous VH genes in the J558 VH gene family and highly homologous Vk1A genes. The majority of TGB5 Id+ 1 degree HP from different donors gave similar heavy and similar light chain gene rearrangements by Southern blot restriction analysis, after correction for known or potential J region differences. The combined nucleotide sequence and Southern blot restriction analysis data suggest that most 1 degree B cells use the same or very similar VH and Vk genes, i.e., the 1 degree response is paucigenic. Different D segments were used by the TGB5 Id+ 1 degree and 2 degrees HP that were sequenced, and there was no apparent correlation between TGB5 idiotypy and VH, D gene, or JH gene usage. However, all TGB5 Id+ HP sequenced used highly homologous genes from the Vk1 group. Expression of a Vk1 light chain correlates with, but is not sufficient for, TGB5 idiotypy, because one GT-binding, TGB5 Id- HP was found to use a Vk1C subgroup light chain. By Southern blot and nucleotide sequence analysis, the Vk genes used by two TGB5 Id+ 2 degrees HP from xid mice are highly homologous, if not identical to the Vk1A gene(s) used by 1 degree and 2 degrees Id+ HP from wild-type mice.     

Characteristics of murine monoclonal anti-CD4. Epitope recognition, idiotype expression, and variable region gene sequence.

We have characterized a series of mouse monoclonal anti-CD4 and describe both their CD4 epitope recognition and Id expression. We also determined the V region gene sequences of these antibodies in an attempt to correlate epitope recognition and Id expression with V region sequence. All of these preparations recognize epitopes that cluster around the HIV gp120 binding site on the human CD4 molecule. However, we observed differences in epitope recognition among the anti-CD4 preparations, based on either competitive inhibition assays or functional assays, such as syncytium inhibition. Analysis of Id specificities using a polyclonal anti-Id generated against anti-Leu 3a indicated that five of the seven monoclonal anti-CD4 expressed a shared Id. Based on V region gene sequences, the V region kappa-chain (V[kappa]) from each of the seven antibodies was encoded by the V[kappa]21 gene family and expressed the J[kappa]4 gene segment. Those preparations that expressed the shared Id with anti-Leu 3a have virtually identical V[kappa] sequences, with a high degree of homology in the CDR. The VH region gene sequences of six of the seven antibodies also shared overall homology and appeared to be encoded by the J558 VH gene family. The seventh anti-CD4 VH region is encoded for by the VHGAM gene family. The majority of these antibodies used JH3 gene segment, although the JH2 and JH4 gene segments were also represented. In addition, several of these antibodies share a common sequence organization within their V-D-J joining regions that appears to involve N and P sequences to generate unique D segments. Together, these data suggest that differences in epitope recognition among the monoclonal anti-CD4 may reflect sequence variability primarily within the CDR3 region of both V[kappa] and VH. The basis for the detection of a shared Id most likely reflects the high degree of homology within the V[kappa] region sequences. In addition, these data, which are based on a limited analysis, suggest the possible restricted use of V region germ-line gene families in the secondary antibody response of BALB/c mice to specific epitopes on the human CD4 molecule.     

Influence of the immunoglobulin heavy chain locus on expression of the VK1GAC light chain

