Antigenic sites on cytochrome c2 from Rhodospirillum rubrum.

The antigenic determinants for three monoclonal antibodies against cytochrome c2 from Rhodospirillum rubrum were partially characterized by differential chemical modification of free and antibody-bound cytochrome c2 and by cross-reactivity analysis with different antigens. Circular dichroism spectroscopy was used to probe the effect of antibody binding on the conformation of cytochrome c2. The binding of two antibodies was strongly dependent on the native folding of the antigen. The first antibody bound to a determinant around the exposed heme edge on the 'front side' of the molecule which is not antigenic in mitochondrial cytochrome c2. Binding of this antibody to cytochrome c increased the induced CD of the ferric heme in a manner similar to that observed previously when mitochondrial cytochrome-c oxidase bound to the front side of cytochrome c. This observation points to a subtle conformational adaptation of the antigen induced by the antibody. The determinant for the second antibody, which also affected the heme CD spectrum of the antigen, was on a polypeptide loop where cytochrome c2 differs from mitochondrial cytochrome c by an eight-residue insertion. The third antibody, which did not induce a change in CD, bound to a sequential determinant near the amino end of cytochrome c2. Only this antibody cross-reacted with isolated cytochrome-c-derived peptides and with apo-cytochrome c2. A preliminary analysis of the polyclonal immune response of five rats against cytochrome c2 indicates that, unlike in eukaryotic cytochrome c, antigenic determinants are distributed over the whole polypeptide chain of the prokaryotic immunogen.     

Differential effects of two anti-apo-cytochrome c-specific monoclonal antibodies on the function of apo-cytochrome c-specific murine T cell clones

A murine monoclonal antibody (SJL 2-4) specific for the antigen apo-cytochrome c was shown to inhibit both antigen-induced proliferation and lymphokine secretion by an apo-cytochrome c-specific BALB/c helper T cell clone. The inhibition was specific because additional apo-cytochrome c-specific T cell clones were not inhibited by the same monoclonal antibody. Time course studies of the inhibition indicated that the initial 8 hr of contact between T cell clones and antigen-presenting cells were critical for activation of the T cell clones. Inhibition of T cell functions by antigen-specific antibodies appeared to correlate with the antibody-antigen binding constant because a second monoclonal antibody (Cyt-1-59), with identical specificity but with a lower affinity constant for apo-cytochrome c, had very little inhibitory effect on the proliferation or lymphokine secretion of apo-cytochrome c-specific T cell clones.     

Characterization of monoclonal antibodies to cytochrome c: analysis of the antigenic structure of holo- and apo-cytochromes, and CNBr-peptide fragments of horse cytochrome c

Five mouse hybridoma cell lines secreting SA, SB, SC, SD, and SE monoclonal antibodies (McAb) to cytochrome c have been produced. From the cross-reactivities of these McAb with various vertebrate cytochromes c, the antigenic sites for SA and SB McAb were proposed to be at Thr(89)-Glu(92)-Ala(96) and Asn(103), respectively. The binding site for other McAb have not been determined. Cross-reactivity studies based on enzyme-linked immunosorbent assays and dot immunobinding assays indicated that SA, SB, and SC McAb did not bind to apo-cytochrome c nor to any of the three CNBr-peptide fragments. This observation suggests that (i) the antigenic specificity of these McAb is dependent on the conformatiuon of the antigenic site which is inherent to the native holoprotein molecule and (ii) the ordered conformation in the C-terminal regions of holo-cytochrome c is destroyed during CNBr-peptide fragmentation. On the other hand, the lack of binding of SD and SE McAb to apo-cytochrome c indicates that these McAb are also specific for conformational sites. The binding of SD and SE McAb to the heme-containing A-peptide fragment (residues 1-65) suggests that the conformation around the heme, as possible antigenic sites, are stable because of the thioether linkages by the Cys residues.     

Topographic determinants on cytochrome c. I. The complete antigenic structures of rabbit, mouse, and guanaco cytochromes c in rabbits and mice1.

