Inactivation Of Calcium Channels Research Articles

Changes in extracellular Ca2+ can affect the pattern of discharge in rat thalamic neurons.

1. The aim of this study was to investigate some of the cellular mechanisms involved in the effects caused by changes in extracellular Ca2+ concentration ([Ca2+](o)). 2. Current- and voltage-clamp experiments were carried out on acutely isolated thalamic neurons of rats. 3. Increasing [Ca2+](o) alone induced a transition of the discharge from single spike to burst mode in isolated current-clamped neurons. 4. Increasing [Ca(2+)](o) caused the voltage-dependent characteristics of the low voltage-activated (LVA) transient Ca2+ currents to shift towards positive values on the voltage axis. Changing [Ca2+](o) from 0.5 to 5 mM caused the inactivation curve to shift by 21 mV. 5. Extracellular Ca2+ blocked a steady cationic current. This current reversed at -35 mV, was scarcely affected by Mg2+ and was completely blocked by the non-selective cation channel inhibitor gadolinium (10 microM). The effect of [Ca2+](o) was mimicked by 500 microM spermine, a polyamine which acts as an agonist for the Ca(2+)-sensing receptor, and was modulated by intracellular GTP-gamma-S. 6. At the resting potential, both the voltage shift and the block of the inward current removed the inactivation of LVA calcium channels and, together with the increase in the Ca2+ driving force, favoured a rise in the low threshold Ca2+ spikes, causing the thalamic firing to change to the oscillatory mode. 7. Our data indicate that [Ca2+](o) is involved in multiple mechanisms of control of the thalamic relay and pacemaker activity. These findings shed light on the correlation between hypercalcaemia, low frequency EEG activity and symptoms such as sleepiness and lethargy described in many clinical papers.

Identification of Inactivation Determinants in the Domain IIS6 Region of High Voltage-activated Calcium Channels

We have recently reported that transfer of the domain IIS6 region from rapidly inactivating R-type (alpha(1E)) calcium channels to slowly inactivating L-type (alpha(1C)) calcium channel confers rapid inactivation (Stotz, S. C., Hamid, J., Spaetgens, R. L., Jarvis, S. E., and Zamponi, G. W. (2000) J. Biol. Chem. 275, 24575-24582). Here we have identified individual amino acid residues in the IIS6 regions that are responsible for these effects. In this region, alpha(1C) and alpha(1E) channels differ in seven residues, and exchanging five of those residues individually or in combination did not significantly affect inactivation kinetics. By contrast, replacement of residues Phe-823 or Ile-829 of alpha(1C) with the corresponding alpha(1E) residues significantly accelerated inactivation rates and, when substituted concomitantly, approached the rapid inactivation kinetics of R-type channels. A systematic substitution of these residues with a series of other amino acids revealed that decreasing side chain size at position 823 accelerates inactivation, whereas a dependence of the inactivation kinetics on the degree of hydrophobicity could be observed at position 829. Although these point mutations facilitated rapid entry into the inactivated state of the channel, they had little to no effect on the rate of recovery from inactivation. This suggests that the development of and recovery from inactivation are governed by separate structural determinants. Finally, the effects of mutations that accelerated alpha(1C) inactivation could still be antagonized following coexpression of the rat beta(2a) subunit or by domain I-II linker substitutions that produce ultra slow inactivation of wild type channels, indicating that the inactivation kinetics seen with the mutants remain subject to regulation by the domain I-II linker. Overall, our results provide novel insights into a complex process underlying calcium channel inactivation.

