Time Constant Of Inactivation Research Articles

Enhancement of sodium metabisulfite on sodium currents in acutely isolated rat hippocampal CA1 neurons

The effect of sodium metabisulfite (SMB) on voltage-gated sodium channel currents ( I Na) was examined in freshly isolated rat hippocampal CA1 neurons using whole-cell patch-clamp technique under voltage-clamp conditions. SMB irreversibly enhanced I Na in a concentration-dependent manner, shifted the inactivation curve to more positive potential, without affecting the current activation curve. In addition, SMB increased the time to peak and the inactivation time constant of I Na. Superoxide dismutase (SOD), catalase (CAT) and glutathione peroxidase (GPx) could all partly inhibit the effect of SMB on the sodium current. These results suggested that SMB have neuronal toxicity by increasing the excitability of neurons and its mechanism might involve the oxidative damage on ion channels.

Effect of the Antifibrillatory Compound Tedisamil (KC-8857) on Transmembrane Currents in Mammalian Ventricular Myocytes

The cellular mechanism of action of tedisamil (KC-8857) (TED), a novel antiarrhythmic/antifibrillatory compound, was studied on transmembrane currents in guinea pig, rabbit and dog ventricular myocytes by applying the patch-clamp and the conventional microelectrode technique. In guinea pig myocytes the rapid component of the delayed rectifier potassium current (IKr) was largely diminished by 1 microM TED (from 0.88+/-0.17 to 0.23+/-0.07 pA/pF, n=5, p<0.05), while its slow component (IKs) was reduced only by 5 microM TED (from 8.1+/-0.3 to 4.23+/-0.07 pA/pF, n=5, p<0.05). TED did not significantly change the IKr and IKs kinetics. In rabbit myocytes 1 microM TED decreased the amplitude of the transient outward current (I(to)) from 20.3+/-4.9 to 13.9+/-2.8 pA/pF (n=5, p<0.05), accelerated its fast inactivation time constant from 8.3+/-0.6 to 3.5+/-0.5 ms (n=5, p<0.05) and reduced the ATP-activated potassium current (IKATP) from 38.2+/-11.8 to 18.4+/-4.7 pA/pF (activator: 50 microM cromakalim; n=5, p<0.05). In dog myocytes 2 microM TED blocked the fast sodium current (INa) with rapid onset and moderately slow offset kinetics, while the inward rectifier potassium (IK1), the inward calcium (ICa) and even the I(to) currents were not affected by TED in concentration as high as 10 microM. The differences in I(to) responsiveness between dog and rabbit are probably due to the different alpha-subunits of I(to) in these species. It is concluded that inhibition of several transmembrane currents, including IKr, IKs, I(to), IKATP and even INa, can contribute to the high antiarrhythmic/antifibrillatory potency of TED, underlying predominant Class III combined with I A/B type antiarrhythmic characteristics.

Effects of sodium metabisulfite on potassium currents in acutely isolated CA1 pyramidal neurons of rat hippocampus

The effects of sodium metabisulfite (SMB), a food preservative mostly used in food and drug industries, on voltage-dependent potassium currents in acutely isolated hippocampal CA1 pyramidal neurons of rat were studied using the whole-cell patch-clamp techniques. SMB increased transient outward potassium current (IA) and delayed rectifier potassium current (IK) in a concentration-dependent manner. 10μM SMB shifted the steady-state activation curve of IK to more negative potentials, and the steady-state inactivation curves of IA and IK to more positive potentials. Time to peak of IA was not affected, but the decay of IA was delayed by SMB. However, the activation and inactivation time constants of IK were both decreased by SMB. These results suggested that SMB differently affected IA and IK, and it would decrease the excitability of hippocampal neuron by increasing potassium currents.

