Interrelationship of concanavalin-A-binding and antigenic sites on the acetylcholine receptor from Torpedo marmorata

A preparation of purified 125I-labelled acetylcholine receptor was shown to bind to concanavalin A and to be totally bound by rabbit antiserum to Torpedo acetylcholine receptor. Pre-incubation of the receptor with F(ab')2 and Fab fragments from antibodies against Torpedo acetylcholine receptor, or with corresponding fragments from control immunoglobulin G showed that subsequent binding of the receptor to concanavalin A was specifically inhibited to a maximum of approximately 25% by the immune fragments. Treatment of acetylcholine receptor with periodate or with glycosidases apparently destroyed or removed carbohydrate residues without affecting the antigenicity of the receptor as assessed by radioimmunoassay. These results suggest that although there is a steric interrelatonship between the antigenic and concanavalin-A-binding sites of the receptor the latter sites do not contain its major antigenic determinants.     

Conotoxin MI inhibits the alpha-delta acetylcholine binding site of the Torpedo marmorata receptor

The muscle-type nicotinic receptor has two pharmacologically distinguishable acetylcholine binding sites at the alpha-gamma and alpha-delta subunit interfaces; alpha-conotoxins can bind them selectively. As reported, alpha-conotoxin MI has greater affinity for the site near the alpha-delta interface of the BC(3)H1 cell receptor but, in the case of the Torpedo californica receptor, displays greater affinity for that near the alpha-gamma interface. To further investigate ligand selectivity, we study the conotoxin MI-Torpedo marmorata receptor interaction. In this work, we show the binding of alpha-conotoxin MI to the T. marmorata receptor and the influence of the antagonist alpha-Bungarotoxin and the agonist carbamylcholine on such binding; in addition, and contrasting with the results for the Torpedo californica receptor, we identify the alpha-delta subunit interface as the high affinity binding site. This is the first work describing different characteristics of the interaction between alpha-conotoxin MI and receptors from different species of the same genus.     

Two binding sites in acetylcholine receptor from Torpedo marmorata electroplax

The sensitivity of acetylcholine receptor to eleven cholinergic drugs, phospholipase A, heat and pH provided evidence that the so-called high-affinity binding (K_d for acetylcholine 11 nm in 1% Triton) and low-affinity binding (K_d 562 nm) were related to two distinct binding sites. The low-affinity binding site was less sensitive to heat and several of the cholinergic drugs, but was a little more sensitive to bungarotoxin than the high-affinity site. Zinc (0.4 mm) and EDTA (10 mm) abolished acetylcholine binding to both sites; the EDTA inhibition was time-dependent.     

Studies on the structure of the acetylcholine receptor from Torpedo marmorata

The purified acetylcholine receptor of Torpedo marmorata has been characterized by sedimentation velocity measurements on dilute solutions using an ultracentrifuge and scanner. Several preparations were studied and all exhibited sedimentation coefficients in the vicinity of 24S. In a number of experiments the receptor could be resolved into two sedimenting boundaries of 18S and 26S, corresponding to minimum molecular weights of about 5 × 10⁵ and 10⁶, respectively. Additions of sodium dodecyl sulfate or Triton X-100 resulted in marked decreases in sedimentation coefficient, while treatment with Lubrol-WX had only a slight effect on the S values. Small changes in S_20,w were produced by guanidine hydrochloride alone, although addition of dithiothreitol with 6 M guanidine hydrochloride resulted in an 8.8S component. Electrophoresis in sodium dodecyl sulfate gave one principal band with a molecular weight of 46,000.     

Amino acids of the Torpedo marmorata acetylcholine receptor alpha subunit labeled by a photoaffinity ligand for the acetylcholine binding site

The acetylcholine-binding sites on the native, membrane-bound acetylcholine receptor from Torpedo marmorata were covalently labeled with the photoaffinity reagent [3H]-p-(dimethylamino)-benzenediazonium fluoroborate (DDF) in the presence of phencyclidine by employing an energy-transfer photolysis procedure. The alpha-chains isolated from receptor-rich membranes photolabeled in the absence or presence of carbamoylcholine were cleaved with CNBr and the radiolabeled fragments purified by high-performance liquid chromatography. Amino acid and/or sequence analysis demonstrated that the alpha-chain residues Trp-149, Tyr-190, Cys-192, and Cys-193 and an unidentified residue(s) in the segment alpha 31-105 were all labeled by the photoaffinity reagent in an agonist-protectable manner. The labeled amino acids are located within three distinct regions of the large amino-terminal hydrophilic domain of the alpha-subunit primary structure and plausibly lie in proximity to one another at the level of the acetylcholine-binding sites in the native receptor. These findings are in accord with models proposed for the transmembrane topology of the alpha-chain that assign the amino-terminal segment alpha 1-210 to the synaptic cleft. Furthermore, the results suggest that the four identified [3H]DDF-labeled residues, which are conserved in muscle and neuronal alpha-chains but not in the other subunits, may be directly involved in agonist binding.     