Distinct Molecular Determinants Govern Syntaxin 1A-Mediated Inactivation and G-Protein Inhibition of N-Type Calcium Channels

We have reported recently that syntaxin 1A mediates two effects on N-type channels transiently expressed in tsA-201 cells: a hyperpolarizing shift in the steady-state inactivation curve as well as a tonic inhibition of the channel by G-protein betagamma subunits (Jarvis et al., 2000). Here we have examined some of the molecular determinants and factors that modulate the action of syntaxin 1A on N-type calcium channels. With the additional coexpression of SNAP25, the syntaxin 1A-induced G-protein modulation of the channel became reduced in magnitude by approximately 50% but nonetheless remained significantly higher than the low levels of background inhibition seen with N-type channels alone. In contrast, coexpression of nSec-1 did not reduce the syntaxin 1A-mediated G-protein inhibition; however, interestingly, nSec-1 was able to induce tonic G-protein inhibition even in the absence of syntaxin 1A. Both SNAP25 and nSec-1 blocked the negative shift in half-inactivation potential that was induced by syntaxin 1A. Activation of protein kinase C via phorbol esters or site-directed mutagenesis of three putative PKC consensus sites in the syntaxin 1A binding region of the channel (S802, S896, S898) to glutamic acid (to mimic a permanently phosphorylated state) did not affect the syntaxin 1A-mediated G-protein modulation of the channel. However, in the S896E and S898E mutants, or after PKC-dependent phosphorylation of the wild-type channels, the susceptibility of the channel to undergo shifts in half-inactivation potential was removed. Thus, separate molecular determinants govern the ability of syntaxin 1A to affect N-type channel gating and its modulation by G-proteins.

Fast Inactivation of Voltage-dependent Calcium Channels: A HINGED-LID MECHANISM?

We recently described domains II and III as important determinants of fast, voltage-dependent inactivation of R-type calcium channels (Spaetgens, R. L., and Zamponi, G. W. (1999) J. Biol. Chem. 274, 22428-22438). Here we examine in greater detail the structural determinants of inactivation using a series of chimeras comprising various regions of wild type alpha(1C) and alpha(1E) calcium channels. Substitution of the II S6 and/or III S6 segments of alpha(1E) into the alpha(1C) backbone resulted in rapid inactivation rates that closely approximated those of wild type alpha(1E) channels. However, neither individual or combined substitution of the II S6 and III S6 segments could account for the 60 mV more negative half-inactivation potential seen with wild type alpha(1E) channels, indicating that the S6 regions contribute only partially to the voltage dependence of inactivation. Interestingly, the converse replacement of alpha(1E) S6 segments of domains II, III, or II+III with those of alpha(1C) was insufficient to significantly slow inactivation rates. Only when the I-II linker region and the domain II and III S6 regions of alpha(1E) were concomitantly replaced with alpha(1C) sequence could inactivation be abolished. Conversely, introduction of the alpha(1E) domain I-II linker sequence into alpha(1C) conferred alpha(1E)-like inactivation rates, indicating that the domain I-II linker is a key contributor to calcium channel inactivation. Overall, our data are consistent with a mechanism in which inactivation of voltage-dependent calcium channels may occur via docking of the I-II linker region to a site comprising, at least in part, the domain II and III S6 segments.

Electrophysiological and pharmacological characteristics of buccal smooth muscle of the pest slug Deroceras reticulatum

Buccal mass muscle of the pest slug Deroceras reticulatum was examined by conventional tension recording and the sucrose-gap electrophysiological technique. Elevated potassium salines induced dose-dependent depolarisations accompanied by tonic contractures with superimposed rapid twitch contractions. The latter were suppressed at over 40 mmol · l−1 external potassium, where depolarisation-induced inactivation of voltage-sensitive calcium channels may have occurred. Acetylcholine caused significant dose-dependent depolarisations and tonic contractures, while 5-hydroxy tryptamine induced lower depolarisations accompanied by phasic contractile activity superimposed on low level tonic force. Of the purines examined only guanosine triphosphate caused significant mechanical activity above a threshold of 0.1 μmol · l−1. The tetrapeptides inhibited buccal muscle spontaneous activity, but the related small cardioactive peptide B was weakly excitatory. The amino acids glutamate and gamma-aminobutyric acid were weakly excitatory on buccal muscle while the molluscicides metaldehyde and methiocarb disrupted normal mechanical activity of the feeding musculature. Acetylcholine and 5-hydroxytryptamine appear to have major roles in regulating feeding muscle activity, seemingly modulated by guanosine triphosphate and inhibited by phenylalanine-methionine-arginine-phenylalanine-NH2 and phenylalanine-leucine-arginine-phenylalanine-NH2.

