A reevaluation of rabbit anti-allotype antibody for the presence of cross-reactive idiotypes. II. Expression of rabbit a1-like images on goat antibody after immunization with anti-a1 antibody

In an effort to generate heterologous anti-idiotype (Ab2) molecules to a suspected IdX on rabbit anti-a1 antibody (Ab1), goats were immunized with either rabbit or guinea pig Ab1. The goat Ab2 preparations reacted with each of 13 rabbit Ab1, as well as two goat Ab1 samples in serologic assays. From 8 to 50% of the molecules in purified rabbit Ab1 preparations reacted with each goat Ab2. Electron microscopy of immune complexes composed of rabbit Fab anti-a1 and goat Ab2 reveals that the Fab anti-a1 binds to the side of the variable region of most goat Ab2 molecules, rather than at the tip (i.e. in the CDR) as expected. This configuration indicates that the goat Ab2 actually represents a population of induced or enhanced Ig molecules expressing a1-like allotypic or isotypic determinants, rather than an anti-IdX Ab or a paratope-associated internal image of a1.     

A reevaluation of rabbit anti-allotype antibody for the presence of cross-reactive idiotypes. I. A species-specific idiotype on rabbit anti-a1 antibody is recognized by guinea pig anti-IdX antibody

Rabbit reagents previously thought to display specificity for a cross-reactive idiotype on anti-VHa allotype antibody from all tested rabbits have recently been shown to be contaminated with an induced (latent) molecule similar or identical to the original antigen (rabbit a1 or a2 allotype). In an attempt to circumvent this problem, we have immunized guinea pigs with rabbit anti-a1 allotype antibody to produce heterologous anti-idiotype antibody. The resulting guinea pig antibody (GP anti-R IdX) recognizes anti-a1 antibody from each of 17 immunized rabbits, and in four tested samples reacts with 22 to 100% of the molecules. Neither goat nor guinea pig anti-a1 reacts with the guinea pig anti-R IdX antibody, even though the goat, guinea pig, and rabbit anti-a1 Ab all recognize a similar set of a1 determinants. The reaction between IdX-bearing rabbit anti-a1 and guinea pig anti-R IdX is inhibited by the original antigen (a1 IgG), demonstrating that the IdX is at or near the antigen combining site of anti-a1 antibody. Immunoelectron microscopy of immune complexes supports this conclusion and demonstrates that the reactive site on the GP anti-R IdX is at or near its antigen combining site.     

Heavy chain variable region allotypic subspecificities of rabbit immunoglobulins. II. Selective escape of the a1-AB Ig subpopulation after the induction of auto anti-a1 antibody.

An a1a2 rabbit (P286-3), neonatally suppressed for the expression of the a1 allotype, was immunized with autologous a1 IgG at 2 months of age. Both auto anti-a1 Ab and a1 IgG molecules were found in the serum of this rabbit after the auto-immunization. The auto anti-a1 Ab and the IgG from the auto anti-a1 Ab-depleted serum were isolated. Of the previously defined a1-AB, a1-AC, and a1-AD Ig subpopulations, the a1 IgG in the IgG preparation from the rabbit P286-3 were all of the a1-AB Ig subpopulation. The auto anti-a1 Ab from rabbit P286-3 did not react with the a1-A, a1-B, and a1-C allotypic subspecificities; thus, it was presumably specific for the a1-AC and a1-D allotypic subspecificity. Thus, the a1-AB Ig subpopulation escaped from allotype suppression in rabbit P286-3, whereas the a1-AD Ig subpopulation remained suppressed. The a1-AD Ig subpopulation will probably remain suppressed for a long time and perhaps permanently since rabbit P286-3 has produced circulating auto-Ab specific for the a1-D allotypic subspecificity. These results indicate that the a1 Ig subpopulations are synthesized by distinct clones of lymphocytes under separate control.     

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.     

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.     

