Allosteric interactions of the membrane-bound acetylcholine reception: kinetic studies with alpha-bungarotoxin.

The specific and irreversible reaction of a snake neurotoxin, α-bungarotoxin, with the acetylcholine receptor of electroplax membrane preparations from $\text{Electrophorus electricus}$ proceeds by an initial fast phase followed by a slower one. The fraction of the reaction in the fast phase increases with increasing initial toxin concentrations, while the fraction going slowly decreases correspondingly. Both phases are affected by compounds which initiate or inhibit nerve impulse transmissions. The time course of the reaction can be fitted to the sum of two exponentials. The dependence on initial toxin concentration of the two exponentials, and of the fraction of reaction governed by the exponentials, can be fitted to a minimum reaction mechanism which involves at least two types of toxin binding sites with different dissociation constants and ligand-induced conversion of one type of site into the other. The mechanism is consistent with our previous data which showed that activators and inhibitors of membrane electrical potential changes occupy separate sites, only half of which interact. This type of mechanism has been seen in a number of allosteric regulatory enzymes.     

Properties of α-bungarotoxin binding sites in foetal human brain

Maximum levels of binding of α-bungarotoxin to foetal human brain membranes were found to remain essentially constant at 30–50 fmol/mg protein (1.1–1.5 pmol/g wet weight in whole brain) between gestational ages of 10 and 24 weeks. Equilibrium binding of α-bungarotoxin to both membranes and to detergent extracts showed saturable specific binding to a single class of sites with K_d (app) values of 3.5 × 10^?9 M and 2.4 × 10^?9 M respectively. Association rate constants, determined from time courses of binding of α-bungarotoxin to membranes and detergent extracts, were 2.3 × 10⁵ M^?1 sec^?1 and 2.6 × 10⁵ M^?1 sec^?1 respectively. Dissociation of α-bungarotoxin from both membrane and detergent extracts showed a rapid initial rate with $\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ approx 15 min which, in the case of the detergent extract, was followed by a slower dissociation accounting for the remaining 20% of the bound ligand. Competition studies with a number of cholinergic ligands indicated that the α-bungarotoxin-binding sites in foetal brain display a predominantly nicotinic profile.     

Saturable binding to cell membranes of the presynanptic neurotoxin, β-Bungarotoxin

Brief exposure to the protein neurotoxin, β-bungarotoxin, is known to disrupt neuromuscular transmission irreversibly by blocking the release of transmitter from the nerve terminal. This neurotoxin also has a phospholipase A2 activity, although phospholipases in general are not very toxic. To determine if the toxicity of this molecule might result from specific binding to neural tissue, we have looked for high affinity, saturable binding using ¹²⁵I-labeled toxin. At low membrane protein concentration ¹²⁵I-labeled toxin binding was directly proportional to the amount of membrane; at fixed membrane concentration ¹²⁵I-labeled toxin showed saturable binding. It was unlikely that iodination markedly changed the toxin's properties since the iodinated toxin had a comparable binding affinity to that of native toxin as judged by competition experiments. Comparison of toxin binding to brain, liver and red blood cell membranes showed that all had high affinity binding sites with dissociation constants between one and two nanomolar. This is comparable to the concentrations previously shown to inhibit mitochondrial function. However, the density of these sites showed marked variation such that the density of sites was 13.0 pmol/mg protein for a brain membrane preparation, 2.4 pmol/mg for liver and 0.25 pmol/mg for red blood cell membranes.In earlier work we had shown that calcium uptake by brain mitochondria is inhibited at much lower toxin concentrations than is liver mitochondrial uptake. Both liver and brain mitochondria bind toxin specifically, but the density of ¹²⁵I-labeled toxin binding sites on brain mitochondrial prepartions ($\text{3.3 ± 0.3}\text{pmol/mg}$) exceeded by a factor of ten the density on liver mitochondrial preparations ($\text{0.3 ± 0.05}\text{pmol/mg}$). It is also shown that the labeled toxin does not cross synaptosomal membranes, suggesting that mitochondria may not be the site of action of the toxin in vivo. We conclude the β-bungarotoxin is an enzyme which can bind specifically with high affinity to cell membranes.     

