Recognition of the acetylcholine receptor binding site of a long-chain neurotoxin by toxin-specific monoclonal antibodies.

The present paper reports the preparation and characterization of two neutralizing monoclonal antibodies (Mabs), called MST1 and MST2, which bind at the central loop of a long-chain neurotoxin from cobra venom. The central loop is a critical region for the binding of the toxin to the nicotinic acetylcholine receptor. Some of the residues incorporated in the epitopes recognized by MST1 and MST2 have been identified on the basis of competition experiments using a set of 'chemical mutants' of the toxin. We show that MST1 and MST2 bind at the base and at the tip of the central loop of the toxin, respectively, however, only MST2 actually overlaps the acetylcholine receptor binding site. Accordingly, only MST2 is capable of recognizing all homologous toxins so far examined. MST2, therefore, mimicks, at least partially, the site by which the nicotinic acetylcholine receptor recognizes a long-chain neurotoxin.     

Design and synthesis of peptides that bind alpha-bungarotoxin with high affinity and mimic the three-dimensional structure of the binding-site of acetylcholine receptor

Alpha-bungarotoxin (alpha-BTX) is a highly toxic snake neurotoxin that binds to acetylcholine receptor (AChR) at the neuromuscular junction, and is a potent inhibitor of this receptor. In the following we review multi-phase research of the design, synthesis and structure analysis of peptides that bind alpha-BTX and inhibit its binding to AChR. Structure-based design concomitant with biological information of the alpha-BTX/AChR system yielded 13-mer peptides that bind to alpha-BTX with high affinity and are potent inhibitors of alpha-BTX binding to AChR (IC(50) of 2 nM). X-Ray and NMR spectroscopy reveal that the high-affinity peptides fold into an anti-parallel beta-hairpin structure when bound to alpha-BTX. The structures of the bound peptides and the homologous loop of acetylcholine binding protein, a soluble analog of AChR, are remarkably similar. Their superposition indicates that the toxin wraps around the binding-site loop, and in addition, binds tightly at the interface of two of the receptor subunits and blocks access of acetylcholine to its binding site. The procedure described in this article may serve as a paradigm for obtaining high-affinity peptides in biochemical systems that contain a ligand and a receptor molecule.     

Synthetic peptides corresponding to sequences of snake venom neurotoxins and rabies virus glycoprotein bind to the nicotinic acetylcholine receptor

Peptides corresponding to portions of loop 2 of snake venom curare-mimetic neurotoxins and to a structurally similar region of rabies virus glycoprotein were synthesized. Interaction of these peptides with purified Torpedo electric organ acetylcholine receptor was tested by measuring their ability to block the binding of 125I-labeled alpha-bungarotoxin to the receptor. In addition, inhibition of alpha-bungarotoxin binding to a 32-residue synthetic peptide corresponding to positions 173-204 of the alpha-subunit was determined. Neurotoxin and glycoprotein peptides corresponding to toxin loop 2 inhibited labeled toxin binding to the receptor with IC50 values comparable to those of nicotine and the competitive antagonist d-tubocurarine and to the alpha-subunit peptides with apparent affinities between those of d-tubocurarine and alpha-cobratoxin. Substitution of neurotoxin residue Arg37, the proposed counterpart of the quaternary ammonium of acetylcholine, with a negatively charged Glu residue reduced the apparent affinity about 10-fold. Peptides containing the neurotoxin invariant residue Trp29 and 10- to 100-fold higher affinities than peptides lacking this residue. These results demonstrate that relatively short synthetic peptides retain some of the binding ability of the native protein from which they are derived, indicating that such peptides are useful in the study of protein-protein interactions. The ability of the peptides to compete alpha-bungarotoxin binding to the receptor with apparent affinities comparable to those of other cholinergic ligands indicates that loop 2 of the neurotoxins and the structurally similar segment of the rabies virus glycoprotein act as recognition sites for the acetylcholine receptor. Invariant toxin residues Arg37 and Trp29 and their viral homologs play important, although not essential, roles in binding, possibly by interaction with complementary anionic and hydrophobic subsites on the acetylcholine receptor. The alpha-subunit peptide most likely contains all of the determinants for binding of the toxin and glycoprotein peptides present on the alpha-subunit, because these peptides bind to the 32-residue alpha-subunit peptide with the same or greater affinity as to the intact subunit.     