Changes in somatic sodium currents of ganglion cells during retinal regeneration in the adult newt

Adult newts can regenerate their entire retinas following a complete removal of the original tissues. During retinal regeneration, ganglion cells differentiate first from the progenitor cells, and develop their capability of spike firing. In the present study, to understand the process of functional differentiation of ganglion cells, we investigated alterations of their voltage-gated sodium currents during retinal regeneration by a whole-cell patch-clamp technique. To minimize space clamp errors, sodium currents were recorded from neurite-free somata of presumptive ganglion cells that were mechanically isolated from living slices of regenerating retinas at different morphological stages. During retinal regeneration, the somatic sodium current density was increased 2.6-fold (48 to 123 pF/pA) and the half-activating voltage was shifted slightly to more hyperpolarizing membrane potentials (−10 to −13 mV), while steady-state inactivation was not changed obviously. Curve fitting analysis of currents revealed that the sodium current consists of two components with different inactivation time constants. During retinal regeneration, the ratio of slow to fast inactivating current component was increased 2.6-fold (0.11 to 0.29). These results suggest that the somatic sodium currents of ganglion cells may undergo modifications of their voltage dependence and kinetic properties during retinal regeneration. A small number of the presumptive ganglion cells in regenerating retinas with a segregating inner plexiform layer exhibited sodium currents comparable to those in the normal retina. This might suggest that maturational regulation of sodium channel function starts during a period of synaptic layer formation within the retina.

Photodynamic Inactivation of the Na,K-ATPase Occurs via Different Pathways

The photodynamic, i.e., the light-induced, inactivation of the Na,K-ATPase in the presence of the sensitizer rose bengal was studied under different conditions. The shape of inactivation curves of the enzyme activity was analyzed as well as partial reactions of the pump cycle. Both experimental approaches showed the existence of two different time constants of inactivation of the ion pump, which reflect two pathways of a photodynamic modification. This is supported by the following observations: (1) The amplitude of the initial fast decay of enzyme activity was enhanced in the presence of D2O and reduced in the presence of the singlet oxygen scavenger imidazole. (Similar results were found for the SR Ca-ATPase.) (2) Contrary to the fast enzyme inactivation the slow process shows an inverse dose-rate behavior. (3) Inactivation of the partial reactions of Na+ -binding and of K+-binding to the membrane domain of the Na,K-ATPase showed only a single time constant, which corresponded to the slower time constant of enzyme inactivation. In the presence of high concentrations of singlet oxygen the fast time constant dominated the inactivation of the ATP-induced partial reaction for which the cytoplasmic domains of the enzyme play an important role. The data support the conclusion that fast inactivation is due to modification of the cytoplasmic domains and slow inactivation due to modifications of the membrane domain of the ion pumps.

“Disinactivation” of N-type Inactivation of Voltage-gated K Channels by an Erbstatin Analogue

In some A-type voltage-gated K channels, rapid inactivation is achieved through the binding of an N-terminal domain of the pore-forming alpha-subunit or an associated beta-subunit to a cytoplasmic acceptor located at or near the channel pore using the ball-and-chain machinery (1-5). This inactivation involving the N terminus is known as N-type inactivation. Here, we describe an erbstatin (Erb) analogue as a small molecule inhibitor of the N-type inactivation in channels of Kv1.4 and Kv1.1+Kvbeta1. We show that this inhibition of inactivation (designated as "disinactivation") is potent and selective for N-type inactivation in heterologous cells (Chinese hamster ovary and Xenopus oocytes) expressing these A-type channels. In Chinese hamster ovary cells, Erb increased the inactivation time constant of Kv1.4 from 86.5 +/- 9.5 to 150 +/- 10 ms (n = 6, p < 0.0 1). Similarly, Erb increased the inactivation time constant of Kv1.1+Kvbeta1 from 10 +/- 0.9 to 49.3 +/- 7 ms (n = 7, p < 0.01). The EC(50) for disinactivating Kv1.1+Kvbeta1 was 10.4 +/- 0.9 microm (n = 2-9). Erb had no effect upon another A-channel, Kv4.3, which does not utilize the ball-and-chain mechanism. The mechanism of Erb-induced disinactivation was also investigated. Neither cysteine oxidation nor tyrosine kinase inhibition was involved. The results demonstrate that Erb can be used as a base structure to identify potent, selective small molecule inhibitors of intracellular protein-protein interactions, and that these disinactivators may offer another therapeutic approach to the treatment of seizure disorders.