Role of gelsolin in the actin filament regulation of cardiac L-type calcium channels.

The actin cytoskeleton is an important contributor to the modulation of the cell function. However, little is known about the regulatory role of this supermolecular structure in the membrane events that take place in the heart. In this report, the regulation of cardiac myocyte function by actin filament organization was investigated in neonatal mouse cardiac myocytes (NMCM) from both wild-type mice and mice genetically devoid of the actin filament severing protein gelsolin (Gsn-/-). Cardiac L-type calcium channel currents (I(Ca)) were assessed using the whole cell voltage-clamp technique. Addition of the actin filament stabilizer phalloidin to wild-type NMCM increased I(Ca) by 227% over control conditions. The basal I(Ca) of Gsn-/- NMCM was 300% higher than wild-type controls. This increase was completely reversed by intracellular perfusion of the Gsn-/- NMCM with exogenous gelsolin. Further, cytoskeletal disruption of either Gsn-/- or phalloidin-dialyzed wild-type NMCM with cytochalasin D (CD) decreased the enhanced I(Ca) by 84% and 87%, respectively. The data indicate that actin filament stabilization by either a lack of gelsolin or intracellular dialysis with phalloidin increase I(Ca), whereas actin filament disruption with CD or dialysis of Gsn-/- NMCM with gelsolin decrease I(Ca). We conclude that cardiac L-type calcium channel regulation is tightly controlled by actin filament organization. Actin filament rearrangement mediated by gelsolin may contribute to calcium channel inactivation.

Inactivation determinant in the I-II loop of the Ca2+ channel alpha1-subunit and beta-subunit interaction affect sensitivity for the phenylalkylamine (-)gallopamil.

1. The role of calcium (Ca2+) channel inactivation in the molecular mechanism of channel block by phenylalkylamines (PAAs) was analysed in a PAA-sensitive rabbit brain class A Ca2+ channel mutant (alpha1A-PAA). Use-dependent barium current (IBa) inhibition of alpha1A-PAA by (-)gallopamil and Ca2+ channel recovery from inactivation and block were studied with two-microlectrode voltage clamp after expression of alpha1A-PAA and auxiliary alpha2-delta- and beta1a- or beta2a-subunits in Xenopus oocytes. 2. Mutation Arg387Glu (alpha1A numbering) in the intracellular loop connecting domains I and II of alpha1A-PAA slowed the inactivation kinetics and reduced use-dependent inhibition (100 ms test pulses at 0.2 Hz from -80 to 20 mV) of the resulting mutant alpha1A-PAA/R-E/beta1a channels by 100 microM (-)gallopamil (53 +/- 2 %, alpha1A-PAA/beta1a vs. 31 +/- 2 %, alpha1A-PAA/R-E/beta1a, n >= 4). This amino acid substitution simultaneously accelerated the recovery of channels from inactivation and from block by (-)gallopamil. 3. Coexpression of alpha1A-PAA with the beta2a-subunit reduced fast IBa inactivation and induced a substantial reduction in use-dependent IBa inhibition by (-)gallopamil (25 +/- 4 %, alpha1A-PAA/beta2a; 13 +/- 1 %, alpha1A-PAA/R-E/beta2a). The time constant of recovery from block at rest was not significantly affected. 4. These results demonstrate that changes in channel inactivation induced by Arg387Glu or beta2a-alpha1-subunit interaction affect the drug-channel interaction.

Calmodulin supports both inactivation and facilitation of L-type calcium channels.