Detection of nicotinic cholinergic transmission in malapteruruselectricus electrop lax

Biochemical and electrophysiological studies were conducted on the electric organ of the electric fish of the Nile, $\text{Malapterurus}$$\text{electricus}$, in order to determine if transmission was chemically mediated. There was no binding of [³H] acetylcholine, [³H] quinuclidinyl benzilate or [³H]-perhydrohistrionicotoxin; but low acetylcholinesterase activity was observed, as was binding of [¹²⁵I] α-bungarotoxin. The latter binding was detectable at 0.85 ± 0.07 pmol/g tissue, and was totally inhibited by 1 μM α-bungarotoxin or 100 μM d-tubocurarine. A tetrodotoxin-sensitive action potential was measured which was Na⁺- dependent. Depolarization (30–40 mV) was caused by carbamylcholine, and this was blocked by d-tubocurarine or α-bungarotoxin. The data suggest that this electric organ which may be a rich source for electrically excitable channels, is innervated by nicotonic cholinergic motoneurons, but the concentrations of acetylcholine receptors and acetylcholinesterase are very low.     

Pyrenesulfonyl azide: a covalent probe permitting in vitro desensitization of labeled acetylcholine-rich membrane fragments from Torpedo californica.

Acetylcholine receptor-rich membrane fragments from $\text{Torpedo}\text{californica}$ electroplax after covalent labelling at the protein-lipid boundary by nitrenes generated $\text{in}\text{situ}$ from pyrenesulfonyl azide can bind $\text{[}{}^{125}\text{I]-α-bungarotoxin}$. The covalent attachment of 6–8 molecules of the fluorescent probe/receptor molecule also does not perturb the marked effect on the rate of α-bungarotoxin binding to electroplax membranes exerted by their preincubation with carbamylcholine. This phenomenon, which is analogous to pharmacological desensitization of receptors in synaptic junctions, is fully reversible upon removal of carbamylcholine (Quast, V., Schmerlik, M., Lee, T., Witzemann, V., Blanchard, V. and Raftery, M.A. (1978) Biochemistry $\text{17}$, 2405–2414). Torpedo electroplax membranes, whether tagged with the covalent probe or freshly isolated, regain the original fast rate of α-bungarotoxin binding upon dilution of carbamylcholine.     

Half-of-the-sites reactivity of the membrane-bound Electrophorus electricus acetylcholine receptor

Equilibrium binding studies of the interaction of activators (decamethonium, carbamylcholine) and inhibitors (d-tubocurarine, α-bungarotoxin) of membrane electrical potential changes in electroplax membrane preparations from $\text{Electrophorus electricus}$ have been carried out at 4°C, in cel Ringer solution, pH 7.0. The properties of the interaction of these chemical mediators with the membrane-bound receptor appear to be similar to those observed with regulatory enzymes which exhibit an allosteric mechanism involving ligand-induced conformational changes. The data presented here show that activators and inhibitors compete for only one-half the available membrane sites. The experiments also provide additional support for the interpretation of kinetic studies which indicated that electroplax membranes contain two different binding sites, one for activators and one for inhibitors of electrical membrane potential changes.     

Binding of scorpion and sea anemone neurotoxins to a common site related to the action potential Na+ ionophore in neuroblastoma cells.

The protein neurotoxin II from the venom of the scorpion $\text{Androctonus}\text{australis}$ Hector was labeled with ¹²⁵I by the lactoperoxidase method to a specific radioactivity of about 100 μCi/μg without loss of biological activity. The labeled neurotoxin binds specifically to a single class of non intereacting binding sites of high affinity (K_D = 0.3 – 0.6 nM) and low capacity (4000 – 8000 sites/cell) to electrically excitable neuroblastoma cells. Relation of these sites to the action potential Na⁺ channel is derived from identical concentration dependence of scorpion toxin binding and increase in duration and amplitude of action potential. The protein neurotoxin II from the sea anemone $\text{Anemona sulcata}$ also affects the closing of the action potential Na⁺ ionophore in nerve axons. The unlabelled sea anemone toxin modifies ¹²⁵I-labeled scorpion toxin II binding to neuroblastoma cells by increasing the apparent K_D for labeled scorpion toxin without modification of the number of binding sites. It is concluded that both $\text{Androctonus}$ scorpion toxin II and $\text{Anemona}$ sea anemone toxin II interact competitively with a regulatory component of the action potential Na⁺ channel.     

Carbamylcholine-induced rapid cation efflux from reconstituted membrane vesicles containing purified acetylcholine receptor.

Membrane preparations containing essentially only the four polypeptides considered to constitute the acetylcholine receptor are purified from $\text{Torpedo}\text{californica}$ electroplax. Treatment of these membranes with 2% ($\text{w}\text{v}$ aqueous sodium cholate followed by removal of all insoluble matter results in a solubilized purified receptor preparation that can be reassociated with phospholipids during dialysis to remove the detergent. Such reconstituted receptor is shown to retain the capability of translocating ²²Na⁺ across the membrane in response to carbamylcholine binding in a highly reproducible manner. The dose response for this effect is similar to that observed for the original electroplax membrane preparation and the carbamylcholine induced signal is completely blocked by α-bungarotoxin.     

