Expression of the alpha(2)delta subunit interferes with prepulse facilitation in cardiac L-type calcium channels.

We investigated the role of the accessory alpha(2)delta subunit on the voltage-dependent facilitation of cardiac L-type Ca(2+) channels (alpha(1C)). alpha(1C) Channels were coexpressed in Xenopus oocytes with beta(3) and alpha(2)delta calcium channel subunits. In alpha(1C) + beta(3), the amplitude of the ionic current (measured during pulses to 10 mV) was in average approximately 1.9-fold larger after the application of a 200-ms prepulse to +80 mV. This phenomenon, commonly referred to as voltage-dependent facilitation, was not observed when alpha(2)delta was coexpressed with alpha(1C) + beta(3). In alpha(1C) + beta(3), the prepulse produced a left shift ( approximately 40 mV) of the activation curve. Instead, the activation curve for alpha(1C) + beta(3) + alpha(2)delta was minimally affected by the prepulse and had a voltage dependence very similar to the G-V curve of the alpha(1C) + beta(3) channel facilitated by the prepulse. Coexpression of alpha(2)delta with alpha(1C) + beta(3) seems to mimic the prepulse effect by shifting the activation curve toward more negative potentials, leaving little room for facilitation. The facilitation of alpha(1C) + beta(3) was associated with an increase of the charge movement. In the presence of alpha(2)delta, the charge remained unaffected after the prepulse. Coexpression of alpha(2)delta seems to set all the channels in a conformational state from where the open state can be easily reached, even without prepulse.

Functional coupling between human E-type Ca2+ channels and mu opioid receptors expressed in Xenopus oocytes.

Neuronal alpha1E Ca2+ channels were expressed in Xenopus laevis oocytes alone and in combination with the mu opioid receptor. Macroscopic currents were recorded under voltage clamp conditions. The stimulation of the morphine receptor by the synthetic [D-Ala2,N-Me-Phe4,Gly-ol5] enkephalin (DAMGO) produced a 20% reduction in the alpha1E ionic current. This effect was associated with a large change in the decay phase of the Ba2+ current. The effect of 1 microM DAMGO was fully antagonized by the universal mu opioid receptor antagonist naloxone and by the selective antagonist beta-funaltrexamine. The ionic current inhibition induced by DAMGO was partially recovered by preceding strong depolarizations. The injection of the catalytic subunit of pertussis toxin (A-protomer) abolished the effect of DAMGO, suggesting the involvement of a GTP binding protein in the alpha1E modulation. The coexpression of the regulatory beta2a Ca2a channel subunit, together with the alpha1E subunit and the mu opioid receptor, prevented the reduction of the ionic current following the receptor stimulation with DAMGO, whereas the coexpression with the beta3 subunit reduced by approximately 50% the modulatory effect of DAMGO. The effect produced by the stimulation of the opioid receptor could be mimicked by coexpressing the alpha1E channel with the G-protein betagamma subunits.

Effect of bay K 8644 (-) and the beta2a subunit on Ca2+-dependent inactivation in alpha1C Ca2+ channels.

Ca2+ currents recorded from Xenopus oocytes expressing only the alpha1C pore-forming subunit of the cardiac Ca2+ channel show Ca2+-dependent inactivation with a single exponential decay. This current-dependent inactivation is not detected for inward Ba2+ currents in external Ba2+. Facilitation of pore opening speeds up the Ca2+-dependent inactivation process and makes evident an initial fast rate of decay. Facilitation can be achieved by (a) coexpression of the beta2a subunit with the alpha1C subunit, or (b) addition of saturating Bay K 8644 (-) concentration to alpha1C channels. The addition of Bay K 8644 (-) to alpha1Cbeta2a channels makes both rates of inactivation faster. All these maneuvers do not induce inactivation in Ba2+ currents in our expression system. These results support the hypothesis of a mechanism for the Ca2+-dependent inactivation process that is sensitive to both Ca2+ flux (single channel amplitude) and open probability. We conclude that the Ca2+ site for inactivation is in the alpha1C pore-forming subunit and we propose a kinetic model to account for the main features of alpha1Cbeta2a Ca2+ currents.

Facilitation by the beta2a subunit of pore openings in cardiac Ca2+ channels.