Effects of aluminum chloride on sodium current, transient outward potassium current and delayed rectifier potassium current in acutely isolated rat hippocampal CA1 neurons

The effects of aluminum chloride (AlCl 3) on sodium current ( I Na), the transient outward potassium ( I A) and delayed rectifier potassium currents ( I K) in hippocampal CA1 neurons of rats were studied using the whole cell patch-clamp technique. AlCl 3 decreased I Na, I A, and I K in a partly reversible, dose and voltage-dependent manner. AlCl 3 prolonged the time to peak of I Na, and increased the inactivation time constants of I Na and I A. In addition, 1000 μM AlCl 3 shifted the voltage dependence of steady-state activation of I Na, I A and I K toward positive potential, and the voltage dependence of steady-state inactivation of I Na, I A toward negative potential. These results imply that AlCl 3 could affect the activation and inactivation courses of sodium current and potassium current of rat hippocampal CA1 neurons, which may contribute to damage of the central nervous system by aluminum.

Multiple Structural Elements Contribute to the Slow Kinetics of the Cav3.3 T-type Channel

Molecular cloning and expression studies established the existence of three T-type Ca(2+) channel (Ca(v)3) alpha(1) subunits: Ca(v)3.1 (alpha(1G)), Ca(v)3.2 (alpha(1H)), and Ca(v)3.3 (alpha(1I)). Although all three channels are low voltage-activated, they display considerable differences in their kinetics, with Ca(v)3.1 and Ca(v)3.2 channels activating and inactivating much faster than Ca(v)3.3 channels. The goal of the present study was to determine the structural elements that confer the distinctively slow kinetics of Ca(v)3.3 channels. To address this question, a series of chimeric channels between Ca(v)3.1 and Ca(v)3.3 channels were constructed and expressed in Xenopus oocytes. Kinetic analysis showed that the slow activation and inactivation kinetics of the Ca(v)3.3 channel were not completely abolished by substitution with any one portion of the Ca(v)3.1 channel. Likewise, the Ca(v)3.1 channel failed to acquire the slow kinetics by simply adopting one portion of the Ca(v)3.3 channel. These findings suggest that multiple structural elements contribute to the slow kinetics of Ca(v)3.3 channels.

Block of HERG current expressed in HEK293 cells by the Na+-channel blocker cibenzoline.

A Na(+)-channel blocker, cibenzoline, blocks the delayed rectifier potassium current ( I(k)), but its detailed action on the rapidly activating component ( I(kr)) of I(k) encoded by the human ether-a-go-go-related gene ( HERG) has not been clarified. We examined the effects of cibenzoline on stably expressed HERG current in HEK293 cells recorded by the patch-clamp technique of whole-cell configuration. Cibenzoline blocked HERG current expressed in HEK293 cells with IC(50) = 3.7 +/- 0.963 micro M and Hill coefficient = 0.74 +/- 0.12. Voltage-depended activation was shifted in a negative direction by cibenzoline. No block or minor block was induced at test depolarization of -40 to -30 mV, and the block increased with depolarization reaching a plateau at 0 mV without a further increase at positive voltages. Voltage-dependent activation of HERG currents became faster at negative test voltages but there were no changes at positive voltages after cibenzoline. No frequency-dependent block of HERG tail current by cibenzoline after equilibration was noted between 1.33 and 0.2 Hz. Steady-state inactivation of the HERG current was shifted in a negative direction by approximately 8 mV but the time constants of fast inactivation were little affected by cibenzoline. Cibenzoline blocks the I(kr)-like current reconstituted by HERG clone transfection with an IC(50) value comparable to therapeutic concentrations. Cibenzoline has a preferential affinity, at least, to the open state of the HERG channel with a rapid access to the binding site.