Extraction of peripheral proteins from nicotinic acetylcholine receptor-enriched membranes

The solubilisation of membrane proteins from nicotinic acetylcholine receptor-enriched membranes from the electric organ of Torpedo marmorata was studied. Chaotropic ions were shown to be ineffective in extracting peripheral proteins from these membranes. Two different anhydrides, 2,3-dimethylmaleic and 3,4,5,6-tetrahydrophthalic anhydride, released certain peripheral membrane proteins but not the integral receptor protein. Treatment of membranes containing $\text{> 3}\text{nmol}$ α-bungarotoxin binding sites per mg protein with anhydride resulted in a 43 kDa polypeptide as the major constituent of the solubilised material. The nature of the 43 kDa polypeptide is discussed. Gentle anhydride treatment did not change the α-bungarotoxin and carbamoylcholine binding properties of the receptor.     

The identification of an invertebrate acetylcholine receptor

The results of a series of experimental studies have culminated in the identification of an acetylcholine receptor from the invertebrate $\text{Limulus polyphemus}$. The binding ligand α-bungarotoxin was used to identify a specific protein in the central nervous system tissue of this organism. The specific interaction of α-bungarotoxin with an acetylcholine receptor has been confirmed by physiological, competitive binding, subcellular fractionation and autoradiographic techniques. The toxin binding protein was solubilized and exhibited properties consistent with the nature of a nicotinic cholinergic receptor. Therefore, the identified protein is proposed as an acetylcholine receptor protein from the central nervous system of this invertebrate species.     

The binding of the insect selective neurotoxin (AaIT) from scorpion venom to locust synaptosomal membranes

The binding of the radioiodinated insect selective neurotoxin from the venom of the scorpion Androctonus australis (AaIT), to synaptic plasma membrane vesicles derived from osmotically shocked insect synaptosomes was studied under kinetic and equilibrium conditions. The integrity of these vesicles and the existence of membrane potential and its modifiability were demonstrated by assays of the uptake of the lipophilic cation tetraphenylphosphonium. It has been shown that ¹²⁵I-labeled AaIT binds specifically and reversibly to a single class of noninteracting binding sites of high affinity ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}{}^1\text{= 1.2–3}\text{nM}$) and low capacity (1.2–2.0 pmol/mg protein). The values of the rate association and dissociation constants k₁ and k_?1 are, respectively, 1.36 · 10⁶ M^?1 · s^?1 and 1.9 · 10^?3 s^?1, and are in a good accordance with the equilibrium constant. The use of various ionophores and changes in external potassium concentration shown to modify the membrane potential of the present neuronal preparation, did not affect the binding of ¹²⁵I-AaIT, thus indicating its voltage-independence. Veratridine, tetrodotoxin, sea anemone toxin and the α and β scorpion toxins specific for vertebrates did not affect the binding of ¹²⁵I-AaIT. Furthermore, the above scorpion toxins were devoid of specific binding to the present insect neuronal preparation. Two additional insect toxins derived from the venom of the scorpion Buthotus judaicus, BjIT₁ (spastic-excitatory toxin, homologus to the AaIT) and BjIT₂ (flaccidity inducing-depressory toxin), were both shown to displace the ¹²⁵I-AaIT with a high affinity (K_d = 2.2 and 1.3 nM, respectively). These data are compared and discussed in light of the information concerning the interaction of scorpion venom toxins affecting vertebrates with mammalian neuronal tissues.     

A fluorescence probe of acetylcholine receptor conformation and local anesthetic binding

The fluorescent dye ethidium bromide binds to the acetylcholine receptor with an apparent K_d of $\text{3 μ}\text{M}$ and a stoichiometry of 1 molecule of ethidium per α-bungarotoxin site. Time dependent fluorescent increases were observed upon addition of carbamylcholine, the amplitude and half-time of which were dependent on the Carb¹ concentration. It appeared that these fluorescence increases resulted from a lowering of the K_d for ethidium as the AcChR-Carb complex underwent an isomerization from low to high affinity form(s) for carb, and more ethidium was bound. Titration with the local anesthetic procaine led to ethidium fluorescence increases at low procaine concentrations, followed by a fluorescence decrease at higher procaine concentrations to that level induced by saturating α-bungarotoxin. Thus it appeared that the ethidium binding site either interacted with or was identical with local anesthetic binding site(s).     