Rabbit, mouse, and guanaco cytochromes c differ from each other by only two amino acid residues. The identification is described of all of the antigenic determinants of mouse and guanaco cytochrome c that elicit an antibody response in rabbits, and those of the rabbit and guanaco proteins that elicity antibodies in the mouse. All except one of these sites center around single amino acid residue differences between the antigen and the host cytochrome c. The corresponding antibody popylations bind only to the areas of the protein in which the substitutions occur. Such antigenic determinants manifested in rabbits by quanaco and mouse cytochromes c are centered around residues 62 and 89, and residues 44 and 89, respectively. Similarly, the mouse recognizes sites containing residues 44 and 62 in guanaco cytochrome c, and residues 44 and 89 in rabbit cytochrome c. In none of these instances has a change in sequence failed to produce an antibody response. Each of these determinants appears to elicit and bind to its antibody, independently of other determinants present on the protein. In addition, two different autoantigenic responses have been detected. The antibodies produced against the determinant formed by glutamyl residue 62 of the guanaco protein in both rabbits and mice, the cytochromes c of which carry an aspartyl residue in that position, also bind to the aspartyl-containing region but with lower affinity. However, mouse and rabbit cytochrome c also elicit antibodies to the area of residue 62 in rabbits and mice, respectively, and these antibodies still bind more strongly to the glutamyl-than to the aspartyl-containing determinant. This last response occurs only when there are residue substitutions elsewhere in the molecule, because mice and rabbits fail to respond to their own cytochrome c. Antibodies produced in mice against the change from alanyl to valyl residue 44 by rabbit and guanaco cytochromes c also bind to the alanyl-containing determinant, except less tightly than to the valyl region. Conversely, antibodies raised in rabbits against the change from valyl to alanyl residue 44 only bind to this region when it carries an alanine. It is suggested that antigenic determinants that arise as a result of amino acid residue substitutions between the immunizing and the corresponding host protein, without a change in the spatial arrangement of the polypeptide backbone, be termed topographic determinants.     

Mapping antibody binding sites on cytochrome c with synthetic peptides: Are results representative of the antigenic structure of proteins?

Crystallographic work on antigen-antibody complexes has revealed that extensive surface areas of proteins may interact with antibodies. On the other hand, most experimental approaches to locate and define antigenic determinants of protein antigens rely on the linear sequence of the polypeptide chain. Hence the question arises whether mapping of antibody binding sites by analysis of the reactivity of anti-protein antibodies with synthetic peptides can provide a representative picture of the antigenic structure of a protein antigen. We have addressed this question using yeast iso-1 cytochrome c as a protein antigen against which antisera were raised in rabbits. The reaction of the antisera with 103 synthetic hexapeptides covering the entire sequence of cytochrome c was tested by the pepscan procedure in which peptides are coupled to polyethylene rods and tested by ELISA. For the assay, anti-cytochrome c antibodies were fractionated by affinity chromatography on native yeast iso-1 cytochrome c and on apo-cytochrome c; the latter is a random coil. It was found that only antibodies retained by the apo-cytochrome c affinity column react with synthetic peptides. These antibodies comprise a small fraction, probably less than 2%, of all cytochrome c-specific antibodies. The majority of antigenic determinants, which seem to consist of strongly conformation-dependent topographic epitopes, could not be uncovered by the peptide approach. Epitope mapping with short peptides seems of limited usefulness in the case of small, globular, and conformationally stable proteins like cytochrome c.     

Multiple overlapping epitopes in the three antigenic regions of horse cytochrome c1

To gain a better understanding of the diversity of epitopes on a protein, the specificities of 103 monoclonal antibodies to a model antigen, horse cytochrome c(cyt c), were analyzed. The antibodies were generated in in vitro monoclonal, secondary antibody responses against horse cyt c coupled to hemocyanin in splenic fragment cultures. For this assay, horse cyt c-primed murine B lymphocytes were transferred to irradiated, hemocyanin-primed recipients. A panel of seven mammalian cyts c differing at one to six residues out of 104 and cyanogen bromide-cleaved fragments of horse cyt c containing residues 1-65, 1-80, and 66-104 was used to examine the specificities of the antibodies. Twenty-two distinct reactivity patterns were observed, even though the majority of the monoclonal antibodies were found to bind in the three previously identified antigenic regions of the molecule about residues 44-47, 60-62, and 89-92. The results indicate that each of the three antigenic regions consists of multiple overlapping epitopes. Few of the antibodies directed to any given antigenic region bound polypeptide fragments inclusive of the epitope sequences, demonstrating that some antibodies were more conformationally dependent than others. Only 13% of the antibodies bound to cyanogen bromide-cleaved polypeptide fragments that together encompassed the entire length of the protein. Considering the large number of antibodies analyzed and the reoccurrence of 13 of the 22 clonotypes in different lymphocyte donors, it is likely that the antibody specificities tabulated herein approach yet do not completely enumerate the total inventory of the horse cyt c-specific B cell repertoire. The remarkable diversity for epitope recognition within antigenic regions observed here is likely to pertain to protein antigens in general, and strongly supports the widely held notion that the entire surface of a protein is potentially antigenic. The restriction of the epitopes of horse cyt c to three antigenic regions where the amino acid sequences of the mammalian cyts c differ probably results from tolerance of the mice to their own cyt c.     

