Molecular biology of the voltage-gated potassium channels of the cardiovascular system.

K+ channels represent the most diverse class of voltage-gated ion channels in terms of function and structure. Voltage-gated K+ channels in the heart establish the resting membrane K+ permeability, modulate the frequency and duration of action potentials, and are targets of several antiarrhythmic drugs. Consequently, an understanding of K+ channel structure-function relationships and pharmacology is of great practical interest. However, the presence of multiple overlapping currents in native cardiac myocytes complicates the study of basic K+ channel function and drug-channel interactions in these cells. The application of molecular cloning technology to cardiovascular K+ channels has identified the primary structure of these proteins, and heterologous expression systems have allowed a detailed analysis of channel function and pharmacology without contaminating currents. To date six different K+ channels have been cloned from rat and human heart, and all have been functionally characterized in either Xenopus oocytes or mammalian tissue culture systems. This initial research is an important step toward understanding the molecular basis of the action potential in the heart. An important challenge for the future is to determine the cell-specific expression and relative contribution of these cloned channels to cardiac excitability.

Functional characterization of RK5, a voltage-gated K+ channel cloned from the rat cardiovascular system.

A voltage-sensitive K+ channel previously cloned from rat heart designated RK5 (rat Kv4.2) (Roberds and Tamkun, 1991, Proc. Natl. Acad. Sci. USA 88, 1798-1802) was functionally characterized in the Xenopus oocyte expression system. RK5 is a homolog of the Drosophila Shal K+ channel, activates with a rise time of 2.8 ms, has a midpoint for activation of -1 mV and rapidly inactivates with time constants of 15 and 60 ms. RK5 is sensitive to 4-AP, IC50 = 5 mM, and is insensitive to TEA and dendrotoxins. The voltage dependence and kinetics of the RK5 induced currents suggest this channel contributes to the Ito current in heart.

Two-dimensional probability density analysis of single channel currents from reconstituted acetylcholine receptors and sodium channels.

Two-dimensional probability density analysis of single channel current recordings was applied to two purified channel proteins reconstituted in planar lipid bilayers: Torpedo acetylcholine receptors and voltage-sensitive sodium channels from rat brain. The information contained in the dynamic history of the gating process, i.e., the time sequence of opening and closing events was extracted from two-dimensional distributions of transitions between identifiable states. This approach allows one to identify kinetic models consistent with the observables. Gating of acetylcholine receptors expresses "memory" of the transition history: the receptor has two channel open (O) states; the residence time in each of them strongly depends on both the preceding open time and the intervening closed interval. Correspondingly, the residence time in the closed (C) states depends on both the preceding open time and the preceding closed time. This result confirms the scheme that considers, at least, two transition pathways between the open and closed states and extends the details of the model in that it defines that the short-lived open state is primarily entered from long-lived closed states while the long-lived open state is accessed mainly through short-lived closed states. Since ligand binding to the acetylcholine-binding sites is a reaction with channel closed states, we infer that the longest closed state (approximately 19 ms) is unliganded, the intermediate closed state (approximately 2 ms) is singly liganded and makes transitions to the short open state (approximately 0.5 ms) and the shortest closed state (approximately 0.4 ms) is doubly liganded and isomerizes to long open states (approximately 5 ms). This is the simplest interpretation consistent with available data. In contrast, sodium channels modified with batrachotoxin to eliminate inactivation show no correlation in the sequence of channel opening and closing events, i.e., have no memory of the transition history. This result is, therefore, consistent with any kinetic scheme that considers a single transition pathway between open and closed states, and confirms the C-C-O model previously inferred from one-dimensional distribution analysis. The strategy described should be of general validity in the analysis of single channel events from channel proteins in both natural and reconstituted membranes.

Sodium channels in planar lipid bilayers. Channel gating kinetics of purified sodium channels modified by batrachotoxin.

