Shared idiotope on monoclonal anti-Ia.7 antibodies reactive with determinants in a structural domain of the I-E molecules

In previous studies, heterologous anti-idiotypic (anti-Id) antisera against the C3H.SW 14-4-4S or the A.TH 41.A anti-Ia.7 monoclonal antibodies (mAb) were shown to identify an interstrain cross-reactive idiotypic specificity (IdX.Ia.7) expressed on monoclonal or conventional anti-Ia.7 alloantibodies. The objective of the present investigation was to characterize further this IdX at the idiotopic level. To this end, 11 hybridomas producing IgG1, IgG2a, or IgM anti-Id mAb were derived from a rat immunized with a mixture of 10 A.TH or A.BY anti-Ia.7 mAb. The specificity of the latter anti-Id mAb was determined by direct Id binding radioimmunoassay (RIA) with the use of a panel of 52 anti-Ia mAb derived from hybridomas produced in various inbred mouse strains. These rat anti-Id mAb recognized idiotopes expressed on i) all anti-Ia.7 mAb against determinants in the topographic domain I of the I-Ek molecule but not on 18 other anti-I-Ek mAb directed at epitopes in domains II or III; ii) three of 19 anti-I-Ak mAb; and iii) one A.TL-derived anti-I-As mAb. Competitive Id binding assays revealed that among the 14 IdX+ anti-Ia.7 mAb, one (81.B) was bound to a lesser extent by various rat anti-Id mAb, suggesting that heterogeneity probably exists in this antibody family. By contrast, two isologous (B10.S(7R)) anti-Id mAb to the IdX.Ia.7+ mAb 41.A displayed a specificity restricted to 41.A individual idiotopes (IdI). Rat anti-IdX.Ia.7 and mouse anti-41.A IdI mAb inhibited the binding of 125I-labeled mAb 41.A to CBA spleen cells. These two sets of mAb bound in a noncompetitive fashion to mAb 41.A-coated plates, indicating that their corresponding public or private idiotopes were spatially distinct. These data may have implications for in vivo manipulations of anti-Ia immune responses.     

Preferential expression of VK21E light chains on IdX Ia.7 positive monoclonal anti-I-E antibodies

We previously characterized major (IdX Ia.7) and minor (IdI) idiotopes in a collection of monoclonal alloantibodies reactive with monomorphic (i.e., Ia.7-like) determinants in the structural domain I of the murine class II I-E molecules. In this report, preliminary structural characterization of this antibody family is presented. First, the contribution of isolated H and L chains of the anti-Ia.7 cluster I mAb 41.A to IdX Ia.7 and IdI 41.A idiotope expression was evaluated by testing the capacity of these chains, either isolated or reassociated in homologous or heterologous hybrid Ig, to inhibit the binding of rat or mouse anti-idiotope mAb to IdX Ia.7+ mAb coated plates. It was found that the IdI 41.A idiotope defined by the mouse anti-idiotopic mAb H90-21.1 required the presence of both 41.A H and L chains for complete expression, while the rat mAb-defined IdX Ia.7 idiotope could be detected on isolated and on reassociated 41.A L chain. To evaluate further the structural correlates of the IdX Ia.7 idiotope, H, L, or both H and L chains of 5 A.BY, 4 A.TH and 1 C3H.SW IdX+ anti-Ia.7 mAb, as well as that of 3 A.TH IdX- anti-I-E or anti-I-A and -I-E mAb were subjected to NH2-terminal amino acid sequencing. These analyses demonstrated a) that different H chains corresponding to different subgroups (at least to the VHII and VHIII) could be expressed without apparent modification of IdX Ia.7 idiotope expression and b) that 9 of 11 IdX+ anti-Ia.7 mAb utilized highly homologous L chains of the VK21E subgroup. The relevance of these findings to the genetic control of the idiotypic markers identified in the Ia.7 system is discussed.     

Structural characterization of a cross-reactive idiotype shared by monoclonal antibodies specific for the human CD4 molecule.