Isolation and chemical characterization of a melanoma-associated proteoglycan antigen

Many melanoma-associated antigens have been identified by monoclonal antibodies. One of these monoclonal antibodies, O₁-94-45, binds only to melanomas, nevus cells, some astrocytomas, and fetal epitheloid cells. There are approximately 100,000 cell surface antigens per melanoma cell with an association constant of 3 × 10⁸m^?1. The antigen is efficiently extracted from the membrane only in the presence of detergent and is, therefore, bound by hydrophobic forces. However, it is also shed into the culture supernatant during normal cell growth. The two components of the O₁-95-45 antigen are a chondroitin sulfate proteoglycan (CSP, >500,000 Da) and a glycoprotein gp260 (260,000 Da, pI 6.9). CSP contains chondroitin sulfate and N-linked and O-linked oligosaccharides. Only N-linked saccharides were associated with gp260. The antigenic site is expressed on both components and is heat-sensitive. Since the CSP was converted to gp260 by chondroitinase, the protein cores of the two molecules are the same or similar. For more detailed study the O₁-95-45 antigen was purified by immunoaffinity chromatography. The amino acid composition of the purified antigen was relatively polar with an unusually high Leu content and low Lys content. Initial attempts to sequence the antigen were unsuccessful probably due to a blocked N-terminus. CSP and gp260 were partially separated by gel filtration chromatography, and both were found to carry the O₁-95-45 antigenic determinant. Three other monoclonal antibodies were found to bind the purified antigen at a site or sites different from the O₁-95-45 epitope and one other monoclonal antibody may bind at the same site. Two of these antibodies were used for a double determinant immunoassay.     

A human cell-surface antigen defined by a monoclonal antibody and controlled by a gene on chromosome 12

A murine monoclonal antibody 602-29, subclass IgG1, that recognizes an antigenic determinant expressed by most human cells is described. Immunoprecipitation and sodium dodecyl sulfate-gel electrophoresis analysis indicate that the antigenic determinant is carried by a protein with an apparent molecular weight of 21,000. The antigen is expressed by human-mouse somatic cell hybrids, and analysis of segregants that have lost human chromosomes indicates that the gene controlling expression of the 602-29 antigen is on chromosome 12.     

Delineation and conformational analysis of two synthetic peptide models of antigenic sites on rodent cytochrome c

Two regions of rodent cytochrome c, one within the first four residues of the molecule, which is N-acetylated, and one at a beta bend around residue 44, are known to be immunogenic and antigenic in rabbits. Using sequential peptide synthesis, we have determined the residues required for linear synthetic peptides within these sequences to bind to antibody raised in rabbits to intact rat cytochrome c. The residues that were important in binding the N-terminal peptides were N-acetylglycine at position 1 and valine at position 3. The smallest peptide sequence around residue 44 that would bind to antibodies was Gln-Ala-Ala-Gly-Phe. A theoretical conformational analysis of these peptides showed that the amino-terminal tetrapeptide adopts a wide statistical ensemble of conformational states and that the addition of residues beyond 41 and 45 in the other sequence does not appear to stabilize longer peptides in the native beta-bend conformation. Thus, the antigenicity conferred by Phe-46 and Gln-42 in this peptide is most likely due to the direct interaction of the side chains of these residues with the antibody binding site. The demonstration here that native conformation is not essential for antigenic peptides to bind to antibodies raised against the whole protein indicates that the association energy between antigen and antibody can be sufficient to induce conformation in conformationally flexible peptides. This supports the concept that anti-protein and anti-peptide antibodies may invoke conformational changes in cross-reactive protein antigens and may explain why longer peptides, which may adopt stable nonnative secondary structure, often do not bind to antibodies raised to the whole molecule.     