Post‐inhibitory rebound properties of dopaminergic cells of the ventral tegmental area

AbstractWe have investigated the post‐inhibitory rebound (PIR) properties of dopamine cells in the ventral tegmental area of the rat midbrain. Using microelectrodes to record intracellularly from rat cells in the midbrain slice, we found that 54% of all recorded DA cells exhibited rebound depolarization in the presence of TTX. We observed primarily two types of rebound responses distinguished by their maximum amplitude and inactivation time constant, which we have termed as the ‘slowly inactivating PIR’ and low‐threshold spike (LTS). 35% of DA cells exhibited a ‘slowly inactivating PIR’ and 19% showed LTS. A subset of the latter exhibited repetitive LTS. The PIR was enhanced in high K+ medium and suppressed in low‐calcium medium. Under voltage clamp conditions, inward rebound currents at the end of a hyperpolarizing voltage step were partially blocked by specific T‐type channel blocker, Ni2+. Repetitive LTSs were reversibly changed to single LTS by blocking the potassium SK current.

Effect of a 125 mT static magnetic field on the kinetics of voltage activated Na+ channels in GH3 cells.

Voltage activated Na(+) channels were examined in GH3 cells, using the whole cell patch clamp method. Channel currents were recorded before, during, and after a 150 s exposure to a 125 mT static magnetic field. There was a slight shift in the current-voltage relationship and a less than 5% reduction in peak current during magnetic field exposure. More pronounced, however, was an increase in the activation time constant, tau(m), during and for at least 100 s following exposure to the field. This change in tau(m) was seen primarily at lower activation voltages. No change was noted in the inactivation time constant, tau(h). Changes were clearly temperature dependent, being evident only at and above 35 degrees C. These findings are consistent with the hypothesis that reorientation of diamagnetic anisotropic molecules in the cell membrane are capable of distorting imbedded ion channels sufficiently to alter their function. The temperature dependence of this phenomenon is probably due to the greater ease with which a liquid crystal membrane can be deformed.

The electrical behaviour of rat connexin46 gap junction channels expressed in transfected HeLa cells.

Pairs of human HeLa cells expressing rat connexin46 were used to study the electrical properties of gap junction channels with the dual voltage-clamp method. The steady-state conductance ( g(j,ss)) had a bell-shaped dependence on transjunctional voltage ( V(j)). The parameters of the Boltzmann fit were: V(j,0)=42 mV, g(j,min)=0.12, z=2.5 (pipette solution: K(+) aspartate(-); 27 degrees C). The Boltzmann parameters were sensitive to the ionic composition of the pipette solution (KCl, K(+) aspartate(-), TEA(+) Cl(-), TEA(+) aspartate(-)). The V(j)-dependent inactivation of the junctional current I(j) was approximated by single exponentials (exceptions: two exponentials with KCl at V(j)>or=75 mV and K(+) aspartate(-) at V(j)=125 mV). The time constant of inactivation (tau(i)) decreased with increasing V(j) and was sensitive to the pipette solution. The larger the ions, the slower the inactivation. Recovery from inactivation followed a single exponential. The time constant of recovery (tau(r)) increased with increasing V(j). Single-channel currents showed a main state, several substates and a residual state. The corresponding conductances gamma(j,main) and gamma(j,residual) decreased slightly with increasing V(j); extrapolation to V(j)=0 mV yielded values of 152 and 28 pS, respectively (K(+) aspartate(-); 37 degrees C). The values of gamma(j,main) and gamma(j,residual) were dependent on pipette solution. The ratio gamma(j,main)/gamma(j,residual) increased with increasing ionic size, suggesting that the residual state impairs ion permeation more severely than the main state. The gamma(j,main) data suggest that the ionic selectivity of Cx46 channels may be controlled primarily by ionic size. Compared with hemichannel results, docking of connexons may modify the channel structure and thereby affect the ionic selectivity of gap junction channels. The open channel probability at steady state ( P(o)) decreased with increasing V(j). The parameters of the Boltzmann fit were: V(j,0)=41 mV, z=2.2 (K(+) aspartate(-); 27 degrees C).