Ligand binding to the membrane-bound acetylcholine receptor from Torpedo marmorata: a complete mathematical analysis.

We have studied by means of equilibrium binding and kinetic experiments the interaction of the membrane-bound nicotinic acetylcholine receptor (nACHR) from Torpedo marmorata with [3H]acetylcholine and the fluorescent agonist NBD-5-acylcholine. In agreement with previous studies by others, we observed the preexistence, in the absence of ligand, of an equilibrium between two states of the nAChR, one with high affinity and the other with low affinity for agonist. As additional requirements for a minimal reaction scheme, we recognized (i) the existence of two ligand-binding sites, each of which may exist in two conformational states when occupied, and (ii) ligand-induced transitions between these conformations. Employing a special form of the allosteric model which considers these requirements, we then developed a suitable algorithm in order to simultaneously fit the whole set of equilibrium binding and kinetic data obtained for the two ligands. In this way we determined for a minimal model of the mechanism of action of the nAChR the complete set of rate constants and KD values involved. With these values available, we were able to simulate the rise and fall in the concentrations of individual receptor-ligand complexes and conformations occurring in the course of excitatory events at the electrocyte synapse. The membrane environment of the nAChR plays a decisive role with respect to the rates of conformational change of the nAChR occurring in the course of ligand interaction. Thus, artificial changes in membrane structure and composition can speed up by several orders of magnitude the rate of conformational change ("desensitization"). A proper structure of the surrounding membrane hence is a prerequisite for the physiological function of the membrane-embedded nAChR.     

Binding of phencyclidine to the detergent solubilized acetylcholine receptor from Torpedo marmorata

The binding of phencyclidine to the acetylcholine receptor from Torpedo marmorata electroplaque was measured following solubilization of the receptor in sodium cholate followed by the exchange of cholate for Tween 80. In both the membrane-bound and solubilized AChR, the addition of cholinergic agonists simultaneously with the addition of PCP results in a 100 to 1000 fold increase in the PCP association rate and a 5 to 10 fold increase in the dissociation rate as compared to the unliganded AChR or AChR equilibrated with agonist prior to PCP addition. In addition, the number of binding sites and the pharmacological properties of the binding are not markedly changed in the soluble receptor. These results suggest that the acetylcholine receptor can undergo similar conformational transitions in the membrane-bound and the Tween 80 solubilized form and that phencyclidine can monitor these transitions in both cases.     

Identification of a cDNA clone coding for the acetylcholine binding subunit of Torpedo marmorata acetylcholine receptor.

A recombinant DNA plasmid has been constructed that contains sequences of the gene coding for the acetylcholine binding subunit (alpha-subunit, 40 000 daltons) of Torpedo marmorata acetylcholine receptor protein (AChR). Polyadenylated RNA purified from Torpedo electric organ was used to construct a cDNA library. The AChR alpha-subunit cDNA clone was then identified by a two-step screening of 700 recombinant clones. As AChR is present in Torpedo electric organ but not in Torpedo liver or spleen, differential screening led to the selection of 12 clones specific for the electric organ. We then tested the ability of cDNA inserts to hybridize alpha-subunit mRNA specifically, as judged by cell-free translation and immunoprecipitation. The insert from one clone, p alpha-1, selectively hybridized with a mRNA species which elicited the synthesis of a 38 000 mol. wt. polypeptide. This polypeptide was precipitated by: (1) a rabbit serum raised against purified denatured alpha-subunit (the pure alpha-subunit displaced the complex); and (2) a rat monoclonal antibody specific for the denatured alpha-subunit. It was thus identified as a precursor of the alpha chain. Blot hybridization analysis of polyadenylated RNA from Torpedo electric organ with the p alpha-1 probe revealed a major species of 2.0 kb, which thus contains approximately 800 non-coding nucleotides.     

