Spontaneous opening at zero membrane potential of sodium channels from eel electroplax reconstituted into lipid vesicles

Summary The voltage-dependent sodium channel from the eel electroplax was purified and reconstituted into vesicles of varying lipid composition. Isotopic sodium uptake experiments were conducted with vesicles at zero membrane potential, using veratridine to activate channels and tetrodotoxin to block them. Under these conditions, channel-dependent uptake of isotopic sodium by the vesicles was observed, demonstrating that a certain fraction of the reconstituted protein was capable of mediating ion fluxes. In addition, vesicles untreated with veratridine showed significant background uptake of sodium; a considerable proportion of this flux was blocked by tetrodotoxin. Thus these measurements showed that a significant subpopulation of channels was present that could mediate ionic fluxes in the absence of activating toxins. The proportion of channels exhibiting this behavior was dependent on the lipid composition of the vesicles and the temperature at which the uptake was measured; furthermore, the effect of temperature was reversible. However, the phenomenon was not affected by the degree of purification of the protein used for reconstitution, and channels in resealed electroplax membrane fragments or reconstituted, solely into native eel lipids did not show this behavior. The kinetics of vesicular uptake through these spontaneously-opening channels was slow, and we attribute this behavior to a modification of sodium channel inactivation.     

Neurotoxin-modulated uptake of sodium by highly purified preparations of the electroplax tetrodotoxin-binding glycopeptide reconstituted into lipid vesicles

Summary Using the dialysable detergent CHAPS (3-[(3-cholamidopropyl)-dimethylammonio]-1-propane sulfonate), the tetrodotoxin-binding protein from the electroplax of the electric eel has been purified to a high degree of both chemical homogeneity and toxin-binding activity. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the best preparations showed only a single microheterogeneous band atM _r approximately 260,000, despite attempts to visualize smaller bands by sample overloading. Upon dialysis, this material became incorporated into the membranes of small unilamellar vesicles, and in this form the purified protein exhibited tetrodotoxin-binding properties similar to the component in the original electroplax membrane. Furthermore, in the presence of activator neurotoxins the vesicles were able to accumulate isotopic sodium in a manner similar to that previously described for less active or less pure preparations of vesicles containing either mammalian or eel electroplax toxinbinding proteins. Quantitative consideration of the isotopic transport activity of this pure material, along with the high degree of purity of the protein, strongly suggests that the 260-kDa glycopeptide from electroplax is necessary and sufficient to account for the sodium channel function seen in these studies, and eliminates the possible involvement of smaller peptides in the channel phenomena observed.     

Reconstituted voltage-sensitive sodium channels from eel electroplax: Activation of permeability by quaternary lidocaine,N-bromoacetamide,and N-bromosuccinimide

Summary We have investigated the ion permeability properties of sodium channels purified from eel electroplax and reconstituted into liposomes. Under the influence of a depolarizing diffusion potential, these channels appear capable of occasional spontaneous openings. Fluxes which result from these openings are sodium selective and blocked (from opposite sides of the membrane) by tetrodotoxin (TTX) and moderate concentrations of the lidocaine analogue QX-314. Low concentrations of QX-314 paradoxically enhance this channel-mediated flux. N-bromoacetamide (NBA) and N-bromosuccinimide (NBS), reagents which remove inactivation gating in physiological preparations, transiently stimulate the sodium permeability of inside-out facing channels to high levels. The rise and subsequent fall of permeability appear to result from consecutive covalent modifications of the protein. Titration of the protein with the more reactive NBS can be used to produce stable, chronically active forms of the protein. Low concentrations of QX-314 produce a net facilitation of channel activation by NBA, while higher concentrations produce block of conductance. This suggests that rates of modifications by NBA which lead to the activation of permeability are influenced by conformational changes induced by QX-314 binding.     

