Interaction of IgG3 anti-streptococcal group A carbohydrate (GAC) antibody with streptococcal group A vaccine: enhancing and inhibiting effects of anti-GAC, anti-isotypic, and anti-idiotypic antibodies

Enhancement of binding of one monoclonal antibody to an antigen in the presence of a second monoclonal antibody (specific for an independent epitope on the same antigen) has been observed for several antigen-antibody systems involving primarily protein, or glycoprotein, antigens. We have analyzed the interaction between radiolabeled IgG3 kappa anti-streptococcal group A carbohydrate (GAC) antibody (125I-HGAC 39) and streptococcal group A vaccine (GAV; traditionally used to elicit anti-GAC antibody) in the absence and presence of unlabeled anti-GAC antibodies, anti-isotypic antibodies, or anti-idiotypic antibodies, respectively. A variety of significant enhancing or inhibiting effects on the binding of 125I-HGAC 39 to solid-phase GAV (GAVsp) were noted. First, high concentrations of IgG3 anti-GAC antibodies specifically inhibit binding of 125I-HGAC 39 to GAVsp, but the presence of lower concentrations of IgG3 anti-GAC antibodies is associated with markedly increased (up to 300 to 400%) binding of 125I-HGAC 39 to GAVsp. In contrast, with the concentrations used, IgM anti-GAC antibodies only inhibit binding of 125I-HGAC 39 to GAVsp. A monoclonal anti-gamma 3 antibody (2E.6) also enhances binding (up to 700%) of 125I-HGAC 39 to GAVsp, whereas another high-affinity anti-isotypic antibody, anti-C kappa (187.1), only inhibits binding of 125I-HGAC 39 to GAVsp. In a similar manner, an antiidiotypic antibody (anti-IdX) specific for a framework idiotope located near the C kappa domain inhibits the interaction between 125I-HGAC 39 and GAVsp. Evidence is presented to suggest that neither anti-C kappa nor anti-IdX blocks the HGAC 39 paratope, and therefore, the inhibition of binding mediated by these antibodies must be on some other basis. An alternative explanation for this effect, on the basis of the impairment of functional bivalency of 125I-HGAC 39, is discussed. Finally, anti-idiotypic antibodies (anti-IdI-3a and anti-IdI-1) that bind closer to the antigen-binding site of HGAC 39 inhibit binding of 125I-HGAC 39 to GAVsp in a manner that is most readily interpreted as competition for the GAC-binding site (or nearby sites) on the HGAC 39 variable domain. These effects are shown to require specific immunologic recognition of either GAVsp or 125I-HGAC 39.     

Serologic and topographic characterization of idiotopes on murine monoclonal anti-streptococcal group A carbohydrate antibodies

We have employed five spectrotypically distinct monoclonal anti-variable region antibodies in the definition and characterization of a set of idiotopes expressed on murine monoclonal antibodies specific for streptococcal group A carbohydrate (GAC). By evaluating which of a panel of monoclonal anti-GAC antibodies were bound by the various anti-idiotopes, we observed four distinct reactivity profiles for the five anti-idiotopes ranging from highly restricted (binding of the homologous anti-GAC monoclonal antibody only) to broadly cross-reactive (binding of 18 of the 38 IgG3 anti-GAC antibodies). With N-acetyl-D-glucosamine and soluble GAC used as haptens, this spectrum of reactivity profiles was paralleled by a gradient of susceptibility to hapten inhibition of anti-idiotope binding to idiotope. The degree of cross-reactivity exhibited by a given anti-idiotope was found to be inversely related to its susceptibility to hapten inhibition. The topographic relationships among the idiotopes, defined by the results of competitive binding assays, were suggestive of a linear idiotope map spanning the variable region from the antigen-binding site to the vicinity of the constant region. Additional data from competitive inhibition assays with isolated and recombined H and L chains from a prototype monoclonal anti-GAC antibody (HGAC 39), and from isoelectric focusing of whole or reduced and alkylated HGAC 39, suggested that one of the idiotopes was located, at least primarily, on the VL domain.     