A panel of mouse monoclonal anti-CD4 antibodies was characterized in terms of idiotypic expression by using specific anti-idiotypic antibody (anti-Id) reagents generated in rabbits immunized with anti-Leu3a, a monoclonal anti-CD4 which inhibits the human immunodeficiency virus (HIV) gp120 binding to CD4. Direct binding and competitive inhibition assays demonstrate that the majority of monoclonal anti-CD4 antibodies able to recognize CD4 epitopes overlapping the epitope recognized by anti-Leu3a expressed an antigen-combining site-related cross-reactive idiotype (IdX). Western blot analysis was used to demonstrate that this IdX is associated primarily with the light (L) chain of the monoclonal anti-CD4 antibodies. To further characterize the structural basis of the IdX, the nucleotide sequence of the variable region of the L kappa chain of anti-Leu3a was determined. Peptides corresponding to the first, second, and third complementarity determining regions (CDRs) of the L chain of anti-Leu3a were synthesized and used to immunize rabbits. All anti-peptide antisera recognized the immunizing peptide, the cognate anti-Leu3a molecule, and several other monoclonal anti-CD4 antibodies by direct binding assays. Western blot analysis utilizing the anti-CDR peptide reagents demonstrates that the reactivity to the monoclonal anti-CD4 antibodies was L chain-specific. The anti-Id generated by immunizing with the intact anti-Leu3a molecule failed to recognize the three L chain-derived CDR synthetic peptides, suggesting that the IdX requires the presence of the three-dimensional configuration of the L chain for its expression. The broad range of reactivity exhibited by the antipeptide antisera indicates that the majority of mouse monoclonal anti-CD4 antibodies characterized in this study utilize L chains encoded by a single germ line variable (V) region kappa (V kappa) chain gene or by V kappa genes that belong to the same gene family.     

Idiotope structure and genetic diversity in anti-streptococcal group A carbohydrate antibodies

Three cross-reactive idiotopes(Id), termed IdX, IdI-1, and Id5, that are present on free L chains from murine anti-group A streptococcal carbohydrate antibodies have been mapped; these Id distinguish between products of three homologous V kappa genes. For each determinant, sequence analysis of anti-streptococcal group A carbohydrate antibody V domains yielded small numbers of amino acids invariably associated with Id expression. Flow micro-fluorimetry was used to isolate three IdI-1- spontaneous mutants of the IdI-1+ hybridoma GAC 39; all had single amino acid changes in the L chain at position 60 and 77, all retained other Id, and all bound group A carbohydrate. Computer modeling was used to examine spatial relationships between Id. A number of the conserved Id5 and IdX residues cluster in the L chain framework region 1 around the first back loop connecting strands of the beta pleated sheets, and overlap at residue 15 (Id5, proline; IdX, leucine). This overlap accords with the mutually exclusive expression of Id5 and IdX. The IdI-1 loss variants have mutations of residues 60 or 77 on adjacent back loops, approximately 7.5 and 14 A from residue 15. Competitive inhibition of anti-IdX and anti-IdI-1 binding to antibodies expressing both Id can be attributed to steric hindrance. The framework back loops may be favored sites for cross-reactive Id expressed by products of a single V region gene. IdI-3a, an individual Id not associated with use of a particular gene segment, has been localized in part to residue 31 (hypervariable region 1) of the H chain.     

An idiotype shared by monoclonal antibodies to different peptides of human myelin basic protein.

A mAb of the IgG1/kappa isotype was raised against human myelin basic protein (MBP) peptide acetyl 1-9. This mAb, termed F23, reacted with human MBP and human MBP peptides acetyl 1-9, 1-14, and 1-44, but not with MBP peptides 10-19, 80-89, or 45-89. According to the guidelines of the molecular recognition theory, a complementary peptide to human MBP peptide 1-9 was synthesized and used to raise murine mAb with anti-Id activity. Two mAb anti-Id, F25F7 and F25C8, both of the IgM/kappa isotype, were selected for further study. These anti-Id reacted with F23, the mAb for which they were selected, and also reacted with another mAb, which was of the IgG1/kappa isotype and was raised to human MBP peptide 80-89. There was no reaction with another control mAb of the IgG1/kappa isotype or murine myeloma IgG1. By immunoblotting techniques, it was demonstrated that the Id on each of the mAbs to MBP peptides was located on the kappa L chain but also could be recognized in nonreduced IgG. The cross-reactive anti-Id suppressed antibody secretion of Id-producing hybridoma cells in an Id-specific manner, and kinetic studies suggest an intracellular mechanism for the suppression. These cross-reactive Id among antibodies to different MBP peptides imply that the same V region genes of kappa L chains are involved in the selection of antibodies to an autoantigen, like MBP, and may play a role in the modulation of immune responses against MBP in certain inflammatory demyelinating diseases.     