Biochemical properties of sodium channels in a wide range of excitable tissues studied with site-directed antibodies

Antibodies against a peptide (SP19) corresponding to a highly conserved, predicted intracellular region of the sodium channel alpha subunit bind rat brain sodium channels with a similar affinity as the peptide antigen, indicating that the corresponding segment of the alpha subunit is fully accessible in the intact channel structure. These antibodies recognize sodium channel alpha subunits from rat or eel brain, rat skeletal muscle, rat heart, eel electroplax, and locust nervous system. alpha subunits from all these tissues except rat skeletal muscle are substrates for phosphorylation by cAMP-dependent protein kinase. Disulfide linkage of alpha and beta 2 subunits was observed for both the RI and RII subtypes of rat brain sodium channels and for sodium channels from eel brain but not for sodium channels from rat heart, eel electroplax, or locust nerve cord. Treatment with neuraminidase reduced the apparent molecular weight of sodium channel alpha subunits from rat and eel brain and eel electroplax by 22,000-58,000, those from heart by 8000, and those from locust nerve cord by less than 4000. Our results provide the first identification of sodium channel alpha subunits from rat heart and locust brain and nerve cord and show that sodium channel alpha subunits are expressed with different subunit associations and posttranslational modifications in different excitable tissues.     

Beta 1 subunits of sodium channels. Studies with subunit-specific antibodies

The purified Na+ channel from rat brain consists of alpha (260 kDa), beta 1 (36 kDa), and beta 2 (33 kDa) subunits. Pure beta 1 subunits were prepared from purified rat brain Na+ channels which had been adsorbed to hydroxylapatite resin and used to prepare specific anti-beta 1 subunit antiserum. Antibodies purified from this antiserum by antigen affinity chromatography immunoprecipitate 125I-labeled, purified beta 1 subunits and purified Na+ channels (measured as high affinity [3H] saxitoxin binding sites) and recognize beta 1 subunits on immunoblots of solubilized rat brain membranes. The affinity-purified anti-beta 1 antibodies recognize beta 1 subunits in rat spinal cord, heart, skeletal muscle, and sciatic nerve, but do not detect immunoreactive beta 1 subunits in eel electroplax or eel brain. The developmental time course of expression of immunoreactive beta 1 subunits in rat forebrain was measured by immunoprecipitation followed by immunoblotting with affinity-purified anti-beta 1 antibodies. The amount of immunoreactive beta 1 subunits increased steadily to adult levels during the first 21 days of postnatal development.     

Two types of mechanosensitive channels in the Escherichia coli cell envelope: solubilization and functional reconstitution.

Mechanosensitive ion channels (MSCs) which could provide for fast osmoregulatory responses in bacteria, remain unidentified as molecular entities. MSCs from Escherichia coli (strain AW740) were examined using the patch-clamp technique, either (a) in giant spheroplasts, (b) after reconstitution by fusing native membrane vesicles with asolectin liposomes, or (c) by reassembly of octylglucoside-solubilized membrane extract into asolectin liposomes. MSC activities were similar in all three preparations, consisting of a large nonselective MSC of 3-nS conductance (in 200 mM KCl) that was activated by high negative pressures, and a small weakly anion-selective MSC of 1 nS activated by lower negative pressures. Both channels appeared more sensitive to suction in liposomes than in spheroplasts. After gel filtration of the solubilized membrane extract and reconstituting the fractions, both large MSC and small MSC activities were retrieved in liposomes. The positions of the peaks of channel activity in the column eluate, assayed by patch sampling of individual fractions reconstituted in liposomes, showed an apparent molecular mass under nondenaturing conditions of about 60-80 kDa for the large and 200-400 kDa for the small MSC. We conclude that (a) the large MSC and the small MSC are distinct molecular entities, (b) the fact that both MSCs were functional in liposomes following chromatography strongly suggests that these channels are gated by tension transduced via lipid bilayer, and (c) chromatographic fractionation of detergent-solubilized membrane proteins with subsequent patch sampling of reconstituted fractions can be used to identify and isolate these MS channel proteins.     

Reconstitution of a purified acetylcholine receptor

Dialysis of the purified acetylcholine receptor from Torpedo californica electroplax with lipids from the same organ results in a vesicular membrane system in which the receptor is embedded in the bilayer and oriented so that most of the neurotoxin-binding sites appear to be on the outer surface. The constituted vesicles are chemically excitable by acetylcholine and carbamylcholine, as measured by ²²Na⁺ efflux. The excitability is specifically blocked by the antagonist α-bungarotoxin. These results demonstrate that the purified reconstituted receptor system not only can specifically bind neurotransmitter but also can trigger ion translocation. It therefore has the properties necessary to effect postsynaptic depolarization in vivo.     