Protection of mice against Clostridium chauvoei infection by anti-idiotype antibody to a monoclonal antibody to flagella

Abstract Polyclonal rabbit anti-idiotypic antibody (anti-Id) against the protective monoclonal antibody specific to the flagella of Clostridium chauvoei was produced, purified, and characterized. Anti-Id inhibited the binding of its related monoclonal antibody to the flagellar antigen, suggesting that the anti-Id bore an internal image of the flagellar antigen. When mice were immunized with anti-Id intraperitoneally, the survival rate increased significantly, compared with mice immunized with normal rabbit IgG ( P < 0.01), and specific anti-flagellar antibodies were induced.     

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.     

A human monoclonal IgG1 with anti-idiotypic activity against anti-human thyroglobulin autoantibody

Sixty-one human myeloma proteins (HMP) from patients with multiple myeloma and Waldenstr?m macroglobulinemia were tested for anti-idiotypic (Id) activity against autoantibodies to double-stranded DNA, small nuclear ribonucleoproteins, and human thyroglobulin (HTg), by competitive radioimmunoassays and enzyme immunoassays. An IgG1, lambda HMP from patient BEN with anti-Id activity against antibodies to HTg is reported. IgG1 BEN was not directed toward human Fc fragments and its activity was not related to allotypic determinants. IgG1 BEN molecules recognized Id determinants (idiotopes) on F(ab')2 anti-HTg fragments, but not idiotopes of F(ab')2 fragments of antibodies of other specificities. This observation supports the general significance of Id network interactions in regulation and diversification of immune responses in man.     

Anti-angiotensin II anti-idiotypic antibodies bind to angiotensin II receptor

An anti-idiotypic serum from a rabbit immunized with one anti-angiotensin II (AII) monoclonal antibody (A25) was shown to identify a cross-reactive idiotope (CRI) shared by six anti-AII monoclonal antibodies, in addition to a binding site-associated private idiotope. This anti-idiotypic reagent bound to rat liver membranes bearing AII receptors; binding was abolished after pretreatment of the membranes with AII. In immunoblotting experiments with rat liver membranes, as well as with rat pituitary homogenates, a 63,000 +/- 2,000 dalton protein was revealed that co-migrated with the AII receptor. After purification by affinity chromatography on an immobilized CRI+-antibody (A41), anti-CRI antibodies could immunoprecipitate the hormone binding activity from detergent-treated rat liver membranes and still recognize the 63,000 dalton protein. In contrast, anti-idiotypic antibodies specific for the private idiotope failed to interact with the AII receptor. Similar results were obtained with a second anti-idiotypic serum produced by immunization with another CRI+ anti-AII monoclonal antibody (A22). The sharing of the CRI determinant between the AII receptor and anti-AII antibodies might account for the reactivity of anti-idiotypic antibodies towards the AII receptor.     

Monoclonal anti-idiotopic antibodies against myasthenia-inducing anti-acetylcholine receptor monoclonal antibodies. Preponderance of nonparatope-directed antibodies affecting antigen binding

To analyze components of the idiotypic network in experimental autoimmune disease, we produced 17 isogeneic anti-idiotopic monoclonal antibodies (anti-Id) against two experimental autoimmune myasthenia gravis-producing anti-acetylcholine receptor (anti-AChR) monoclonal antibodies. We studied the binding of five of the anti-Id to the anti-AChR monoclonal antibodies bearing the complementary idiotopes (Id-mAb). They bound with Kd values ranging from 0.06 to 0.86 nM, values comparable to those of Id-mAb:AChR complexes (0.26 and 0.34 nM). All of the anti-Id tested moderately inhibited the binding of AChR to Id-mAb, whereas for each anti-Id, AChR either strongly inhibited anti-Id binding or had no effect on anti-Id binding. Hence, the inhibition of Id-mAb:AChR binding by anti-Id was not reciprocal with the inhibition of anti-Id:Id-mAb binding by AChR. For each anti-Id, the relative affinities of anti-Id and AChR for Id-mAb together with the lack of symmetry of inhibition by anti-Id compared to inhibition by AChR indicate that these two "ligands" are not competitive inhibitors. Consequently, anti-Id and AChR do not bind to overlapping sites on the Id-mAb, suggesting that the observed inhibition is mediated allosterically. This may be a common mechanism of anti-Id:Id binding, which would have important implications for the mechanism of anti-Id-induced suppression.     