The VK1GAC light chain represents the dominant V kappa structure employed in the antibody response of A/J mice to streptococcal group A carbohydrate ( GAC ). Two anti-idiotypic antisera, anti- Id5 and anti- Id20 , with specificity for the VK1GAC light chain were used to examine anti- GAC antibody responses in a series of inbred mouse strains that differ at the heavy chain constant region ( IgCH ) allotype locus. Both idiotypes were expressed in normal and immune sera from mice of most IgCH allotypes, except IgCHb (C57BL/6J) and IgCHf (CE/J). C57BL/6J mice expressed Id5 , but not Id20 , whereas CE/J mice did not express either idiotype. Testing of recombinant inbred strains between BALB/c and C57BL/6 indicated that the pattern of idiotype expression did not correlate with IgCH allotype. The C X B recombinants expressed all three idiotype patterns that were observed in the panel of inbred strains. Testing of allotype congenic mice between BALB/c and C57BL/6 showed that CB.20 and BC.8 mice were Id20 -, whereas BAB-14 mice were Id20 +, indicating that both VH and background (V kappa or regulatory) loci must be derived from BALB/c to obtain Id20 expression. The difference in the frequency of idiotype expression observed between BALB/c and BAB-14 mice indicates that the IgCH locus may exert a quantitative influence on the expression of this light chain. To examine the Id20 -, Id5 + antibodies of C57BL/6 mice, anti- GAC hybridomas were prepared. Of 16 C57BL/6-derived anti- GAC monoclonal antibodies, six were reactive with anti- Id5 and not with anti- Id20 . Isoelectric focusing of the purified kappa light chains from three of these antibodies revealed two distinct spectrotypes that co-migrated with the two known VK1GAC spectrotypes observed with A/J anti- GAC light chains. Idiotypic analysis of in vitro recombinants between the heavy and light chains of A/J and C57BL/6 monoclonal antibodies demonstrated that the C57BL/6 light chains were idiotypically similar to A/J light chains when they were free in solution or paired with A/J heavy chains. These results demonstrate that C57BL/6 mice can express a light chain that is very similar, if not identical, to the VK1GAC light chain, although the light chain is expressed in lower frequency and is paired with a distinct VH structure, which can mask expression of one of the VK1GAC idiotypes. These effects on V kappa expression map to at least three genetic loci: VH, CH, and an unlinked locus.     

Detection of a regulatory idiotype on a spontaneous neonatal self-reactive hybridoma antibody

To investigate the physiologic relevance of an idiotype-driven regulation of the immune system, we began a search for spontaneous self-reactive hybridomas in neonatal BALB/c mice. We sought hybridoma antibodies reactive with thyroglobulin (Tg) and expressing Id62, a recurrent idiotype with regulatory properties borne on induced adult autoantibodies to Tg. We describe herein such a neonatal Tg binding/Id62-positive monoclonal antibody (mAb) B10H2, and compare it with prototype mAb 62, an adult Tg-binding/Id62-positive mAb. Both mAb react with the same Tg epitope, as demonstrated by their abilities to totally inhibit the binding of the other to Tg. Moreover, as assessed by a double-reciprocal plot of their binding to Tg, their relative affinities for Tg are comparable. Likewise, mAb B10H2 appears idiotypically similar to mAb 62 because it totally inhibits the binding of mAb 62 to homologous anti-idiotype. Finally, as previously shown for mAb 62, mAb B10H2 expresses Id62 independently on both heavy (H) and light (L) chains, as evidenced by the immunoblot binding of a specific anti-Id62 probe to separated H and L chains. By molecular genetic analysis both antibodies appear to have made use of a member of the same VH 7183 gene family. Altogether, these findings suggest that neonatal mAb B10H2 and adult mAb 62 are very similar if not identical, and regulatory idiotype Id62 may be germline encoded. Furthermore this observation supports, in general, the concept of an idiotype-driven regulation for autoimmune responses.     

Suppression of murine lupus nephritis by administration of an anti-idiotypic antibody to anti-DNA

The suppression of pathogenic antibodies to DNA in NZB/NZW f1 female mice was achieved by repeated inoculation of the mice with a monoclonal anti-idiotypic antibody (anti-Id). The anti-Id, an IgG1, kappa, was directed against a major cross-reactive idiotype (Id) on NZB/NZW IgG antibodies to DNA. One hundred micrograms of the anti-Id were inoculated i.p. every 2 wk, beginning at 6 wk of age (nondiseased mice--no circulating anti-DNA or proteinuria) or 20 wk of age (diseased mice--all with circulating anti-DNA, one-third with proteinuria). As controls, littermates received an IgG, kappa non-DNA-binding myeloma or no treatment. In the young mice, nephritis and anti-DNA antibodies appeared at the same time in all groups, and their circulating antibodies to DNA did not bear the target Id. In the older (20-wk-old) mice, survival was significantly prolonged because of delay in the onset of nephritis; the total quantities of antibodies to DNA were diminished, and the target Id, initially present on circulating IgG, was deleted. These benefits were transient; the suppression of antibodies was followed by the appearance of large quantities of anti-DNA that did not bear the major Id. Therefore, although administration of anti-Id was effective in reducing an undesirable antibody response after the target Id was present on circulating antibodies, the benefits were limited, probably by Id "switch" or by increased synthesis of pathogenic antibodies bearing a minor Id.     