Thymus-dependent antiidiotype and anti-antiidiotype responses to a dinitrophenyl-specific monoclonal antibody

BALB/c mice were inoculated i.p. with graded doses of a DNP-specific, IgM mAb (designated 57.1). Injection with unmodified 57.1 in the absence of adjuvants resulted in the generation of an anti-Id response (Ab2) and an anti-anti-Id response (Ab3). The generation of serum anti-Id antibodies was found to be thymus dependent. Nude mice immunized with 57.1 were unable to produce a serum Ab2 response above nonimmunized controls whereas euthymic mice receiving identical doses of 57.1 produced strong Ab2 responses. To examine the specificity of serum anti-Id, sera from mice receiving 57.1 were screened against a panel of mAb representing at least five distinct VH gene families. Serum titers were significantly higher against 57.1 than against any of the other antibodies in the panel. Three of the antibodies in this panel bind FD5-1, a monoclonal anti-Id (Ab2) that also binds 57.1. However, sera from mice receiving 57.1 bound 57.1 only. Thus, the serum Ab2 response appears to be highly specific for idiotopes on 57.1. The predominant isotype of these anti-Id antibodies was IgG1. The number of isotypes detected increased in a dose dependent manner with all IgG subclasses having anti-Id specificity in sera from animals receiving the higher doses of 57.1. Further analysis of the serum demonstrated that approximately 8% of the Ab2 response was paratope-specific (inhibitable by the monovalent hapten DNP-lysine). The same sera were analyzed for the presence of Ab3 by binding to the monoclonal anti-Id antibody FD5-1. Lower serum titers of Ab3 were generated in comparison to serum titers of Ab2. Analysis of the binding specificity of the Ab3 response revealed that DNP-BSA was able to partially inhibit the binding of serum IgM and IgG Ab3 to FD5-1. A subset of the Ab3 response. Ab1' that is specific for DNP was observed in a direct binding assay where detectable amounts of DNP binding IgM, IgG1, and IgG3 isotypes were present. We have thus described a complete circuit (Ab1----Ab2----Ab3) of antibodies within the Id network by immunizing animals with an unmodified mAb in the absence of Ag or adjuvants.     

Xenogeneic antibodies with apparent public idiotypic specificity for anti-Ia.7 antibodies are directed in part against V kappa 21D and E subgroup marker

Public idiotypes (IdX) expressed on monoclonal antibodies (mAb) against a monomorphic alpha-chain determinant of the I-E molecule (Ia.7 epitope cluster I) have been studied by using xenogeneic anti-Id reagents derived from pig, rabbit, and rat. IdX+ anti-Ia.7 mAb were recently demonstrated to be structurally related by a high frequency expression of the V kappa 21E light chain subgroup. This raised the question of whether V region determinants of the IdX were related to V kappa 21E sequences or whether they were unique to hypervariable regions of Ia.7 binding antibodies. To clarify this question, the possible association between the expression of the public Id (IdX(s)Ia.7) and the presence of V kappa sequences (V kappa 21E and/or J kappa segment) was examined. The reactivity of the anti-Id reagents with a random panel of 28 myeloma products (each containing a light chain from one of the different V kappa 21 subgroups) was studied by assaying the ability of these mAb to inhibit the binding between the anti-Id and anti-Ia.7 mAb. This analysis demonstrates that what has previously been defined as IdX Ia.7 includes determinants shared by V kappa 21E and V kappa 21D light chain V regions. The structures recognized are expressed irrespective of the J kappa segment. In addition, this study demonstrates interspecies variation in immune responses to such V kappa 21E antigenic determinants. Additional IdX components are found on anti-Ia.7 mAb but not on other V kappa 21E or D proteins. Thus V region subgroup considerations have crucial implications for Id characterization. In addition, this work describes the first division of the V kappa 21 subgroup into component parts by a mAb.     

