A rabbit antiserum detects a VH J558 subgroup marker highly expressed among anti-alprenolol antibodies

A rabbit antiserum raised against anti-alprenolol mAb 14C3 detects common antigenic determinants (ADC3) in 10 out of 14 anti-alprenolol mAb that use different germ-line VH and/or Vk genes. The anti-14C3 antiserum binds only to H chains in immunoblots, therefore suggesting that at least part of the ADC3 determinants may be encoded by H chain V region genes. Analysis of VH gene family usage among the anti-alprenolol mAb reveals that the expression of ADC3 correlates with utilization of VH genes that belong to the J558 gene family, regardless of the JH, Vk, and Jk genes. To determine whether the ADC3 determinants are general V region markers or whether they are unique to anti-alprenolol antibodies, we have extended our analysis to a random panel of antibodies that also use VH genes of the J558 family. Among 23 mAb of various specificities, 14 react with the anti-14C3 antiserum in immunoblot and in ELISA, irrespective of antibody specificity. Adsorption of the antiserum on one of these positive antibodies results in a loss of reactivity toward both anti-alprenolol and unrelated antibodies. Therefore, several but not all antibodies that use a J558 VH gene also express the complete set of epitopes defining ADC3. These results strongly suggest that ADC3 are markers of a subset of J558 VH gene products. The anti-14C3 antiserum may thus constitute a "serologic probe" for identification of a VH gene subgroup from the J558 gene family.     

A set of closely related antibodies dominates the primary antibody response to the antigenic site CB of the A/PR/8/34 influenza virus hemagglutinin

Approximately 50% of the primary antibody response of BALB/c mice to the A/PR/8/34 influenza virus hemagglutinin is directed to the Cb site, one of the four major antigenic regions of the molecule. To determine the structural basis of the anti-Cb site response, we have examined the paratypic and genetic diversity exhibited by a panel of 24 primary and 4 secondary response mAb specific for this antigenic region. Reactivity pattern analysis demonstrated 20 distinct fine specificities among these antibodies, and V region gene sequence analysis showed that they are encoded by 17 different VH gene segments from 6 VH gene families and 14 different VK gene segments from 6 VK gene groups. Despite this overall diversity, many of the antibodies can be placed in a limited number of sets based on the shared expression of VH and/or VK genes. One set contains antibodies encoded by a single gene of the VK4/5 group in combination with one of two closely related genes from the J558 VH family. This set accounts for half of the Cb site-specific primary response hybridomas, indicating that the representation of the various anti-Cb site B cell specificities during the primary response to A/PR/8/34 influenza virus is not uniform. The preferential participation of B cells expressing this VH/VK combination is largely responsible for the dominance of anti-Cb site antibodies in the primary anti-hemagglutinin response.     

Peptides of human thyroglobulin reactive with sera of patients with autoimmune thyroid disease

Autoantibodies to thyroglobulin (Tg) are a prominent feature of the two autoimmune thyroid diseases, chronic lymphocytic (Hashimoto's) thyroiditis and Graves' disease. Similar autoantibodies are found in the serum of many normal individuals without evidence of thyroid disease. Previous studies have indicated that patients with autoimmune thyroid disease recognize epitopes of Tg which are not usually recognized by normal individuals. The goal of this investigation was to identify peptide fragments of Tg bearing these disease-associated epitopes. For this purpose, we utilized a panel of mAbs that bind to different epitopes of the Tg molecule. One of these mAbs (137C1) reacted with an epitope that was also recognized by the sera of patients with autoimmune thyroiditis. In the present study, we show that two peptides (15 and 23 kDa) that reacted with mAb 137C1 are located in different parts of the Tg molecule. Each peptide inhibited the binding of mAb 137C1 to the other peptide and to the intact Tg, indicating that the same epitope was represented on the two peptides. Loops and helices of the secondary structure of the two peptides might be involved in the conformational epitope recognized by mAb 137C1. A striking finding of this study is that two apparently unrelated fragments of the Tg molecule bind to the same mAb. These findings may have important ramifications with regard to epitope spread and the progression of the autoimmune response to disease.     

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.     