Chromatin protein kinases and phosphoproteins during myoblast growth and differentiation

A photolabile derivative of α-bungarotoxin which binds specifically to $\text{Torpedo}\text{californica}$ acetylcholine receptor has been used to investigate the topography of the membrane associated protein. It is shown that the toxin can be crosslinked to a polypeptide of 40,000 daltons, to which it is known to bind, and in addition to another polypeptide of 65,000 daltons which is a major constituent of the membrane. The results substantiate the notion that this nicotinic acetylcholine receptor is composed of different polypeptides and that some of these interact with each other or are in close proximity on the exterior surface of the post-synaptic membrane.     

A second mechanism for sodium extrusion in Halobacterium halobium: a light-driven sodium pump.

Membrane vesicles from a red mutant of $\text{Halobacterium}\text{halobium}$ R₁ accumulate protons when illuminated causing the pH of the suspension to rise. Sodium is extruded from the vesicles and a membrane potential is formed. This potential and the proton uptake are abolished by valinomycin if K⁺ is present. In contrast, Na⁺-efflux is uninhibited by valinomycin even though no membrane potential is detectable and H⁺ influx does not occur. $\text{Bis}$ (hexafluoracetonyl)acetone (1799) stimulates proton uptake but does not abolish membrane potential. We propose that a light-dependent sodium pump is present. Passive proton uptake occurs in response to the electrical gradient created by this light-driven Na⁺ pump in contrast to the $\text{active}$ proton, and passive Na⁺ flux that occurs in response to the light-driven proton pump described in vesicles of the parent strain of $\text{H.}\text{halobium}$ R₁.     

Mechanism of action of Clostridium perfringens enterotoxin. Effects on membrane permeability and amino acid transport in primary cultures of adult rat hepatocytes

Purified enterotoxin from the bacterium Clostridium perfringens rapidly decreased the hormonally induced uptake of α-aminoisobutyric acid in primary cultures of adult rat hepatocytes. At 5 min after toxin addition the decrease in α-aminoisobutyric acid uptake appeared not due to increased passive permeation (estimated with l-glucose) or to increased α-aminoisobutyric acid efflux. When short uptake assay times were employed a depression of α-aminoisobutyric acid influx was observed in toxin-treated hepatocytes. The depression of α-aminoisobutyric acid influx was correlated with a rapid increase in intracellular Na⁺ (estimated using ²²Na⁺) apparently effected by membrane damage. In contrast, the uptake of cycloleucine in the presence of unlabeled α-aminoisobutyric acid (assay for Na⁺-independent amino acid uptake) by hepatocytes treated with toxin for 5 min was decreased to only a small extent or not at all depending upon experimental design. At later times, C. perfringens enterotoxin increased the exodus of l-glucose, $\text{3-O-}\text{methylglucose}$ and α-aminoisobutyric acid from pre-loaded cells indicating that the toxin effects progressive membrane damage. When enterotoxin was removed by repeated washing after 5–20 min the decay of α-aminoisobutyric acid uptake ceased and appeared to undergo recovery towards the hormonally induced control level. The degree of recovery of α-aminoisobutyric acid uptake was inverse to the length of time of exposure to toxin. Adding at 10 min specific rabbit antiserum against C. perfringens enterotoxin without medium change also reversed the effect of toxin on increased intracellular ²²Na⁺, and on the exodus (from preloaded cells) of α-aminoisobutyric acid, L-glucose, and $\text{3-O-}\text{methylglucose}$.     

Effects of thiol modification and Ca++ on agonist-specific state transitions of nicotinic acetylcholine receptor from Torpedo californica electroplax.

The agonist binding affinity of nicotinic acetylcholine receptor (nAChR) from $\text{Torpedo}$$\text{californica}$ electroplax, as inferred from ability of agonist to inhibit specific curaremimetic neurotoxin binding to nAChR, is sensitive to the duration of exposure to agonist. The concentration of carbachol necessary to prevent one-half of toxin binding over a 30 min incubation with nAChR (K₃₀) is 10 μM when toxin and carbachol are simultaneously added to membrane-bound nAChR, and 3 μM when nAChR are pretreated with carbachol for 30 min prior to the addition of toxin. These alterations in agonist affinity may be mimicked by modification of nAChR thiol groups. Affinity of nAChR for carbachol is decreased following treatment with dithiothreitol (DTT). Dithio-bis-nitrobenzoic acid treatment of DTT-reduced membranes yields K₃₀ values of 5 μM for carbachol, while N-ethylmaleimide treatment of DTT-reduced nAChR produces nAChR with reduced affinity for carbachol, reflected in K₃₀ values of about 400 μM. In the absence of Ca⁺⁺, K₃₀ values for carbachol binding to native and DTT-reduced nAChR are diminished 3–6 fold. These affinity alterations are not observed with d-tubocurarine (antagonist) binding to nAChR. Thus, Ca⁺⁺ and the oxidation state of nAChR thiols appear to affect the affinity of nAChR for agonists (but not antagonists), and may therefore be related to agonist-mediated events in receptor activation and/or desensitization.     