Idiotypic determinants of monoclonal antibodies that bind to 3-fucosyllactosamine

Many monoclonal antibodies that react with the lacto-N-fucopentaose III (LNF III) antigenic determinant, Gal beta 1-4(Fuc alpha 1-3)GlcNAc beta 1-3Gal beta 1-4Glc, have been described recently. The terminal trisaccharide of this determinant, fucosyllactosamine, is present on glycolipids and glycoproteins and on the surface of granulocytes, monocytes, and other cells. To study the structural and genetic diversity of these antibodies, syngeneic anti-idiotypic monoclonal antibodies were produced in BALB/c mice against PMN 6, a monoclonal antibody directed against this sequence. Anti-idiotypic antibodies 6B1 and 6C4 reacted with 50% of a panel of 20 anti-LNF III monoclonal antibodies, whereas 6A3 reacted strongly only with PMN 6. This indicates that the determinants recognized by 6C4 and 6B1 represent major cross-reactive idiotopes of this family of antibodies. The binding of idiotypic antibodies to a glycolipid bearing this antigenic determinant was completely inhibited by the three anti-idiotypic antibodies, 6A3, 6B1, and 6C4. The idiotopes could be demonstrated on the heavy chain of the monoclonal antibodies by an antibody transfer technique when mild reducing conditions were employed, but a high concentration of reducing agent destroyed the idiotypic determinants. This suggests that the anti-idiotypic antibodies recognize conformational structures expressed on the heavy chain molecules. The binding of 18 monoclonal antibodies to two glycolipid antigens and to a fucosyllactosamine-bovine serum albumin conjugate was compared. Antibodies that possessed the 6C4 cross-reactive idiotope bound to fucosyllactosamine-bovine serum albumin more weakly than idiotype-negative antibodies (p = 0.001). This suggests that the 6C4-positive antibodies might represent germline structures.     

Anti-idiotype antibodies prevent antibody binding to mouse sperm and antibody-mediated inhibition of fertilization

Antibodies to components of sperm can interfere with sperm function and prevent fertilization by blocking specific steps of gamete interaction. It can be proposed that anti-idiotype antibodies (anti-Ids) that recognize determinants located close to or within the antigen-binding site of an anti-sperm antibody could block antibody binding to sperm antigen and antibody-mediated inhibition of fertilization. To test this hypothesis, rabbit polyclonal antibodies to idiotypic determinants of the monoclonal anti-sperm antibody M42.15 were developed and characterized. Previous studies demonstrated that M42.15 monoclonal antibody (mAb) inhibits fertilization in vitro and in vivo by inhibiting sperm-zona pellucida interaction. Anti-idiotype antibodies to M42.15 mAb (anti-Id M42) were isolated by affinity chromatography on immobilized M42.15 mAb. Binding specificity of anti-Id M42.15 was demonstrated in a solid-phase radioimmune binding assay and by specific immunoprecipitation of soluble M42.15 mAb. Anti-Id M42 competitively inhibited M42.15 mAb, but not P220.2 mAb, binding to mouse sperm, confirming that the anti-Id preparation contained antibodies directed against idiotopes within or adjacent to the antigen-binding site of the mAb. At equimolar concentrations, anti-Id M42 inhibited binding of 125I-labeled M42.15 mAb to sperm by greater than 80%. These results showed that anti-Id M42 efficiently blocked antibody binding to sperm and suggested that anti-Id M42 could be used to neutralize the anti-fertility activity of the M42.15 mAb. When tested in in vitro fertilization assays, anti-Id M42, but not rabbit immunoglobulin, prevented M42.15 mAb-induced inhibition of fertilization. Together, these results show that the inhibitory activity of anti-sperm antibodies capable of interfering with gamete interaction can be neutralized by anti-Id that recognize determinants close to the antigen-combining site of the anti-sperm antibody.     