Sequences of the VH and VL regions of murine monoclonal antibodies against 3-fucosyllactosamine

Many mAb that bind the carbohydrate antigenic determinant 3-fucosyl-lactosamine (3-FL), Gal beta 1-4[Fuc alpha-3]GlcNAc-R have been raised in BALB/c mice, and we are studying the structure and regulation of these antibodies. In this report, we present the first information about their amino acid sequences and the Ig gene segments used to encode them. V regions of the H and L chains of three anti-3-FL antibodies, PMN6, PMN29, and PM81, were sequenced by a combination of mRNA and amino acid sequencing. The L chain sequences of PMN6 and PM81 antibodies indicate that their VK and JK regions are encoded by VK24B and JK1 germ-line genes, respectively. The nucleotide and amino acid sequences of the H chains suggest that the three anti-3-FL antibodies are encoded by the VH441 gene segment of the X24 VH family, and this conclusion was supported by Southern filter hybridization with VH441 and JH3-JH4 probes. PMN29 has at least 11 amino acid substitutions, which is an unusually large amount of somatic mutation for an IgM antibody. Previous analyses of BALB/c genomic libraries with VHX24 and VH441 probes make it unlikely that this VH family contains additional germ-line genes, but this possibility cannot be excluded. All three antibodies use the DQ52 and JH4 gene segments. The single VH and VL gene segments used to encode the anti-3-FL antibodies is in contrast to the multiple VH and VL segments used by antibodies against other carbohydrate Ag such as alpha 1-6 dextran and group A streptococcal carbohydrate. VH441 also encodes the VH regions of antibodies against galactan and levan (beta 2-6 fructosan). The similarities among VH segments of antibodies against 3-FL, levan, and galactan, and the striking differences in their CDR3 sequences, suggest that CDR3 plays an important role in the formation of the Ag binding site. The use of a single VH segment from the smallest VH gene family by antibodies against at least three different carbohydrate determinants is noteworthy. It raises the possibility that the amino acid sequence encoded by VH441 has some general structural features that make it particularly well adapted for binding to carbohydrate sequences.     

Characterization of a novel H2A(-)E+ transgenic model susceptible to heterologous but not self thyroglobulin in autoimmune thyroiditis: thyroiditis transfer with Vbeta8+ T cells.

Recently we reported on a novel H2E transgenic, IA-negative model of experimental autoimmune thyroiditis (EAT) that excludes reactivity to self in its susceptibility pattern to heterologous thyroglobulin (Tg). In conventional, susceptible mouse strains, EAT is inducible with both homologous and heterologous Tg; e.g., human (h)Tg shares conserved thyroiditogenic epitopes with mouse (m)Tg. However, when an H2Ea(k) transgene is introduced into class II-negative B10.Ab(0) mice, which express neither surface IA (mutant Abeta-chain) nor surface IE (nonfunctional Ea gene), the resultant H2E(b) molecules are permissive for EAT induction by hTg, but not self mTg. Also, the hTg-primed cells do not cross-react with mTg. To explore this unique capacity of E+B10.Ab(0) mice to distinguish self from nonself Tg, we have developed T cell lines to examine the T cell receptor repertoire and observed a consistent Vbeta8+ component after repeated hTg stimulation. Enrichment and activation of Vbeta8+ T cells by either superantigen staphylococcal entertoxin B or anti-Vbeta8 in vitro enabled thyroiditis transfer to untreated A-E+ recipients, similar to hTg activation. Vbeta8+ T cells isolated by FACS from hTg-immunized mice also proliferated to hTg in vitro. These studies support the contribution of Vbeta8 genes to the pathogenicity of hTg in this H2A-E+ transgenic model.     

Two induced anti-Z-DNA monoclonal antibodies use VH gene segments related to those of anti-DNA autoantibodies