Effects of deglycosylation of sodium channels on their structure and function

Voltage-gated sodium channels are important membrane proteins underlying electrical signaling in the nervous and muscular systems. They undergo rapid conformational changes between closed resting, activated, and inactivated states. Approximately 30% of the mass of the sodium channel is carbohydrate, present as glycoconjugate chains, mostly composed of N-acetylhexosamines and sialic acid. In this study, the effects of removing the carbohydrate on the functional and structural properties of highly purified sodium channels from Electrophorus electricus were investigated. After enzymatic deglycosylation, channels were reconstituted into planar lipid bilayers. In the presence of batrachotoxin, substates became evident and the single-channel conductance of the deglycosylated channels was slightly reduced relative to that of native channels, consistent with electrostatic effects due to the reduction in negative charge at the extracellular vestibule of the channel. The previously reported state-dependent changes in the circular dichroism spectra that are associated with the binding of the anticonvulsant drug Lamotrigine and batrachotoxin are also seen in the modified channels. Synchrotron radiation circular dichroism (SRCD) spectroscopy on the type of sugars found in the sodium channel showed that unlike most carbohydrates, these sugars produce a significant dichroic signal in the far-ultraviolet region. This can account for all of the measured SRCD-detected spectral differences between the native and deglycosylated channels, thereby indicating that no net change in protein secondary structure results from the deglycosylation procedure. Furthermore, thermal denaturation studies detected no significant differences in stability between native and deglycosylated channels. In summary, while the sugars of the voltage-gated sodium channels from electroplax are not essential for functional or structural integrity, they do appear to have a modulating effect on the conductance properties of these channels.     

Isolation of Membrane Fractions with Sodium Channels Sensitive to Veratridine and tetrodotoxin from the Electric Organ of the Eel Electrophorus electricus

The veratridine/tetrodotoxin-sensitive sodium influx was measured in membrane fractions isolated from the electric organ of Electrophorus electricus. The fractions were characterized, and the main biochemical markers and their acetylcholine receptor content were determined. The innervated and noninnervated faces of the electroplax were separated. The different biochemical criteria used indicate that the pre- and postsynaptic membranes of the innervated face were isolated. Sodium influx increased by veratridine and blocked by tetrodotoxin was found in fractions from the presynaptic membrane. Because some of the vesicles in this fraction are in the inside-out conformation, tetrodotoxin had to be applied to both faces of the vesicles so that sodium influx was blocked completely. The fractions from the innervated face of the electroplax contained sodium channels with sensitivities to tetrodotoxin and veratridine similar to those of fractions from other nerve membrane preparations.     

Characterization of reconstituted plasma membrane H+-ATPase from maize roots

Corn ( Zea mays L.) plasma membranes from KI-washed microsomal fractions were further purified by isopycnic sucrose density centrifugation. An examination of separated fractions indicated that vesicles with nitrate-insensitive proton transport copurified with fractions containing vanadate-sensitive ATPase activity. The ATPase in purified plasma membrane was reconstituted into liposomes by a detergent dilution technique using deoxycholate. The reconstituted ATPase exhibited characteristics similar to those of the native enzyme. However, reconstituted preparations showed an enhanced sensitivity to vanadate, a diminished phosphatase activity and a high specific rate of ATP-dependent H⁺-transport. Apparent K_i values of reconstituted and native enzymes with respect to vanadate were 20 and 50 μ M , respectively; the KJ value of the H+-pumping of reconstituted ATPase was 30 μ M. The proton pumping of reconstituted vesicles could be discharged rapidly by p -trifluoromethoxyphenyl hydrazone (FCCP), hexokinase and vanadate. The hydrolysis of Mg-ATP by both native and reconstituted ATPases obeyed simple Michaelis-Menten plots with a K_m between 0.5 and 0.6 m M. The reconstituted ATPase retained a pH profile similar to that of native enzyme with a maximum of pH 6.5.     