Anti-immunoglobulin antibodies. II. Expression of individual and cross-reactive idiotypes on syngeneic and homologous anti-idiotype antibodies

Syngeneic anti-(anti-Id) antibodies were prepared against BALB/c anti-A48Id antibodies, BALB/c anti-460Id monoclonal antibodies, and A/J anti-J558 IdI monoclonal antibodies. With these anti-(anti-Id) antibodies we identified cross-reactive idiotypes on syngeneic and homologous anti-A48Id and anti-460Id antibodies. By contrast, tbe idiotypic determinants of A/J anti-J558 IdI monoclonal antibodies were not shared by other syngeneic, homologous, or xenogenic anti-J558 IdI or IdX antibodies. These results suggest that idiotype-antiidiotype reactions that serve as regulatory controls within the immune system are characteristic for each particular antigen system, strain, or species and that such interactions make the system self-limited with respect to the whole antild repertoire.     

Monoclonal antibodies to streptococcal group A carbohydrate. II. The VK1GAC light chain is preferentially associated with serum IgG3

A kappa-light chain variable region (V kappa) dominantly employed in the serum antibody response of A/J mice to streptococcal group A carbohydrate (GAC) has been termed VK1GAC. Examination of in vitro recombinants between the isolated heavy and light chains of VK1GAC+ and VK1GAC-anti-GAC hybridomas and non-GAC-binding myeloma proteins indicated that two antisera (anti-Id5 and anti-Id20) recognized the VK1GAC light chain when it was free in solution or paired with several heterologous heavy chains. Screening of a panel of A/J anti-GAC monoclonal antibodies with these antisera showed almost complete concordance between Id5 and Id20 expression and the presence of VK1GAC light chain as detected by its unique isoelectric focusing spectrotype. These antisera were used to examine serum expression of the VK1GAC light chain in normal and hyperimmune serum of A/J mice. Normal A/J serum contained from 20 to 100 micrograms Id5/ml serum, whereas only 1 to 10 micrograms Id20/ml serum was detected. The levels of both VK1GAC idiotypes increased dramatically 10- to 20-fold after hyperimmunization of mice with group A vaccine. When serum IgG from normal and immune mice was fractionated into the IgG subclasses (IgG1, IgG2a, and IgG3), it was found that the VK1GAC light chain does not pair randomly with heavy chains of the IgG subclasses, but rather is associated preferentially with heavy chains of the IgG3 subclass whether or not it is associated with antibodies to GAC. These results suggest that the heavy chain pairing exhibited by this VK product may not be random.     

VH-related idiotopes detected by site-directed mutagenesis. A study induced by the failure to find CD4 anti-idiotypic antibodies mimicking the cellular receptor of HIV.

The function of the CD4 cell surface protein as coreceptor on T helper lymphocytes and as receptor for HIV makes this glycoprotein a prime target for an immune intervention with mAb. A detailed understanding of the structural determinants on the therapeutic CD4 mAb that are involved in Ag binding or are recognized by anti-idiotypic mAb (anti-Id) may be important for designing antibodies with optimal therapeutic efficacy. Seven anti-Id raised against the CD4 mAb M-T310 were selected from a large panel with the intention to obtain CD4 mimicking structures with specificity for HIV gp120. The selected anti-Id did not react with other CD4-specific mAb cross-blocking M-T310. Among these, mAb M-T404, although having the same L chain as M-T310 and a VH region sequence differing only at 14 amino acid positions, was not recognized by the anti-Id. M-T310 H chain complexed with the J558L L chain reacted with all anti-Id, thus demonstrating that the recognized idiotopes are located within the VH region. To identify the idiotopes of M-T310 seen by the anti-Id, variants of M-T404 containing one or more of the M-T310-derived substitutions were generated by oligonucleotide-directed mutagenesis. The reactivity pattern of the mutant proteins with the anti-Id demonstrated that the idiotopes reside within the complementarity determining region (CDR) 2 and CDR3 loops of the VH region. A major idiotope was defined by a single amino acid in CDR2 that was recognized by three anti-Id, whereas the four other anti-Id reacted with determinants of CDR3. Although the performed amino acid substitutions did influence the Id recognition, Ag binding was not significantly affected, suggesting that none of the anti-Id can be considered as a mimicry of the CD4 Ag.     