The cDNA for H and L chain V regions of two anti-Z-DNA mAb, Z22 and Z44, were cloned and sequenced. These are the first experimentally induced anti-nucleic acid antibody sequences available for comparison with autoantibody sequences. Z22 and Z44 are IgG2b and IgG2a antibodies from C57BL/6 mice. They recognize different facets of the Z-DNA structure. They both use VH10 family genes and share 95% sequence base sequence identity in the VH and leader sequences; however, they differ in the 5'-untranslated region of the VH mRNA, indicating they arise from different germline genes. Both use JH4 segments. They differ from each other very extensively in the CDR3 of both H and L chains. The most closely related H chains in the current GenBank/EMBL data base are two mouse IgG anti-DNA autoantibodies, one from an MRL-lpr/lpr mouse (MRL-DNA4) and one from an NZB/NZW mouse (BV04-01). Z22 and Z44 share 95% sequence identity with these antibodies in the VH segment. In addition, Z22 is identical to MRL-DNA4 at 91% of the positions in the 5'-untranslated region of the H chain mRNA. The two antibodies share 95% base sequence identity in the V kappa segment. The most closely related L chains, with 97 to 98% sequence identity, are the V kappa 10b germline gene for Z22 and the V kappa 10a germ line gene, which is associated with A/J anti-arsonate antibodies and BALB/c anti-ABO blood group substance antibodies, for Z44. Z22 and Z44 share several structural features (similarities in VH, JH, and V kappa) but differ very markedly in the L chain CDR1 and both H and L chain CDR3 sequences; these regions may determine the differences in their specific interactions with Z-DNA.     

Two families of monoclonal antibodies to alpha(1----6)dextran, VH19.1.2 and VH9.14.7, show distinct patterns of J kappa and JH minigene usage and amino acid substitutions in CDR3.

Nine groove-type mAb to alpha(1----6)dextran were cloned and sequenced. Together with previous reports from this laboratory, the VH and VL of 34 mAb have been sequenced, in which 10 VH19.1.2 and 11 VH9.14.7 combined with the V kappa-Ox1 gene to form two major families of anti-alpha(1----6)dextrans. The same D minigene (DFL16) was used by all VH19.1.2 and VH9.14.7 mAb; however, the patterns of JH and J kappa usage are quite different. VH19.1.2 mAb used only JH3 and J kappa 2, whereas VH9.14.7 mAb used three JH (JH1, JH2, and JH3) and all four active J kappa (J kappa 1, J kappa 2, J kappa 4, and J kappa 5). Relative uniformity in the lengths of VH CDR3 and the junctional sequences is seen in both families. Some mAb from different mouse strains share common structural features. The differences in idiotypic specificities and in the amino acid sequences suggest that VH19.1.2 and VH9.14.7 may differ in the conformation of CDR1 and CDR2. Combining with V kappa-Ox1 gene to generate groove-type combining sites to the single site-filling epitope of alpha(1----6)dextran, the two VH chains may require certain conformations of CDR3. Whether such conformational requirements influence the choice of J minigenes, the selection of the length of VH CDR3 and the sequences at junctions, are discussed.     

Germline V genes encode viable motheaten mouse autoantibodies against thymocytes and red blood cells

Autoantibodies against thymocytes and RBC may contribute to the pathophysiology of homozygous viable motheaten (mev) autoimmune disease. Whether the production of these autoantibodies in mev mouse results from polyclonal nonspecific B cell activation or specific Ag-driven stimulation is not known. To understand the mechanisms involved in the induction of antithymocyte autoantibody response in mev mouse, we have studied the fine antigenic specificity, structure, and origin of three antithymocyte autoantibodies derived from mev splenic B cell hybridomas. Western blot analysis showed that these mAb bind to polypeptides of 33 and 105 kDa present in RBC and thymocytes, respectively. Additional specificities for the epitopes present in other polypeptides distinguished these three autoantibodies. Northern hybridization and flow microfluorimetry analysis indicated that these hybridomas are derived from the Ly1+ B cell subset. These autoreactive Ly-1 B cell hybridomas, chosen on the basis of their specificity, expressed L chain V genes from a single VK family (VK9) and VH genes from J606 and S107 families. Hybridomas UN34.11 and UN42.5 expressed the VK9 gene identical to that used by peritoneal Ly1+ B cells from various mouse strains and malignant B lymphoma cells secreting anti-mouse RBC treated with proteolytic enzyme bromelin and anti-SRBC antibodies. The third hybridoma, S2-14.2, used a VK9 gene identical to that expressed by MOPC41. None of the VK genes encoding these autoantibodies showed any somatic mutations. In the case of VH genes, the two hybridomas UN42.5 and S2-14.2 derived from two separate fusions, used identical VH genes from the J606 family. The third hybridoma UN34.11 used unmutated V11 germline VH gene, a member of the S107 family. Southern hybridizations, using oligonucleotide probes specific for CDR1 and CDR2, showed that the VH genes encoding the J606 autoantibodies were derived from a germline gene found in the 6.7-kb fragment of EcoRI-digested germline DNA. This germline VH gene is distinct from VH22.1 germline gene that codes for antigalactan antibodies. Sequence analysis of this gene showed perfect homology with the rearranged VH genes confirming the lack of somatic mutations. Thus, our data demonstrate that antithymocyte antibody response occurring in mev mouse is polyclonal and it involves Ly-1 B cells expressing unmutated germline VH and VK genes. These results indicate that antigen driven stimulation may not play an important role in the induction of anti-thymocyte antibody response in mev mouse.     