Monoclonal anti-alpha (1----3) dextran antibodies of Igha BALB/c and Ighb C.B20 mice display striking similarities

Allotype Ighb congenic C.B20 mice when immunized with dextran B1355S are unable to produce anti-alpha (1----3) dextran antibodies that express the VH-associated cross-reactive IdX idiotype. This intrastrain-specific idiotype is normally associated only with the anti-dextran response of Igha mice of which BALB/c is a prototype strain. In this study we have obtained monoclonal hybridoma antibodies specific for the alpha (1----3) glucosidic linkage of dextran from C.B20 mice that were presensitized with rabbit anti-IdX antibodies. These antibodies display the light chain isotype distribution, the H chain amino terminal sequence, share VH-associated IdX idiotypic determinants, and finally the similar fine specificity for dextrans observed for anti-alpha (1----3) dextran antibodies of BALB/c mice.     

Idiotype restriction in murine lupus; high frequency of three public idiotypes on serum IgG in nephritic NZB/NZW F1 mice

Antibodies to self-antigens are characteristic of several human and murine autoimmune diseases. Subsets of those autoantibodies cause organ damage in some instances, such as IgG antibodies to DNA in human and murine systemic lupus erythematosus (SLE). Our experiments in the NZB/NZW F1 (BW) female mouse model of SLE were designed to define idiotypic (Id) structures on antibodies to DNA in attempts to distinguish pathogens from nonpathogens within the anti-DNA population. Two important findings emerged. First, the number of public Id expressed became relatively restricted as the mice aged, with three such Id (IdX, IdGN1 and IdGN2) dominating and accounting for 30 to 95% of the total serum IgG in all individual nephritic mice studied, and 81 to 86% of the total IgG in serum pools from 30-wk-old nephritic mice. Second, IdGN1 and IdGN2 constituted approximately 50% of the IgG deposited in glomeruli of nephritic mice; IdX was present in negligible quantities in glomeruli, whereas it was usually the most frequent Id in BW serum. These latter findings suggested that pathogens and nonpathogens can be distinguished by their idiotypy in this animal model. The finding of relative Id restriction suggests the occurrence of an idiotypic "spreading" phenomenon, in which a regulatory process appears as BW mice age that results in repeated selection and expansion of this small number of Id, one group of which, the IdGN, is pathogenic. This process was further suggested in experiments in which IdX was suppressed by administration of anti-IdX; the "escape" antibodies to DNA appearing after suppression of IdX were composed largely of IdGN1 and IdGN2, without a major contribution from Id-negative mutants. Defining the basis of this Id spreading or restriction phenomenon may provide important information regarding the pathogenesis of this autoimmune disease.     

Partial amino acid sequence and genetic control of latent a2 allotype induced in rabbits by immunization with anti-a2 antibody

We have shown that after immunization of homozygous a1 rabbits of the B immunoglobulin (Ig) heavy chain haplotype with anti-a2 antibody (Ab) a population of molecules appears that has all of the serologic characteristics of the a2 allotype. We have now isolated these putative latent a2 molecules, have separated the heavy chains, and after enzymatic deblocking, have determined the first 19 N-terminal amino acids. For all eight allotype-associated residues, these putative latent a2 molecules have the amino acid residues typical of a2 allotype. As expected, the preimmune IgG from this a1a1 rabbit has the amino acids typical of the a1 allotype. Thus by partial amino acid sequence analysis, we provide additional evidence that the latent a2 allotype can be induced in a1a1 rabbits of the B heavy chain haplotype by immunization with anti-a2 Ab. Rabbits of other heavy chain haplotypes were also immunized with anti-a2 Ab and were tested for their ability to synthesize latent a2 allotype. Thus far, a1a1 rabbits of the A, B, C, and I heavy chain haplotypes all synthesize latent a2 allotype. In contrast, a3a3 rabbits of the G and H heavy chain haplotypes did not synthesize latent a2 allotype.     

