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.     

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

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

Sharing of Ia antigens between species. IV. Interspecies cross-reactivity of monoclonal antibodies directed against polymorphic mouse Ia determinants

The specificity of interspecies Ia cross-reactions has been analyzed by testing a panel of monoclonal antibodies (mAb) to mouse I-E and I-A antigens for reactivity with pig Ia antigens. Our earlier studies showed that mouse anti-I-E alloantisera recognized common determinants on Ia antigens of other species, whereas anti-I-A alloantisera showed much more limited cross-reactivity. These results were confirmed using a panel of 17 anti-I-E mAb, 10 of which were cytotoxic to pig cells. 2D gel electrophoretic analyses of precipitates with these mAb of 35S-labeled, NP40 solubilized pig cells revealed a limited set of protein spots that appeared to be identical to the subset of pig Ia antigens precipitated by A.TH anti-A.TL alloantiserum. Because the cross-reactive mouse sera were produced in mouse strains that do not express an I-E molecule (H-2b and H-2s), it was anticipated that the cross-reacting antibodies would be reactive with the monomorphic determinant of the I-E molecule, Ia.7. However, comparison of the reactivity of these mAb with pig cells and mouse cells revealed that the cross-reactivity on pig cells correlated not with Ia.7 but rather with detection of epitope(s) of the I-E molecule associated with inter-strain polymorphism. Anti-I-A cross-reactions were also detected, but were weaker and more limited. These findings may have implications for the evolution of Ia antigens in mammalian species.     

Genetic control of immune response to staphylococcal nuclease. XII: Analysis of nuclease antigenic determinants using anti-nuclease monoclonal antibodies

Summary SJL mice, which are high responders to Staphylococcal nuclease (nuclease), were immunized and used to produce hybridoma cell lines secreting anti-nuclease monoclonal antibodies (mAb). Ten stable clones were derived from a single fusion. Seven of these produced antibodies of the IgG_1, isotype and were more precisely characterized for antigenic specificity. Only one hybridoma cell line (54-10-4) produced anti-nuclease antibodies capable of inhibiting enzymatic activity of nuclease. Binding inhibition analyses strongly suggest that the other monoclonal antibodies, which failed to inhibit nuclease activity detect two different antigenic regions, or epitopes, of the molecule: epitope cluster 1 domain is defined by hybridomas 54-2-7, 54-5-2, 54-9-8, and 54-10-8; epitope cluster 2 by 54-5-1 and 54-1-9. Because of its capacity to inhibit nuclease enzymatic activity mAb 54-10-4 was considered specific for a third epitope of the nuclease molecule called epitope 3. Binding studies of these monoclonal antibodies were extended to peptide fragments of the nuclease molecule in order to examine possible cross-reactions with such fragments, as has previously been reported for antibodies purified from polyclonal antisera. Monoclonal antibodies specific for epitope cluster 1 on the native molecule also bound to the fragments 1–126 and 49–149 but failed to bind to fragment 99–149, suggesting that the corresponding epitope(s) is determined by amino acids localized between residues 49 and 99. The epitope clusters 2 and 3 appeared to be expressed only on the native molecule. Monoclonal antibodies of different clusters exhibited very different migration patterns on isoelectric focusing while monoclonal antibodies of the same cluster were indistinguishable, which suggests that they may have originated from the same B cell precursor. Taken together these data suggest that this panel of monoclonal antibodies detects at least three distinct epitopes of the nuclease molecule, one of which could be involved in the determination of the enzymatic site.     

Specificity of monoclonal antibodies against human thyroglobulin; comparison with autoimmune antibodies.