Single channel currents of sodium channels purified from rat brain and reconstituted into planar lipid bilayers were recorded. The kinetics of channel gating were investigated in the presence of batrachotoxin to eliminate inactivation and an analysis was conducted on membranes with a single active channel at any given time. Channel opening is favored by depolarization and is strongly voltage dependent. Probability density analysis of dwell times in the closed and open states of the channel indicates the occurrence of one open state and several distinct closed states in the voltage (V) range-120 mV less than or equal to V less than or equal to +120 mV. For V less than or equal to 0, the transition rates between stages are exponentially dependent on the applied voltage, as described in mouse neuroblastoma cells (Huang, L. M., N. Moran, and G. Ehrenstein. 1984. Biophysical Journal. 45:313-322). In contrast, for V greater than or equal to 0, the transition rates are virtually voltage independent. Autocorrelation analysis (Labarca, P., J. Rice, D. Fredkin, and M. Montal. 1985. Biophysical Journal. 47:469-478) shows that there is no correlation in the durations of successive open or closing events. Several kinetic schemes that are consistent with the experimental data are considered. This approach may provide information about the mechanism underlying the voltage dependence of channel activation.

Functional reconstitution of the purified brain sodium channel in planar lipid bilayers.

The ion conduction and voltage dependence of sodium channels purified from rat brain were investigated in planar lipid bilayers in the presence of batrachotoxin. Single channel currents are clearly resolved. Channel opening is voltage dependent and favored by depolarization. The voltage at which the channel is open 50% of the time is -91 +/- 17 mV (SD, n = 22) and the apparent gating charge is approximately 4. Tetrodotoxin reversibly blocks the ionic current through the sodium channels. The Ki for the tetrodotoxin block is 8.3 nM at -50 mV and is voltage dependent with the Ki increasing e-fold for depolarizations of 43 mV. The single channel conductance, gamma, is ohmic. At 0.5 M salt concentrations gamma = 25 pS for Na+, 3.5 pS for K+, and 1.2 pS for Rb+. This study demonstrates that the purified brain sodium channel--which consists of three polypeptide subunits: alpha (Mr approximately 260,000), beta 1 (Mr approximately 39,000), and beta 2 (Mr approximately 37,000)--exhibits the same voltage dependence, neurotoxin sensitivity, and ionic selectivity associated with native sodium channels.

The sodium channel from rat brain. Purification and subunit composition.

A procedure is described for purification of the sodium channel 1380-fold from rat brain to essential homogeneity. The channel is solubilized in Triton X-100 and stabilized by addition of phosphatidylcholine and 10 mM CaCl2. It is purified by sequential chromatography on DEAE-Sephadex, hydroxylapatite, and wheat germ agglutinin/Sepharose followed by sedimentation through sucrose gradients. The final preparation binds 2910 pmol of saxitoxin (STX)/mg of protein or 0.9 mol of STX/mol of sodium channel of Mr approximately 316,000. Three polypeptide subunits comprise 90% of the silver stain intensity on sodium dodecyl sulfatepolyacrylamide gels of the pure protein and migrate as a stoichiometric complex coincident with STX-binding activity in sucrose gradient sedimentation: alpha with Mr approximately 260,000, beta 1 with Mr approximately 39,000, and beta 2 with Mr approximately 37,000. The alpha subunit, both purified and in intact synaptosomes, is shown to behave anomalously during sodium dodecyl sulfate-polyacrylamide gel electrophoresis exhibiting an unusually high extrapolated electrophoretic free mobility. A subunit stoichiometry of alpha 1(beta 1)1(beta 2)1 is proposed.

The saxitoxin receptor of the sodium channel from rat brain. Evidence for two nonidentical beta subunits.

