Molecular size of the tetrodotoxin binding site estimated by irradiation inactivation

Posttranslational Modification of Sodium Channels

Voltage-gated sodium channels (VGSCs) are critical determinants of excitability. The properties of VGSCs are thought to be tightly controlled. However, VGSCs are also subjected to extensive modifications. Multiple posttranslational modifications that covalently modify VGSCs in neurons and muscle have been identified. These include, but are not limited to, phosphorylation, ubiquitination, palmitoylation, nitrosylation, glycosylation, and SUMOylation. Posttranslational modifications of VGSCs can have profound impact on cellular excitability, contributing to normal and abnormal physiology. Despite four decades of research, the complexity of VGSC modulation is still being determined. While some modifications have similar effects on the various VGSC isoforms, others have isoform-specific interactions. In addition, while much has been learned about how individual modifications can impact VGSC function, there is still more to be learned about how different modifications can interact. Here we review what is known about VGSC posttranslational modifications with a focus on the breadth and complexity of the regulatory mechanisms that impact VGSC properties.

The ionic channels in excitable membranes

The ionic channels in excitable membranes are of two classes: those that open and close when the membrane potential alters and those that respond to the release of an appropriate chemical transmitter. The former are responsible for the conduction of impulses in nerve and muscle fibres and the latter for synaptic transmission. It is now clear that the sodium and potassium channels in electrically excitable membranes are functionally distinct, since each can be blocked without affecting the behaviour of the other. It has recently proved possible to study, in the voltage-clamped squid giant axon, the movements of the mobile charges or dipoles that form the voltage-sensitive portion of the sodium channels, which give rise to the so-called 'gating' current. Detailed comparisons can now be made between the kinetics of the ionic conductances as described by Hodgkin & Huxley, and the steady-state distribution and kinetics of the charged controlling particles, which should lead to useful conclusions about the intramolecular organization of the sodium channels and the conformational changes that take place under the influence of the electric field. There is as yet little information about the chemical nature of the electrically excitable channels, but significant progress has been made towards the isolation and characterization of the acetylcholine receptors in muscle and electric organ.

Docking of mu-conotoxin GIIIA in the sodium channel outer vestibule

mu-Conotoxin GIIIA (mu-CTX) is a high-affinity ligand for the outer vestibule of selected isoforms of the voltage-gated Na(+) channel. The detailed bases for the toxin's high affinity binding and isoform selectivity are unclear. The outer vestibule is lined by four pore-forming (P) loops, each with an acidic residue near the mouth of the vestibule. mu-CTX has seven positively charged residues that may interact with these acidic P-loop residues. Using pair-wise alanine replacement of charged toxin and channel residues, in conjunction with double mutant cycle analysis, we determined coupling energies for specific interactions between each P-loop acidic residue and selected toxin residues to systematically establish quantitative restraints on the toxin orientation in the outer vestibule. Xenopus oocytes were injected with the mutant or native Na(+) channel mRNA, and currents measured by two-electrode voltage clamp. Mutant cycle analysis revealed novel, strong, toxin-channel interactions between K9/E403, K11/D1241, K11/D1532, and R19/D1532. Experimentally determined coupling energies for interacting residue pairs provided restraints for molecular dynamics simulations of mu-CTX docking. Our simulations suggest a refined orientation of the toxin in the pore, with toxin basic side-chains playing key roles in high-affinity binding. This modeling also provides a set of testable predictions for toxin-channel interactions, hitherto not described, that may contribute to high-affinity binding and channel isoform selectivity.

Molecular aspects of human brain sodium channel

The sodium channel content of human brain was measured by tritiated tetrodotoxin specific binding. After solubilization, the sodium channel was submitted to chromatography on diethylaminoethyl(cellulose) Sephadex, hydroxylapatite and wheat germ agglutinin sepharose. An increase of tritiated tetrodotoxin binding specific activity was subsequently observed. Eluted sodium channels from wheat germ agglutinin sepharose were overlaid on a sucrose gradient. Electrophoretical analysis of the material obtained after the sedimentation step revealed two co-purified peptides, alpha (Mr = 275,000 mol. wt) and beta (Mr = 30,000-36,000 mol. wt.). Alpha showed an exceptionally high free electrophoretic mobility, which is a common feature for all sodium channels previously described. However, the high denaturation rate of the solubilized tetrodotoxin receptor site 1 did not allow tetrodotoxin receptor quantification by the tritiated toxin binding in sucrose fractions. Sodium channel effective reconstitution in liposomes was demonstrated: (1) 22Na+ influx in proteoliposomes was sensitive to sodium channel-specific neurotoxins: (2) reconstituted proteins showed a cation selectivity similar to that previously described for animal sodium channels. The sodium channel preparation obtained after four chromatographic steps shows two peptides on the electrophoretic analysis. Reconstituted sodium channels displayed some physiological properties found in intact conducting membranes.