Neutralization of HIV-1 by anti-idiotypes to monoclonal anti-CD4. Potential for idiotype immunization against HIV.

Anti-idiotypic antibodies were raised in rabbits against a panel of 11 murine mAb directed to the human CD4 receptor. Selection of mAb for vaccination was based on inhibition studies demonstrating that these mAb recognized CD4/V1 epitopes implicated in HIV-1-gp120 binding. Purified antisera showed high titer anti-Id activity and reacted specifically with Ag-combining site-related Id of the mAb used for their generation. Anti-Id either detected a private Id of the immunizing mAb or displayed a partial cross-reactivity with Id of other mAb to CD4. Eight anti-Id to six different mAb were shown to recognize determinants of recombinant HIV-1-gp120 or of HIV-1-gp160 as shown by ELISA and radioimmunoprecipitation assay. These anti-Id were capable of inhibiting HIV infection up to 100% in a MT-4 cell assay in vitro. In addition to neutralizing infectivity of cell-free virus, anti-Id to two mAb--the mAb IOT4a and 7.3F11--were also shown to inhibit HIV-induced syncytia formation up to 100%. Anti-Id to the mAb IOT4a, 7.3F11, and to the mAb anti-Leu3a interfered with rgp120 binding to cellular CD4 as assessed by flow cytometry. These results demonstrated that mAb specific for both CDR2- and CDR3-like regions of CD4 were capable of inducing HIV-1-gp120 cross-reacting anti-Id neutralizing HIV-1 in vitro. These studies may have implications for the development of a gp120 internal image based vaccine against HIV.     

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.     

The assignment of chain specificities for anti-Ia monoclonal antibodies using L cell transfectants

The chain specificities of 18 Ak and 26 Ab-reactive anti-Ia monoclonal antibodies have been determined. L cells were transfected with haplotype-matched (A alpha k:A beta k, A alpha b:A beta k) or haplotype-mismatched (A alpha k:A beta b, A alpha b:A beta k) cDNA pairs, lines expressing high levels of surface A complex were selected, and antibody reactivity with a panel of reagents was assessed by cytofluorimetric analysis. Most of the antibodies recognized a determinant specified by one chain, either alpha or (more commonly) beta. A few examples of more complex determinants were also observed. A knowledge of the chain specificities of anti-Ia monoclonal antibodies should prove useful for a variety of studies aimed at dissecting Ia structure-function relationships.     

A pathogenic monoclonal antibody, G8, is characteristic of antierythrocyte autoantibodies from Coombs'-positive NZB mice.

With age, NZB mice develop anti-RBC autoantibodies resulting in the development of autoimmune hemolytic anemia. We now have evidence that this spontaneous autoantibody response consists of antibodies that are similar in specificity and Id expression to a pathogenic autoantibody (G8) that was cloned from an autoimmune NZB mouse. Similar to autoantibodies eluted from Coombs'-positive mouse E (MRBC), the G8 mAb recognizes native (unmodified) MRBC but not RBC from other species. Interestingly, G8 and four additional mAb bind with a higher titer to bromelain-treated MRBC than to native MRBC. Nucleotide sequence analysis reveals, however, that unlike "natural" antibodies that react solely with bromelain-MRBC, G8 is encoded by a J558 VH gene and a V kappa 12,13 L-chain gene. Thus G8 is clearly distinct from antibodies to bromelain-MRBC which are encoded by unrelated V genes. Instead, the sequence of the G8 VH chain was found to be nearly identical to that of an anti-DNA mAb derived from an MRL-lpr/lpr mouse. The results suggest Coombs'-positive autoantibodies from NZB mice are not derived from "natural" antibodies, but rather, consist of a restricted set of autoantibodies expressing the G8 IdX.     

Anti-idiotypic antibodies recognizing stable epitopes limit the emergence of idiotype variants in a murine B cell lymphoma.