L-type Ca2+ channels support Ca2+ entry into cells, which triggers cardiac contraction, controls hormone secretion from endocrine cells and initiates transcriptional events that support learning and memory. These channels are examples of molecular signal-transduction units that regulate themselves through their own activity. Among the many types of voltage-gated Ca2+ channel, L-type Ca2+ channels particularly display inactivation and facilitation, both of which are closely linked to the earlier entry of Ca2+ ions. Both forms of autoregulation have a significant impact on the amount of Ca2+ that enters the cell during repetitive activity, with major consequences downstream. Despite extensive biophysical analysis, the molecular basis of autoregulation remains unclear, although a putative Ca2+-binding EF-hand motif and a nearby consensus calmodulin-binding isoleucine-glutamine ('IQ') motif in the carboxy terminus of the alpha1C channel subunit have been implicated. Here we show that calmodulin is a critical Ca2+ sensor for both inactivation and facilitation, and that the nature of the modulatory effect depends on residues within the IQ motif important for calmodulin binding. Replacement of the native isoleucine by alanine removed Ca2+-dependent inactivation and unmasked a strong facilitation; conversion of the same residue to glutamate eliminated both forms of autoregulation. These results indicate that the same calmodulin molecule may act as a Ca2+ sensor for both positive and negative modulation.

N-Type Calcium Channel Inactivation Probed by Gating-Current Analysis

N-type calcium channels inactivate most rapidly in response to moderate, not extreme depolarization. This behavior reflects an inactivation rate that bears a U-shaped dependence on voltage. Despite this apparent similarity to calcium-dependent inactivation, N-type channel inactivation is insensitive to the identity of divalent charge carrier and, in some reports, to the level of internal buffering of divalent cations. Hence, the inactivation of N-type channels fits poorly with the “classic” profile for either voltage-dependent or calcium-dependent inactivation. To investigate this unusual inactivation behavior, we expressed recombinant N-type calcium channels in mammalian HEK 293 cells, permitting in-depth correlation of ionic current inactivation with potential alterations of gating current properties. Such correlative measurements have been particularly useful in distinguishing among various inactivation mechanisms in other voltage-gated channels. Our main results are the following: 1) The degree of gating charge immobilization was unchanged by the block of ionic current and precisely matched by the extent of ionic current inactivation. These results argue for a purely voltage-dependent mechanism of inactivation. 2) The inactivation rate was fastest at a voltage where only ∼ 1/3 of the total gating charge had moved. This unusual experimental finding implies that inactivation occurs most rapidly from intermediate closed conformations along the activation pathway, as we demonstrate with novel analytic arguments applied to coupled-inactivation schemes. These results provide strong, complementary support for a “preferential closed-state” inactivation mechanism, recently proposed on the basis of ionic current measurements of recombinant N-type channels (Patil et al., 1998. Neuron. 20:1027–1038).

Calmodulin Is the Ca 2+ Sensor for Ca 2+-Dependent Inactivation of L-Type Calcium Channels

Elevated intracellular Ca 2+ triggers inactivation of L-type calcium channels, providing negative Ca 2+ feedback in many cells. Ca 2+ binding to the main α 1C channel subunit has been widely proposed to initiate such Ca 2+-dependent inactivation. Here, we find that overexpression of mutant, Ca 2+-insensitive calmodulin (CaM) ablates Ca 2+-dependent inactivation in a “dominant-negative” manner. This result demonstrates that CaM is the actual Ca 2+ sensor for inactivation and suggests that CaM is constitutively tethered to the channel complex. Inactivation is likely to occur via Ca 2+-dependent interaction of tethered CaM with an IQ-like motif on the carboxyl tail of α 1C. CaM also binds to analogous IQ regions of N-, P/Q-, and R-type calcium channels, suggesting that CaM-mediated effects may be widespread in the calcium channel family.

Mutations in the EF-Hand Motif Impair the Inactivation of Barium Currents of the Cardiac α1C Channel