Specific modulation of sodium channels in mammalian nerve by monoclonal antibodies

Monoclonal antibodies (mAbs) were generated against the sodium channels in the intact membrane of the eel electroplax. These antibodies bind to nodes of Ranvier, as indicated by immunofluorescence. When externally applied to rat nerve fibers one of these mAbs blocks impulse conduction. In voltage-clamp experiments, this mAb was found to attenuate sodium current amplitude without affecting the time course. The dose-response curve was very steep and had an ED50 of 133 nM. About half of the mAb effect was shown to be due to a shift, in the hyperpolarizing direction, of the steady-state sodium inactivation versus membrane potential curve. The remaining effect was voltage- and time-independent. This mAb had no effect on the potassium or leakage currents. The results indicate that on the external surface of the sodium channel, there are a number of antigenically similar determinants, which are functionally linked to specific elements of the sodium conductance system. These functionally related determinants were preserved through the course of evolution.

Solubilization and partial purification of putative calcium channels labelled with [3H]-nimodipine

High-affinity binding sites for the potent 1,4-dihydropyridine calcium channel blocker [3H]-nimodipine were solubilized from guinea-pig skeletal muscle microsomes with digitonin and CHAPS [3-(3-cholamidopropyl)-dimethyl-ammonio-l-propanesulfonate]. Detergent-solubilized binding sites could not be sedimented by centrifugation (50,000 X g, 4 h), passed freely through 0.2 micron nitrocellulose filters and were stable at 4 degrees C with half-lives of greater than 60 h. The solubilized 1,4-dihydropyridine binding sites were precipitable with polyethyleneglycol 6000 on Whatman GF/C filters. Saturation analysis of solubilized microsomes with [3H]-nimodipine revealed a single class of binding sites (Bmax = 0.5 to 1.7 pmol per mg of protein) with a KD of 2.2-3.6 nmol/l at 37 degrees C. Specific binding of the 1,4-dihydropyridine calcium channel label was fully reversible (k-1 = 1.5 min-1, at 37 degrees C). The solubilized drug receptors discriminated between the optical enantiomers of chiral 1,4-dihydropyridine calcium channel blockers, (-)- and (+)D-600 as well as between l-cis and d-cis-diltiazem. d-cis-Diltiazem stimulated the binding of [3H]-nimodipine (ED50:3.6 mumol/l), by increasing the Bmax and slowed the dissociation rate of the labelled 1,4-dihydropyridine calcium channel blocker. The solubilized binding sites were sensitive to pronase, alpha-chymotrypsin and phospholipases A and C indicating their protein nature as well as their lipid requirement. Chelation of endogeneous divalent cations by EDTA, EGTA or CDTA inhibits high-affinity [3H]-nimodipine binding, demonstrating that divalent cations are required for high affinity [3H]-nimodipine binding. Detergent-solubilized binding sites are adsorbed by several sepharose-immobilized lectins, including concanavalin A, wheat germ agglutinin and lentil-lectin but not by helix pomatia lectin. Preparative chromatography on concanavalin A sepharose was performed and the adsorbed [3H]-nimodipine binding sites were selectively eluted by alpha-methylmannoside; NaCl (1 mol/l) being completely ineffective as elutant. The purification factors by this method were 17-40-fold. The binding sites could be also purified (up to 10-fold) by sucrose density centrifugation. The S20, w value of the drug receptors is 12.9 s. It is concluded that the 1,4-dihydropyridine binding sites of the putative calcium channel are intimately associated with carbohydrate containing structures. Since the detergent-solubilized material shows allosteric regulation of 1,4-dihydropyridine binding, interaction with chemically different classes of calcium channel blockers, metalloprotein nature and a S20, w value which is indicative of structure large enough to span the membrane, we conclude that we have solubilized and partially purified the putative calcium channel.