The emergence of Id variants is a major escape mechanism from anti-Id therapy of human B cell malignancies and of the murine B cell lymphoma 38C13. To determine what impact the epitope specificity of anti-Id antibodies has on the prevention of emergence of such Id variants in the 38C13 lymphoma, anti-Id mAb of varying epitope specificity for the Id of 38C13 tumor cells were produced and studied. Some antibodies, produced by immunizing mice with both the wild-type 38C13 IgM and variant IgM, cross-reacted with wild-type 38C13 IgM and with all four members of a panel of variant IgM. These anti-Id did not react with separated 38C13 IgM H or L chains by Western blot, but did react with the cytoplasmic H chain of the surface Ig- variant cell line T2D that expresses the same H chain as wild-type 38C13 in its cytoplasm but does not express any associated L chain. In contrast, anti-Id of narrower specificity did not react with this H chain. This indicated that the broadly cross-reactive antibodies recognized a stable epitope on 38C13 H chain. When a broadly cross-reactive antibody MS11G6 was compared to S1C5, an antibody of narrower specificity, MS11G6, was superior at preventing tumor growth in mice inoculated with 38C13 cells. Moreover, no surface Ig+ variants emerged in escaping tumors in the MS11G6-treated group, whereas such variants were common in the S1C5 treated group. Both anti-Id were of equal efficacy in eliminating wild-type 38C13 cells by using 38C13 cells in tumor inoculums that had just been cloned in vitro, but MS11G6 was also capable of preventing the growth of several surface Ig+ variant cell lines in vivo. We conclude that anti-Id recognizing more stable Id determinants can limit the emergence of Id variants and therefore be more effective therapeutic agents. This finding is of additional importance as additional in vivo and immunophenotypic studies demonstrated that the generation of Id variants was an ongoing process both in cloned parental 38C13 cells and its variants.     

Idiotope mapping on the variable region of an antibody clonotype produced by normal (nonmalignant) human B cells

Human anti-N-acetyl-D-glucosamine (GlcNAc) antibodies were prepared by affinity chromatography from serum of a healthy donor (MSS). They were heterogeneous but contained a unique antibody clonotype (1A) representing 7% of all anti-GlcNAc antibodies. Out of a series of monoclonal anti-idiotopic antibodies (anti-Id mAb), we identified five antibodies that bound to clonotype 1A as shown by isoelectric focusing and Western blotting. Two of them were specific for clonotype 1A (10F59 and 13F15), thus indicating its clonal origin. However, three anti-Id mAb (16F433, 16F539, and 16F812) bound to various additional portions of anti-GlcNAc antibodies of donor MSS. With the exception of one mAb, all anti-Id mAb have very similar relative affinities to clonotype 1A, so results from competition experiments between the different antibodies and between each antibody and antigen should reveal spatial relationships between the corresponding Id and between each Id and the antigen-combining site. The results show a consistent topography of Id on the V-region of clonotype 1A. Id 59, 812, and 433 were found to be arranged in one cluster (cluster I), whereas Id 15 and 539 belonged to a second cluster (cluster II). Cluster I resides completely in the antigen-combining site, whereas only Id 15 of cluster II weakly overlaps with the binding site. Our study demonstrates an analysis of spatial relationships of Id expressed on a human antibody clonotype. To our knowledge, this is the first demonstration of Id mapping on antibodies produced by a normal (nonmalignant) B cell clone that should be accessible to regulatory signals. Such analysis may contribute to a more detailed characterization of anti-Id mAb, and may provide additional information for a better understanding of their immunoregulatory effects.     

Novel human light chain V kappa segment: serologic and structural analyses of the kappa III-like Bence Jones protein and IgG kappa light chain REE

Immunochemical and sequence analyses of kappa light chain REE (Bence Jones protein REE and the light chain isolated from IgG kappa myeloma protein REE) revealed antigenic and structural features not previously described for human kappa-chains. Although closely related to proteins of the V kappa III subgroup, light chain REE is readily distinguished from light chains classified serologically as members of the kappa IIIa or kappa IIIb sub-subgroups. Light chains REE (Bence Jones protein REE and light chain REE) are identical in sequence and differ from kappa III proteins by at least 10 uncommon amino acid substitutions in the first three framework regions. Further, kappa-chain REE is unique by virtue of a four-residue deletion in the third complementarity-determining region. The deletion encompasses the three carboxyl-terminal residues in the V kappa-encoded segment and the first residue at the site of V-J recombination. Urine specimens from patient REE also contained a light chain fragment that lacked the first (amino-terminal) 85 residues of the native light chain but otherwise was identical in sequence to the light chain REE. The extensive amino acid differences and unique length of the V kappa segment in light chain REE indicate that this kappa-chain is the product of an unusual V kappa III gene or, alternatively, represents a rarely expressed and novel human V kappa gene.     