Ten monoclonal antibodies (mAb) directed against human thyroglobulin (hTgb) were produced, purified and characterized. The mAb avidity for hTgb ranged from 10(-10) to 10(-6) M. The species specificity of the mAb was as follows: eight mAb reacted with monkey Tgb, three with dog Tgb and one with pig Tgb; none with bovine and ovine Tgb. The binding of mAb to hTgb was not significantly inhibited in the presence of Tgb carbohydrate moieties, tyrosine, iodotyrosines and iodothyronines. The topology of the antigenic determinants recognized by the 10 mAb on hTgb was explored by inhibition of Tgb binding of radiolabeled mAb by the other antibodies. Six distinct clusters of reactivity were described. Localization of the antigenic determinants recognized by mAb on hTgb was attempted using tryptic fragments of hTgb to inhibit the binding of mAb to hTgb. The inhibitory effect of hydrolysis products was different for each mAb but exhibited partial analogies between mAb of the same cluster of reactivity. Anti-hTgb autoimmune antibodies (aAb) purified from sera of Graves patients cross-reacted essentially with mAb of one out of the six clusters. These results demonstrate that the large number of antigenic determinants presented by the hTgb are not disseminated on the molecule but are clustered in antigenic regions. Furthermore, from the six antigenic regions evidenced in this paper, only one is involved in autoimmune antibody production in Grave's disease.     

Hybrid genes between HLA-A2 and HLA-A3 constructed by in vivo recombination allow mapping of HLA-A2 and HLA-A3 polymorphic antigenic determinants

HLA-A2 and -A3 genes have been modified in their third exon (second domain) by using in vivo recombination. In this method Escherichia coli are transfected with a plasmid which contains two highly homologous sequences (e.g., the third exons of HLA-A2 and -A3) and has been linearized by cleavage between these two sequences. Circularization takes place in the bacteria by homologous recombination leading to hybrid A2-A3 sequences. The analysis by DNA sequencing of a number of such recombinants shows that they indeed occur by homologous recombination (no insertions or deletions) and that the probability of crossing over decreases as the distance from the free end of DNA in the homologous region increases. No double recombinants were observed. These hybrid exons were reinserted into either HLA-A2 or HLA-A3 genes, thus generating a panel of functional hybrid genes containing one or several HLA-A2 specific substitutions in an HLA-A3 background or vice versa. These genes were expressed by transfection into murine P815-high transfection efficiency recipient cells. Serologic analysis leads to the conclusion that expression of polymorphic antigenic determinants specific for HLA-A2 (detected with M58, A2A28M1, and CR11.351 mAb) is linked to the presence of threonine residue (amino acid (AA) 142) and/or histidine residue (AA 145) and valine residue (AA 152). The expression of specific HLA-A3 polymorphic determinants (recognized by GAP-A3 mAb) is correlated with the existence of a asparagine residue (AA 127) and a aspartic residue (AA 161). But aspartic residue 161 contributes with glutamic acid residue 152 in the formation of the A3 epitope recognized by the anti-A3 mAb X1.23.2.     

A conformational epitope expressed upon association of CD3-epsilon with either CD3-delta or CD3-gamma is the main target for recognition by anti-CD3 monoclonal antibodies.

We have performed immunofluorescence analysis of COS cells transfected with human CD3 genes and detergent permeabilized to define the specificity of several anti-CD3 antibodies. We have found that the mAb OKT3, WT31, UCHT1, and Leu-4 did not stain COS cells singly transfected with the CD3-epsilon chain. However, these antibodies very strongly stained COS cells doubly transfected with a combination of CD3-epsilon plus either CD3-gamma or CD3-delta. By contrast, the antibodies SP34 and APA 1/1, which were raised against isolated SDS-denatured CD3-epsilon protein, gave a strong staining of COS cells singly transfected with CD3-epsilon as well as of the double transfectans. The recognition by this panel of anti-CD3 antibodies of CD3-gamma/epsilon and CD3-delta/epsilon complexes and not of CD3-epsilon alone was assessed by immunoprecipitation. These findings suggest that the most widely used mAb specific for the CD3 complex recognize conformational epitopes on CD3-epsilon, which are expressed when this chain is bound to either CD3-gamma or CD3-delta. It should also be highlighted that antibody WT31 clearly recognizes the CD3 moiety of the TCR/CD3 complex.     