A restricted human antitetanus clonotype shares idiotypic cross-reactivity with tetanus antibodies from most human donors and rabbits: reactivity with antibodies of widely differing electrophoretic mobility

Antitetanus antibodies from each of 20 hyperimmunized human donors were isolated on a tetanus immunoadsorbent, eluted with acidic buffer, and examined by isoelectric focusing (IEF). There was electrophoretic restriction, as determined by IEF, in the IgG of only 20% of the purified antibodies studied. The remaining 80% showed a more diffuse polyclonal spectrotype. Several IEF bands from the most electrophoretically restricted sample were isolated and used to immunize rabbits. Virtually every IgG-IEF band in the antitetanus antibodies of the original donor shared idiotypic cross-reactivity as detected by one or more of the three rabbit anti-Id reagents, even though major qualitative differences in binding from one rabbit anti-Id reagent to another were noted. Antitetanus antibodies of each of the 20 donors were separated by IEF and transferred to a nitrocellulose membrane. By using a sensitive and specific ELISA detection method, cross-reactivity was detected with the rabbit anti-Id reagents in 1 to 50% of the antitetanus antibodies of individual donors. This cross-reactivity was greater than 10% in 15 of the 19 antisera studied. In addition, these cross-reactive antibodies had very different electrophoretic mobility. Binding of the rabbit anti-Id reagents to the tetanus antibodies was almost completely blocked by pretreatment with soluble tetanus toxoid antigen. This idiotypic cross-reactivity with antibodies of different electrophoretic mobility from the same and unrelated donors suggests sharing among these antibodies of one or more of the germ-line DNA-encoded hypervariable regions present in the antibody-combining site.     

Auto-antibody to an Ig VH region allotype: induction of anti-a1 antibody in an a1-suppressed a1a2 heterozygous rabbit.

Two a1a2 heterozygous sibling rabbits were first suppressed for the paternally inherited a1 VH region allotype and then immunized with a1 IgG. Anti-a1 antibody was detected in the serum of one of the rabbits. The anti-a1 auto-antibody reacted with the same amount of a1 IgG as did a conventional anti-a1 allo-antibody. Most of the IgG and IgM of this rabbit was of the a2 allotype and no significant amount of the a1 allotype was detected as would be expected for an a1 suppressed a1a2 heterozygous rabbit. However, allotype suppression in this rabbit is maintained by endogenous anti-allotype antibody. Rabbits with anti-allotype auto-antibody may be exploited to produce litters of heterozygous and homozygous rabbits efficiently suppressed for selected allotypes.     

An anti-idiotype vaccine elicits a specific response to N-glycolyl sialic acid residues of glycoconjugates in melanoma patients

We generated the 1E10 gamma-type anti-idiotype mAb (Ab2) specific to an Ab1 mAb able to react specifically with N-glycolyl-containing gangliosides and with Ags expressed on human melanoma and breast carcinoma cells. This Ab2 mAb induced an Ab response in animal models sharing immunochemically defined idiotopes with the Ab1. The treatment of tumor-bearing mice with 1E10 mAb induced a strong antitumor activity. A clinical trial was conducted in 20 patients with advanced malignant melanoma. Patients were treated with six intradermal injections of aluminum hydroxide-precipitated 1E10 anti-Id mAb given at 2-wk intervals. Sixteen of the 17 patients who received at least four doses of the anti-Id vaccine develop Ab3 Abs capable of inhibiting Ab2 binding to Ab1 (Ab3Id+). In contrast to the incapacity of 1E10 mAb to generate Ab3 Abs with the same antigenic specificity as the Ab1 mAb in mice, a very specific and strong Ab3 response against N-glycolyl-containing gangliosides was induced in 16 patients (Ab3Ag+). No evidence of serious or unexpected adverse effects has been observed in this clinical trial. 1E10 anti-Id vaccine was safe, well tolerated, and immunologically effective, with most patients being able to generate a specific immune response against 1E10 and Neu-glycolyl-GM(3) ganglioside.     

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.     