Calcium-dependent inactivation has been described as a negative feedback mechanism for regulating voltage-dependent calcium influx in cardiac cells. Most recent evidence points to the C-terminus of the α 1C subunit, with its EF-hand binding motif, as being critical in this process. The EF-hand binding motif is mostly conserved between the C-termini of six of the seven α 1 subunit Ca 2+ channel genes. The role of E1537 in the C-terminus of the α 1C calcium channel inactivation was investigated here after expression in Xenopus laevis oocytes. Whole-cell currents were measured in the presence of 10 mM Ba 2+ or 10 mM Ca 2+ after intracellular injection of 1,2-bis(2-aminophenoxy)ethane- N, N, N′, N′-tetraacetic acid. Against all expectations, our results showed a significant reduction in the rate of voltage-dependent inactivation as measured in Ba 2+ solutions for all E1537 mutants, whereas calcium-dependent inactivation appeared unscathed. Replacing the negatively charged glutamate residue by neutral glutamine, glycine, serine, or alanine significantly reduced the rate of Ba 2+-dependent inactivation by 1.5-fold (glutamine) to 3.5-fold (alanine). The overall rate of macroscopic inactivation measured in Ca 2+ solutions was also reduced, although a careful examination of the distribution of the fast and slow time constants suggests that only the slow time constant was significantly reduced in the mutant channels. The fast time constant, the hallmark of Ca 2+-dependent inactivation, remained remarkably constant among wild-type and mutant channels. Moreover, inactivation of E1537A channels, in both Ca 2+ and Ba 2+ solutions, appeared to decrease with membrane depolarization, whereas inactivation of wild-type channels became faster with positive voltages. All together, our results showed that E1537 mutations impaired voltage-dependent inactivation and suggest that the proximal part of the C-terminus may play a role in voltage-dependent inactivation in L-type α 1C channels.

Preferential Closed-State Inactivation of Neuronal Calcium Channels

We have investigated the inactivation mechanism of neuronal N-, P/Q-, and R-type calcium channels. Although channels inactivate slowly during square-pulse depolarization, as observed previously, we now find that they inactivate profoundly during a train of action potential (AP) waveforms. The apparent paradox arises from a voltage-dependent mechanism in which channels inactivate preferentially from intermediate closed states along the activation pathway. Inactivation can therefore extend beyond the brief duration of AP waveforms to continue between spikes, as the channel undergoes repetitive cycles of activation and deactivation. The extent of inactivation during a train is strongly affected by the subunit composition of channels. Preferential closed-state inactivation of neuronal calcium channels could produce widely variable depression of Ca 2+ entry during a train of APs.

Carbon dioxide and the cerebral circulation.

Carbon dioxide and the cerebral circulation.

In Vivoandin VitroInhibition of theL-type Calcium Current in Isolated Guinea-pig Cardiomyocytes by the Immunosuppressive Agent Cyclosporin A

Cyclosporin A (CsA), an immunosuppressive agent used to reduce rejection after organ transplantation, induces secondary effects in heart tissue. We have studied the effectsin vivoandin vitroof CsA onl-type Ca2+current (ICa) and the associated gating currents of isolated guinea-pig ventricular myocytes using the whole-cell patch-clamp technique. Forin vivoexperiments, a group of animals (n=28) was treated for 21 days by subcutaneous injection of CsA (15 mg/kg/day). Blood level of CsA was 1191±221 ng/ml (n=9). In cells from these animals (n=65, 19 animals), ICawas reduced to about 75% of that recorded from control cells (n=32, six animals). CsA decreased the availability of Ca2+channels at potentials more positive than +30 mV. Isoproterenol (100 nm) was still able to increase ICabut only by 30±6% (n=9), whereas in control it increased ICaby 290±22% (n=5). Gating currents related tol-type Ca2+channels were not altered in cells from CsA-treated animals. Inin vitroexperiments, CsA reduced ICawhen applied directly to cardiomyocytes. CsA affected the kinetics of ICainactivation, slowing down the rapid phase and accelerating the slow phase (n=4). The steady-state inactivation curve of ICawas shifted to more negative voltages and the degree of availability at −80 mV decreased byin vitroapplication of CsA. The half inactivation potential (V1/2) changed from −23±0.6 mV in control to −31±2 mV, −48±0.6 mV and −49±0.6 mV, in 1, 50 and 80μmCsA, respectively. In these cells, the gating currents related tol-type Ca2+channels were also not altered by CsA. CsA does not modify the Ca2+channel density, although it induces a decrease in theβ1-adrenergic stimulation of ICa. The results are explained by a direct effect on the calcium channel inactivation of CsA and a non specific indirect effect.