Image analysis of the heavy form of the acetylcholine receptor from Torpedo marmorata

The structure of the heavy (H) form of the acetylcholine receptor, which comprises two covalently linked 250,000 M_r oligomers, has been investigated by numerical analysis of electron microscope images. Na-cholate solubilized Torpedo marmorata H-form receptor was reintegrated into artificial lipid vesicles and negatively stained with uranyl acetate prior to imaging in a conventional transmission microscope. The reconstituted preparations exhibited the standard polypeptide composition of the purified receptor (α₂βγδ) and the same transmembrane arrangement as in the native subsynaptic membrane. Covalent disulfide linkage between the two oligomers took place exclusively through the δ chains.In agreement with previous work (Cartaud et al., 1980) the H-form appeared as “doublets” of two coplanar 9 nm rosettes at a center-to-center distance of 9.2 ± 1.1 nm. The relative angular orientation of the two rosettes in a doublet was examined by correlation analysis in the real space. It exhibited a marked variability, few of the doublets featuring any kind of symmetry, suggesting that the two oligomers of a doublet are connected via an extended and flexible chain or loop. The area of contact between the two rosettes of a doublet therefore does not necessarily represent a reliable clue as to the location of the δ chain within the structure.Averaged images obtained after reorientation and summation of up to 132 rosettes revealed the three major peaks and the two grooves already observed in previous studies. Two additional smaller peaks were identified.Tentative assignment of structural details to individual subunits was deduced from an examination of α-bungarotoxin-labeled doublets. The α subunits, which carry part or all of the acetylcholine binding sites, are probably located in nonadjacent positions in the vicinity of the newly found peaks. This assignment is consistent with the image analysis of receptor-toxin complexes recently reported by Zingsheim et al. (1982b).     

Rapid kinetics of agonist binding and permeability response analyzed in parallel on acetylcholine receptor rich membranes from Torpedo marmorata

Excitable acetylcholine receptor rich membrane fragments from Torpedo marmorata have been used to measure, in parallel, (1) the permeability response to the fluorescent cholinergic agonist Dns-C6-Cho (in the 0.1 microM to millimolar concentration range) characterized by both the initial rate of Li+ transport and the rate of channel closure using the rapid-mixing quench-flow technique and (2) the kinetics of interaction of Dns-C6-Cho with the acetylcholine receptor sites using the rapid-mixing stopped-flow technique. Analysis of the kinetics of Dns-C6-Cho binding in the millisecond to minute time scale leads to the identification of at least three conformational states of the acetylcholine receptor: a "low-affinity" one (approximately 50 microM) that can be interconverted in the fraction of a second to a transient state of "intermediate affinity" (approximately 1 microM), followed by the final stabilization, in the second to minute time range, of a state of "high affinity" (approximately 3 nM). Comparison of Dns-C6-Cho binding data with the permeability response to the same agonist demonstrates that the binding to the low-affinity conformation(s) of the acetylcholine receptor sites coincides with the triggering of the permeability increase--or "activation"--and the transitions to the intermediate- and high-affinity states with the two-step process of channel closing--or "desensitization". The data are interpreted in terms of a minimum four-state "allosteric" model for the acetylcholine receptor.     

Site-selective agonist binding to the nicotinic acetylcholine receptor from Torpedo californica

Fluorescent energy transfer measurements of dansyl-C6-choline binding to the nicotinic acetylcholine receptor (AChR) from Torpedo californica were used to determine binding characteristics of the alpha gamma and alpha delta binding sites. Equilibrium binding measurements show that the alpha gamma site has a lower fluorescence than the alpha delta site; the emission difference is due to differences in the intrinsic fluorescence of the bound fluorophores rather than differences in energy transfer at the two sites. Stopped-flow fluorescence kinetics showed that dissociation of dansyl-C6-choline from the AChR in the desensitized conformation occurs 5-10-fold faster from the alpha gamma site than from the alpha delta site. The dissociation rates are robust for distinct protein preparations, in the presence of noncompetitive antagonists, and over a broad range of ionic strengths. Equilibrium fluorescent binding measurements show that dansyl-C6-choline binds with higher affinity to the alpha delta site (K = 3 nM) than to the alpha gamma site (K = 9 nM) when the AChR is desensitized. Similar affinity differences were observed for acetylcholine itself. The distinct dissociation rates permit the extent of desensitization to be measured at each site during the time course of binding. This sequential mixing method of measuring the desensitized state population at each agonist site can be applied to study the mechanism of AChR activation and subsequent desensitization in detail.     