Subunit interface selectivity of the alpha-neurotoxins for the nicotinic acetylcholine receptor

Peptide toxins selective for particular subunit interfaces of the nicotinic acetylcholine receptor have proven invaluable in assigning candidate residues located in the two binding sites and for determining probable orientations of the bound peptide. We report here on a short alpha-neurotoxin from Naja mossambica mossambica (NmmI) that, similar to other alpha-neurotoxins, binds with high affinity to alphagamma and alphadelta subunit interfaces (KD approximately 100 pM) but binds with markedly reduced affinity to the alphaepsilon interface (KD approximately 100 nM). By constructing chimeras composed of portions of the gamma and epsilon subunits and coexpressing them with wild type alpha, beta, and delta subunits in HEK 293 cells, we identify a region of the subunit sequence responsible for the difference in affinity. Within this region, gammaPro-175 and gammaGlu-176 confer high affinity, whereas Thr and Ala, found at homologous positions in epsilon, confer low affinity. To identify an interaction between gammaGlu-176 and residues in NmmI, we have examined cationic residues in the central loop of the toxin and measured binding of mutant toxin-receptor combinations. The data show strong pairwise interactions or coupling between gammaGlu-176 and Lys-27 of NmmI and progressively weaker interactions with Arg-33 and Arg-36 in loop II of this three-loop toxin. Thus, loop II of NmmI, and in particular the face of this loop closest to loop III, appears to come into close apposition with Glu-176 of the gamma subunit surface of the binding site interface.     

Design and synthesis of peptides that bind α-bungarotoxin with high affinity and mimic the three-dimensional structure of the binding-site of acetylcholine receptor

α-Bungarotoxin (α-BTX) is a highly toxic snake neurotoxin that binds to acetylcholine receptor (AChR) at the neuromuscular junction, and is a potent inhibitor of this receptor. In the following we review multi-phase research of the design, synthesis and structure analysis of peptides that bind α-BTX and inhibit its binding to AChR. Structure-based design concomitant with biological information of the α-BTX/AChR system yielded 13-mer peptides that bind to α-BTX with high affinity and are potent inhibitors of α-BTX binding to AChR (IC₅₀ of 2 nM). X-Ray and NMR spectroscopy reveal that the high-affinity peptides fold into an anti-parallel β-hairpin structure when bound to α-BTX. The structures of the bound peptides and the homologous loop of acetylcholine binding protein, a soluble analog of AChR, are remarkably similar. Their superposition indicates that the toxin wraps around the binding-site loop, and in addition, binds tightly at the interface of two of the receptor subunits and blocks access of acetylcholine to its binding site. The procedure described in this article may serve as a paradigm for obtaining high-affinity peptides in biochemical systems that contain a ligand and a receptor molecule.     

Structure-function relationship of lapemis toxin: a synthetic approach

The synthetic approach to the structure-function relationship of lapemis toxin has been very useful in clarifying the important binding regions. To identify the neurotoxic binding domain(s) of lapemis toxin, several peptides were synthesized using the 9-fluorenylmethoxycarbonyl protocols. These peptides were based on the sequence of lapemis toxin, a 60-amino-acid, short-chain postsynaptic neurotoxin found in sea snake (Lapemis hardwickii) venom. The peptides were purified using high-performance liquid chromatography and sequenced to verify the correct synthesis, isolation, and purity. The synthetic peptide names and single letter sequences were Peptide A1 (15 mer) CCNQQSSQPKTTTNC Peptide B1 (18 mer) CYKKTWSDHRGTRIERGC Peptide B2 (16 mer) YKKTWSDHRGTRIERG Peptide C1 (12 mer) CPQVKPGIKLEC Peptide NS (20 mer) EACDFGHIKLMNPQRSTVWY. The peptide NS (nonsense peptide) sequence was arbitrarily determined and used as a control peptide. Biological activities of the synthetic peptides were determined by in vivo as well as by in vitro assay methods. For the in vivo assay, lethality was determined by intravenous injection in mice (Swiss Webster). For the in vitro assay, peptide binding to the Torpedo californica nicotinic acetylcholine receptor was determined. The peptides were found to be nontoxic at approximately 114 times the known LD50 of lapemis toxin. Binding studies with 125I-radiolabeled lapemis toxin and tyrosine-containing peptides indicated that lapemis toxin and peptide B1 bound the receptor, while the other peptides had no detectable binding. The central loop domain of lapemis toxin (peptide B1) plays a dominate role in the toxin's binding ability to the receptor. These results and the hydrophilicity analysis predict peptide B1 may serve as an antagonist or antigen to neutralize the neurotoxin effects in vivo.     