Developmental regulation of the a-type potassium-channel current in hippocampal neurons: role of the kvβ1.1 subunit

The rapidly inactivating A-type K + current (I A) is prominent in hippocampal neurons; and the speed of its inactivation may regulate electrical excitability. The auxiliary K + channel subunit Kvβ1.1 confers fast inactivation to Shaker-related channels and is postulated to affect I A. Whole-cell patch clamp recordings of rat hippocampal pyramidal neurons in primary culture showed a developmental decrease in the time constant of inactivation (τ in) of voltage-gated K + currents: 17.9±1.5 ms in young neurons (5–7 days in vitro; n=53, mean±S.E.M.); 9.9±1.0 ms in mature neurons (12–15 days in vitro; n=72, mean±S.E.M., P<0.01). During the same developmental time, the level of Kvβ1.1 transcript increased more than two-fold in vitro and in vivo, determined by semi-quantitative reverse transcriptase-polymerase chain reaction for hippocampus. The hypothesis that up-regulation of Kvβ1.1 led to the changes in τ in was tested in vitro, using antisense knockdown. Kvβ1.1-specific antisense DNA was introduced with a modified herpes virus co-expressing enhanced green fluorescent protein and knockdown of Kvβ1.1 was verified by immunocytochemistry. Following transduction with the antisense virus, mature neurons reverted to τ in values characteristic of young neurons: 18.3±2.4 ms ( n=20). The effect of antisense knockdown on electrical excitability was tested using current-clamp protocols to induce repetitive firing. Treatment with the antisense virus increased the interspike interval over a range of membrane depolarization (baseline membrane potential=−40 to +20 mV). This effect was most pronounced at −40 mV, where the ISI of the first pair of action potentials was nearly doubled. These data indicate that Kvβ1.1 contributes to the developmental control of I A in hippocampal neurons and that the magnitude of effect is sufficient to regulate electrical excitability. Viral-mediated antisense knockdown of Kvβ1.1 is capable of decreasing the electrical excitability of post-mitotic hippocampal neurons, suggesting this approach has applicability to gene therapy of neurological diseases associated with hyperexcitability.

Lucifer Yellow slows voltage-gated Na+ current inactivation in a light-dependent manner in mice.

Lucifer Yellow CH (LY), a membrane-impermeant fluorescent dye, has been used in electro-physiological studies to visualize cell morphology, with little concern about its pharmacological effects. We investigated its effects on TTX-sensitive voltage-gated Na+ channels in mouse taste bud cells and hippocampal neurons under voltage-damp conditions. LY applied inside cells irreversibly slowed the inactivation of Na+ currents upon exposure to light of usual intensities. The inactivation time constant of Na+ currents elicited by a depolarization to -15 mV was increased by fourfold after a 5 min exposure to halogen light of 3200 Ix at source (3200 Ix light), and sevenfold after a 1-min exposure to 12,000 Ix light. A fraction of the Na+ current became non-inactivating following the exposure. The non-inactivating current was approximately 20 % of the peak total Na+ current after a 5 min exposure to 3200 Ix light, and approximately 30 % after a 1 min exposure to 12,000 Ix light. Light-exposed LY shifted slightly the current-voltage relationship of the peak Na+ current and of the steady-state inactivation curve, in the depolarizing direction. A similar light-dependent decrease in kinetics occurred in whole-cell Na+ currents of cultured mouse hippocampal neurones. Single-channel recordings showed that exposure to 6500 Ix light for 3 min increased the mean open time of Na+channels from 1.4 ms to 2.4 ms without changing the elementary conductance. The pre-incubation of taste bud cells with 1 mM dithiothreitoL a scavenger of radical species, blocked these LY effects. These results suggest that light-exposed LY yields radical species that modify Na+ channels.

Inhibition of cloned HERG potassium channels by the antiestrogen tamoxifen.

Tamoxifen is a nonsteroidal antiestrogen that is commonly used in the treatment of breast cancer. Although antiestrogenic drugs are generally believed not to cause acquired long QT syndrome (LQTS), concerns have been raised by recent reports of QT interval prolongation associated with tamoxifen treatment. Since blockade of human ether-a-go-go-related gene (HERG) potassium channels is critical in the development of acquired LQTS, we investigated the effects of tamoxifen on cloned HERG potassium channels to determine the electrophysiological basis for the arrhythmogenic potential of this drug. HERG channels were heterologously expressed in Xenopus laevis oocytes, and currents were measured using the two-microelectrode voltage clamp technique. Tamoxifen blocked HERG potassium channels with an IC(50) value of 45.3 microM. Inhibition required channel opening and unblocking occurred very slowly. Analysis of the voltage-dependence of block revealed loss of inhibition at positive membrane potentials, indicating that strong channel inactivation prevented block by tamoxifen. No marked changes in electrophysiological parameters such as voltage-dependence of activation or inactivation, or inactivation time constant could be observed, and block was not frequency-dependent. This study demonstrates that HERG potassium channels are blocked by the antiestrogenic drug tamoxifen. We conclude that HERG current inhibition might be an explanation for the QT interval prolongation associated with this drug.