Affinity labelling of the tetrodotoxin-binding component of the Na+ channel

Tetrodotoxin-binding sites were covalently labelled with a highly tritiated derivative of tetrodotoxin. Cross-linking experiments, using dissucinimidyl suberate, on partially purified tetrodotoxin-binding component from electroplax of Electrophorus electricus, revealed covalent labelling of a single polypeptide chain of MW 270,000.

Purification of binding protein for Tityus gamma toxin identified with the gating component of the voltage-sensitive Na+ channel

The gating component associated with the voltage-sensitive Na+ channel from electroplax membranes of Electrophorus electricus has been purified by using toxin gamma from the venom of the scorpion Tityus serrulatus serrulatus. The toxin-binding site was efficiently solubilized with Lubrol PX, resulting in an extract of high initial specific activity. Purification was achieved by adsorption of the toxin-binding component to DEAE-Sephadex A-25 followed by desorption at high ionic strength and chromatography on either wheat germ agglutinin-Ultrogel or Sepharose 6B. Maximal final specific activities were at least 42% of the specific activity expected for a pure toxin-binding component. The purified material exhibited a Stokes radius of 85 A, and sodium dodecyl sulfate/polyacrylamide gel electrophoresis demonstrated a single polypeptide component of Mr 270,000. Furthermore, tetrodotoxin binding activity and Tityus gamma toxin binding activity copurified, suggesting that the selectivity filter and the gating component of the Na+ channel are carried by the same polypeptide chain.

Determination of the molecular size of the nitrendipine-sensitive Ca2+ channel by radiation inactivation

The molecular size of the [3H] nitrendipine receptor of transverse tubules prepared from rabbit skeletal muscle and from rat cortex synaptic membranes have been investigated. Radiation inactivation of the specific binding of [3H] nitrendipine was consistent with Mr equals 210 000 +/- 20,000 for the receptor in each membrane preparation indicating a common size for the [3H] nitrendipine receptor.

Immunocytochemical localization of sodium channel distributions in the excitable membranes of Electrophorus electricus

The tetrodotoxin binding protein, a major component of the Na+ channel, has been purified from the electric organ of the South American eel Electrophorus electricus. Antibodies to this protein were raised in rabbits and their specificity was demonstrated by a highly sensitive radioimmunoassay and by immunoprecipitation procedures. These antibodies were used to examine the distribution of the binding protein in the eel electroplax membranes and along myelinated nerve axons. The distribution of the antigen was determined by using the peroxidase-antiperoxidase technique at both the light and electron microscopic levels. In the electrocytes of the electric organ, only the innervated face showed staining in experimental material. The stained regions of electroplax plasmalemma included the caveolae of the innervated surface while caveolae of the non-innervated surface did not stain. Thus, the innervated surface including caveolae exclusively contains the Na+ channels. Along myelinated axons, staining was limited to the nodal zone of the node of Ranvier. The paranodal and internodal zones did not stain for the binding protein. Limited diffusion of primary IgG and subsequent reactants into the paranodal and internodal sites was eliminated as a possible source of focal staining at nodes because mechanically demyelinated preparations also exhibited focal nodal staining. Thus, this tetrodotoxin binding protein component of the Na+ channel is located solely within the nodal zone of the node of Ranvier.

Electron microscopic visualization of the tetrodotoxin-binding protein from Electrophorus electricus

Preparations of highly purified tetrodotoxin-binding protein (sodium channel) from the electric organ of the eel Electrophorus electricus were examined in negatively stained preparations. Structures observed in preparations exhibiting the highest tetrodotoxin binding tended to aggregate into ordered clusters with a unique ribbon-like conformation. The individual particles of these aggregates are elongated or rod-shaped, approximately 40 A wide and 170 A long. Stereoscopic imaging of the three-dimensional aspects of the structures revealed that the rod-like image is not an edge view of a flattened disc but represents a cylindrical structure. Individual rods in nonclustered forms were also observed but with greater frequency in preparations with lower specific activity. The dimensions of the particles suggest that they represent a protein core formed by perhaps one copy of the large glycopeptide previously identified as being part of the sodium channel. The structure of the sodium channel component visualized by negative staining is discussed in the context of the excitable properties it contributes to biological membranes.