The activation of pigeon cytochrome c-specific T cell hybridomas by antigenic peptides is influenced by non-native sequences at the amino terminus of the determinant

We recently demonstrated that the sequence 95-104 contains all the residues necessary for direct recognition of the I-Ek restricted pigeon cytochrome c determinant but that residues located in sequences to the amino-terminal side of residue 95 improve the ability of peptides containing the sequence 95-104 to stimulate Ag-specific T cell clones. In this study we use synthetic peptides with amino-terminal leader sequences containing residues that differ with respect to their conformational stabilizing effects, charge, and hydrophilicity to examine the mechanism by which they modulate T cell recognition. Our findings indicate that the role of these residues in T cell stimulation is not related to their ability to stabilize alpha-helical secondary structure, nor do they appear to be processed differently. The leader sequences do not differentially influence the ability of the peptides to be presented by APC displaying Ia molecules of related haplotype, i.e., E alpha kE beta k, E alpha kE beta b, and E alpha kE beta s, to T cells which recognize the pigeon cytochrome c determinant on such presenting cells. Because antigenic potency correlates with the inclusion of hydrophobic residues and positively charged residues in the leader sequences, we discuss our findings with reference to the possibility that they non-specifically enhance the interaction of the antigenic peptides with the APC membrane.     

Antigenic surveillance of the influenza virus by mass spectrometry

The use of a mass spectrometric-based immunoassay to survey the antigenic identity of a type A influenza strain is described. Antigenic surveillance of the influenza virus remains a critical step in the identification of new viral strains and the subsequent use of such strains or synthetic constructs in vaccine preparations. The immunoassay is shown to be capable of detecting a determinant of a single hemagglutinin antigen, responsible for the initial stages of infection, in a mixture of viral proteins with high sensitivity and specificity. The determinant comprises residues 207-225 of the hemagglutinin HA1 chain of the type A strain which occupies a highly accessible region of beta-sheet atop the antigen. Peptide determinants are identified without the need to immobilize antibody or isolate antibody-peptide complexes which are shown to be preserved during mass spectrometric analysis. This immunoassay achieves optimal sensitivity (femtomole level) with minimal sample handling and is amenable to high sample throughput and automation. Determinants are identified by a direct comparison of the matrix-assisted laser desorption ionization mass spectra obtained for an antibody reaction mixture and unreacted control. The sequence and antigenic identity of a component antigen can be rapidly identified by searching protein databases with the mass spectral data in conjunction with tandem mass spectrometric sequencing.     

The structure of an antigenic determinant in a protein

The immunogenic and antigenic determinants of a synthetic peptide and the corresponding antigenic determinants in the parent protein have been elucidated. Four determinants have been defined by reactivity of a large panel of antipeptide monoclonal antibodies with short, overlapping peptides (7-28 amino acids), the immunizing peptide (36 amino acids), and the intact parent protein (the influenza virus hemagglutinin, HA). The majority of the antipeptide antibodies that also react strongly with the intact protein recognize one specific nine amino acid sequence. This immunodominant peptide determinant is located in the subunit interface in the HA trimeric structure. The relative inaccessibility of this site implies that antibody binding to the protein is to a more unfolded HA conformation. This antigenic determinant differs from those previously described for the hemagglutinin and clearly demonstrates the ability of synthetic peptides to generate antibodies that interact with regions of the protein not immunogenic or generally accessible when the protein is the immunogen.     