C-type inactivation involves a significant decrease in the intracellular aqueous pore volume of Kv1.4 K+ channels expressed in Xenopus oocytes.

Channels are water-filled membrane-spanning proteins, which undergo conformational changes as they gate, i.e. open or close. These conformational changes affect both the shape of the channel and the volume of the water-filled pore. We measured the changes in pore volume associated with activation, deactivation, C-type inactivation and recovery in an N-terminal-deleted mutant of the Kv1.4 K+ channel (Kv1.4DeltaN) expressed in Xenopus oocytes. We used giant-patch and cut-open oocyte voltage clamp techniques and applied solutes which are too large to enter the pore mouth to exert osmotic pressure and thus favour smaller pore volume conformations. Applied intracellular osmotic pressure (300 mM sucrose) sped inactivation (time constants (tauinactivation): control, 0.66 +/- 0.09 s; hyperosmotic solution, 0.29 +/- 0.04 s; n = 5, P < 0.01), sped deactivation (taudeactivation: control, 18.8 +/- 0.94 ms; hyperosmotic solution, 8.01 +/- 1.92 ms; n = 5, P < 0.01), and slowed activation (tauactivation: control, 1.04 +/- 0.05 ms; hyperosmotic solution, 1.96 +/- 0.31 ms; n = 5, P < 0.01). These effects were reversible and solute independent. We estimated the pore volume change on inactivation to be about 4500 A3. Osmotic pressure had no effect when applied extracellularly. These data suggest that the intracellular side of the pore closes during C-type inactivation and the volume change is similar to that associated with activation or deactivation. This is also similar to the pore volume estimated from the crystal structure of KcsA and MthK K+ channels. Intracellular osmotic pressure also strongly inhibited re-opening currents associated with recovery from inactivation, which is consistent with a physical similarity between the C-type inactivated and resting closed state.

The antipsychotic drug chlorpromazine inhibits HERG potassium channels.

(1) Acquired long QT syndrome (aLQTS) is caused by prolongation of the cardiac action potential because of blockade of cardiac ion channels and delayed repolarization of the heart. Patients with aLQTS carry an increased risk for torsade de pointes arrhythmias and sudden cardiac death. Several antipsychotic drugs may cause aLQTS. Recently, cases of QTc prolongation and torsade de pointes associated with chlorpromazine treatment have been reported. Blockade of human ether-a-go-go-related gene (HERG) potassium channels, which plays a central role in arrhythmogenesis, has previously been reported to occur with chlorpromazine, but information on the mechanism of block is currently not available. We investigated the effects of chlorpromazine on cloned HERG potassium channels to determine the biophysical mechanism of block. (2) HERG channels were heterologously expressed in Xenopus laevis oocytes, and ion currents were measured using the two-microelectrode voltage-clamp technique. (3) Chlorpromazine blocked HERG potassium channels with an IC(50) value of 21.6 micro M and a Hill coefficient of 1.11. (4) Analysis of the voltage dependence of block revealed a reduction of inhibition at positive membrane potentials. (5) Inhibition of HERG channels by chlorpromazine displayed reverse frequency dependence, that is, the amount of block was lower at higher stimulation rates. No marked changes in electrophysiological parameters such as voltage dependence of activation or inactivation, or changes of the inactivation time constant were observed. (6) In conclusion, HERG channels were blocked in the closed and activated states, and unblocking occurred very slowly.

Role of L-type calcium channels in pacing-induced short-term and long-term cardiac memory in canine heart.