Mechanisms of inactivation of L-type calcium channels in human atrial myocytes.

We used whole cell patch-clamp and microfluorimetric (indo 1) techniques to measure Ca2+ current through L-type Ca2+ channels (I(Ca)) and Ca2+ transients in human atrial myocytes. During 1-s depolarizing pulses, I(Ca) inactivation was biexponential. The rate of rapid inactivation was slowed by ryanodine and was correlated with the rate of rise of cytoplasmic free Ca2+ concentration (r = 0.80, P < 0.01). Slower-phase I(Ca) inactivation was not affected by ryanodine but was accelerated by increasing the availability of Ca2+ to permeate the Ca2+ channel. Thus Ca2+ released from the sarcoplasmic reticulum (SR) was responsible for most I(Ca) inactivation during the first 50 ms of a depolarization to 0 mV, and thereafter inactivation by Ca2+ permeating the channel predominated. Pure voltage-dependent inactivation had a much slower time course of development (tau > 2 s) and played a smaller role than Ca2+-dependent mechanisms over a duration comparable to that of an action potential. We conclude that human atrial myocytes show both voltage- and Ca2+-dependent I(Ca) inactivation, that Ca2+-dependent mechanisms predominate over the time course of an action potential, and that although both Ca2+ released from the SR and Ca2+ permeating Ca2+ channels play a role, SR-released Ca2+ is particularly important in early, rapid I(Ca) inactivation, whereas Ca2+ permeating Ca2+ channels is more important in the slower phase of Ca2+-dependent inactivation.

Identification of a second region of the beta-subunit involved in regulation of calcium channel inactivation.

Previous studies have shown that NH2 termini of the type 1 and 2 beta-subunits modulate the rate at which the neuronal alpha 1E calcium channel inactivates in response to voltage and that they do so independently of their common effect to stimulate activation by voltage (R. Olcese, N. Qin, T. Schneider, A. Neely, X. Wei, E. Stefani, and L. Birnbaumer, Neuron 13: 1433-1438, 1994). By constructing NH2-terminal deletions of several splice variants of beta-subunits, we have now found differences in the way they affect the rate of alpha 1E inactivation that lead us to identify a second domain that also regulates the rate of voltage-induced inactivation of the Ca2+ channel. This second domain, named segment 3, lies between two regions of high-sequence identity between all known beta-subunits and exists in two lengths (long and short), each encoded in a separate exon. Beta-Subunits with the longer 45- to 53-amino acid version cause the channel to inactivate more slowly than subunits with the shorter 7-amino acid version. As is the case for the NH2 terminus, the segment 3 does not affect the regulation of channel activation by the beta-subunit. In addition, the effect of the NH2-terminal segment prevails over that of the internal segment. This raises the possibility that phosphorylation, other types of posttranslational modification, or interaction with other auxiliary calcium channel subunits may be necessary to unmask the regulatory effect of the internal segment.

Voltage gated calcium channels in molluscs: classification, Ca2+ dependent inactivation, modulation and functional roles.

Molluscan neurons and muscle cells express transient (T-type like) and sustained LVA calcium channels, as well as transient and sustained HVA channels. In addition weakly voltage sensitive calcium channels are observed. In a number of cases toxin or dihydropyridine sensitivity justifies classification of the HVA currents in L, N or P-type categories. In many cases, however, pharmacological characterization is still preliminary. Characterization of novel toxins from molluscivorous Conus snails may facilitate classification of molluscan calcium channels. Molluscan preparations have been very useful to study calcium dependent inactivation of calcium channels. Proposed mechanisms explain calcium dependent inactivation through direct interaction of Ca2+ with the channel, through dephosphorylation by calcium dependent phosphatases or through calcium dependent disruption of connections with the cytoskeleton. Transmitter modulation operating through various second messenger mediated pathways is well documented. In general, phosphorylation through PKA, cGMP dependent PK or PKC facilitates the calcium channels, while putative direct G-protein action inhibits the channels. Ca2+ and cGMP may inhibit the channels through activation of phosphodiesterases or phosphatases. Detailed evidence has been provided on the role of sustained LVA channels in pacemaking and the generation of firing patterns, and on the role of HVA channels in the dynamic changes in action potentials during spiking, the regulation of the release of transmitters and hormones, and the regulation of growth cone behavior and neurite outgrowth. The accessibility of molluscan preparations (e.g. the squid giant synapse for excitation release studies, Helisoma B5 neuron for neurite and synapse formation) and the large body of knowledge on electrophysiological properties and functional connections of identified molluscan neurons (e.g. sensory neurons, R15, egg laying hormone producing cells, etc.) creates valuable opportunities to increase the insight into the functional roles of calcium channels.