Amino acid sequence of a phosphocholine-binding antibody from an immune defective CBA/N mouse employing the T15 VH region associated with unusual DH, JH, and V kappa segments

Mice expressing the xid gene exhibit an altered immune response to phosphocholine (PC)-conjugated keyhole limpet hemocyanin (KLH). Less than 25% of their anti-PC-KLH response is PC specific, and most of these antibodies lack the normally predominant T15 idiotype. These findings suggested that immune defective mice might employ different variable region genes than normal mice in their anti-PC response. To examine this possibility, we characterized by Southern blot analysis the gene family encoding PC-VH regions and determined the amino acid sequence and fine specificity of binding of a T15-, IgG2, PC-specific hybridoma (1B8E5) produced by fusion of the SP2/O cell line and PC-KLH immune CBA/N spleen cells. Southern blot analysis of DNA from CBA/N mice by using a PC-VH probe (S107 VH) revealed a hybridization pattern virtually identical to that of DNA from normal CBA/J mice, indicating that CBA/N mice do not suffer from a gross deletion of PC-VH genes. Analysis of the 1B8E5 antibody reveals that both the binding specificity and relative affinity of this antibody are different from the anti-PC antibodies of the T15, M167-M511, and M603 families. The complete amino acid sequence of the heavy (H) chain variable region shows that 1B8E5 uses a VH segment identical to the allelic form of T15 (C3) but has a unique D region of three amino acids and use the JH1 joining segment. Both the DH and JH regions are unusual when compared to PC-specific antibodies from normal mice, which have a D region composed of five to eight amino acids and use the JH1 joining segment. The amino terminal sequence of the 1B8E5 light (L) chain demonstrates that this anti-PC antibody carries a Vk3 subgroup L chain. Chains from this subgroup have not previously been found in association with PC-binding antibodies. Thus, the Vk, DH, and JH segments expressed in 1B8E5 make this hybridoma unique in terms of the anti-PC antibodies studied to date, and suggests that additional PC-specific antibodies exist in inbred mice that employ "unusual" V gene segments.     

Evidence that anti-idiotype induced immunity to experimental African trypanosomiasis is genetically restricted and requires recognition of combining site-related idiotopes

The ability of anti-idiotypic (anti-Id) antibodies to immunize mice against African trypanosomiasis independent of antigen has been confirmed. Of three allogeneic anti-Id antibodies raised against three protective monoclonal antibodies, each with specificity for the variant surface antigen of a clone of Trypanosoma rhodesiense, only one (anti-7H11 Id) was effective in immunizing BALB/c mice against homologous challenge. The immunity was associated with the more rapid and enhanced expression of the corresponding Id after infection. The immunity was restricted to mice bearing genes linked to Igh-Ca, which appeared to control expression of this Id both in response to infection and anti-Id treatment. Another Id, 11D5, appeared to be under similar genetic control. Anti-11D5 Id, however, was ineffective in immunizing mice against infection despite inducing high levels of Id bearing molecules before challenge. The immunizing potential of the respective anti-Id antibodies appeared to be related to the relative concentrations of antibodies reactive with idiotopes near to or within the antigen-combining site, which, in turn, determined the relative proportion of Id-bearing clones activated that had antigen binding activity.     

V region sequences of anti-DNA and anti-RNA autoantibodies from NZB/NZW F1 mice

The V region sequences of two anti-DNA (A52, D42) and two anti-RNA (D44, D444) autoantibodies, derived from lupus prone NZB/NZW F1 female mice, were determined by mRNA sequencing. The sequences had the following features: 1) there was no clear sequence relationship between anti-DNA and anti-RNA antibodies; 2) there were no major similarities between any of the L chain sequences and each VL gene segment belonged to a different mouse VK subgroup; 3) the H chains of the two anti-RNA antibodies showed closely related sequences of VH gene segments and very similar third complementarity determining regions (CDR3); 4) the H chains of the two anti-DNA antibodies had VH segments belonging to different VH gene families but had a unique and similar combination of D segments and junctional sequences, suggesting a common recognition element for Ag and/or for idiotypic regulation in the H chain CDR3; and 5) the VH gene segment of one anti-DNA antibody (D42) was found to be very similar to the VH gene segment of a CBA mouse hybridoma antibody (6G6) which binds to the environmental Ag phosphocholine. The three-dimensional structure of the Fv-region of the anti-DNA antibody (D42) was modeled by computer and a stretch of poly(dT), ssDNA was docked to a cleft in the antibody combining site, formed by the three H chain CDR and by CDR1 and CDR3 of the L chain. The cleft is characterized by a preponderance of arginine and tyrosine residues, lining both the walls and base of the cleft.     