Dissection of the poly(Glu60 Ala30 Tyr10) (GAT)-specific T-cell repertoire in H-2I k mice

Twenty-five allospecific monoclonal antibodies (mAb), produced in the A. TH. A.BY, or B10.S (7R) anti-A.TL combinations, were shown to recognize determinants organized in four spatially distinct polymorphic regions on the same I-Ak-encoded molecule(s). These reagents were used to assess the recognition of the class II major histocompatibility complex (MHC) determinants in a series of GAT-reactive A.TL T-cell clones exhibiting various restriction specificity or alloreactivity patterns. Of the proliferative responses of 13 cloned T cells, 12 responses were found to be inhibited similarly by the same set of mAbs.A hierarchy in the blocking effects of these reagents that could be correlated with the spatial organization of their determinants was observed. (i) All the mAbs defining the epitope region I (i.e., recognizing public Ia.1- or Ia.17-like determinants, presumably expressed on the A beta subunit) and some of those identifying new public determinants in the epitope region II profoundly inhibited these T-cell responses. (ii) Intermediate blocking was observed when mAbs recognizing public determinants in the epitope region III were used. (iii) Finally, among the mAbs that identified the epitope group IV, the Ia.19-specific mAb 39.J was inhibitory, whereas mAbs directed against private Ia.2-like determinants were not. By contrast, the GAT-specific proliferative response of the T-cell clone AT-20.1, which recognized its nominal antigen in an extensively cross-reactive MHC-restricted fashion, could only be inhibited by a subset of the mAbs recognizing epitopes in groups I and II, but not by those recognizing epitopes in groups III and IV. It was also shown that the same subset of I-Ak-and I-Au-reactive mAbs displayed similar blocking effects on the proliferation of two T-cell clones exhibiting dual specificity for I-Ak- and I-Au-restricting and/or I-Ak- and I-Au-alloactivating determinants. Finally, all the cloned T-cell responses examined were found to be inhibited by rat mAbs against the LFA.1 molecule or the murine equivalent of the human OKT4 differentiation antigen. These studies suggest that class II specific mAbs can impair proliferation of cloned T-cells by a mechanism(s) other than the masking of the T-cells' restriction determinants per se.     

Regulation of B cell responses to the variant surface glycoprotein (VSG) molecule in trypanosomiasis. I. Epitope specificity and idiotypic profile of monoclonal antibodies to the VSG of Trypanosoma brucei rhodesiense.

Regulatory mechanisms governing B cell responses to the trypanosome variant surface glycoprotein (VSG) molecule currently are being studied. As a fundamental basis for examining such regulation, the epitope specificities and idiotypic profiles of murine mAb produced to the VSG of Trypanosoma brucei rhodesiense clone LouTat 1.5 were determined. Variant specific mAb were used to probe VSG proteolytic peptides in Western blot analysis, to serve as competitive inhibitors in RIA analyses with purified VSG molecules, and to examine membrane-binding patterns of labeled trypanosome cells in order to evaluate epitope specificities. By using these approaches, a conformational epitope expressed only on the VSG 1.5 surface coat of viable trypanosomes was detected, and two nonconformationally determined epitope clusters were recognized within the subsurface V region of the VSG 1.5 molecule. The subsurface epitope clusters may be repeated on the VSG molecule because each was present on more than one proteolytic VSG peptide fragment. Idiotypic profiles of selected VSG-specific mAb subsequently were determined with xenogeneic antiidiotypic typing sera. Results from competitive inhibition RIA analyses using these reagents demonstrated that varying levels of idiotypic cross-reactivity exist among the subsurface VSG epitope-specific mAb; this cross-reactivity extended to idiotope(s) expressed by a mAb recognizing a surface conformational epitope of the VSG 1.5 molecule. Analysis of complementary idiotypic/antiidiotypic antibody pairs revealed that these specific interactions were inhibited by purified VSG 1.5 but not by purified VSG 1.9, which was derived from a heterologous variant antigenic type. The model mAb described here, and reagents recognizing their idiotypic markers, comprise a foundation for analysis of idiotypic regulation of VSG-specific B cell responses during infection.     

Monoclonal antibodies directed against the galactose-binding lectin of Entamoeba histolytica enhance adherence.