Axoglial junctions in the mouse mutant Shiverer

Analysis of Shiverer central nervous tissue by the freeze-fracture method shows that axoglial junctions of the type found normally in the paranodal region occur commonly despite the gross reduction in myelin. On a substructural level these junctions appear identical to those that form between paranodal oligodendroglial processes and axolemma. On a grosser level, however, they are bizarre in shape, arrangement and distribution. Isolated glial processes, or small sheaves of them, course among axons and form such junctions in an irregular patchy manner, usually without apparent relationship to paranodal regions. These aberrant junctions may be oriented transversely, obliquely or longitudinally with respect to the axonal axis. Axolemmal E face particle accumulations, which characterize normal nodes of Ranvier, are usually not found in the membrane adjacent to the aberrant junctional patches. Thus, axoglial junctional specializations of the paranodal type can form in this mutant in the absence of the myelin proteins that are deficient in Shiverer, and such junctions may appear in areas not related to other paranodal or nodal structures. The relevance of these findings to differentiation of the axolemma and to the neurological defects in this mutation is discussed.

Batrachotoxinin-A 20-alpha-benzoate: a new radioactive ligand for voltage sensitive sodium channels

Batrachotoxinin-A 20-alpha-benzoate (BTX-B), an analog of the potent depolarizing agent batrachotoxin (BTX), was prepared by selective esterification of naturally occurring batrachotoxin-A with benzoic acid. BTX-B depolarized rat phrenic nerve-diaphragm preparations with a time course and concentration dependence virtually indistinguishable from that of BTX. A specific, saturable component of equilibrium binding of [3H]BTX-B to mouse cerebral cortex homogenates was measured, described by an equilibrium dissociation constant of 0.7 microM and a maximum number of binding sites of 90 pmol per gram of tissue (wet weight). Specific binding is inhibited by BTX and other BTX analogs, veratridine, and grayanotoxin but is unaffected by tetrodotoxin and cevine. Under conditions of this assay, neither crude Leiurus quinquestriatus scorpion venom nor purified sea anemone toxin have any effect of specific binding. The data support the conclusion that BTX-B interacts with a recognition site associated with voltage sensitive sodium channels which is identical to the recognition site for BTX.

Nodal and paranodal membrane structure in complementary freeze-fracture replicas of amphibian peripheral nerves

Complementary freeze-fracture replicas of frog peripheral nerves have revealed new details of membrane structures at the node of Ranvier and paranodal axon-Schwann cell junction. At the node both E and P fracture faces of the axolemma have high particle concentrations (approximately 1350/sq. micron and 1600/sq. micron respectively) and these particles do not overlap when tracings from the respective fracture faces are superimposed. A high proportion of the E face particles are large (> 9.5 nm) and cast long shadows while the proportion of large particles in the P face is much lower. In the paranodal region the diagonal pattern of parallel rows in the junctional axolemma always has the same orientation within a given fracture face. In the E face, the parallel rows form a positive (+ 30 degrees) angle to the groove below and in the P face, a negative (-30 degrees) angle to the ridge above. This implies that the diagonal pattern derives from asymmetric subunits that are able to associate along only one axis and are unable to 'flip over' with respect to the junctional membranes.

Nucleoside transport in human erythrocytes. Apparent molecular weight of the nitrobenzylthioinosine-binding complex estimated by radiation-inactivation analysis

Nitrobenzylthioninosine, a potent nucleoside-transport inhibitor, binds specifically to functional nucleoside transport sites. Irradiation of freeze-dried human erythrocyte membranes with high-energy electrons was used to estimate the apparent molecular weight of the nitrobenzylthioninosine-binding complex in situ. The nitrobenzylthioinosine-binding complex had an apparent mol.wt. of 122000.

Size characteristics of the solubilized sodium channel saxitoxin binding site from mammalian sarcolemma

The sodium channel saxitoxin binding component from rat sarcolemma was solubilized with medium chain length non-ionic detergents including NP-40, Brij-96 and Lubrol-PX. Phospholipid was required for stability of the binding component. Specific saxitoxin binding was significantly temperature sensitive even with optimal levels of phospholipid present. The solubilized saxitoxin binding component chromatographed on Sepharose 6B at a position corresponding to that of a globular protein of 95--10 A Stokes radius, but had an apparent s20,w typical of a smaller molecule (s20,w = 9.2--10). Column behavior and s20,w were independent of the specific detergent used for solubilization. Anomalous column behavior may reflect molecular asymmetry, contribution from bound detergent or similar considerations.