Studies on a reconstituted acetylcholine receptor system: effect of agonists

An impure preparation of acetylcholinesterase from electroplax of the electric eel can be incorporated into a bimolecular lipid membrane. The acetylcholinesterase-modified bimolecular lipid membrane shows a concentration-dependent increase in membrane conductance elicited by several agonists (acetylcholine, carbamylcholine, phenyltrimethylammonium ion, tetraethylammonium ion, decamethonium ion, and nicotine) added to the compartment opposite that to which acetylcholinesterase was originally added. Affinity and efficacy of the various agonists in generating the conductance increase were measured from dose-response curves; these are in good quantitative agreement with corresponding values observed for depolarization of intact eel electroplax. The ion conduction pathways induced by agonists in the modified bimolecular lipid membrane show a slight cation selectivity, Na ? K > Cl (3:3:1), similar to that observed for the depolarized electroplax membrane. Evidence is presented that suggests that some components other than acetylcholinesterase induce the acetylcholine receptor response in the bimolecular lipid membrane.     

Purified and unpurified sodium channels from eel electroplax in planar lipid bilayers

Highly purified sodium channel protein from the electric eel, Electrophorus electricus, was reconstituted into liposomes and incorporated into planar bilayers made from neutral phospholipids dissolved in decane. The purest sodium channel preparations consisted of only the large, 260-kD tetrodotoxin (TTX)-binding polypeptide. For all preparations, batrachotoxin (BTX) induced long-lived single-channel currents (25 pS at 500 mM NaCl) that showed voltage-dependent activation and were blocked by TTX. This block was also voltage dependent, with negative potentials increasing block. The permeability ratios were 4.7 for Na+:K+ and 1.6 for Na+:Li+. The midpoint for steady state activation occurred around -70 mV and did not shift significantly when the NaCl concentration was increased from 50 to 1,000 mM. Veratridine-induced single-channel currents were about half the size of those activated by BTX. Unpurified, nonsolubilized sodium channels from E. electricus membrane fragments were also incorporated into planar bilayers. There were no detectable differences in the characteristics of unpurified and purified sodium channels, although membrane stability was considerably higher when purified material was used. Thus, in the eel, the large, 260-kD polypeptide alone is sufficient to demonstrate single-channel activity like that observed for mammalian sodium channel preparations in which smaller subunits have been found.     

Reconstitution of the rat liver vasopressin receptor coupled to guanine nucleotide-binding proteins

The V1 vasopressin receptor has been solubilized from rat liver membranes with the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammoniol]-1-propanesulfonate (CHAPS) and reconstituted into phospholipid vesicles. There is essentially complete solubilization of the receptor by 3% CHAPS at a protein concentration of 15 mg/ml. Reconstitution into soybean phospholipid vesicles is readily achieved either by gel filtration chromatography or by membrane dialysis. The binding of [3H]vasopressin to proteoliposomes is specific, saturable, reversible, and magnesium-dependent. In contrast, the detergent-soluble vasopressin receptor does not display specific binding. The apparent affinity of the reconstituted receptor for [3H]vasopressin is approximately 4-fold lower than that of the receptor in native membranes. In addition, the binding of [3H]vasopressin to reconstituted vesicles is not sensitive to 100 microM guanosine 5'-O-thiotriphosphate (GTP gamma S) as it is in native membranes. However, the apparent affinity of the reconstituted receptor for ligand approximates that of native membranes when membranes are prebound with vasopressin prior to solubilization and reconstitution into vesicles. Furthermore, vesicles reconstituted from membranes prebound with vasopressin show GTP gamma S sensitivity of [3H] vasopressin binding. This finding strongly suggests that vasopressin stabilizes a receptor-G-protein complex during solubilization. The rat liver vasopressin receptor is a glycoprotein, as shown by its specific binding to the lectin "wheat germ agglutinin." The vasopressin receptor can be reconstituted from the N-acetylglucosamine-eluted peak of a wheat germ agglutinin-Sepharose column, and [3H] vasopressin binding activity is purified 5-6-fold from membranes by this chromatographic procedure. The functionality of the partially purified receptor is indicated by its ability to bind ligand with high affinity and by its ability to functionally interact with a G-protein when vasopressin is bound prior to solubilization.     