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.     

V kappa gene usage, idiotype expression, and antigen binding among clones expressing the VHX24 gene family derived from naive and anti-idiotype immune BALB/c mice

The BALB/c myeloma protein ABPC48 binds beta(2-6)-linked fructosans and expresses genes derived from the VHX24 and V kappa 10 gene families. We have selected 30 hybridomas expressing the VHX24 gene family derived from mitogen-stimulated spleen cells of naive BALB/c mice and mice injected at birth with the syngeneic monoclonal anti-ABPC48Id, IDA10. The majority of mAb with kappa L chains uses V kappa 1. Antibodies reacting with IDA10 use both V kappa 10 and V kappa 1. Most of these VHX24+ mAb reacted with one or more members of a limited panel of predominantly polysaccharide Ag that have been previously observed to interact with antibodies expressing the VHX24 gene family. Nucleotide sequencing of selected VH and V kappa genes shows a very low frequency of somatic mutation. The effect of neonatal anti-Id injection on VHX24-V kappa pairing and Id expression is discussed.     

Heavy chain variable region gene families evolved early in phylogeny. Ig complexity in fish

The V regions of channel catfish H chain cDNA clones have been analyzed. Based upon sequence relationships and hybridization analyses, five different groups of VH genes are identified whose definition is consistent with that of five different VH families. Genomic Southern blots indicate that as many as 100 different germ-line VH genes are likely represented by these families. The sequence diversity between identified members of these different families is similar in magnitude to the divergence represented between members of different human or mouse VH families. The FR regions are the most conserved regions when members of different catfish VH families are compared; specific amino acid positions appear to be highly conserved in phylogeny. Equally important is that diversity is represented in complementarity-determining regions CDR1 and CDR2 in members of the different families as well as in members of the same VH family. These results suggest that an extensive repertoire of VH genes can contribute to antibody diversity in this lower vertebrate. Sequence comparisons indicate that one of the catfish VH families shares considerable structural similarity to several higher vertebrate VH gene families--a relationship which suggests that this VH family may be ancestral to some VH gene families of higher vertebrates. Characteristic of the genomic organization of higher vertebrate H chains, catfish appear to have different VH families wherein a VH gene likely undergoes functional recombination with putative DH gene segments and one of apparently several different JH segments. The recombined V region is expressed with the same C region gene. These combined results suggest that bony fishes are the earliest known phylogenetic representatives to have evolved extensive V region gene families.     

Patterns of Ig V region expression among neonatal hemagglutinin-responsive B cells. Evidence for non-random VH gene representation during later stages of development

Hybridoma libraries were established whose specificities reflect those within the BALB/c hemagglutinin-responsive B cell repertoire at 1 or 2 wk of age. These libraries were generated through chronic immunization regimes that induce responses dominated by clonotypes available at the age of initial immunization. Dot blot analyses of cytoplasmic RNA from these hybridomas were performed to determine the Ig H chain V region (VH) families associated with the repertoire at each age. Although genes from most known VH families can generate hemagglutinin-specific antibodies, clonotypes prevalent during the first week of life disproportionately use VH7183 gene segments. In contrast, hybridomas representative of the repertoire in 2-wk-old individuals preferentially use VHS107, VH36-60, and VHX24 gene segments. These results demonstrate changes in VH gene family predominance that correlate with the age-related patterns of clonal emergence and turnover previously shown in the hemagglutinin-reactive B cell pool. Taken together, these findings suggest that the very early neonatal Ag-responsive B cell pool closely reflects preferential VH gene rearrangements within the pre-B cell compartment. Further, they suggest that either non-random strategies of VH gene expression, or selective clonal expansion strategies based on VH, operate even at later stages of development.     