The Entamoeba histolytica galactose-binding lectin is a surface glycoprotein composed of 170- and 35-kDa subunits. Inhibition of this lectin with galactose or anti-170 kDa subunit polyclonal antibody blocks amebic adherence to target cells and colonic mucin glycoproteins. We describe the properties of 10 mAb with specificity for the 170-kDa subunit. Based on competitive binding studies, six nonoverlapping antigenic determinants on the lectin were identified. The effect of the mAb on adherence of amebic trophozoites to both Chinese hamster ovary (CHO) cells and human colonic mucins was measured. Antilectin antibodies directed against epitopes 1 and 2 enhanced adherence, with the number of amebae having at least three adherent CHO cells increasing with the addition of epitope 1 mAb from 26 +/- 9 to 88 +/- 2% and the binding of colonic mucins increasing from 34 +/- 1 to 164 +/- 3 pg/10(5) amebae. Antibody-enhanced adherence remained 90 to 100% galactose inhibitable, occurred at 4 degrees C and was not Fc mediated. Univalent Fab fragments of epitope 1 mAb augmented mucin binding by 238% and CHO cell adherence by 338%. The binding of purified lectin to CHO cells was increased from 1.1 +/- 0.1 to 2.4 +/- 0.3 ng/10(3) CHO cells by mAb directed to epitope 1, demonstrating that enhanced adherence was due to direct activation of the lectin. mAb to epitope 3 bound to the lectin only upon its solubilization from the membrane and had no effect on adherence. Adherence to CHO cells and mucins was inhibited from 50 to 75% by mAb to epitopes 4 and 5; epitope 6 mAb inhibited amebic adherence to CHO cells but not mucins. The pooled sera from 10 patients with amebic liver abscess blocked the binding to the 170-kDa subunit of mAb directed to all six epitopes. Striking individual variations in the effects of immune sera on adherence were observed. Although the sera of all 44 South African patients with amebic liver abscess had high titer anti-lectin antibodies, 16 patients' sera significantly (more than 3 SEM) enhanced adherence whereas 25 patients' sera significantly inhibited adherence. Antilectin antibodies exert profound functional effects on the interaction of E. histolytica with target cells and human colonic mucins. Exploration of the clinical consequences of adherence-enhancing and inhibitory antibody responses may give insight into the role of antilectin antibodies in immunity to invasive amebiasis.     

Expression of variable exon A-, B-, and C-specific CD45 determinants on peripheral and thymic T cell populations.

A mAb (I/24) has been generated that is specific for a determinant on mouse CD45 molecules. Reactivity of this mAb with a panel of CD45 transfected cell lines demonstrated that the determinant recognized is dependent upon expression of one or more CD45 variable exons and that exon C is sufficient for its expression. The exon C-specific epitope detected by I/24 is expressed at high density on essentially all B lymphocytes and at an intermediate density on the vast majority of CD8+ splenic T cells. Two distinct subpopulations of CD4+ splenic T cells were detected, a minor subpopulation that expresses this exon determinant at high density and a major subpopulation that expresses it at a much lower density. This first identification of a CD45RC-specific reagent allowed a comparison of the expression of exon A-, exon B-, and exon C-specific determinants on peripheral and thymic lymphoid populations. When splenic lymphocytes were analyzed for expression of CD45RA (reactive with mAb 14.8), CD45RB (reactive with mAb 23G2 or mAb 16.A), and CD45RC (reactive with mAb I/24) determinants, it was found that each of these CD45 determinants had a distinct pattern of expression on CD4+ and CD8+ T cells and B cells. CD45RB and RC epitopes were also detected at high density on a small proportion (0.7 to 4.1%) of thymocytes. Both CD45RB and RC epitopes were found predominantly on CD4-CD8- and CD4-CD8+ thymocytes but were also found on small numbers of CD4+CD8+ and CD4+CD8- cells. The population of thymocytes that expressed CD45RB and CD45RC determinants displayed a novel TCR CD3 phenotype characterized by a level of expression that was intermediate between that seen in the larger CD3 bright and CD3 dull populations of thymocytes.     

