Isolation of a terminal cisterna protein which may link the dihydropyridine receptor to the junctional foot protein in skeletal muscle.

The isolated dihydropyridine receptor and junctional foot protein were employed as protein ligands in overlay experiments to investigate the mode of interaction of these two proteins. As previously demonstrated by Brandt et al. [Brandt et al. (1990) J. Membr. Biol. 113, 237-251], the DHP receptor directly binds to an intrinsic terminal cisterna protein of Mr 95,000 (95-kDa protein). The junctional foot protein also binds to an Mr 95,000 protein showing similar organelle distribution to the 95-kDa protein which binds to the dihydropyridine receptor. The 95-kDa protein which binds to the dihydropyridine receptor was isolated to over 85% purity employing sequential column chromatography. Junctional foot protein and dihydropyridine receptor overlays of the column fractions at successive stages of isolation show an identical pattern of distribution, indicating that both probes bind to the same protein. When CHAPS-solubilized terminal cisterna/triads were passed through Sepharose with attached 95-kDa protein, the junctional foot protein was specifically retained, as evidenced by ryanodine binding. The junctional foot protein was incompletely released by 1 M NaCl. The alpha 1 subunit but not the beta subunit of the dihydropyridine receptor was also specifically retained, as evidenced by immunoblotting employing dihydropyridine receptor subunit-specific antibodies. A 170-kDa Stains-all blue staining protein, which appears to be bound to the luminal side of the terminal cisterna, was also retained on the 95-kDa protein column. From these findings, a model for the triad junction is proposed.

Molecular interactions of the junctional foot protein and dihydropyridine receptor in skeletal muscle triads.

Isolated triadic proteins were employed to investigate the molecular architecture of the triad junction in skeletal muscle. Immunoaffinity-purified junctional foot protein (JFP), glyceraldehyde 3-phosphate dehydrogenase (GAPDH), aldolase and partially purified dihydropyridine (DHP) receptor were employed to probe protein-protein interactions using affinity chromatography, protein overlay and crosslinking techniques. The JFP, an integral protein of the sarcoplasmic reticulum (SR) preferentially binds to GAPDH and aldolase, peripheral proteins of the transverse (T)-tubule. No direct binding of JFP to the DHP receptor was detected. The interactions of JFP with GAPDH and aldolase appear to be specific since other glycolytic enzymes associated with membranes do not bind to the JFP. The DHP receptor, an integral protein of the T-tubule, also binds GAPDH and aldolase. A ternary complex between the JFP and the DHP receptor can be formed in the presence of GAPDH. In addition, the DHP receptor binds to a previously undetected Mr 95 K protein which is distinct from the SR Ca2+ pump and phosphorylase b. The Mr 95 K protein is an integral protein of the junctional domain of the SR terminal cisternae. It is also present in the newly identified "strong triads" (accompanying paper). From these findings, we propose a new model for the triad junction.

Heterogeneity of calcium channels from a purified dihydropyridine receptor preparation.

Dihydropyridine receptors were purified from rabbit skeletal muscle transverse tubule membranes and incorporated into planar lipid bilayers. Calcium channels from both the purified dihydropyridine receptor preparation and the intact transverse tubule membranes exhibited two sizes of unitary currents, corresponding to conductances of 7 +/- 1 pS and 16 +/- 3 pS in 80 mM BaCl2. Both conductance levels were selective for divalent cations over monovalent cations and anions. Cadmium, an inorganic calcium channel blocker, reduced the single channel conductance of calcium channels from the purified preparation. The organic calcium channel antagonist nifedipine reduced the probability of a single channel being open with little effect on the single channel conductance. The presence of two conductance levels in both the intact transverse tubule membranes and the purified dihydropyridine receptor preparation suggests that the calcium channel may have multiple conductance levels or that multiple types of calcium channels with closely related structures are present in transverse tubule 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.

The sodium channel from rat brain. Reconstitution of voltage-dependent scorpion toxin binding in vesicles of defined lipid composition.