Many variable region genes are utilized in the antibody response of BALB/c mice to the influenza virus A/PR/8/34 hemagglutinin

We have examined how many different H chain variable (VH) and kappa-chain variable (Vk) germ-line genes are used in the antibody response to the influenza virus A/PR/8/34 hemagglutinin (PR8 HA), and have assessed how the expression of individual VH and/or Vk genes contributes to the generation of specificity for the HA. A panel of 51 hybridoma antibodies that recognize two antigenic regions on the HA were compared for the sequence of their Ig H and L chain V regions. The hybridomas were obtained from 28 individual BALB/c mice that had been immunized with PR8 under a variety of primary and secondary response immunization protocols. The degree and pattern of sequence similarity suggests that 29 different VH genes drawn from seven different VH gene families, and 25 different Vk genes drawn from 12 different Vk gene families were used in this panel. Based on current estimates of the total numbers of VH and Vk genes in the mouse, this suggests that between 2.5 and 10% of the entire VH and Vk germ-line repertoires were used by these hybridomas. Despite this extensive diversity, some V genes were repetitively identified among these hybridomas, and were most often expressed in the context of specific VH/Vk combinations. Because antibodies that used identical VH/Vk combinations also usually displayed similar reactivity patterns with a panel of mutant viruses, this indicates that VH/Vk pairing can be important in establishing the specificity of antibodies for the HA.     

Gonococcal outer-membrane protein PIB: comparative sequence analysis and localization of epitopes which are recognized by type-specific and cross-reacting monoclonal antibodies.

Comparison of the inferred amino acid sequence of outer-membrane protein PIB from gonococcal strain P9 with those from other serovars reveals that sequence variations occur in two discrete regions of the molecule centred on residues 196 (Var1) and 237 (Var2). A series of peptides spanning the amino acid sequence of the protein were synthesized on solid-phase supports and reacted with a panel of monoclonal antibodies (mAbs) which recognize either type-specific or conserved antigenic determinants on PIB. Four type-specific mAbs reacted with overlapping peptides in Var1 between residues 192-198. Analysis of the effect of amino acid substitutions revealed that the mAb specificity is generated by differences in the effect of single amino acid changes on mAb binding, so that antigenic differences between strains are revealed by different patterns of reactivity within a panel of antibodies. The variable epitopes in Var1 recognized by the type-specific mAbs lie in a hydrophilic region of the protein exposed on the gonococcal surface, and are accessible to complement-mediated bactericidal lysis. In contrast, the epitope recognized by mAb SM198 is highly conserved but is not exposed in the native protein and the antibody is non-bactericidal. However, the conserved epitope recognized by mAb SM24 is centred on residues 198-199, close to Var1 , and is exposed for bactericidal killing.     

Specific VDJ gene combinations contribute to the specificity of memory antibodies to the phosphorylcholine hapten.

Based on their fine specificity, two groups of antibodies against the phosphorylcholine (PC) hapten have been described. Group I antibodies react predominantly with the PC moiety of the hapten and group II are directed against the entire hapten including the azophenyl spacer to the protein carrier. We have analyzed the VH gene segment utilization of hybridomas from the memory response to PC by Southern blot analysis and nucleotide sequencing of the functional VDJ rearrangements. Three main specificities of anti-PC antibodies could be distinguished. Anti-PC hybridomas with group I fine specificity utilize the VH1-DFL 16.1-JH1 rearrangement. A major portion of group II antibodies recognized the phenyl-PC part and expressed the same VH1 gene in combination with a member of the SP2 family and JH1 or JH2. The other anti-PC antibodies either used the PJ14-DFL16-JH3 rearrangement in combination with a lambda 1 L chain or a member of the VGam3.8 VH family rearranged to the DFL16.1 and the JH3 gene segments. The PJ14 and VGam3.8 V gene expressing antibodies were directed to the phenyl group and were either not or barely inhibitable by PC chloride. Thus, specific VDJ gene combinations contribute to the fine specificity of antibodies in the memory response to the PC hapten. The use of the S107, Q52, and VGam3.8. VH gene families, together with FL16.1 or SP2 D segments and JH1, JH2, or JH3 results in different fine specificities to the PC, phenyl-PC, or the azophenyl moiety of the PC hapten. These fine specificities of the memory response use V, D, and J segments of the initial T15Id+ response in combination with gene segments usually related to phenyl specificity.     