The localization of sodium and calcium to schwann cell paranodal loops at nodes of Ranvier and of calcium to compact myelin

High-voltage electron microscopy (HVEM) has been used to determine the distribution of cationic precipitates in myelinated axons resulting from the application of two cytochemical techniques: a direct osmium pyroantimonate treatment for precipitating Na+, Ca2+ and Mg2+; and a 5 mM Ca2+ inclusion procedure (Oschman & Wall) for imparting electron density to Ca2+ binding sites. Electron probe wavelength spectroscopy was then used on semi-thick tissue sections to identify the species of ions present in the following regions: Schwann cell paranodal loops, axoplasm at the node, compact myelin and extracellular matrix. With these combined procedures we were able to localize elevated concentrations of both Na+ and Ca2+ to cytoplasmic compartments of the Schwann cell paranodal loops, as well as to detect the presence of Ca2+ at elevated levels in compact myelin. The involvement of the Schwann cell paranodal loops in providing a source and/or sink for Na+ involved in impulse conduction is suggested by these results, and the significance of such a role is discussed. A role for Ca2+ in the formation and stabilization of myelin lamellae is also suggested.

Purification from rat sarcolemma of the saxitoxin-binding component of the excitable membrane sodium channel

The saxitoxin-binding component (SBC) of the excitable membrane sodium channel has been solubilized and purified from rat skeletal muscle sarcolemma. Phospholipid was required in mixed micelles with detergent for stability of the mammalian SBC. Even at optimal detergent-to-phospholipid ratio, the solubilized SBC showed significant temperature-dependent loss of specific toxin binding with time, necessitating maintenance of low temperatures during purification. Characteristics of saxitoxin binding to the solubilized material closely resembled those seen in intact membranes. A weak anion-exchange column was synthesized; it provided rapid 10- to 20-fold purification of the solubilized SBC. Additional necessary purification was obtained by chromatography on immobilized wheat germ agglutinin. Specific saxitoxin-binding activity of the purified material averaged approximately 1500 pmol of saxitoxin bound per mg of protein. Three bands were present in this material on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The purified material sedimented on a sucrose gradient with an apparent s20,w of 9.9 S.

Rows of dimeric-particles within the axolemma and juxtaposed particles within glia, incorporated into a new model for the paranodal glial-axonal junction at the node of Ranvier

Using freeze-fracture techniques, we have analyzed the glial-axonal junction (GAJ) between Schwann cells and axons in the peripheral nervous system, and between oligodendrocytes and axons in the central nervous system of the rat. We have identified a new set of dimeric-particles arranged in circumferential rows within the protoplasmic fracture faces (P-faces) of the paranodal axolemma in the region of glial-axonal juxtaposition. These particles, 260 A in length, composed of two 115-A subunits, are observed in both aldehyde-fixed and nonfixed preparations. The rows of dimeric-particles within the axonal P-face are associated with complementary rows of pits within the external fracture face (E-face) of the paranodal axolemma. These axonal particles are positioned between rows of 160-A particles that occur in both fracture faces of the glial loops in the same region. We observed, in addition to these previously described 160-A particles, a new set of 75-A glial particles within the glial P-faces of the GAJ. These 75-A particles form rows that are centered between the rows of 160-A particles and are therefore superimposed over the rows of dimeric-particles within the paranodal axolemma. Our new findings are interpreted with respect to methods of specimen preparation as well as to a potential role for the paranodal organ in saltatory conduction. We conclude that this particle-rich junction between axon and glia could potentially provide an intricate mechanism for ion exchange between these two cell types.

Molecular specializations of the axon membrane at nodes of Ranvier are not dependent upon myelination