Topographic antigenic determinants recognized by monoclonal antibodies on human choriogonadotropin beta-subunit

We describe a first attempt to study the antibody-combining sites recognized by monoclonal antibodies raised against the beta-subunit of human choriogonadotropin (hCG). Two groups of antibodies were first defined by their ability to recognize only the free beta-subunit or the free and combined subunit. Antibodies FBT-11 and FBT-11-L bind only to hCG beta-subunit but not to hCG, whereas antibodies FBT-10 and D1E8 bind to both the beta-subunit and the hormone. In both cases, the antigenic determinants were localized to the core of the protein (residues 1-112), indicating the weak immunogenicity of the specific carboxyl-terminal extension of hCG-beta. Nine synthetic peptides spanning different regions of hCG-beta and lutropin-beta were assessed for their capacity to inhibit antibody binding. A synthetic peptide inclusive of the NH2-terminal region (residues 1-7) of the hCG beta-subunit was found to inhibit binding to the radiolabeled subunit of a monoclonal antibody specific for free hCG-beta (FBT-11). Further delineation of the antigenic site recognized by this antibody provided evidence for the involvement of fragment 82-92. Moreover, monoclonal antibody FBT-11 inhibited the recombination of hCG-beta to hCG-alpha, indicating that its antigenic determinant might be located nearby or in the hCG-beta portion interacting with the alpha-subunit. Binding of monoclonal antibody FBT-10, corresponding to the second antigenic determinant, was weakly inhibited by fragment 82-105 and did not impair the recombination of the hCG beta-subunit to the hCG alpha-subunit. Its combining site appeared to be located in a region of the intact native choriogonadotropin present at the surface of the hormone-receptor complex.     

Monoclonal antibodies to rabbit and pig zonae pellucidae distinguish species-specific and shared antigenic determinants

Monoclonal antibodies against rabbit or porcine zonae pellucidae (ZP) demonstrate species-specific and shared antigenic determinants. In addition, these antibodies are used to characterize the biochemical nature of these determinants. All of six monoclonal antibodies developed against porcine ZP react with porcine but not with rabbit ZP. Only one of seven monoclonal antibodies developed against rabbit ZP cross-reacts with porcine ZP. None of these antibodies recognized antigens associated with other tissues tested. High-resolution, two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) followed by immunoblotting was used to demonstrate that the cross-reactive antibody recognizes an antigenic determinant which is associated with the major low molecular weight glycoprotein of both the pig and rabbit ZP. Since this antibody recognizes all charge species of this glycoprotein, it is apparent that the antigenic determinant recognized by this antibody involves protein. Further studies demonstrate that proteolytic digestion of ZP will destroy the antigenic determinant while glycosidic digestion of ZP has no effect on antibody binding. Although polyclonal antibodies to this glycoprotein inhibit sperm from binding to the zona pellucida, this monoclonal antibody does not affect sperm binding. None of the species-specific antibodies recognize ZP glycoproteins following 2D-PAGE. This is a property typical of antibodies directed against conformational antigenic determinants. The presence of common as well as unique zona antigenic determinants could explain why ZP proteins induce heteroantibodies which result in infertility while alloimmunization has no effect on fertility.     

Structural basis of Redox-coupled protein substrate selection by the cytochrome c biosynthesis protein ResA

Post-translational maturation of cytochromes c involves the covalent attachment of heme to the Cys-Xxx-Xxx-Cys-His motif of the apo-cytochrome. For this process, the two cysteines of the motif must be in the reduced state. In bacteria, this is achieved by dedicated, membrane-bound thiol-disulfide oxidoreductases with a high reducing power, which are essential components of cytochrome c maturation systems and are also linked to cellular disulfide-bond formation machineries. Here we report high-resolution structures of oxidized and reduced states of a soluble, functional domain of one such oxidoreductase, ResA, from Bacillus subtilis. The structures elucidate the structural basis of the protein's high reducing power and reveal the largest redox-coupled conformational changes observed to date in any thioredoxin-like protein. These redox-coupled changes alter the protein surface and illustrate how the redox state of ResA predetermines to which substrate it binds. Furthermore, a polar cavity, present only in the reduced state, may confer specificity to recognize apo-cytochrome c. The described features of ResA are likely to be general for bacterial cytochrome c maturation systems.     