1. Single channel recordings were performed on the cardiac calcium channel (alpha1C) in order to study the effect of coexpression of the accessory beta2a subunit. On-cell patch clamp recordings were performed after expression of these channels in Xenopus oocytes. 2. The alpha1C subunit, when expressed alone, had similar single channel properties to native cardiac channels. Slow transitions between low and high open probability (Po) gating modes were found as well as fast gating transitions between the open and closed states. 3. Coexpression of the beta2a subunit caused changes in the fast gating during high Po mode. In this mode, open time distributions reveal at least three open states and the beta2a subunit favours the occupancy of the longest, 10-15 ms open state. No effect of the beta2a subunit was found when the channel was gating in the low Po mode. 4. Slow gating transitions were also affected by the beta2a subunit. The high Po mode was maintained for the duration of the depolarizing pulse in the presence of the beta2a subunit; while the alpha1C channel when expressed alone, frequently switched into and out of the high Po mode during the course of a sweep. 5. The beta2a subunit also affected mode switching that occurred between sweeps. Runs analysis revealed that the alpha1C subunit has a tendency toward non-random mode switching. The beta2a subunit increased this tendency. A chi2 analysis of contingency tables indicated that the beta2a subunit caused the alpha1C channel to gain 'intrinsic memory', meaning that the mode of a given sweep can be non-independent of the mode of the previous sweep. 6. We conclude that the beta2a subunit causes changes to the alpha1C channel in both its fast and slow gating behaviour. The beta2a subunit alters fast gating by facilitating movement of the channel into an existing open state. Additionally, the beta2a subunit decreases the slow switching between low and high Po modes.

Voltage-controlled gating in a large conductance Ca2+-sensitive K+channel (hslo).

Large conductance calcium- and voltage-sensitive K+ (MaxiK) channels share properties of voltage- and ligand-gated ion channels. In voltage-gated channels, membrane depolarization promotes the displacement of charged residues contained in the voltage sensor (S4 region) inducing gating currents and pore opening. In MaxiK channels, both voltage and micromolar internal Ca2+ favor pore opening. We demonstrate the presence of voltage sensor rearrangements with voltage (gating currents) whose movement and associated pore opening is triggered by voltage and facilitated by micromolar internal Ca2+ concentration. In contrast to other voltage-gated channels, in MaxiK channels there is charge movement at potentials where the pore is open and the total charge per channel is 4-5 elementary charges.

Feedback inhibition of Ca2+ channels by Ca2+ depends on a short sequence of the C terminus that does not include the Ca2+ -binding function of a motif with similarity to Ca2+ -binding domains.

alpha(1C)- and alpha(1E)-based Ca2+ channels differ in that the former are inhibited by Ca2+ entering through its pore, while the latter are not. It has been proposed on the basis of analysis of alpha(1E)/alpha(1C) chimeras that the molecular determinants responsible for Ca2+ inhibition involve both a conserved Ca2+-binding motif (EF hand) plus additional sequences located C-terminal to the EF hand. Through construction of similar alpha(1E)/alpha(1C) chimeras, we transferred Ca2+ inhibition from alpha(1C) to alpha(1E) by replacing a 134-aa segment of alpha(1E) with the homologous 142-aa segment of alpha(1C). This segment is located immediately after the proposed Ca2+ -binding EF hand motif. Replacement of the alpha(1C) EF hand with the corresponding EF hand of alpha(1E) did not interfere with inhibition of alpha(1C) by Ca2+, and a triple mutant of alpha(1C), alpha(1C)[D1535A,E1537A,D1546A], that disrupts the potential Ca2+-coordinating ability of the EF hand continued to be inhibited by Ca2+. These results indicate that a small portion of the alpha(1C) C terminus is essential for inhibition by Ca2+ and place the Ca2+ -binding site anywhere in alpha(1C), with the exception of its EF hand-like motif.

Effective gating charges per channel in voltage-dependent K+ and Ca2+ channels.