On the molecular mechanisms of neutralization of a cobra neurotoxin by specific antibodies

Examination of 76 homologous neurotoxin sequences suggested that the "toxic" domain of these compounds consists of twelve highly conserved residues. Five of these, namely Lys-27, Trp-29, Asp-31, Arg-33 and Glu-38, together with a variant residue at position 36 are organized into a pattern which resembles that of d-tubocurarine. Two lines of experimental evidence are in agreement with the proposed topology of the "toxic" site in Naja nigricollis toxin alpha--Three highly conserved residues (Lys-27, Trp-29 and Lys-47) have been modified individually in toxin alpha. These modifications induce a decrease in binding affinity of toxin alpha for its target, the nicotinic acetylcholine receptor. In contrast, modifications of three residues (Leu-1, Lys-15 and Lys-51) excluded from the "toxic" domain, do not alter the binding properties of toxin alpha.--Five toxin derivatives carrying a nitroxide group at residues 1, 15, 27, 47 or 51 have been prepared. ESR spectra have been recorded for each derivative in both the free state and bound to the receptor. Mobility of the probes of the residues excluded from the "toxic" site is not altered upon receptor binding. In contrast mobility of the nitroxide of the presumed "toxic" Lys-47 becomes markedly reduced after toxin receptor complex formation. Lys-27 nitroxide is immobilized in both the free and bound state. The antigenic structure of N. nigricollis toxin alpha has been partially clarified using two different approaches. --Fifteen antigenically important residues of toxin alpha have been identified by analyzing cross-reactions between toxin alpha and eleven homologous neurotoxins, using polyclonal antibodies.--- One monoclonal antibody (M alpha 1) specific for toxin alpha has been prepared. Competition experiments, made with (3H) toxin alpha, six mono modified toxin derivatives or alpha three homologous neurotoxins, showed that the binding site of (M alpha 1) comprises the N-terminal group, Lys-15, Pro-18 and probably Thr-16. This site is topographically different from the "toxic" domain. (M alpha 1) inhibits the toxicity of toxin alpha under both in vivo and in vitro conditions. In addition, (M alpha 1) is capable of "removing" toxin molecules bound to the receptor, allowing a rapid recovery of the functional properties of the receptor.     

Localization and synthesis of the acetylcholine-binding site in the alpha-chain of the Torpedo californica acetylcholine receptor.

The sequence of the alpha-chain of the acetylcholine receptor of T. californica has been determined by recent cloning studies. The integrity of the disulphide bond between Cys-128 and cys-142 has been shown to be important for the maintenance of the binding activity of the receptor, thus implicating the regions around the disulphide bridge in binding with acetylcholine. In the present work, a synthetic peptide containing this loop region (residues 125-147) was synthesized. Solid-phase radiometric binding assays demonstrated a high binding of 125I-labelled alpha-bungarotoxin to the synthetic peptide. It was further shown that the free peptide bound well to [3H]acetylcholine. Additional experiments demonstrated that pretreatment of peptide 125-147 with 2-mercaptoethanol destroyed its binding activity, clearly showing that the integrity of the disulphide structure was essential for binding. Unlabelled acetylcholine also inhibited the binding of labelled acetylcholine to the synthetic peptide. The region 125-147, therefore, contains essential elements of the acetylcholine binding site of the Torpedo receptor.     

Evidence that the acetylcholine binding site is not formed by the sequence alpha 127-143 of the acetylcholine receptor

The sequence alpha 127-143 of the alpha subunit of the acetylcholine receptor has been proposed to contain several important features: (1) the acetylcholine binding site, (2) the only N-glycosylation site of the alpha subunit, at asparagine-alpha 141, and (3) two cysteine residues, at alpha 128 and alpha 142, that may participate in a disulfide bond known to be near the binding site. We tested these hypotheses by using antisera to receptor and its subunits and monoclonal antibodies to the synthetic peptide alpha 127-143 cyclized by a disulfide bond between alpha 128 and alpha 142. Antisera to receptor and its alpha subunit were able to immunoprecipitate the iodinated peptide, and this reaction was inhibited by soluble receptor, but not by membrane-bound receptor. alpha-Bungarotoxin did not inhibit antiserum binding to solubilized receptor. Similarly, cholinergic ligands had little or no effect on binding to immobilized receptors of anti-peptide monoclonal antibodies. In addition, these monoclonal antibodies, when bound to the receptor, did not affect toxin binding kinetics. By contrast, preincubation with concanavalin A did inhibit monoclonal antibody binding. Reduction of the receptor significantly decreased the binding of three of the monoclonal antibodies, but subsequent alkylation with N-ethylmaleimide or the affinity labeling reagent bromoacetylcholine had no additional effect on binding. A dithiothreitol concentration about 100-fold higher that the one needed to reduce the disulfide near the acetylcholine binding site was necessary to inhibit monoclonal antibody binding. We conclude that the sequence alpha 127-143 is not fully exposed on the surface when the receptor is in the membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of myasthenic serum globulin with the acetylcholine receptor.