Nodes of Ranvier from normal and 'dystrophic' mice have been examined with quantitative freeze-fracture electron microscopy. Regions of nodal, paranodal and interparanodal axolemma of normal fibres are clearly distinguishable on the basis of particle size distributions in electron micrographs of freeze-fractured replicas. Protoplasmic fracture faces of normal nodes of Ranvier, contain approximately 40% 100 A particles and about 25% elongated particles 150 by 250 A. Paranodal and interparanodal membranes contain a more uniform distribution of smaller diameter particles. 'Dystrophic', mice of the 129/ReJ-Dy strain have a genetic defect of Schwann cell development and myelinogenesis. Axons of the sciatic and deep peroneal nerves in dystrophic mice, which appear to be normally myelinated, possess approximately the same distributions of particles as axons in normal mice. However, in affected regions of the ventral and dorsal roots, Schwann cell wrappings may be missing, creating heminodes of Ranvier where the myelination terminates or begins again. At such heminodes, there is a circular band of axonal membrane which bears particles of sizes and packing densities similar to that found at normal nodes. High voltage electron microscopic examination of 0.25--1 micron thick sections from these hemi-nodal regions reveals the presence of a filamentous layer beneath the particle-rich membrane. In addition, completely amyelinated regions of root axons contain particle patches having size-density distributions similar to that of both normal and hemi-nodal membranes. Thus, the nodal membrane displays a characteristic particle-size distribution profile. The occurrence of this particle profile does not appear to be dependent upon the presence or absence of Schwann cells. These observations suggest that the functions subserved by the numerous particles at the node of Ranvier are not dependent upon myelination for their local differentiation within the axonal membrane.

Physiologically induced changes in intramembranous particle frequency in the axons of an osmoconforming bivalve

Freeze-fractured axonal membrane surfaces from the connectives of Mytilus edulis show an increment in particle frequency of 52% (fixed tissues) or 68% (unfixed tissues) after long-term adaptation to low salinity. Particle size distribution was unaffected by osmotic adaptation, but was significantly different in fixed and unfixed material. The possibility that these structural changes reflect the known increase in sodium pump frequency in this osmoconforming tissue is considered.

Axonal surface charges: evidence for phosphate structure

The effect of different extracellular alkaline-earth cations (Ca2+, Mg2+, Sr2+, Ba2+) upon the threshold membrane potential for spike initiation in crayfish axon has been studied by means of intracellular microelectrodes. This was done at the following extracellular concentrations of the divalent uranyl ion (UO2/2+): 1.0 X 10(-6) M, 3.0 X 10(-6) M, and 9.0 X 10(-6) M. At each concentration employed, extensive neutralization of axonal surface charges by UO2/2+ was evidenced by the fact that equal concentrations (50 mM) of alkaline-earth cations did not have the same effect on the threshold potential. The selectivity sequences observed at the different uranyl-ion concentrations were: 1.0 X 10(-6) M UO2/2+, Ca2+ greater than Mg2+ greater than Sr2+ greater than Ba2+; 3.0 X 10(-6) M UO2/2+, Ca2+ greater than Mg2+ greater than Ba2+ larger than or equal to Sr2+; 9.0 X 10(-6) M UO2/2+, Ca2+ approximately Ba2+ greater than Sr2+ greater than Mg2+. These selectivity sequences are in accord with the equilibrium selectivity theory for alkaline-earth cations. At each of the concentrations used, uranyl ion did not have any detectable effect on the actual shape of the action potential itself. It is concluded that many (if not most) of the surface acidic groups in the region of the sodium gates represent phosphate groups of membrane phospholipids, but that the m gates themselves are probably protein-aceous in structure.

Tetrodotoxin binding to normal depolarized frog muscle and the conductance of a single sodium channel

1. We have examined the binding of tritium-labelled and unlabelled tetrodotoxin to frog twitch muscle. Bio-assay as well as radioisotope experiments show a saturable component of tetrodotoxin binding with a binding capacity of about 22 p-mole/g wet wt., and a dissociation constant of about 5 nM. 2. If the observed uptake of tetrodotoxin by muscles represents one-to-one binding of the drug to sodium channels, the channel density is about 380 channels/mum2 of a muscle fibre's surface membrane. On the basis of this result and electrical measurements of sodium conductance in frog muscle, we calculate that the conductance of a single sodium channel is of the order of 10(-12) reciprocal ohms. This is one to two orders of magnitude less than previous estimates. 3. We have looked for an effect of membrane depolarization on saturable tetrodotoxin binding, and have found none. This suggests that there is little molecular interaction between the "gating" portion of the sodium channel molecule, and that which binds tetrodotoxin.

The molecular form of acetylcholinesterase as determined by irradiation inactivation

The molecular size of acetylcholinesterase (EC 3.1.1.7) from the electric organ of Electrophorus electricus and erythrocyte ;ghosts' was estimated in both membrane-bound and purified preparations by irradiation inactivation. Results suggest that the form of the enzyme in the membrane is a monomer of molecular weight approx. 75000 and that multiple forms of the enzyme observed in solubilized preparations are aggregates of this monomer.