In voltage-dependent ion channels, the gating of the channels is determined by the movement of the voltage sensor. This movement reflects the rearrangement of the protein in response to a voltage stimulus, and it can be thought of as a net displacement of elementary charges (e0) through the membrane (z: effective number of elementary charges). In this paper, we measured z in Shaker IR (inactivation removed) K+ channels, neuronal alpha 1E and alpha 1A, and cardiac alpha 1C Ca2+ channels using two methods: (a) limiting slope analysis of the conductance-voltage relationship and (b) variance analysis, to evaluate the number of active channels in a patch, combined with the measurement of charge movement in the same patch. We found that in Shaker IR K+ channels the two methods agreed with a z congruent to 13. This suggests that all the channels that gate can open and that all the measured charge is coupled to pore opening in a strictly sequential kinetic model. For all Ca2+ channels the limiting slope method gave consistent results regardless of the presence or type of beta subunit tested (z = 8.6). However, as seen with alpha 1E, the variance analysis gave different results depending on the beta subunit used. alpha 1E and alpha 1E beta 1a gave higher z values (z = 14.77 and z = 15.13 respectively) than alpha 1E beta 2a (z = 9.50, which is similar to the limiting slope results). Both the beta 1a and beta 2a subunits, coexpressed with alpha 1E Ca2+ channels facilitated channel opening by shifting the activation curve to more negative potentials, but only the beta 2a subunit increased the maximum open probability. The higher z using variance analysis in alpha 1E and alpha 1E beta 1a can be explained by a set of charges not coupled to pore opening. This set of charges moves in transitions leading to nulls thus not contributing to the ionic current fluctuations but eliciting gating currents. Coexpression of the beta 2a subunit would minimize the fraction of nulls leading to the correct estimation of the number of channels and z.

Helothermine, a lizard venom toxin, inhibits calcium current in cerebellar granules.

Helothermine (HLTx), a 25.5-kDa peptide toxin isolated from the venom of the Mexican beaded lizard (Heloderma horridum horridum), was found to be an inhibitor of Ca2+ channels in cerebellar granule cells of newborn rats. Macroscopic currents, carried by 10 mM Ba2+, were measured in whole-cell configuration. The toxin at the saturating dose of 2.5 microM reversibly produced an approximately 67% block of the voltage-dependent Ca2+ current by a fast mechanism of action. The current inhibition and recovery were reached in less than 1 min. Inhibition was concentration-dependent, with a half-effective dose of 0.25 microM. The current block was practically voltage-independent, whereas the steady-state inactivation h infinity was significantly affected by HLTx (approximately 10 mV). The toxin did not affect the activation and inactivation kinetics of the Ca2+ current. Experiments with other Ca2+ channel blockers showed that HLTx abolished omega-cono-toxin GVIA-sensitive Ca2+ currents, as well as omega-Aga-IVA- and dihydropyridine-sensitive Ca2+ currents. These drugs had virtually no effect when HLTx was applied first. The present results indicate that HLTx produce a high-potency blockage of the three pharmacologically distinct Ca2+ current components.

Characterization of a voltage-dependent potassium channel in squid Schwann cells reconstituted in planar lipid bilayers.

An affinity column prepared with noxiustoxin (NTx), a K+ channel blocker from the venom of the Mexican scorpion Centruroides noxius, was used to purify a functional channel from a detergent extract of Schwann cell membrane of the giant axon of the squid Loligo vulgaris. The purified protein was reconstituted as a functional unit in a planar lipid bilayer and tested with a sequence of potentials to obtain information about single-channel amplitude and kinetics. The reconstituted channel showed delayed rectifier behavior with a slope conductance of 10 pS under 5:1 asymmetric KCl concentrations and a clear tendency to open under negative potentials. The zero-current potential was +36mV, which fitted well with the Nernst equation for the CIS/TRANS K(+)-concentration ratio of 5:1. The channel also showed a strong sensitivity to tetraethylammonium and its activity was inhibited by NTx, as expected from the purification procedure. The behavior of this protein in the presence of 0.5 mM ATP (cis side) was also tested, significantly increasing current fluctuations across the membrane. In order to compare the modulation of the Schwann cell K+ channel with that of the axonal K+ channel, a purified protein from the squid axon membrane was also tested in the presence of ATP. This 10-11 pS, delayed rectifier channel from the squid giant axon (Prestipino et al., FEBS Lett. 250:570-574, 1989) was also tested in the presence of ATP and showed a similar rise in activity.