A serum factor from patients with myasthenia gravis which inhibited the binding of 125I-labeled alpha-bungarotoxin to acetylcholine receptor extracted with Triton X-100 from rat muscle has been studied in detail. The inhibitory activity was localized to the IgG fraction based upon the fractionations by sodium sulfate precipitation and DEAE chromatography as well as reaction with anti-IgG globulin. The myasthenic globulin inhibited toxin binding to receptors extracted from degenerated muscle but did not inhibit toxin binding to normal junctional receptors. At saturation levels of myasthenic globulin, the number of denervated acetylcholine receptors available for toxin binding was reduced approx. 50 percent. The myastehnic globulin was found to bind to denervated acetylcholine receptors but not to normal acetylcholine receptors by a radioimmunoassay technique in which myasthenic globulin incubated with 125I-labeled alpha bungarotoxin-receptor complexes was precipitated by anti-IgG serum. The globulin binding was saturable over the same range as inhibition of toxin binding. The data suggest that the myasthenic IgC binds to a site on the receptor complex juxtaposed to the acetylcholine receptor site. The myasthenic globulin appears to be a useful probe for investigation differences between acetylcholine receptors extracted from normal and denervated muscle and for investigating the pathogenesis of myasthenia gravis.     

Structure-function relationships of curaremimetic neurotoxin loop 2 and of a structurally similar segment of rabies virus glycoprotein in their interaction with the nicotinic acetylcholine receptor

Peptides corresponding to portions of curaremimetic neurotoxin loop 2 and to a structurally similar segment of rabies virus glycoprotein were synthetically modified in order to gain information on structure-function relationships of neurotoxin loop 2 interactions with the acetylcholine receptor. Binding of synthetic peptides to the acetylcholine receptor of Torpedo electric organ membranes was assessed by measuring their ability to inhibit the binding of 125I-alpha-bungarotoxin to the receptor. The peptides showing the highest affinity for the receptor were a peptide corresponding to the sequence of loop 2 (residues 25-44) of Ophiophagus hannah (king cobra) toxin b (IC50 = 5.7 x 10(-6) M) and the structurally similar segment (residues 173-203) of CVS rabies virus glycoprotein (IC50 = 2.6 x 10(-6) M). These affinities were comparable to those of d-tubocurarine (IC50 = 3.4 x 10(-6) M) and suberyldicholine (IC50 = 2.5 x 10(-6) M). These results demonstrate the importance of loop 2 in the neurotoxin interaction with the receptor. N- and C-terminal deletions of the loop 2 peptides and substitution of residues invariant or highly conserved among neurotoxins were performed in order to determine the role of individual residues in binding. Residues 25-40 are the most crucial in the interaction with the acetylcholine receptor. Modifications involving Lys-27, Trp-29, Phe-33, Arg-37, and Gly-38 reduced affinity of binding. R37D and F33T modifications reduced the affinity of alpha-bungarotoxin residues 28-40 by an order of magnitude. Arg-37 may correspond to the positively charged quaternary ammonium group and Phe-33 to the hydrophobic acetyl methyl group of acetylcholine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structure of nicotinic acetylcholine receptor homolog AChBP in complex with an alpha-conotoxin PnIA variant

Conotoxins (Ctx) form a large family of peptide toxins from cone snail venoms that act on a broad spectrum of ion channels and receptors. The subgroup alpha-Ctx specifically and selectively binds to subtypes of nicotinic acetylcholine receptors (nAChRs), which are targets for treatment of several neurological disorders. Here we present the structure at a resolution of 2.4 A of alpha-Ctx PnIA (A10L D14K), a potent blocker of the alpha(7)-nAChR, bound with high affinity to acetylcholine binding protein (AChBP), the prototype for the ligand-binding domains of the nAChR superfamily. Alpha-Ctx is buried deep within the ligand-binding site and interacts with residues on both faces of adjacent subunits. The toxin itself does not change conformation, but displaces the C loop of AChBP and induces a rigid-body subunit movement. Knowledge of these contacts could facilitate the rational design of drug leads using the Ctx framework and may lead to compounds with increased receptor subtype selectivity.     