Characterization of cell lines expressing mutant I-Ab and I-Ak molecules allows the definition of distinct serologic epitopes on A alpha and A beta polypeptides

A series of seven I-Ab-reactive monoclonal antibodies (mAb) has been derived from a BALB/c anti-C57BL/6 immunization. Analysis of the reactivity patterns of these mAb with spleen cells of mice from the independent haplotypes has revealed three groups of mAb: group I mAb react with all haplotypes except d, group II with all except d and k, and group III with all except d, k, and j. In addition, the group I and group II mAb also react with human class II-expressing cells. We have used these mAb to isolate one mutant I-Ab-expressing cell line and three additional I-Ak mutant cell lines. These antibodies have been used, in conjunction with a large panel of I-A-reactive mAb available from others, to extensively characterize our collection of mutant I-A-expressing cell lines. Analysis of the mutant cell lines has allowed us to assign the reactivity of each mAb to either the A alpha- or the A beta-polypeptide. All seven newly isolated mAb appear to react with determinants on the A alpha-polypeptide. Furthermore, analysis of the panel of A alpha k- and A beta k-mutants has allowed us to discriminate at least five epitopes that are separable by mutation on the A beta k-polypeptide, and two epitopes on the A alpha k-polypeptide.     

In vitro mutagenesis of HLA-B27. Amino acid substitutions at position 67 disrupt anti-B27 monoclonal antibody binding in direct relation to the size of the substituted side chain.

The class I MHC molecule HLA-B27 bears an unpaired Cys residue at position 67, which is predicted to face the Ag binding pocket, based on the x-ray crystallographic model of HLA-A2. To investigate the potential of this residue in the antigenic structure of HLA-B27, a panel of 11 mutant HLA-B27 genes has been created, each bearing a separate amino acid substitution at position 67. The genes were transfected into mouse L cells and the resulting cells analyzed by cytofluorography with a panel of antibodies reactive with the wild-type B27 molecule. Although previous studies had indicated that all mAb that bound the B27 molecule on human lymphocytes bound comparably to L cells transfected with the wild-type B27 gene in the absence of h beta 2-m (human beta 2-microglobulin), the first of the mutant B27 genes was found to express several mAb epitopes in the presence but not in the absence of a h beta 2-m gene. Therefore, subsequent analysis of the B27 mutant panel was conducted in L cells coexpressing the h beta 2-m gene. Under these circumstances, all of the mutants bound the monomorphic anti-class I HLA mAb W6/32 and B.9.12.1, as well as the broadly polymorphic mAb B.1.23.2. Binding to the mutant transfectants of three anti-B27 mAb that cross-react with HLA-B7, ME1, GS145.2, and GSP5.3, was directly proportional to the size of the substituted amino acid side chain. The binding of another anti-B27 mAb, B27M2, that recognizes a B27 determinant that includes the region of amino acids 77-81, was not affected by the Cys67- greater than Tyr67 substitution. Rabbit antibodies to a synthetic peptide composed of B27 amino acids 61-84 bound to both the wild-type B27 and to the Tyr67 mutant. This binding, but not the binding of ME1 or B27M2, was inhibited by the synthetic peptide. These data are interpreted as suggesting that the large amino acid substitutions at position 67 induce a limited conformational change that disrupts the epitopes of the three anti-B27, B7 mAb, that are themselves at least partially conformational. The potential implications of these findings for the role of HLA-B27 in disease pathogenesis are discussed.     

一株新型抗46 ku-细胞角蛋白的单特异性单克隆抗体

利用杂交瘤技术制备了一株单克隆抗体 T2-2,对其生化性质的研究及其与抗细胞角蛋白多克隆抗体完全重合的定位表明,该抗体特异性识别一种分子质量为 46 ku 的角蛋白. 对 68 例正常组织和 65 例肿瘤组织的免疫组化结果显示,单克隆抗体 T2-2 具有上皮细胞特异性. 与其他多数抗细胞角蛋白抗体常与一种以上细胞角蛋白多肽表现出交叉反应不同的是,该抗体只识别 46 ku 细胞角蛋白多肽上的某一单特异性表位. 另外,单克隆抗体 T2-2 适用于多种免疫实验技术,包括 ELISA、免疫组化、细胞免疫荧光及蛋白质印迹等,而且适用于多种固定剂. 以上结果表明,单克隆抗体 T2-2 将成为细胞角蛋白功能研究和肿瘤诊断的有力工具.     