Immune responses during human Schistosoma mansoni. XVII. Recognition by monoclonal anti-idiotypic antibodies of several idiotopes on a monoclonal anti-soluble schistosomal egg antigen antibody and anti-soluble schistosomal egg antigen antibodies from patients with different clinical forms of infection

A monoclonal human anti-soluble schistosomal egg Ag(SEA) antibody (E5) that stimulates anti-Id T cells and is idiotypically represented in pools of immunoaffinity-purified human anti-SEA antibodies from chronic, generally asymptomatic, intestinal (INT) patients (AM1 and AM5) was used to raise several monoclonal anti-Id: 1C2, 1C6, 4A8, 4F9, and 2A7. Cross-inhibition between these anti-Id identified distinct idiotopes on E5. Anti-SEA preparations from schistosomiasis patients (AM1, AM5, and others) were tested for their inhibition of the E5/monoclonal anti-Id reactions, in competitive ELISA. In either the E5/4A8 or E5/1C6 ELISA system, anti-SEA from INT (AM1 or AM5) or hepatointestinal (HI) (AM7) patients were able to inhibit these reactions. However, anti-SEA antibodies from acute (AM9) or hepatosplenic (HS) (AM3 or AM8) patients did not express Id that were inhibitory in these systems. These results suggest that a relatively high proportion of INT and HI anti-SEA antibodies express a dominant cross-reactive idiotope (CRI) recognized by 1C6/4A8. This CRI is also easily detected in plasmas from individual INT patients. Anti-Id 1C2 reacted strongly with an Id in AM1, AM5, or AM7, but one which also occurred, to a lesser extent, in AM3, AM8, and AM9. Monoclonal anti-Id 4F9 and 2A7 reacted weakly with idiotopes expressed by antibodies from all patients, regardless of the clinical form of their infection. These observations indicate that anti-SEA antibodies from INT and HI, but not acute or HS patients express dominant, CRI that are identified by 1C6, 4A8, or 1C2 and are also expressed on the INT-derived anti-SEA mAb E5.     

A conserved anti-DNA antibody idiotype associated with nephritis in murine and human systemic lupus erythematosus

In order to identify unique structural features of pathogenic autoantibodies to DNA in SLE, a murine anti-anti-DNA (anti-Id) mAb (mAb 1C7) was produced in response to immunization of lupus mice with a syngeneic anti-DNA mAb (mAb 3E10). Immunization of lupus mice with mAb 3E10 inhibited production of native anti-DNA antibodies, suppressed development of lupus kidney disease (nephritis), and induced production of anti-anti-DNA (anti-Id) antibodies. mAb 1C7 bound F(ab')2 fragments of mAb 3E10, and it bound other murine anti-DNA mAb, but not murine mAb or polyclonal serum antibodies unreactive with DNA. Moreover, binding of mAb 1C7 anti-Id to mAb 3E10 was inhibited by DNA, suggesting anti-Id binding within or near the binding site for DNA. Furthermore, mAb 1C7 bound serum IgG immunoglobulins from 9/12 patients with lupus nephritis and serum anti-DNA antibodies compared to only 3/12 SLE patients with comparable serum levels of anti-DNA antibodies, but without nephritis (p = 0.04), and only 1/53 SLE patients without serum anti-DNA antibodies, 0/49 patients with rheumatoid arthritis, and 1/47 healthy subjects (p less than 0.001). These results provide evidence that mAb 1C7 identifies a conserved Id associated with anti-DNA antibodies in murine and human SLE and may be useful as a structural probe to characterize pathogenic anti-DNA antibodies in SLE.     