A novel peptide mimicking the interaction of α-neurotoxins with acetylcholine receptor

A peptide corresponding to residues 26–41 of α-bungarotoxin, and closed by a disulfide bond between two cysteine residues at the amino and C terminal ends of the peptide, was synthesized and the monomeric form was purified. The peptide, which represents the exposed part of the long central loop of the toxin molecule, was examined for binding to acetylcholine receptor. The peptide was shown by radiometric titrations to bind radiolabeled receptor, and radiolabeled peptide was bound by receptor. The specificity of the binding was confirmed by inhibition with the parent toxin. A synthetic analog of the peptide in which Trp-28 was replaced by glycine had very little (10%) of the original activity. Succinylation of the amino groups of the peptide resulted in virtually complete (98%) loss of the binding activity. These results indicate that a shortened loop peptide corresponding to the region 26–41 of α-bungarotoxin exhibits binding activities mimicking those of the parent molecule. In this region, Trp-28, and one or both of Lys-26 and Lys-38, are essential contact residues in the binding to receptor.     

Rabies virus binding to an acetylcholine receptor alpha-subunit peptide

The binding of 125I-labeled rabies virus to a synthetic peptide comprising residues 173-204 of the alpha 1-subunit of the nicotinic acetylcholine receptor was investigated. Binding of rabies virus to the receptor peptide was dependent on pH, could be competed with by unlabeled homologous virus particles, and was saturable. Synthetic peptides of snake venom, curaremimetic neurotoxins and of the structurally similar segment of the rabies virus glycoprotein, were effective in competing with labeled virus binding to the receptor peptide at micromolar concentrations. Similarly, synthetic peptides of the binding domain on the acetylcholine receptor competed for binding. These findings suggest that both rabies virus and neurotoxins bind to residues 173-204 of the alpha 1-subunit of the acetylcholine receptor. Competition studies with shorter alpha-subunit peptides within this region indicate that the highest affinity virus binding determinants are located within residues 179-192. A rat nerve alpha 3-subunit peptide, that does not bind alpha-bungarotoxin, inhibited binding of virus to the alpha 1 peptide, suggesting that rabies binds to neuronal nicotinic acetylcholine receptors. These studies indicate that synthetic peptides of the glycoprotein binding domain and of the receptor binding domain may represent useful antiviral agents by targeting the recognition event between the viral attachment protein and the host cell receptor, and inhibiting attachment of virus to the receptor.     

An H-bond between two residues from different loops of the acetylcholine binding site contributes to the activation mechanism of nicotinic receptors

The molecular mechanisms of nicotinic receptor activation are still largely unknown. The crystallographic structure of the acetylcholine binding protein (AChBP) reveals a single H-bond between two different acetylcholine binding loops. Within these homologous loops we systematically introduced alpha4 residues into the alpha7/5HT(3) chimeric receptor and found that the single point mutations G152K (loop B) and P193I (loop C) displayed a non-additive increase of equilibrium binding affinity for several agonists compared with the double mutant G152K/P193I. In whole-cell patch-clamp recordings, G152K, P193I and G152K/P193I mutants displayed an increase up to 5-fold in acetylcholine potency with a large decrease of the apparent Hill coefficients (significantly smaller than one). Concomitantly, the G152K/P193I mutant showed a dramatic loss of high-affinity alpha-bungarotoxin binding (100-fold decrease), thus pinpointing a new contact area for the toxin. Fitting the data with an allosteric-kinetic model, together with molecular dynamic simulations, suggests that the presence of the inter-backbone H-bond between positions 152 and 193, revealed in alpha4 and in alpha7 double mutant but not in alpha7, coincides with a large stabilization of both open and desensitized states of nicotinic receptors.     