The epitope specificity and tissue reactivity of four murine monoclonal anti-CD22 antibodies

The CD22 antigen is expressed on the surface of normal human B cells and some neoplastic B cell lines and tumors. Previous cross-blocking studies using a panel of monoclonal anti-CD22 antibodies have defined four epitope groups, termed A-D. In the present studies, we have further dissected the epitopes recognized by four monoclonal anti-CD22 antibodies using immunoprecipitation and cross-blocking techniques, immunofluorescence analyses with a variety of cell lines, and immunoperoxidase analyses of 36 normal human tissues. Two of the antibodies, HD6 and RFB4, have been described previously, and two, UV22-1 and UV22-2, are described in this report. Our studies indicate that the four monoclonal antibodies show unexpected complexities in their reactivity with CD22+ and CD22- cells and their reactivity with solubilized CD22 molecules. The four antibodies, which recognize epitopes defined previously as CD22-A and CD22-B, further subdivide these epitope clusters into four determinants, A1, A2, B1, and B2. Furthermore, only two of the antibodies, RFB4 and UV22-2, are B cell-specific. In summary, our data indicate that RFB4 and UV22-2 would be the antibodies of choice for constructing immunotoxins to treat B cell tumors.     

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

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

Immunization with an anti-idiotypic antibody against the broadly lipopolysaccharide-reactive antibody WN1 222-5 induces Escherichia coli R3-core-type specific antibodies in rabbits

The mouse monoclonal antibody (mAb) WN1 222-5 recognizes a carbohydrate epitope in the inner core region of LPS that is shared by all strains of Escherichia coli and Salmonella enterica and is able to neutralize their endotoxic activity in vitro and in vivo. Immunization of mice with mAb WN1 222-5 yielded several anti-idiotypic mAbs one of which (mAb S81-19) competitively inhibited binding of mAb WN1 222-5 to E. coli and Salmonella LPS. After immunization of rabbits with mAb S81-19, the serological responses towards LPS were characterized at intervals over two years. Whereas the serological response against the anti-idiotype developed as expected, the anti-anti-idiotypic response against LPS developed slowly and antibodies appeared after 200?d that bound to E. coli LPS of the R3 core-type and neutralized its TNF-α inducing capacity for human peripheral mononuclear cells. We describe the generation of a novel anti-idiotypic antibody that can induce LPS core-reactive antibodies upon immunization in rabbits and show that it is possible, in principle, to obtain LPS neutralizing antibodies by anti-idiotypic immunization against the mAb WN1 222-5. The mimicked epitope likely shares common determinants with the WN1 222-5 epitope, yet differences with respect to either affinity or specificity do exist, as binding to smaller oligosaccharides of the inner core was not observed.     

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.     

Clonal T lymphocyte recognition of the fine structure of the HLA-A2 molecule

A human alloimmune cytotoxic T lymphocyte (CTL) clone (4E4) was generated against the HLA-A2 molecule. Lysis of 51Cr-labeled HLA-A2 target cells was blocked by monoclonal antibodies (mAb), including mAb PA2.1 (anti-HLA-A2), mAb BB7.2 (anti-HLA-A2), mAb 4B (anti-HLA-A2-plus-A28), mAb MA2.1 (anti-HLA-A2-plus-B17), and mAb W6/32 (anti-HLA-A,B,C), which are directed against different serologic epitopes on the HLA-A2 molecule. However, HLA-A2 mutant lines lacking the serologic epitope recognized by mAb BB7.2 (anti-HLA-A2) were efficiently lysed by CTL 4E4. Thus, although mAb may block cytolysis, the HLA-A2 epitope recognized the 4E4 CTL clone is distinct from the HLA-A2-specific epitope recognized by serologic reagents. Moreover, analysis of HLA-A2 population variants revealed that only the predominant HLA-A2.1 subtype molecule was recognized by CTL 4E4. No cross-reactivity on other, biochemically related HLA-A2 population subtypes was observed, including HLA-A2.2 cells (Hill, CVE, ZYL, M7), HLA-A2.3 cells (TENJ, DK1), or HLA-A2.4 cells (CLA, KNE). This CTL clone appears to recognize a single epitope and, like monoclonal antibody counterparts, can be used to discriminate among immunogenic cellular and serologic epitopes on closely related HLA-A2 molecules. On the basis of the known sequence changes in mutant and subtype HLA-A2 molecules, it appears that the sequence spanning residues 147 to 157 may be critical for cellular recognition of this Class I MHC molecule.