The developmental patterns of B cell precursors distinguishing between environmental and nonenvironmental forms of phosphocholine.

We have analyzed the developmental patterns of two groups of B cell precursors in nonimmunized BALB/c mice with respect to their relative proportions, absolute frequencies, V gene usage, fine specificity, and avidity for antigen. One group of B cells (group I) secretes antibodies specific for PC and PC-containing bacteria, whereas the other group (group II) produces antibodies recognizing only nonenvironmental PC-protein conjugates. A marked shift in the proportions of group I and group II occurs during ontogeny: while the group I B cells dominate (greater than 85%) the adult antibody repertoire, the group II B cells have equal representation in neonatal mice from Days 1 to 7, and remain as a significant portion until 2 weeks of age. Examination of the absolute frequencies of group I and group II B cells revealed that the frequency of group II B cells remained relatively stable throughout ontogeny, whereas group I B cells expanded rapidly after 7 days of age to predominate in the adult. Genetic analysis indicated that early group I antibodies were encoded by VH and VL genes different from adult group I antibodies which are mostly encoded by a single VH (S107) and VL (V kappa 22) gene combination (the T15 idiotype). On the other hand, early group II antibodies used VH genes comparable to their adult counterparts. The majority of early group I antibodies have lower avidity for PC than adult T15+ antibodies, whereas the avidity of neonatal group II antibodies varies considerably and is comparable with that of the adult group II antibodies. Our results suggest that the ontogeny of phosphocholine-specific B cells may be regulated according to their fine specificity rather than to their avidity or V gene usage.     

A new cross-reactive idiotype-defined family in the phthalate humoral immune response of mice. I. Linkage of VH-Xmp to IgCH allotype locus and mapping with respect to other known VH genes

A cross-reactive idiotype family was previously identified from a very large library of phthalate-specific hybridoma clones. The prototype of this idiotype family is the hybridoma, 2E9, secreting an IgM antibody with phthalate specificity. A portion of both primary and secondary anti-phthalate antibodies elicited in all BALB/c mice tested expresses the 2E9 cross-reactive idiotype. This idiotype has now been found in the anti-phthalate antibodies of several other inbred strains of mice (A/HeHa, DBA/2, and C3Hf/HeHa) tested but not in C57BL/6 mice. Anti-phthalate antibodies elicited from congenic mice BC.8, which express the same IgCH allotype as BALB/c mice but possess C57BL/6 genetic background, contain the 2E9 cross-reactive idiotype, whereas this idiotype is not expressed on the anti-phthalate antibodies derived from another congenic mouse CB.20, which expresses a C57BL/6 IgCH allotype and a genetic background of the BALB/c strain. These results indicate that the gene controlling the 2E9 idiotype is closely linked to the IgCH allotype locus. The 2E9 cross-reactive idiotype was also found in all of the F1 mice (BALB/c X C57BL/6) tested, and the level of expression of this idiotype in the F1 mice was quantitatively equivalent to the allotype/idiotype homozygous mice. The expression of the 2E9 idiotype in the phthalate repertoire has been followed in 12 different wild mouse populations. As expected, the 2E9 idiotype was observed in a large proportion of the wild mouse strains. Surprisingly, several examples of nonconcordance in the expression of idiotype and allotype were observed in these mice. One likely explanation for the linkage breakdown is a crossing over of the heavy chain constant and variable region gene complexes. In the SM/J inbred strain of mice, where such a crossover has occurred, nonconcordance between allotype and 2E9 idiotype expression was demonstrated. By using the recombinant inbred BXD strains of mice, the VH gene encoding the 2E9 idiotype has been mapped with respect to other known VH gene families. Relative to other VH genes the VH-Xmp is situated very close to the IgCH gene region.     