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.     

Mapping the idiotopes of a monoclonal anti-myoglobin antibody with syngeneic monoclonal anti-idiotypic antibodies: detection of a common idiotope

A panel of syngeneic monoclonal anti-idiotypic antibodies was prepared by immunizing A.SW mice with keyhole limpet hemocyanin-coupled A.SW monoclonal anti-myoglobin (HAL 19, IgG1) and screening the cloned hybridomas for production of IgG2 binding to idiotype but not to certain other anti-myoglobin antibodies of the same subclass in an ELISA. With these antibodies, we identified three nonoverlapping idiotopes, based on three clusters of monoclonal anti-idiotopes that mutually inhibit within each cluster, but not between clusters (Cluster I: S2, S6, S8; Cluster II: S5, S7; Cluster III: S9). Only Cluster II antibodies block the binding of myoglobin to HAL 19 and so identify a binding site-related idiotope(s). Binding of both Cluster II monoclonals (S5 and S7) to Hal 19 is inhibited by a rabbit anti-idiotype that we previously reported detects a common cross-reactive anti-myoglobin idiotope in immune sera. However, only one of these, S7, and not S5, identifies an idiotope that is present on 20 to 30% of A.SW anti-myoglobin antibodies in immune sera and ascites. The panel of syngeneic monoclonal anti-idiotype antibodies also detects new idiotopes not detected by the rabbit anti-idiotype. The development of a panel of syngeneic monoclonal anti-idiotypic antibodies to different clusters of idiotopes on the same antibody molecule, including one that identifies a major common idiotope in immune sera, should allow the analysis of possible idiotype network regulation in vivo and in vitro in a completely syngeneic system.     

Collagen-Induced Arthritis Suppressed with Monoclonal Anti-Idiotypic Antibody

In foregoing work, we identified at least 5 distinct epitopes on human type II collagen (CII), using 8 murine monoclonal antibodies (mAb) against human CII, and suggested that a species-nonspecific epitope on CII recognized by anti-CII mAb termed 1-5 is an arthritogenic epitope. We also found that antibody response against a selected epitope of human CII could be induced by immunization with rabbit anti-idiotypic (Id) antibody against anti-CII mAb. The author developed and characterized monoclonal anti-Id antibodies against 1-5 mAb recognizing a putative arthritogenic epitope. The author also investigated whether the anti-Id mAb could regulate antibody response directed against a selected epitope recognized by 1-5 mAb, and the induction of collagen-induced arthritis in DBA/1J mice. DBA/1J mice intravenously preinjected with anti-Id mAb to 1-5, did not produce anti-CII antibody expressing 1-5 Id upon immunization with human CII. Furthermore, as the development of collagen-induced arthritis (CIA) in DBA/1J mice pretreated with anti-Id mAb to 1-5 was significantly suppressed, anti-Id mAb will be a useful tool for studying the regulation of antibody response to a selected epitope. This study lends support to our hypothesis that the 1-5 epitope is an arthritogenic epitope.     