Characterization of the antibody response against NeuGcGM3 ganglioside elicited in non-small cell lung cancer patients immunized with an anti-idiotype antibody

1E10 mAb is an anti-Id murine mAb (Ab2 mAb) specific for an Ab1 mAb that reacts with NeuGc-containing gangliosides, sulfatides, and Ags expressed in some human tumors. In preclinical studies, this Ab2 Ab was able to mimic NeuGc-containing gangliosides only in animals lacking expression of these Ags in normal tissues. In this study, we report on the immune responses elicited in 20 non-small cell lung cancer patients treated with 1 mg of aluminum hydroxide-precipitated 1E10 mAb. In the hyperimmune sera from 16 of 20 patients, a strong specific Ab response of both IgM and IgG isotypes against NeuGcGM3 ganglioside was observed. Patient immune sera were able to induce complement-independent cell death of NeuGcGM3-expressing X63 murine myeloma target cells. Significant immunoreactivity to NeuGcGM3 was still detected after the complete abrogation of the reactivity against 1E10 mAb by the adsorption of patient sera with this Ab. We hypothesize that Id(-)Ag(+) Abs could reflect the activation of an autologous idiotypic cascade into the patients. Both Id(+)Ag(+) and Id(-)Ag(+) fractions were separated by affinity chromatography and characterized. Although IgG isotype Abs were found in both fractions, IgM isotype Abs were found only in the Id(-)Ag(+) fraction. Both Id(+)Ag(+) and Id(-)Ag(+) Abs were able to specifically recognize and induce cell death in NeuGcGM3-expressing X63 myeloma target cells. Patients that developed IgG and/or IgM Abs against NeuGcGM3 showed longer median survival times.     

Immune response to levan. II. T independence of suppression of cross-reactive idiotypes by anti-idiotype antibodies.

Pretreatment of BALB/c mice with antisera to a cross-reactive idiotype (E109IdX) expressed on many anti-bacterial levan (BL) and anti-inulin (Inu) antibodies leads to a prolonged suppression in production of IdX-bearing molecules in response to BL immunization. There is a comparable suppression in numbers of plaque-forming cells secreting IdX-bearing anti-BL and anti-Inu molecules. Furthermore, spleen cells from anti-E109IdX pretreated mice are unable to transfer to irradiated recipients the ability to produce IdX-bearing anti-BL and anti-Inu antibodies. These results indicate that the suppressive effect is at the precursor level and not simply a clearance of antibodies bearing the IdX. Suppression of IdX production can be achieved by pretreating nu/nu BALB/c mice with anti-E109IdX antibodies. Furthermore, spleen cells from pretreated mice do not inhibit the capacity of spleen cells from normal mice transferred to irradiated recipients to produce E109IdX in response to BL. This indicates that the suppression of IdX production in the anti-BL system is T independent and probably represents direct inhibition of precursors by anti-IdX.     

Antiidiotypic antibody related to the 84 kD human sperm membrane protein

Wistar rats were inoculated with purified YWK-I antibody.The anti-idiotypic antibodies were isolated from rat sera by successive passage over affinity chromatography columns of YWK-I mAb and normal mouse Igs.Specificity of anti-Id antibody was established by ELISA.The 84kD protein inhibited the binding of anti-Id to YWK-I mAb,but failed to repress antibody against normal mouse Ig binding to YWK-I mAb.In competitive inhibition assay,84kD protein had shown the ability to compete with anti-Id binding to YWK-I mAb in a dose-dependent manner.Crude sperm extract showed a lower competitive ability.No effect was found with the irrelevant 36kD sperm protein.The antisera from the Balb/C micr immunized with AId contained Ab3 that reacted with 84kD sperm protein.The binding of anti-Id to YWK-I mAb was inhibited by Ab3 in a dose-dependent fashion and Ab3 was shown to be able to induce human sperm agglutination.These results indicate that anti-Id which may mimic an epitope of the 84kD protein could be exploited as an antigen to raise antibodies against sperm protein.     