Site-directed chemical modification of horse cytochrome c results in changes in antigenicity due to local and long-range conformational perturbations

Comparative binding studies with peptide fragments of the whole antigen, or with evolutionarily related intact proteins with varying degrees of sequence homology, have been used extensively to map antigenic sites on proteins to the resolution of single amino acid residues. These methods are limited, however, since high affinity antibodies will often not react with peptides and evolutionarily related proteins are available for only a few antigens. In this study we use site-directed chemical modification of horse cytochrome c to identify residues involved in the binding sites of four monoclonal antibodies specific for this protein. Thus, we have N-formylated the single tryptophan found in horse cytochrome c at position 59 and N-carbethoxylated one of the histidyl residues, which was determined to be at position 26 by the analysis of proteolytic cleavage fragments of the modified protein using liquid secondary ion-mass spectrometry on triple quadropole or tandem quadropole Fourier transform instruments. We discuss the impact of these modifications on the antigenicity of horse cytochrome c with regard to the conformational perturbations introduced by such modifications and with reference to our previous studies on the binding sites of these antibodies using other methodologies (Jemmerson, R., and Paterson, Y. (1986) BioTechniques 4, 18-31).     

Identification of a monoclonal antibody that specifically recognizes corneal and skeletal keratan sulfate. Monoclonal antibodies to cartilage proteoglycan

Monoclonal antibodies were raised against proteoglycan core protein isolated after chondroitinase ABC digestion of human articular cartilage proteoglycan monomer. Characterization of one of the monoclonal antibodies (1/20/5-D-4) indicated that it specifically recognized an antigenic determinant in the polysaccharide structure of both corneal and skeletal keratan sulfate. Enzyme immunoassay analyses indicated that the mouse monoclonal IgG1 recognized keratan sulfate in native proteoglycan aggregate and proteoglycan monomer preparations isolated from hyaline cartilages of a wide variety of animal species (human, monkey, cow, sheep, chicken, and shark cartilage). The 1/20/5-D-4 monoclonal antibody did not recognize antigenic determinants on proteoglycan isolated from Swarm rat chondrosarcoma. This finding is consistent with several biochemical analyses showing the absence of keratan sulfate in proteoglycan synthesised by this tissue. A variety of substructures isolated after selective cleavage of bovine nasal cartilage proteoglycan (Heineg?rd, D., and Axelsson, J. (1977) J. Biol. Chem. 252, 1971-1979) were used as competing antigens in radioimmunoassays to characterize the specificity of the 1/20/5-D-4 immunoglobulin. Substructures derived from the keratan sulfate attachment region of the proteoglycan (keratan sulfate peptides) showed the strongest inhibition. Both corneal and skeletal keratan sulfate peptides as competing antigens in radioimmunoassays showed similar inhibition when compared on the basis of their glucosamine content. Therefore, the 1/20/5-D-4 monoclonal antibody appears to recognize a common determinant in their polysaccharide moieties. Chemical desulfation of the keratan sulfate reduced the antigenicity of the glycosaminoglycan. The antibody did not recognize determinants present in dermatan sulfate, heparin, heparin sulfate, or hyaluronic acid.     

Characterization of an oviductal glycoprotein associated with the ovulated hamster oocyte

Hamster oviducts in culture incorporate [35S]-methionine into secretory proteins. One of these proteins is immunoprecipitated by a monoclonal antibody specific to an antigen found in oviductal oocytes but not in ovarian oocytes. This antigen, called oviductin, is progressively added to the oocyte during its transit through the oviduct. Oviductin migrates as a diffuse band with a molecular mass between 160 and 250 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. The electrophoretic behavior of this protein suggests the presence of polysaccharide side chains. Chemical deglycosylation causes a decrease in molecular mass and removes the antigenic determinant originally present on the glycoprotein. By using the radiation inactivation method, the molecular mass of the core protein has been found to be approximately 44 kDa. These results indicate that the oviduct is an actual site of synthesis of the oviductin. This glycoprotein contains a high proportion of sugar residues, which account for antigenic determinant recognized by the monoclonal antibody.     

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.     

Monoclonal antibody as a probe for structure and function of an Escherichia coli outer membrane protein

Eight independently derived monoclonal antibodies directed against the LamB protein were produced and characterized. By using these antibodies as probes, we identified four distinct topological and functional regions in the LamB molecule. Four monoclonal antibodies recognize antigenic determinants of the protein exposed on the outer side of the membrane. Two of these have their binding sites located in a region involved in maltose transport. One monoclonal antibody presumably binds to a determinant which is normally hidden in the membrane and three monoclonal antibodies recognize determinants facing the periplasmic space.