We tested the hypothesis that ICa,L is important to the development of cardiac memory. The effects of L-type Ca2+ channel blockade and beta-blockade were tested on acutely anesthetized and on chronically instrumented, conscious dogs. Short-term memory (STM) was induced by 2 hours of ventricular pacing and long-term memory (LTM) by ventricular pacing for 21 days. STM dogs received placebo, nifedipine, or propranolol, and LTM dogs received placebo, atenolol, or amlodipine. AT1 receptor blockade (candesartan) and ACE inhibition (trandolapril) were also tested in LTM. Microelectrodes were used to record transmembrane potentials from isolated epicardial and endocardial slabs using a protocol simulating STM in intact animals. Left ventricular epicardial myocytes from LTM or sham control dogs were dissociated, and ICa,L was recorded (whole-cell patch-clamp technique). Evolution of STM and LTM was attenuated by ICa,L blockers but not beta-blockers. Neither AT1 receptor blockade nor ACE inhibition suppressed LTM. In microelectrode experiments, pacing induced an epicardial-endocardial gradient change mimicking STM that was suppressed by nifedipine. In patch-clamp experiments, peak ICa,L density in LTM and control were equivalent, but activation was more positive and time constants of inactivation longer in LTM (P<0.05). ICa,L blockade but not beta-adrenergic blockade suppresses cardiac memory. LTM evolution is unaffected by angiotensin II blockade and is associated with altered ICa,L kinetics.

Solution Structure and Function of the “Tandem Inactivation Domain” of the Neuronal A-type Potassium Channel Kv1.4

Cumulative inactivation of voltage-gated (Kv) K(+) channels shapes the presynaptic action potential and determines timing and strength of synaptic transmission. Kv1.4 channels exhibit rapid "ball-and-chain"-type inactivation gating. Different from all other Kvalpha subunits, Kv1.4 harbors two inactivation domains at its N terminus. Here we report the solution structure and function of this "tandem inactivation domain" using NMR spectroscopy and patch clamp recordings. Inactivation domain 1 (ID1, residues 1-38) consists of a flexible N terminus anchored at a 5-turn helix, whereas ID2 (residues 40-50) is a 2.5-turn helix made up of small hydrophobic amino acids. Functional analysis suggests that only ID1 may work as a pore-occluding ball domain, whereas ID2 most likely acts as a "docking domain" that attaches ID1 to the cytoplasmic face of the channel. Deletion of ID2 slows inactivation considerably and largely impairs cumulative inactivation. Together, the concerted action of ID1 and ID2 may promote rapid inactivation of Kv1.4 that is crucial for the channel function in short term plasticity.

Modulation of human ether-à-go-go-related K+ (HERG) channel inactivation by Cs+ and K+.

Unlike many other native and cloned K+ channels, human ether-à-go-go-related K+ (HERG) channels show significant Cs+ permeability with a PCs/PK (the permeability of Cs+ relative to that of K+) of 0.36 +/- 0.03 (n = 10). Here, we find that raising the concentration of external Cs+ (Cs+o) dramatically slows HERG channel inactivation without affecting activation. Replacement of 5 mM K+o by 135 mM Cs+o increased both inactivation and recovery time constants and shifted the mid-point of the steady-state inactivation curve by 25 mV in the depolarized direction (n = 6, P < 0.01). Raising [Cs+]o also modulated the voltage sensitivity of inactivation gating. With 130 mM Cs+i and 135 mM NMDG+o, the inactivation time constant decreased e-fold per 47.5 +/- 1.1 mV (n = 5), and when 20 mM Cs+ was added to the bath solution, the inactivation time constant decreased e-fold per 20.6 +/- 1.3 mV (n = 5, P < 0.01). A quantitative analysis suggests that Cs+o binds to a site in the pore that is influenced by the transmembrane electrical field, so that Cs+o-induced slowing of HERG inactivation is less prominent at strong depolarizations. K+o has effects that are similar to Cs+o and their effects were additive, suggesting Cs+o and K+o may share a common mechanism of action. The strong effects of Cs+ on inactivation but not on activation highlight the importance of ion and channel interactions during the onset of inactivation in the HERG channel.