The relationship between agonist occupation and the permeability response of the cholinergic receptor revealed by bound cobra alpha-toxin.
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The decrement in functional capacity of the nicotinic receptor on intact BC3H-1 cells has been simultaneously compared with the fractional occupation of the receptor by cobra alpha-toxin. A parabolic, concave inward relationship between the fractional occupation of receptors by alpha-toxin and the decrement in permeability response is observed when the latter is tested over a range of agonist concentrations. Since alpha-toxin binding appears equivalent at each site on the receptor, the observed relationship is accommodated by a model where activation of a permeability response requires agonist occupation of two toxin-binding sites per functional receptor. Furthermore, the binding of alpha-toxin and agonist appears to be mutually exclusive, but occupation of either of the two sites by alpha-toxin is sufficient to block the functional capacity of the receptor. Consistent with this model, when a major fraction of sites is occupied by alpha-toxin, the concentration dependence for either carbamylcholine-mediated activation or desensitization of the remaining functional receptors is not detectably altered and retains positive cooperativity. In contrast, progressive occupation of the available sites by alpha-toxin leads to a decrease in apparent affinity and a corresponding loss of positive cooperation for agonist occupation functions generated upon instantaneous or following equilibrium exposure to the agonist. At high degrees of fractional occupancy to alpha-toxin, where the dominant species capable of binding agonist would contain a single bound toxin molecule, the Hill coefficient for the equilibrium occupation function for full agonists falls from a value of 1.4 to 0.7. By contrast, the binding isotherms for antagonists which typically exhibit values less than 1.0 are not altered following fractional irreversible occupation by alpha-toxin. Thus, the two binding sites on the receptor oligomer are not intrinsically equivalent for the binding of agonists and reversible antagonists. A scheme for desensitization of the receptor is presented which incorporates both nonequivalence in the two agonist binding-sites and the maintenance of symmetry in the receptor states undergoing transitions. (+info)
Determination of soluble nAChR-binding activity of alpha-neurotoxins by an innovative precipitation with DEAE-Sephacel.
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A simple and convenient method for determining the binding activity of alpha-neurotoxins toward soluble nicotinic acetylcholine receptor (snAChR) by precipitation with DEAE-Sephacel was established. The determination was carried out by incubation of 125I-neurotoxin with snAChR, followed by precipitation with DEAE-Sephacel. The DEAE-Sephacel particles bind negatively charged snAChR with high affinity and simultaneously precipitate the 125I-neurotoxin bound to the receptors. After centrifugation, the free 125I-neurotoxin in the supernatant was counted, and the amounts of neurotoxins bound to snAChR could be determined. Two alpha-neurotoxins, cobrotoxin and alpha-bungarotoxin, were employed to verify the feasibility of this determination. The different binding characteristics of cobrotoxin and alpha-bungarotoxin to snAChR could be distinguished. This method required only small quantities of DEAE-Sephacel (7 mg), snAChR (0.54 micrograms), and 125I-neurotoxin (90 fmol) for each reaction, and minimized the handling of isotopic materials as compared with the conventional methods. This method is reliable, reproducible, and superior to current methods for the determination of the snAChR-binding activity for alpha-neurotoxins. (+info)
The structural loop II of cobrotoxin is the main binding region for nAChR and epitope in the region is conformation-dependent.
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Modification of positively charged residues, Lys and Arg, in cobrotoxin revealed that Lys-27, Lys-47, Arg-28, Arg-30, Arg-33, and Arg-36 of cobrotoxin were essential for the lethality and binding activity to nicotinic acetylcholine receptor (nAChR). The antigenicity of cobrotoxin was drastically diminished when Lys-47, Arg-28, Arg-30, Arg-33, and Arg-36 were modified, while that of the Lys-27-modified derivative was not significantly changed. The CD spectra of cobrotoxin displayed similar patterns after modification of Lys-27, Lys-47, and Arg-28. These findings suggest that Lys-27, Lys-47, and Arg-28 residues may be related to the direct binding to nAChR, and that there is no involvement of Lys-27 in the antigenic determinants of cobrotoxin. Extending the modification to Arg-30, Arg-33, and Arg-36 caused progressive conformational changes of cobrotoxin and resulted in decreased binding activity to antibody and nAChR. This indicates that Arg-30, Arg-33, and Arg-36 may be of structural importance for maintaining the active conformation of cobrotoxin. These results, together with the facts that Tyr-25, Tyr-35, and Trp-29 of cobrotoxin are important in nAChR binding activity, but Trp-29 and Tyr-35 residues are not essential for the antigenicity, suggest that the structural loop II of cobrotoxin is the main binding region for nAChR and the epitope in that region is conformation-dependent. (+info)
Photolabeling reveals the proximity of the alpha-neurotoxin binding site to the M2 helix of the ion channel in the nicotinic acetylcholine receptor.
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A photoactivatable derivative of neurotoxin II from Naja naja oxiana containing a 125I-labeled p-azidosalicylamidoethyl-1,3'-dithiopropyl label at Lys-25 forms a photo-induced cross-link with the delta subunit of the membrane-bound Torpedo californica nicotinic acetylcholine receptor (AChR). The cross-linked radioactive receptor peptide was isolated by reverse-phase HPLC after tryptic digestion of the labeled delta subunit. The sequence of this peptide, delta-(260-277), and the position of the label at Ala-268 were established by matrix-assisted laser-desorption-ionization mass spectrometry based on the molecular mass and on post-source decay fragment analysis. With the known dimensions of the AChR molecule, of the photolabel, and of alpha-neurotoxin, finding the cross-link at delta Ala-268 (located in the upper part of the channel-forming transmembrane helix M2) means that the center of the alpha-neurotoxin binding site is situated at least approximately 40 A from the extracellular surface of the AChR, proximal to the channel axis. (+info)
Analysis of a conformation-independent epitope and a conformational epitope in a protein: a study on cobrotoxin from Taiwan cobra venom.