Immune response to human immunodeficiency virus. In vivo administration of anti-idiotype induces an anti-gp160 response specific for a synthetic peptide

Anti-idiotypic antibodies (anti-Id) to chimpanzee antibodies directed against a synthetic peptide corresponding to a native epitope associated with gp41 of human immunodeficiency virus (HIV) envelope glycoprotein were produced in rabbits. The peptide was analogous to amino acid sequences 735 to 752 from the human T cell leukemia virus-IIIB isolate of HIV. Characteristics of the anti-Id preparation included: 1) detection of a shared determinant present on a second chimpanzee and one of three rabbit antibody preparations directed against the synthetic peptide, 2) failure to recognize an idiotype (Id) in BALB/c mouse antisera to the peptide, and 3) partial inhibition of the homologous chimpanzee Id preparation from binding either peptide or a recombinant HIV gp160 preparation. Immunization of BALB/c mice with the anti-Id induced an antipeptide response which bound a recombinant gp160 preparation without subsequent peptide or gp160 exposure. The anti-gp160 containing sera from mice immunized with anti-Id were able to inhibit the Id-anti-Id reaction indicating that an Id-positive antibody response was induced. This Id is not normally expressed in the murine anti-gp 160 immune response to the synthetic peptide and suggests that this anti-Id may activate normally silent clones. This study indicates that Id networks may be operational during the immune response to HIV epitopes. Alternatively, anti-Id may be useful in altering the serologic characteristics of an antibody response to HIV and may offer potential for modulating the immune response in this viral infection.     

Induction of an anti-hepatitis B surface antigen response in mice by noninternal image (Ab2 alpha) anti-idiotypic antibodies

Anti-idiotype antibodies to a mouse monoclonal antibody A-12 directed against HBsAg were produced in rabbits. The anti-Id consisted of an Ab-2 alpha preparation that did not display any detectable internal image activity. Immunization of BALB/c mice with the anti-Id (Ab-2 alpha) coupled to KLH induced an anti-HBs response without subsequent HBsAg exposure. No anti-HBs was detected in control groups of mice immunized with other rabbit anti-Id-KLH preparations. The anti-HBs containing sera from mice immunized with the Ab-2 alpha were able to inhibit the Id-anti-Id reaction, indicating that an Id-positive, anti-HBs response was induced. This idiotype is not normally expressed during the murine immune response to HBsAg and suggests that noninternal image anti-Id activates silent clones. This study, along with our previous results obtained with the use of internal image anti-Id, suggests that there is more than one Id network operational during the BALB/c murine immune response to HBsAg.     

Tumor idiotype vaccines. VII. Analysis and correlation of structural, idiotypic, and biologic properties of protective and nonprotective Ab2

We have previously generated and used anti-Id mAb (Ab2) to induce protective immunity against the L1210 DBA/2 tumor and for immunotherapy of established tumors. Among various anti-Id that were typed serologically as internal image Ab2 of the mouse mammary tumor virus tumor-associated Ag gp52, only one induced protective immunity and was effective in immunotherapy. In this study we compared the structural, idiotypic, and network properties of the protective and nonprotective antiidiotypic antibodies. The DNA sequence of the variable regions of six anti-Id was determined. The VH sequence of four Ab2, including the protective Ab2, are highly homologous, whereas the VL sequences differ and were assigned to different Vk families. In addition, the DH sequence region of the same four Ab2 are identical, whereas one is highly homologous and another one without homology. Search for amino acid sequence homologies between the Ab2 and gp52 showed the strongest similarities in the CDR2 of the L chain from the protective Ab2. In addition, the CDR2 region also had homology with a T cell epitope on gp52. The biologic basis of effective idiotypic mimicry was studied at the level of Ab3 induced by the Ab2. Id inhibition analysis using Ab3 induced by either protective or nonprotective Ab2, revealed differences. Thus, there is evidence for differences among the Ab1-Ab2-Ab3 cascade induced by protective and nonprotective anti-Id.