Veratridine modification of the purified sodium channel alpha- polypeptide from eel electroplax

In the interest of continuing structure-function studies, highly purified sodium channel preparations from the eel electroplax were incorporated into planar lipid bilayers in the presence of veratridine. This lipoglycoprotein originates from muscle-derived tissue and consists of a single polypeptide. In this study it is shown to have properties analogous to sodium channels from another muscle tissue (Garber, S. S., and C. Miller. 1987. Journal of General Physiology. 89:459-480), which have an additional protein subunit. However, significant qualitative and quantitative differences were noted. Comparison of veratridine-modified with batrachotoxin-modified eel sodium channels revealed common properties. Tetrodotoxin blocked the channels in a voltage-dependent manner indistinguishable from that found for batrachotoxin-modified channels. Veratridine-modified channels exhibited a range of single-channel conductance and subconductance states. The selectivity of the veratridine-modified sodium channels for sodium vs. potassium ranged from 6-8 in reversal potential measurements, while conductance ratios ranged from 12-15. This is similar to BTX-modified eel channels, though the latter show a predominant single-channel conductance twice as large. In contrast to batrachotoxin-modified channels, the fractional open times of these channels had a shallow voltage dependence which, however, was similar to that of the slow interaction between veratridine and sodium channels in voltage-clamped biological membranes. Implications for sodium channel structure are discussed.     

Target size of D-beta-hydroxybutyrate dehydrogenase. Functional and structural molecular weight based on radiation inactivation

D-beta-Hydroxybutyrate dehydrogenase is a lipid-requiring enzyme which is localized on the inner face of the mitochondrial inner membrane. The apoenzyme has been purified to homogeneity from beef heart; it is devoid of lipid and inactive. It can be functionally reconstituted with lecithin or phospholipid mixtures containing lecithin. The active form of the enzyme is the enzyme-phospholipid complex. Classical target analysis of radiation-inactivation data has now been used to determine the molecular size of the enzyme both in the native membrane (submitochondrial vesicles) and in the reconstituted enzyme inserted into phospholipid vesicles containing lecithin. For both forms of the enzyme, we find the same molecular size, approximately 110,00 daltons. This size is consistent with a tetramer. Radiation results in fragmentation of the polypeptide and the destruction of the polypeptide correlates with loss of enzymic function. A similar size is obtained when purified D-beta-hydroxybutyrate dehydrogenase is inserted into a nonactivating mixture of phospholipid (i.e. in the absence of lecithin). We conclude that: 1) the native enzyme in submitochondrial vesicles and the purified active enzyme in phospholipid vesicles are the same size, approximating a tetramer; 2) radiation of D-beta-hydroxybutyrate dehydrogenase results in loss of activity and fragmentation of the polypeptide; and 3) the role of lecithin in activation of D-beta-hydroxybutyrate dehydrogenase is unrelated to determining oligomeric size of the enzymes since both active and nonactive forms exhibit the same structural size.     

Partial purification and characterization of (Na++K+)-ATPase from garfish olfactory nerve axon plasma membrane

Summary The (Na⁺+K⁺)-ATPase of garfish olfactory nerve axon plasma membrane was purified about sixfold by treatment of the membrane with sodium dodecyl sulfate followed by sucrose density gradient centrifugation. The estimated molecular weights of the two major polypeptide components of the enzyme preparation on sodium dodecyl sulfate gels were 110,000 and 42,000 daltons, which were different from those of the corresponding peptides of rabbit kidney (Na⁺+K⁺)-ATPase. No carbohydrate was detected in the 42,000-dalton component either by the periodic acid-Schiff reagent or by the more sensitive concanavalin A-peroxidase staining procedure. The molecular properties of the garfish (Na⁺+K⁺)-ATPase, such as theK _m for ATP, pH optimum, energies of activation, Na and K ion dependence and vanadium inhibition, were, however, similar to those of the kidney enzyme.The partially purified garfish (Na⁺+K⁺)-ATPase was reconstituted into phospholipid vesicles by a freeze-thaw-sonication procedure. The reconstituted enzyme was found to catalyze a time and ATP dependent²²Na⁺ transport. The ratio of²²Na⁺ pumped to ATP hydrolyzed was about 1; under the same reconstitution and assay conditions, eel electroplax (Na⁺+K⁺)-ATPase, however, gave a²²Na⁺ pumped to ATP hydrolyzed ratio of nearly 3.     