Idiotype network components are involved in the murine immune response to simian virus 40 large tumor antigen

Summary Baculovirus-derived recombinant simian virus 40 (SV40) large tumor antigen (SV40 T-Ag), a monoclonal antibody specific for SV40 T-Ag (Ab-1 preparation), and a monoclonal anti-idiotypic antibody (anti-Id), designated 58D, were used to analyze the humoral immune response of Balb/c mice either immunized with recombinant SV40 T-Ag or challenged with SV40-transformed cells. Inhibition assays indicated that antibodies from mice immunized with SV40 T-Ag and from those bearing SV40 tumor inhibited the SV40 T-Ag/Ab-1 reaction. These data suggested that the antibody response in immunized or tumorchallenged mice recognized similar epitope(s) on SV40 T-Ag to that detected by the monoclonal Ab-1. These anti-(SV40 T-Ag) response antibodies also inhibited the Ab-1/anti-Id reaction and recognized the anti-Id in direct binding assays. Together, these data indicate that murine anti-(SV40 T-Ag) responses shared an idiotope with a monoclonal anti-(SV40 T-Ag) Ab-1 preparation. This idiotope, which is recognized by the monoclonal anti-Id preparation, 58D, appears to be involved in the humoral immune response to SV40 T-Ag in both SV40-T-Ag-immunized and tumor-bearing mice. The monoclonal anti-Id preparation may represent a focal point for manipulating the humoral immune response to tumors induced by SV40-transformed cells.     

Human monoclonal multiple-organ-reactive autoantibodies distinguished by mouse monoclonal anti-idiotypic antibodies: expression of idiotopes in humans with and without autoimmune diseases

Previously we reported on the production and characteristics of a number of human monoclonal autoantibodies. All of these autoantibodies were of the IgM class and reacted with antigens in multiple organs. In this study we generated IgG murine monoclonal anti-idiotypic antibodies against five human monoclonal autoantibodies, (i.e., MOR-h2, MOR-h3, MOR-h4, CG1, and CG2). These anti-idiotypic antibodies reacted strongly with the corresponding human monoclonal autoantibody, but minimally or not at all with other human monoclonal autoantibodies. By using these anti-idiotypic antibodies as probes, we screened sera obtained from normal individuals and patients with insulin-dependent diabetes mellitus, Hashimoto's thyroiditis, and systemic lupus erythematosus for the expression of idiotopes. Our study showed that the idiotopes recognized by three of the anti-idiotypic antibodies, i.e., anti-CG1, anti-CG2, and anti-MOR-h2, were not expressed, but the idiotopes recognized by two of the anti-idiotypic antibodies, i.e., anti-MOR-h3 and anti-MOR-h4, were expressed in normal individuals. In patients with autoimmune disorders, there was no increase in the expression of the CG1, CG2, and MOR-h2 idiotopes, but 45 and 23% of the patients with systemic lupus erythematosus showed a significant increase in the expression of the MOR-h3 and MOR-h4 idiotopes respectively. These findings show that there is widespread expression in the B cell repertoire of certain autoantibody-associated idiotopes.     

Biological Mimicry of the Bluetongue Virus Core Protein VP7 by Rabbit Anti-Idiotype

A subpopulation of rabbit polyclonal anti-idiotypic antibody (anti-Id) was previously produced to a murine monoclonal antibody (mAb) (M1875) specific for the bluetongue virus core protein VP7. In this report, mimicry of VP7 by this anti-Id (designated RAb2-A) was functionally analyzed through immunization of Balb/c mice with RAb2-A or purified VP7. Animals immunized with RAb2-A were able to produce an M1875-like Ab3 antibody response with idiotype and epitope specificity resembling that of M1875 without subsequent exposure to the nominal antigen. This conclusion was supported by experiments showing that the RAb2-A-induced Ab3 antibodies (i) reacted specifically with the immunizing anti-Id; (ii) were capable of binding VP7; (iii) inhibited M1875 from binding to VP7; and (iv) inhibited M1875 from binding to RAb2-A. Similarly, mice immunized with purified VP7 also produced antibodies that exhibited characteristics such as idiotype and epitope specificity in common with M1875. No antibody response to VP7 was detected in control groups of mice immunized with either normal rabbit IgG or BHK-21 cell components. Therefore, it can be concluded that rabbit anti-Id RAb2-A mimics an M1875-defined VP7 epitope sufficiently to function as a surrogate antigen for inducing an anti-bluetongue virus response.     

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.     