Allogeneic manipulation of the GAT idiotypic cascade. Immunization of C57BL/6 mice by BALB/c anti-idiotypes stimulates similar strain-specific V genes as the original antigen

Antibodies specific for the immunizing Ag (Ab1) (Id+ Ag+) and Ab3 (Id+ Ag+ or Id+ Ag-) of the (Glu60 Tyr10 Ala30) (GAT) idiotypic cascade express similar pGAT public determinants in BALB/c and C57BL/6 strains. These determinants have been shown to be dependent upon both VH and Vkappa encoded segments. The VH of the BALB/c Ab1 (germ-line gene H10) and that of the C57BL/6 Ab1 (germ-line gene V186-2) are only 75% homologous, whereas VK are much more conserved. C57BL/6 mice were immunized with BALB/c Ab2 (anti-idiotypic) antibodies and monoclonal Ab3 were derived after fusion of immunized spleen cells with the nonsecreting hybridoma cell line Sp/2.0-Ag. From 13 cell lines, five clones (four Id+ Ag- and one Id+ Ag+) were isolated and the mRNA V regions sequenced. Immunization with BALB/c anti-idiotypes elicits expression of the same or closely related C57BL/6 VH and Vkappa genes as when C57BL/6 mice were immunized with GAT, although functional VH BALB/c equivalents have been isolated in the B6 strain. Our results suggest that manipulation of the repertoire via antigenic or idiotypic stimulation both lead to the expression of different genes in different strains. They further confirm that the immune system is largely degenerate, for both idiotype expression and Ag recognition.     

A molecular and structural analysis of the VH and VK regions of monoclonal antibodies bearing the A48 regulatory idiotype

The results presented in this paper explore the molecular basis for expression of the A48 regulatory Id (RI). A48 RI+ mAb derived from idiotypically manipulated mice molecularly resembled the A48 and UPC 10 prototypes of this system by utilizing a VHX24-Vk10 combination. Id expression by these antibodies was not restricted by a particular D region sequence, JH, or JK segment, but quantitative differences in Id expression were associated with utilization of different members of the VK10 germ-line gene families. The VL sequences of these A48 RI+ mAb has identified amino acid residues lying in four different idiotope-determining regions which may contribute to the structural correlate of this Id. A comparative sequence analysis of the VH regions of these VHX24 utilizing A48 RI+ mAb with several A48 RI+ mAb utilizing VHJ558 or VH7183 VH genes as well as a hybrid transfectoma antibody derived from two A48 RI-, VHJ558 utilizing hybridomas, all suggested that four nonconsecutive positions which lie outside the idiotope-determining regions may contribute structural elements toward expression of this Id. The VH and VL regions of the A48RI+, VHX24-Vk 10+ mAb showed low to moderate levels of somatic mutation which showed different patterns of distribution between the complementary determining region (CDR) and framework regions in the H and L chains. Although the VK sequences contained 50% of the replacement mutations in the CDR, with a replacement/silent mutation ratio of 10, the CDR of the VH sequences contained only 31% of the replacement mutations with a replacement/silent mutation ratio of 0.69.     

Inheritance of idiotype expression unlinked to the H chain allotype locus. Novel features of genetic control in the Ia.7 system

We have observed a pattern of inherited idiotype expression in three mouse strains that is unexpected from the genetics of the strains: a dominant idiotype that was expressed at high levels in two parental strains was expressed only at low levels in a heavy chain allotype congenic strain derived from them. In the C3H.SW strain, the antibody response to the class II MHC Ag I-E is of limited diversity, with dominant expression of an idiotype and the V kappa 21 L chain. The C57BL/10 strain expresses the same idiotype at high levels, whereas the CWB/12 strain, which was derived by replacing the Ig H chain Igh-Cj allele of C3H.SW with the Igh-Cb allele derived from C57B1/10, has been found to express little of this dominant idiotype. CWB/12 responds, with titers equal to those of the parental strains, to the I-E epitope responsible for dominant idiotype expression, and it expresses normal V kappa 21 levels; thus deficiencies in epitope-specific responsiveness or in V kappa 21 expression cannot explain the low Id expression in CWB/12. Furthermore, Southern blot analysis of three VH families gave no evidence of recombination within the the VH locus of CWB/12, which was Igh-Vb throughout. Black-cross analysis demonstrated that expression of the dominant idiotype segregated independently of Ig allotype, and was therefore due to genes unlinked to the H chain gene locus. To our knowledge, this pattern of Id expression is unprecedented, and indicates the need for caution in the interpretation of studies using allotype congenic strains. It also demonstrates a role for genes outside the Igh locus in the control of Id expression.