Lipid-dependent recovery of alpha-bungarotoxin and monoclonal antibody binding to the purified alpha-subunit from Torpedo marmorata acetylcholine receptor. Enhancement by noncompetitive channel blockers

Recently the purified alpha-subunit from Torpedo marmorata acetylcholine receptor was shown to bind alpha-bungarotoxin with a KD approximately 3 nM in the presence of sodium dodecyl sulfate (Tzartos, S.J., and Changeux, J.P. (1983) EMBO J. 2, 381-387). Here we describe a further significant step toward renaturation of the alpha-subunit as judged by toxin and monoclonal antibody binding. Purified T. marmorata receptor subunits were diluted with 1% lipids (asolectin) plus 0.5% Na+ cholate. An anion-exchange resin eliminated most of the detergents, leaving approximately 0.1% Na+ cholate and the lipids. After this treatment, about 20% of the alpha-subunit recovered (but not the beta-, gamma-, or delta-subunit) exhibited a high affinity for radioiodinated alpha-bungarotoxin with a KD approximately 0.5 nM. The 34,000- and 27,000-dalton proteolytic peptides of the alpha-subunit conserved this lipid-dependent toxin binding. Unlabeled alpha-toxins, hexamethonium, and carbamylcholine competed with alpha-bungarotoxin for the renatured alpha-subunit. Noncompetitive channel blockers doubled the lipid-dependent toxin-binding capacity of the alpha-subunit but had no effect on the 27,000-dalton peptide. The binding of several monoclonal antibodies to the main immunogenic region (which is particularly sensitive to denaturation) significantly increased. In particular, binding of antibody 16 changed from 1% to denatured to 100% to the lipid-renaturated alpha-subunit. The binding of these antibodies was lost with the lipid-renatured 34,000- and 27,000-dalton peptides.     

Interconversion between different states of affinity for acetylcholine of the cholinergic receptor protein from Torpedo marmorata.

In receptor-rich membrane fragments from Torpedo, acetylcholine binds, in the presence of 70 muM Tetram, to a homogeneous population of high-affinity sites with Kd = (3.4 +/- 0.8) x 10(08) M. Dissolution of these membrane fragments by sodium cholate causes a decrease of affinity associated with the appearance of medium-affinity (Kd approximately 10(-7) M) and low-affinity (Kd greater than or equal to 10(-6) M) sites. Dissolution by neutral detergents Triton X-100 or Emulphogene preserves the high affinity of the acetylcholine binding sites. In all the soluble states of the receptor protein, Ca2+ ions and local anaesthetics no longer enhance the affinity for acetylcholine. Elimination of sodium cholate by dilution leads to the reassociation of the receptor protein, the recovery of high-affinity sites and the control by Ca2+ ions and local anaesthetics. Purification by affinity chromatography of the receptor protein in Triton X-100 is accompanied by a conversion of a majority of the acetylcholine sites into their state of low affinity. High-affinity sites can no longer be recovered by detergent dilution from these low-affinity ones.     

Monoclonal antibodies to Torpedo acetylcholine receptor. Characterisation of antigenic determinants within the cholinergic binding site

Thirteen monoclonal antibodies (mAb) to the acetylcholine receptor (AChR) from Torpedo marmorata showed high avidity for the receptor but none exhibited binding to muscle AChR solubilised from seven other animal species. Five mAb and Fab monomer fragments prepared from two of them, inhibited alpha-bungarotoxin (alpha BuTx) binding to receptor by a maximum of 50%. In the presence of excess mAb the 125I-alpha BuTx bound could be precipitated by anti-IgG indicating that the mAb bound to only one of the two alpha BuTx binding sites on each AChR monomer. This site appeared to have a lower affinity for d-tubocurarine and decamethonium than the non-mAb site. Binding of five anti-site mAb was mutually competitive and four of them (AS2-AS5) were inhibited by other cholinergic ligands and influenced by four non-toxin binding site antibodies. One (AS1) bound within the toxin binding site yet outside the main neurotransmitter binding region. It is concluded that these five mAb distinguish between the two alpha BuTx binding sites on the Torpedo AChR, and bind only to the site which displays lower affinity for d-tubocurarine and other competitive ligands.     