Identification and characterization of a taxon-specific three-finger toxin from the venom of the Green Vinesnake (Oxybelis fulgidus; family Colubridae)

Snake venoms contain a variety of protein and peptide toxins, and the three-finger toxins (3FTxs) are among the best characterized family of venom proteins. The compact nature and highly conserved molecular fold of 3FTxs, together with their abundance in many venoms, has contributed to their utility in structure-function studies. Although many target the nicotinic acetylcholine receptor of vertebrate skeletal muscle, often binding with nanomolar K_ds, several non-conventional 3FTxs show pronounced taxon-specific neurotoxic effects. Here we describe the purification and characterization of fulgimotoxin, a monomeric 3FTx from the venom of Oxybelis fulgidus, a neotropical rear-fanged snake. Fulgimotoxin retains the canonical 5 disulfides of the non-conventional 3FTxs and is highly neurotoxic to lizards; however, mice are unaffected, demonstrating that this toxin is taxon-specific in its effects. Analysis of structural features of fulgimotoxin and other colubrid venom 3FTxs indicate the presence of a “colubrid toxin motif” (CYTLY) and a second conserved segment (WAVK) found in Boiga and Oxybelis taxon-specific 3FTxs, both in loop II. Because specific residues in loop II conventional α-neurotoxic 3FTxs are intimately associated with receptor binding, we hypothesize that this loop, with its highly conserved substitutions, confers taxon-specific neurotoxicity. These findings underscore the importance of rear-fanged snake venoms for understanding the evolution of toxin molecules and demonstrate that even among well-characterized toxin families, novel structural and functional motifs may be found.     

High resolution x-ray analysis of two mutants of a curaremimetic snake toxin.

A previous mutational analysis of erabutoxin a (Ea), a curaremimetic toxin from sea snake venom, showed that the substitutions S8G and S8T caused, respectively, 176-fold and 780-fold affinity decreases for the nicotinic acetylcholine receptor (AchR). In view of the fact that the side-chain of Ser8 is buried in the wild-type toxin, we wondered whether these affinity changes reflect a direct binding contribution of S8 to the receptor and/or conformational changes that could have occurred in Ea as a result of the introduced mutations. To approach this question, we solved X-ray structures of the two mutants S8G and S8T at high resolution (0.18 nm and 0.17 nm, with R factors of 18.0% and 17.9%, respectively). The data show that none of the mutations significantly modified the toxin structure. Even within the site where the toxin binds to the receptor the backbone conformation remained unchanged. Therefore, the low affinities of the mutants S8T and S8G cannot be explained by a large conformational change of the toxin structure. Although we cannot exclude the possibility that undetectable structural changes have occurred in the toxin mutants, our data support the view that, although buried between loop I and II, S8 is part of the functional epitope of the toxin.     

The mechanism for acetylcholine receptor inhibition by alpha-neurotoxins and species-specific resistance to alpha-bungarotoxin revealed by NMR

The structure of a peptide corresponding to residues 182-202 of the acetylcholine receptor alpha1 subunit in complex with alpha-bungarotoxin was solved using NMR spectroscopy. The peptide contains the complete sequence of the major determinant of AChR involved in alpha-bungarotoxin binding. One face of the long beta hairpin formed by the AChR peptide consists of exposed nonconserved residues, which interact extensively with the toxin. Mutations of these receptor residues confer resistance to the toxin. Conserved AChR residues form the opposite face of the beta hairpin, which creates the inner and partially hidden pocket for acetylcholine. An NMR-derived model for the receptor complex with two alpha-bungarotoxin molecules shows that this pocket is occupied by the conserved alpha-neurotoxin residue R36, which forms cation-pi interactions with both alphaW149 and gammaW55/deltaW57 of the receptor and mimics acetylcholine.     

Targeting of specific domains of diphtheria toxin by site-directed antibodies.

Antibodies highly selective for two functionally distinct regions of diphtheria toxin (DTx) were prepared using synthetic peptide conjugates as immunogens. Three peptides were selected for synthesis: sequence DTx141-157 on fragment A, which contains the putative protein elongation factor (EF-2) ADP-ribosyltransferase site; DTx224-237 on fragment B, selected on the basis of forming a predicted surface loop; and DTx513-526 on fragment B, forming a part of the region containing the putative receptor binding domain. All of the anti-peptide antibodies recognized the corresponding peptide, and also reacted with the toxin, specifically with the fragment containing the sequence against which they were raised, confirming the utility of this approach in generating fragment-specific antibodies. The anti-peptide antibody with the highest binding titre both to the peptide and to the native toxin was the one prepared against the sequence with the highest surface and loop likelihood indices of the three peptides selected. The similarity of the reactivity profiles with peptide and native and denatured toxin is consistent with the prediction that the region selected occurs in a surface loop and that the structure of the peptide is similar to the conformation of this region in the native protein. The epitopes for two of the anti-peptide antibodies were mapped. The results indicated that even though the antisera were raised to peptides containing 14 amino acids (aa) they were directed predominantly against a narrow region within the peptide, consisting of only 5-6 aa residues.(ABSTRACT TRUNCATED AT 250 WORDS)