A stereoselective pentobarbital binding site in cholinergic membranes from Torpedocalifornica

Acetylcholine receptor-rich membranes from $\text{Torpedo}\text{californica}$ contain a binding site for [¹⁴C] pentobarbital which has a dissociation constant of 210 ± 24 μM and 1.4 ± 0.18 sites per acetylcholine site. (+) pentobarbital competes for this site three times more effectively than (?) pentobarbital. Cholinergic ligands decrease [¹⁴C] pentobarbital binding and this effect is blocked by pre-incubation with α-bungarotoxin. Pentobarbital decreases [³H] acetylcholine binding non-competitively with an apparent dissociation constant similar to the dissociation constant for [¹⁴C] pentobarbital binding. Thus, the pentobarbital and acetylcholine binding sites appear to interact with each other allosterically.     

Catecholamine receptors and cyclic AMP formation in the central nervous system: effects of tetrahydroisoquinoline derivatives.

The ability of a series of tetrahydroisoquinoline (THIQ) alkaloids to inhibit the binding of radioligands to catecholamine receptors in the CNS has been examined. $\text{(+)}$ THP was the most potent inhibitor of [³H] dihydroalprenolol binding to β-adrenergic receptors and of [³H] haloperidol to dopaminergic receptors and was the least potent inhibitor of [³H] WB-4101 binding to α-adrenergic receptors. Other THIQ alkaloids examined such as salsoline, salsolinol, and reticuline were less potent than $\text{(+)}$ THP in inhibiting radioligand binding to β-adrenergic and dopaminergic receptors, and more potent than $\text{(+)}$ THP in inhibiting radioligand to α-adrenergic receptors. The marked potency of $\text{(+)}$ THP in inhibiting radioligand binding to β-adrenergic receptors (IC₅₀ ～ 10^?7 M) was confirmed by the potency of this compound in inhibiting (?) isoproternol elicited accumulations of cyclic AMP in brain slice preparations. These data indicate that, if formed $\text{in}$$\text{vivo}$ during alcohol consumption, THIQ derivatives such as THP may affect catecholamine neurons in the CNS.     

Transport of alpha-methyl glucoside in mutants of Escherichia coli K12 deficient in Ca2+, Mg2+-activated adenosine triphosphatase.

The initial rate of uptake of methyl α-D-glucopyranoside by $\text{Escherichia coli}$ is inhibited by respiration. The inhibition is more pronounced in mutant strains which cannot use the energy-rich state of the membrane to form ATP because of a defective Ca²⁺, Mg²⁺-activated ATPase. In both mutant and normal strains, the inhibition of glucoside uptake is not accompanied by an increase of the ATP content of the cells and is abolished by carbonyl cyanide $\text{m}$-chlorophenylhydrazone, a drug which dissipates membrane energy. It appears, therefore, that the inhibitory effect of respiration is mediated by the energy-rich state of the membrane and that ATP does not participate in the inhibition.     

Demonstration of separate binding sites for the folate coenzymes and deoxynucleotides with inactivated Lactobacilluscasei thymidylate synthetase

In contrast to (+)5,10-methylenetetrahydropteroylmonoglutamate which does not bind to $\text{Lactobacillus}\text{casei}$ thymidylate synthetase, the corresponding tetraglutamate analog binds to a single site with a K_D = 2 × 10^?5 M. Alkylation of one of the enzyme's four cysteines with N-ethylmaleimide or iodoacetate prevented the binding of dUMP, but did not affect the binding of the pteroyltetraglutamate. Inactivation of the synthetase with carboxypeptidase A, however, prevented the binding of (+)5,10-methylenetetrahydropteroyltetraglutamate but not that of dUMP. The binding of (+)5,10-methylenetetrahydropteroyltetraglutamate to native enzyme was associated with the appearance of a positive circular dichroic band at 303 nm ([θ] = 7 × 10⁴ deg·cm²dmol^?1). The latter effect was not impaired by the inhibition of the enzyme with N-ethylmaleimide, whereas formation of the ternary complex, coenzyme-synthetase-FdUMP, was prevented by alkylation. These studies reveal that thymidylate synthetase can be inactivated in a manner that does not prevent the binding of the substrates individually.