A public idiotypic determinant is present on spontaneous cationic IgG antibodies to DNA from mice of unrelated lupus-prone strains

A monoclonal anti-idiotypic antibody (anti-Id) to a public idiotype (Id) present on spontaneous IgG antibodies to DNA from NZB/NZW F1 mice recognized similar determinants on polyclonal and monoclonal IgG anti-DNA antibodies from mice of the unrelated MRL/lpr and BXSB strains. Incubation of the anti-Id with four of five monoclonal Id in solid phase inhibited their ability to bind DNA; however, different Id+ antibodies recognized different epitopes within the DNA molecule. Therefore, the public Id was located close to the antigen-binding regions but did not comprise all of those regions. Analysis of multiple polyclonal and monoclonal antibodies to DNA showed the Id on all subclasses of IgG. However, antibodies bearing the Id carried a neutral or cationic charge (10 of 10 monoclonals with pI greater than 7 were Id+); the presence of the Id on anionic IgG (pI less than or equal to 7) was infrequent (one of 21 serums, one of eight monoclonal antibodies). Therefore, IgG autoantibodies to DNA are constructed from closely related public idiotypes in several mouse strains that spontaneously develop lupus, and that Id is restricted to antibodies with a pI of 7 or greater.     

Autoimmunity induced by HgCl2 in Brown-Norway rats. II. Monoclonal antibodies sharing specificities and idiotypes with mouse natural monoclonal antibodies

Spleen cells derived from BN rats receiving HgCl2 were fused with the nonsecreting rat myeloma cell line IR983F. We screened 59 supernatants from immunoglobulin-secreting hybrids for antibody activity against actin, tubulin, autologous and heterologous myosin, myoglobin, dsDNA, peroxidase, and the haptens TNP, NIP, NNP, and NBrP. Six monoclonal antibodies (mAb) were found to react with antigen(s) of the panel. At least three groups of antibody specificities were identified: clones reacting with TNP (1 IgM, 1 IgE); clones reacting with horseradish peroxidase (1 IgM); and clones possessing widespread reactivity for several antigens as found for mouse natural autoantibodies (2 IgM, 1 IgE). We also analyzed the idiotypic (Id) determinants of the 59 mAb by using anti-Id antibodies described elsewhere prepared in rabbits against the BALB/c D23 natural monoclonal autoantibody and recognizing a BALB/c recurrent Id (Id D23) of natural polyspecific autoantibodies. We found that all rat mAb that possessed widespread reactivities bore this Id. We performed similar studies in sera from normal and mercury-stimulated rats. The results indicate a role for HgCl2 in the stimulation of natural antibodies producing cells and the existence of interspecies cross-reactive Id among mouse and rat natural antibodies.     

Idiotypic and antiidiotypic T and B lymphocytes in myasthenia gravis.

The prevalence of Id and anti-Id T and B cells as measured by their reactivities with two human mAb, one antiacetylcholine receptor mAb and one anti-Id mAb, was studied in 38 patients with myasthenia gravis and in 27 healthy individuals. Id and anti-Id T cells were estimated by enumerating the numbers of cells secreting IFN-gamma in response to 10 pg/ml of the human mAb. T cell stimulation, measured as numbers of IFN-gamma-secreting cells that exceeded the mean + 2 SD of controls, was induced by the Id mAb in 78.9% of the patients and in 7.4% of the controls, whereas the anti-Id mAb-stimulated T cells in 55.3% of the patients and in 3.7% of the controls. The mean value of the Id and anti-Id-reactive T cells in the patients was 18.3/10(5) and 10.1/10(5) PBMC, respectively. B cells secreting IgM antibodies binding to the human mAb were increased in patients with myasthenia gravis compared to healthy controls. Seventy-five percent of the patients and 12% of the controls had B cells secreting IgM antibodies binding to the Id mAb, although 89% of the patients and 16% of the controls had B cells secreting IgM antibodies binding to the anti-Id mAb. The mean value of B cells secreting IgM antibodies binding to Id or anti-Id mAb in the patients were 7.4 cells/10(6) and 5.5 cells/10(6) PBMC, respectively. We conclude that Id and anti-Id T and B cells are present in myasthenia gravis. These methods allow a quantitative estimation of T and B cells with defined specificities and thus a way of mapping the repertoire of lymphocytes.