Reconstitution of High-Affinity Binding of a β-Scorpion Toxin to Neurotoxin Receptor Site 4 on Purified Sodium Channels

Abstract: Reconstitution of purified sodium channels into phospholipid vesicles restores many aspects of sodium channel function including high-affinity neurotoxin binding and action at neurotoxin receptor sites 1–3 and 5, but neurotoxin binding and action at receptor site 4 has not previously been demonstrated in purified and reconstituted preparations. Toxin IV from the venom of the American scorpion Centruroides suffusus suffusus (Css IV), a β-scorpion toxin, shifts the voltage dependence of sodium channel activation by binding with high affinity to neurotoxin receptor site 4. Sodium channels were purified from rat brain and reconstituted into phospholipid vesicles composed of phosphatidylcholine and phosphatidylethanolamine (65:35). ¹²⁵I-Css IV, purified by reversed-phase HPLC, bound rapidly and specifically to reconstituted sodium channels. Dissociation of the bound toxin was biphasic with half-times of 0.22 min^?1 and 0.015 min^?1. At equilibrium, the toxin bound to two classes of specific high-affinity sites, a variable minor class with K_D of ～0.1 nM and a major class with a K_D of ～5 nM. Approximately 0.8 mol ¹²⁵I-Css IV was bound per mole of reconstituted, right-side-out sodium channels, as assessed from comparison of binding of saxitoxin and Css IV. Binding of Css IV was unaffected by membrane potential or by neurotoxins that bind at sites 1–3 or 5, consistent with the characteristics of binding of β-scorpion toxins to sodium channels in cells and membrane preparations. Our results show that specific, high-affinity binding at neurotoxin receptor site 4 on purified sodium channels can be restored by reconstitution into phospholipid vesicles and provide an experimental approach to analysis of the peptide components of the toxin receptor site.     

Biosynthesis of electroplax sodium channels in Electrophorus electrocytes and Xenopus oocytes

We have synthesized the eel electroplax sodium channel core polypeptide in both a cell-free and a frog oocyte system and report it does not possess the unusual electrophoretic properties of the mature, native sodium channel polypeptide isolated from electroplax membranes. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the mature channel polypeptide exhibits both a diffuse banding pattern (microheterogeneity) and an extremely high electrophoretic free mobility. In contrast, the core polypeptide synthesized in vitro or in vivo migrates as a sharp band with a near-normal electrophoretic free mobility (Mr 230,000). The microheterogeneity of the mature peptide has been inferred to result from varying degrees of glycosylation of the channel polypeptide [Miller, J.A., Agnew, W.S., & Levinson, S.R. (1983) Biochemistry 22, 462-470]. We present evidence here that the anomalously high electrophoretic free mobility is due to the binding of large amounts of sodium dodecyl sulfate to posttranslationally modified domains on the protein. In addition, we have followed the posttranslational processing of eel sodium channels in both the eel electrocyte and the frog oocyte. Using lectin binding and Ferguson analysis, we found that the channel was processed relatively rapidly to an intermediate form in the Golgi apparatus that apparently contained fewer carbohydrate and hydrophobic domains than the mature channel. The further addition of carbohydrate and hydrophobic domains, which are required before the channel acquires its characteristic physicochemical properties, proceeded relatively slowly in the electrocyte and appeared not to have occurred to the majority of intermediately processed channels in the frog oocyte.     

A modified mammalian tandem affinity purification procedure to prepare functional polycystin-2 channel

The tandem affinity purification (TAP) procedure was initially developed as a tool for rapid purification of native protein complexes expressed at their natural levels in yeast cells. This purification procedure was also applied to study interactions between soluble proteins in mammalian cells. In order to apply this procedure to mammalian membrane proteins, we created a modified TAP tag expression vector and fused with the PKD2 gene, encoding a membrane cation channel protein, polycystin-2, mutated in 15% of autosomal dominant polycystic kidney disease. We generated epithelial Madin-Darby canine kidney cell line stably expressing TAP-tagged polycystin-2, improved the subsequent steps for membrane protein release and stability, and succeeded in purifying this protein. Using patch clamp electrophysiology, we detected specific polycystin-2 channel activities when the purified protein was reconstituted into a lipid bilayer system. Thus, this modified TAP procedure provides a powerful alternative to functionally characterize membrane proteins, such as ion channels, transporters and receptors, using cell-free system derived from mammalian cells.