Association of spin-labeled local anesthetics at the hydrophobic surface of acetylcholine receptor in native membranes from Torpedo marmorata

The interactions between a series of spin-labeled local anesthetic analogues and the nicotinic acetylcholine receptor (AChR) have been investigated by means of electron spin resonance (ESR) and fluorescence spectroscopy. The paramagnetic local anesthetic analogues quenched the intrinsic tryptophan fluorescence of AChR-rich membranes in an agonist-dependent manner, demonstrating a direct interaction with the AChR. The quenching efficiency was greater for the benzocaine than for the thioprocaine analogue. The protein was found to restrict directly the molecular motion of the spin-labeled analogues, as seen by the appearance of a highly anisotropic component in the ESR spectrum. The relative affinity of the population of local anesthetic probes which interacts directly with the integral protein of the AChR-rich membranes was calculated on the basis of relative association constants, Kr, determined by ESR. By comparison with the relative association constant for spin-labeled phospholipid, Kro, it was possible to differentiate between local anesthetic analogues interacting with high (Kr/Kro greater than 2), intermediate (Kr/Kro = 1.6-1.9), and low (Kr/Kro less than or equal to 1.3) specificity and to calculate the fraction of protein-associated probe in each case. Differences were observed in the presence of agonist (0.1 mM carbamylcholine) with some, but not all, of the spin-labeled derivatives. The role of the protonatable diethylammonium group in the specificity of the interaction of the procaine and thioprocaine analogues was investigated. Only in the uncharged form, or in the charged form at high ionic strength, was there a preferential association of these two local anesthetic analogues.(ABSTRACT TRUNCATED AT 250 WORDS)     

Time-dependent binding of paramagnetic and fluorescent hydrophobic ions to the acetylcholine receptor from Torpedo

In receptor-rich vesicles isolated from Torpedo, paramagnetic or fluorescent phosphonium ions bind to both the acetylcholine receptor (AcChR) and the receptor membrane. When added to receptor vesicles, two to three phosphoniums undergo a slow time-dependent binding to the AcChR. The presence of agonist increases the rate but not the extent of binding of the alkylphosphonium nitroxides. Approximately one phosphonium per receptor can be displaced by the addition of saturating concentrations of the high-affinity histrionicotoxin derivative isodihydrohistrionicotoxin or by the addition of phencyclidine or quinacrine mustard. In addition, preincubation of the receptor with these channel blockers prevents approximately one phosphonium from binding to the receptor. When a series of alkyltriphenylphosphonium ions was studied, it was found that the rate of phosphonium binding to the receptor decreased with increasing probe hydrophobicity. This appears to be a function of the partitioning of the probe between membrane and aqueous phases. The phosphonium ions used here promote desensitization of the receptor, as judged by the binding rate of the fluorescent agonist NBDA-C5-acylcholine or alpha-bungarotoxin. Preincubation of the receptor with isodihydrohistrionicotoxin virtually eliminates the phosphonium-mediated desensitization. The rates of the phosphonium-mediated desensitization also appear to be dependent upon the phase partitioning of the probe. These results strongly suggest that the binding sites for the phosphonium ion (and the high-affinity histrionicotoxin blocking site) are accessible only through the aqueous phase. The phosphonium binding and agonist-induced transitions observed here are not observed with a negative hydrophobic ion probe, or a negative surface amphiphile, indicating that modifications in membrane electrostatics do not contribute to the observed changes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Targeting of acetylcholine receptor and 43 kDa rapsyn to the postsynaptic membrane in Torpedo marmorata electrocyte

In this study we have investigated the intracellular routing of two major components of the postsynaptic membrane in Torpedo electrocytes, the nicotinic acetylcholine receptor and the extrinsic 43 kDa protein rapsyn, and of a protein from the non-innervated membrane, the Na⁺, K⁺ ATPase. We isolated subpopulations of post-Golgi vesicles (PGVs) enriched either in AChR or in Na⁺,K⁺ ATPase. Rapsyn was associated to AChR-containing PGVs suggesting that both AChR and rapsyn are targeted to intracellular organelles in the secretory pathway before delivery to the postsynaptic membrane. In vitro assays further show that rapsyn-containing PVGs do bind more efficiently to microtubules compared to Na⁺,K⁺ ATPase-enriched PVGs. These data provide evidence in favor of the contribution of the secretory pathway to the delivery of synaptic components.