Purified sodium channels incorporated into phosphatidylcholine (PC) vesicles mediate neurotoxin-activated 22Na+ influx but do not bind the alpha-scorpion toxin from Leiurus quinquestriatus (LqTx) with high affinity. Addition of phosphatidylethanolamine (PE) or phosphatidylserine to the reconstitution mixture restores high affinity LqTx binding with KD = 1.9 nM for PC/PE vesicles at -90 mV and 36 degrees C in sucrose-substituted medium. Other lipids tested were markedly less effective. The binding of LqTx in vesicles of PC/PE (65:35) is sensitive to both the membrane potential formed by sodium gradients across the reconstituted vesicle membrane and the cation concentration in the extravesicular medium. Binding of LqTx is reduced 3- to 4-fold upon depolarization to 0 mV from -50 to -60 mV in experiments in which [Na+]out/[Na+]in is varied by changing [Na+]in or [Na+]out at constant extravesicular ionic strength. It is concluded that the purified sodium channel contains the receptor site for LqTx in functional form and that restoration of high affinity, voltage-dependent binding of LqTx by the purified sodium channel requires an appropriate ratio of PC to PE and/or phosphatidylserine in the vesicle membrane.

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. Reconstitution of neurotoxin-activated ion flux and scorpion toxin binding from purified components.

The rat brain Na+ channel was purified to homogeneity and reconstituted into pure egg phosphatidylcholine vesicles or vesicles composed of a mixture of egg phosphatidylcholine and rat brain lipid. In each case, the binding affinities at 37 degrees C for saxitoxin (STX) and tetrodotoxin (TTX) are nearly identical with those measured for intact Na+ channels. Approximately 50% of the reconstituted channels are oriented right-side-out. Veratridine stimulates the initial rate of 22Na+ uptake 8- to 15-fold with a K0.5 of 28 microM. External TTX blocks the fraction of Na+ channels oriented right-side-out with a Ki of 14 nM. All of the veratridine-stimulated 22Na+ uptake is blocked when TTX is present on both sides of the vesicle membrane, or when tetracaine is added to the external medium. The veratridine-activated reconstituted Na+ channel transports cations with a permeability ratio of PNa+/PRb+/PCa+ = 1.0:0.25:0.12. We estimate that at least 30% and perhaps as many as 70% of the reconstituted channels are active. Purified sodium channels reconstituted in egg phosphatidylcholine vesicles do not bind 125I-scorpion toxin (125I-LqTx). In contrast, when incorporated into vesicles containing rat brain lipids, 76% of the Na+ channels bound 125I-LqTx with an average KD of 80 nM. Thermal denaturation of purified Na+ channels at 36 degrees C prior to reconstitution causes a parallel loss of both the [3H]STX- and 125I-LqTx-binding activity measured after reconstitution. Sea anemone toxin II displaces bound 125I-LqTx with a KD 60-fold greater than that of unlabeled LqTx. These data indicate that the alpha, beta 1, and beta 2 subunits of the sodium channel are sufficient for reconstitution of both selective, veratridine-stimulated ion transport and 125I-LqTx binding.

Reconstitution of neurotoxin-stimulated sodium transport by the voltage-sensitive sodium channel purified from rat brain.

Incorporation of the saxitoxin receptor of the sodium channel solubilized with Triton X-100 and purified 250-fold from rat brain into phosphatidylcholine vesicles is described. Fifty to 80% of the saxitoxin receptor sites are recovered in the reconstituted vesicles (KD = 3 nM). Unlike the detergent-solubilized saxitoxin receptor, the reconstituted saxitoxin binding activity is stable to incubation at 36 degrees C. Approximately 75% of the reconstituted saxitoxin receptor sites are externally oriented and 25% are inside-out. The initial rate of 22Na+ uptake into reconstituted vesicles is increased up to 3- to 4-fold by veratridine with a K0.5 of 11 microM. Seventy per cent of this increase is blocked by external tetrodotoxin (TTX) with a Ki of 10 nM. All of the veratridine-stimulated 22Na+ uptake is blocked when TTX is present on both sides of the vesicle membrane, or when tetracaine is added to the external medium. The apparent binding constants for veratridine, saxitoxin, and TTX are essentially identical to those in intact rat brain synaptosomes. The results demonstrate reconstitution of sodium transport, as well as neurotoxin binding and action, from substantially purified sodium channel preparations.