The saxitoxin receptor of the sodium channel purified from rat bran contains three types of subunits: alpha with Mr approximately 270,000, beta 1 with Mr approximately 39,000, and beta 2 with Mr approximately 37,000. These are the only polypeptides which quantitatively co-migrate with the purified saxitoxin receptor during velocity sedimentation through sucrose gradients. beta 1 and beta 2 are often poorly resolved by gel electrophoresis in sodium dodecyl sulfate (SDS), but analysis of the effect of beta-mercaptoethanol on the migration is covalently attached to the alpha subunit by disulfide bonds while the beta 1 subunit is not. The alpha and beta subunits of the sodium channel were covalently labeled in situ in synaptosomes using a photoreactive derivative of scorpion toxin. Treatment of SDS-solubilized synaptosomes with beta-mercaptoethanol decreases the apparent molecular weight of the alpha subunit band without change in the amount of 125I-labeled scorpion toxin associated with either the alpha or beta subunit bands. These results indicate that the alpha and beta 1 subunits are labeled by scorpion toxin whereas beta 1 is not and that the beta 2 subunit is covalently attached to alpha by disulfide bonds in situ as well as in purified preparations.

Molecular Properties of neurotoxin receptors sites associated with sodium channels from mammalian brain.

Neurotoxins that act at specific receptor sites on voltage-sensitive sodium channels have been used as molecular probes to identify and purify protein components of sodium channels from mammalian brain. Photoreactive derivatives of scorpion toxin have been prepared and used to covalently label sodium channels in intact synaptosomes. Two polypeptides, alpha with Mr approximately 270,000 and beta with Mr approximately 38,000, are specifically labeled indicating that they are components of the scorpion toxin receptor site on the sodium channel. The sodium channel can be solubilized with retention of specific binding of [3H] saxitoxin using nonionic detergents such as Triton X-100. The solubilized saxitoxin receptor has molecular weight of 316,000 +/- 63,000 and binds 0.9 g of Triton X-100 and phospholipid per g of protein. The solubilized receptor can be purified 750-fold by ion exchange chromatography, wheat germ lectin/Sepharose chromatography and sucrose gradient sedimentation to a final specific activity of 1488 pmol/mg. Analysis of the polypeptide chain composition of the most highly purified fractions indicates that alpha and beta comprise 65% of the protein of these fractions and are only the polypeptides whose presence correlates with saxitoxin binding activity. These studies lead to a working hypothesis of sodium channel structure in which the intact channel is comprised of a complex with Mr of approximately 316,000 containing one mole of alpha (Mr approximately 270,000) and one to three moles of beta (Mr approximately 38,000).

Purification of the saxitoxin receptor of the sodium channel from rat brain.

The saxitoxin (STX) receptor has been purified 740-fold from rat brain by a combination of ion exchange chromatography, wheat germ agglutinin chromatography, and sedimentation on sucrose gradients to a specific activity of 1488 pmol/mg of protein. The best fractions were estimated to be 47% pure from their specific activity or 66% pure on the basis of NaDodSO4 gel electrophoresis. Two polypeptides, alpha (Mr approximately equal to 270,000 +/- 10,000) and beta (Mr approximately equal to 38,300 +/- 2000) (mean +/- SD) copurify with STX binding activity. Two polypeptides of the same apparent Mr are specifically covalently labeled by photoreactive derivatives of 125I-labeled scorpion toxin in rat brain synaptosomes and are likely to be identical to alpha and beta. The solubilized STX receptor has a Mr of 316,000 +/- 63,000, limiting its composition to one alpha polypeptide and one or more beta polypeptides per soluble receptor. Our results suggest that the alpha and beta polypeptides contain both the STX binding site and the scorpion toxin binding site of the mammalian sodium channel.

Size characteristics of the solubilized saxitoxin receptor of the voltage-sensitive sodium channel from rat brain.

The saxitoxin receptor of the voltage-sensitive sodium channel from rat brain was solubilized with Triton X-100 and stabilized with phosphatidylcholine. The size characteristics of the detergent . phospholipid . receptor complex were studied by gel filtration and sucrose gradient sedimentation in H2O and D2O. The complex has Stokes radius = 80 A, S20,W = 12 S, v = 0.82 ml/ g, and Mr = 601,000 +/- 48,000. Assuming v = 0.73 ml/g for the saxitoxin receptor protein, the mass of the complex consists of 47.4% detergent and phosphatidylcholine and 52.6% saxitoxin receptor protein with Mr = 316,000 +/- 63,000.