Cloning and sequence analysis of the VH and VL regions of an anti-myelin/DNA antibody from a patient with peripheral neuropathy and chronic lymphocytic leukemia

We have cloned and determined the nucleotide sequence of the Ig VH and VL region genes of an IgM kappa mAb that binds to denatured DNA and myelin from a patient (POP) with chronic lymphocytic leukemia and peripheral neuropathy. Sequence analysis indicates that the V region of the kappa L chain gene (PopVK) has 99% homology to a V kappa IIIa germ-line gene and the V region of the mu H chain gene (PopVH) has 96% homology to the VH26 germ-line gene that is a member of the VH3 gene family. It is likely the V kappa and VH genes arose from these respective germ-line genes via somatic mutation or from closely related genes. V kappa III genes have frequently been used by other IgMk mAb especially those with rheumatoid factor activity, and the VH26 gene with no somatic mutation has been used by several anti-DNA antibodies, suggesting the possibility of preferential association of these or related germ-line genes with autoantibodies. The minor differences between the sequences of POP's VH and V kappa genes and sequences used by other autoantibodies, may be responsible for this antibody's crossreactivity with myelin and, as a result, the autoimmune neuropathy.     

Natural auto- and polyreactive antibodies differing from antigen-induced antibodies in the H chain CDR3

We describe three sets of natural (preimmune) polyreactive antibodies and Ag-induced antibodies that share the same VH-VL combinations. The amino acid homology in the VH and VL segments averaged 92%. These sets were found among 49 neonatal and adult natural mAb that were compared with 35 Ag-induced monoclonals produced during the memory response to phosphocholine (PC)-keyhole limpet hemocyanin. Both groups of monoclonals had been selected on the basis of a restricted fine specificity pattern, namely the ability to recognize PC-protein and p-nitrophenyl phosphocholine but not PC. All of the antibodies were tested for reactivity against a panel of 15 self and foreign Ag. Despite their common fine specificity as the basis for selection, 33/49 natural antibodies were poly/auto reactive whereas 0/35 Ag-induced antibodies had such poly/auto reactive properties. The natural antibodies were encoded by genes representing nine different VH families and several V kappa and V lambda families. There were a few replacement substitutions distinguishing the Ag-induced antibodies from the natural antibodies in each set; however, the most noteworthy difference was the extreme variability of CDR3 in the natural antibodies that differed in both length and amino acid sequence from each other and from Ag-induced antibodies. The results suggest that CDR3 of the H chain may play a critical role in distinguishing poly- from monospecific combining sites in natural and Ag-induced antibodies.     

A cross-reactive idiotype on anti-DNA antibodies defines a H chain determinant present almost exclusively on IgG antibodies

We have previously reported two anti-idiotypic antibodies, 3I and 8.12, that recognize L chain determinants on anti-DNA antibodies. We have generated a new anti-idiotypic antibody, F4, that recognizes a H chain determinant on cationic anti-DNA antibodies. F4 reactivity is present in high titer in serum of approximately 60% of SLE patients and on 84 of 706 myeloma proteins. It is preferentially associated with 3I reactive L chains. Furthermore, antibodies bearing both the F4 and 3I idiotypic determinants preferentially bind DNA. Amino acid sequencing of H chains isolated from four F4-reactive myeloma proteins suggests that they derive from two currently identified VH gene families. F4 reactivity is restricted almost exclusively to Ig of the IgG isotype suggesting that F4 may recognize either a somatically mutated hypervariable region or a variable region used late in the immune response. F4, therefore, represents a new idiotypic family preferentially associated with auto-Ag specificity and having features of an Ag-driven immune response.     

Immunosuppressive anti-immunoglobulin autoantibodies: specificity, gene structure and function in health and disease.

Anti-immunoglobulin autoantibodies (anti-Ig auto-Abs) are part of the physiological immune repertoire. Herein we focus on Abs directed against the F(ab')2 region of the Ig molecule. The vast majority of previously described anti-F(ab')2 auto-Abs were antiidiotypes. The antibodies we studied recognize epitopes located in the hinge region of IgG and in other conserved domains of F(ab')2. Gene structure analyses revealed germline gene identity of VL chains and 88% homology with the closest germline gene of VH chains. We present evidence for a B cell suppressive role of anti-Ig Abs and discuss the mechanism of suppression. Moreover, the role of anti-Ig auto-Abs in immunoregulation as well as in the pathogenesis of autoimmune and other diseases is discussed. There is substantial evidence indicating that anti-Ig auto-Abs are important immunoregulatory molecules.