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The antibodies against cobrotoxin were separated into two antibody preparations by successive affinity chromatographies on reduced and S-carboxymethylated (RCM)-cobrotoxin-Sepharose, and cobrotoxin-Sepharose columns. The antibodies (abbreviated as Abcf-i) that bound with the RCM-cobrotoxin-Sepharose were verified to specifically recognize the continuous epitopes of cobrotoxin, which were insensitive to conformational changes. Whilst the antibodies (abbreviated as Abcf-d) that did not bind with the RCM-cobrotoxin-Sepharose column recognized the conformational epitopes in cobrotoxin. The two antibody preparations were employed to screen the antigenic peptides derived from the proteolytic hydrolysate of cobrotoxin and RCM-cobrotoxin. Five antigenic peptides (AP-4, AP-5, AP-10, AP-11, and AP-12) were obtained from the acid protease A-digested hydrolysate of cobrotoxin, and two antigenic peptides (V8-2 and V8-4) were found in the hydrolysate of RCM-cobrotoxin after hydrolysis with Saccharomyces aureus V8 protease. The segments at positions 1-21 and 22-38 encompassed the peptide fractions, AP-4, AP-5, V8-2, and V8-4, that reacted with Abcf-i, indicating that the two segments bore the continuous epitopes of cobrotoxin. Alternatively, AP-10, AP-11, and AP-12 reacted with both Abcf-i and Abcf-d. The structures of the three peptides had a common segment at positions 43-62, suggesting that this region comprised the conformation-independent epitopes as well as conformational epitopes in cobrotoxin. These results reflected that the conformation-independent and conformational epitopes in a protein can be separately identified. (+info)
Immunological neutralization of cobrotoxin by its homologous precipitin and non-precipitin antibodies.
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Anti-cobrotoxin antibodies can be separated into precipitin and non-precipitin antibodies. The precipitin antibody possesses the same binding affinity to cobrotoxin as non-precipitin antibody, but the neutralizing capability of the latter is superior to that of the former in blocking cobrotoxin binding to nicotinic acetylcholine receptor (nAChR). After preincubation with antibodies, cobrotoxin completely lost its binding activity to nAChR. The dissociation of cobrotoxin-nAChR complex by the antibodies was low, and 60% of the complex formation appeared to be irreversible. These results indicate that the neutralization of cobrotoxin by the antibody may predominantly involve unbound, receptor-free cobrotoxin. The relationships of neutralization capacity and binding affinity as well as bond strength between cobrotoxin and its antibodies are incongruous. Different local conformational changes of a unique Trp in cobrotoxin on binding with the precipitin and non-precipitin antibodies seem to lead to different accessibility for fluorescence quenchers. Characterization of the binding domains by immunoprecipitation with the antibodies correlated with the quenching results. Thus, the binding topography of cobrotoxin may play an important role over the binding affinity and bond strength in neutralization by cobrotoxin antibody. (+info)
A new class of photoactivatable and cleavable derivatives of neurotoxin II from Naja naja oxiana. Synthesis, characterisation, and application for affinity labelling of the nicotinic acetylcholine receptor from Torpedo californica.
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A new series of photoactivatable and cleavable derivatives of neurotoxin II from the cobra Naja naja oxiana is investigated which can be used for mapping the surface topology of the nicotinic acetylcholine receptor from Torpedo electric tissue. The preparation and characterisation of five toxin derivatives, each with a radioactive 125I-azidosalicylamidoethyl-1,3'-dithiopropyl group in a defined position within the primary structure, are described. The photoinduced cross-linking reaction of the toxin derivatives with membrane-bound receptor is investigated. The photoactivatable group located at position K25 reacts almost exclusively with the delta subunit of the receptor, whereas the K15 derivative reacts with the alpha and beta subunits. The other derivatives did not react with the receptor to any significant extent. It is shown that, with respect to the receptor subunits, the cross-linking pattern depends on the length and chemical nature of the cross-linking group. (+info)
Snake venom toxins, unlike smaller antagonists, appear to stabilize a resting state conformation of the nicotinic acetylcholine receptor.
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Previous studies have shown that the pattern and degree of 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID) photoincorporation into the nicotinic acetylcholine receptor (nAChR) can be used as a sensitive measure of nAChR conformation. Upon desensitization by prolonged exposure to agonists, certain drugs and detergents, or reconstitution into desensitizing lipids, the levels of [125I]TID incorporation into the subunits of the nAChR are dramatically reduced. In this study, we characterized the effects of the snake venom proteins alpha-bungarotoxin and alpha-cobrotoxin, as well as the smaller antagonists tubocurarine and gallamine, on [125I]TID incorporation into the subunits of both partially-purified nAChR in native lipids, or affinity-purified nAChR reconstituted into different combinations of lipids. Unlike all other compounds previously tested, alpha-bungarotoxin and alpha-cobrotoxin reproducibly increased the level of [125I]TID incorporation into all four subunits of nAChR reconstituted into dioleoylphosphatidylcholine, dioleoylphosphatidic acid and cholesterol. Gallamine had little or no effect on [125I]TID incorporation at any concentration tested (0.1 microM-5 mM). Tubocurarine had no effect on [125I]TID incorporation at low concentrations, but at higher concentrations reduced the level of [125I]TID labeling. The snake venom proteins may shift the population of nAChR, which exists as a mixture of resting state and desensitized conformations, entirely to the resting state. However, the binding of the snake venom toxins does not appear sufficient to induce the resting state conformation in nAChR which have been desensitized by other means, such as solubilization in desensitizing detergents or reconstitution in densitizing lipids. (+info)