The idiotypic characterization of the immune response to a defined epitope of a protein antigen and the specific in vivo suppression of the immune response to this epitope by anti-idiotypic antibodies

C10, a monoclonal antibody of C3H.SW (CSW) origin, binds a decapeptide epitope of the tobacco mosaic virus protein (TMVP) representing residues 103-112 of the protein. In vivo administration of syngeneic anti-idiotypic antibodies to C10 (anti-C10) prior to immunization with TMVP suppressed the expression of antibodies to this decapeptide determinant in CSW mice without a significant reduction of the total anti-TMVP titer. The suppression could not be overcome with repeated challenges by antigen even 6 months after administration of anti-C10. Analysis of anti-C10 showed that it contains antibodies to at least two idiotopes found on C10. One of these idiotopes, C10-Idm, is found on a very small fraction of CSW anti-TMVP antibodies capable of binding the decapeptide epitope. The other idiotope, C10-IdX, is found on most of the anti-TMVP antibodies which bind the decapeptide determinant. With synthetic analogues of the decapeptide determinant, a correlation was established between the presence of the C10-IdX and the fine specificity of the decapeptide-binding antibodies. The studies reported herein demonstrate that anti-idiotypic antibodies are potent modulators of the immune response and that the C10-IdX is important in the determination of the fine specificity of antibodies to this decapeptide epitope of TMVP.     

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.     

Immunohistochemistry of the guinea-pig trachea using an anti-idiotypic antibody recognizing substance P receptors

The airways receive a dense innervation from sensory neurons containing substance P (SP). An anti-SP anti-idiotypic antibody (anti-Id ab) recognizing SP receptors was previously characterized pharmacologically and proved to be useful in immunohistochemistry of the central nervous system. This antibody was used to localize SP binding sites in the guinea-pig trachea by immunohistochemistry. Immunolabelling was considered as specific when it could be prevented by a) preabsorption of the anti-Id ab with a C-terminal specific monoclonal anti-SP antibody, and b) preincubation of the tissue sections with either of the tachykinins, substance P and neurokinin A, in the presence of the inhibitor of neutral endopeptidase, phosphoramidon, and addition of these compounds into the antibody incubation medium. Moreover, immunofluorescence was absent when the acetone-fixed of fresh frozen sections were exposed to the detergent Tween 20 prior to immunohistochemistry, which points to a membrane localization of the detected tissue antigen, as expected for SP receptors. Compared with previous reports on autoradiographic localization of SP receptors in the guinea-pig trachea, the present immunohistochemical approach proved to be superior in enabling discrimination of labelled elements: Trachealis muscle, cylindrical epithelial cells and some roundish, singly lying cells in the epithelium and subepithelial lamina propria displayed specific immunofluorescence. These morphological findings match well with the known pharmacological actions of SP on the guinea-pig trachea.     

Induction of a neutralizing immune response to human respiratory syncytial virus with anti-idiotypic antibodies.

Anti-idiotypic (anti-Id) antibodies were raised in rabbits against monoclonal antibodies that recognized either F glycoprotein 47F or G glycoprotein 63G, 62G, or 74G of the human respiratory syncytial virus Long strain. Anti-Id sera inhibited the virus binding of the immunizing monoclonal antibodies and in some cases the binding of other antibodies reacting with overlapping epitopes. The anti-Id sera also inhibited virus neutralization mediated by the original monoclonal antibodies. Affinity purified anti-Id antibodies were subsequently used to raise a homologous anti-anti-Id response in rabbits. One of the rabbits, inoculated with anti-Id 63G, generated antibodies that reacted with the G protein of respiratory syncytial virus and neutralized the virus to high titers. The antiviral antibodies induced by anti-Id 63G were broadly cross-reactive with strains of the A and B subtypes. However, the specificities of monoclonal antibody 63G and anti-anti-Id 63G were not exactly the same, as indicated by their reaction with escape mutants to antibody 63G. These results demonstrate for the first time the induction of an anti-respiratory syncytial virus response by anti-Id antibodies.