Membrane stiffness and channel function.

Alterations in the stiffness of lipid bilayers are likely to constitute a general mechanism for modulation of membrane protein function. Gramicidin channels can be used as molecular force transducers to measure such changes in bilayer stiffness. As an application, we show that N-type calcium channel inactivation is shifted reversibly toward negative potentials by synthetic detergents that decrease bilayer stiffness. Cholesterol, which increases bilayer stiffness, shifts channel inactivation toward positive potentials. The voltage activation of the calcium channels is unaffected by the changes in stiffness. Changes in bilayer stiffness can be predicted from the molecular shapes of membrane-active compounds, which suggests a basis for the pharmacological effects of such compounds.

Extracellular inhibition and intracellular enhancement of Ca2+ currents by Pb2+ in bovine adrenal chromaffin cells.

1. Effects of highly neurotoxic, inorganic lead ions (Pb2+) on voltage-dependent calcium channels were investigated with the use of the whole cell patch-clamp technique in bovine adrenal chromaffin cells maintained in short-term primary culture (1-5 days). 2. Extracellularly applied Pb2+ induced a concentration-dependent, reversible inhibition of Ca2+ currents, with an estimated IC50 approximately equal to 3.0 x 10(-7) M free Pb2+. 3. Elevation of the intracellular free Ca2+ concentration above 10(-8) M dose-dependently reduced the amplitude of the initial Ca2+ current and increased the exponential rate of current rundown. 4. Intracellularly applied Pb2+ prevented the Ca(2+)-dependent reduction of the initial Ca2+ current amplitude and altered the current rundown kinetics from exponential to linear. The effect was dose dependent and saturable, with an estimated EC50 approximately equal to 2.0 x 10(-10) M free Pb2+. 5. These results indicate that in contrast to extracellular blockade, intracellular Pb2+ promotes Ca2+ currents by attenuating the Ca(2+)-dependent, steady-state inactivation of calcium channels. This provides a novel mechanism through which Pb2+ may disrupt calcium signaling in chronically lead-exposed cells.

Involvement of the Carboxyl-terminal Region of the α1 Subunit in Voltage-dependent Inactivation of Cardiac Calcium Channels

Intracellular application of proteases increases cardiac calcium current to a level similar to beta-adrenergic stimulation. Using transiently transfected HEK 293 cells, we studied the molecular mechanism underlying calcium channel stimulation by proteolytic treatment. Perfusion of HEK cells, coexpressing the human cardiac (hHT) alpha 1, alpha 2, and beta 3 subunits, with 1 mg/ml of trypsin or carboxypeptidase A, increased the peak amplitude of the calcium channel current 3-4-fold without affecting the voltage dependence. Similar results were obtained in HEK cells cotransfected with hHT alpha 1 and alpha 2 or with alpha 1 alone, suggesting that modification of the alpha 1 subunit itself is responsible for the current enhancement by proteolysis. To further characterize the modification of the alpha 1 subunit by trypsin, we expressed a deletion mutant in which part of the carboxyl-terminal tail up to amino acid 1673 was removed. The expressed calcium channel currents no longer responded to intracellular application of the proteases; however, a 3-fold higher current density as well as faster inactivation compared with the wild type was observed. The results provide evidence that a specific region of the carboxyl-terminal tail of the cardiac alpha 1 subunit is an important regulatory segment that may serve as a critical component of the gating machinery that influences both inactivation properties as well as channel availability.