Voltage-dependent calcium and potassium conductances in striated muscle fibers from the scorpion,Centruroides sculpturatus

Ionic currents responsible for the action potential in scorpion muscle fibers were characterized using a three-intracellular microelectrode voltage clamp applied at the fiber ends (8–12°C). Large calcium currents (I _Ca) trigger contractile activation in physiological saline (5 mm Ca) but can be studied in the absence of contractile activation in a low Ca saline (2.5 mm). Barium (Ba) ions (1.5–3 mm) support inward current but not contractile activation.Ca conductance kinetics are fast (time constant of 3 msec at 0 mV) and very voltage dependent, with steady-state conductance increasing e-fold in approximately 4 mV. Half-activation occurs at –25 mV. Neither I _Ca nor I _Ba show rapid inactivation, but a slow, voltage-dependent inactivation eliminates I _Ca at voltages positive to –40 mV. Kinetically, scorpion channels are more similar to L-type Ca channels in vertebrate cardiac muscle than to those in skeletal muscle.Outward K currents turn on more slowly and with a longer delay than do Ca currents, and K conductance rises less steeply with voltage (e-fold change in 10 mV; half-maximal level at 0 mV). K channels are blocked by externally applied tetraethylammonium and 3,4 diaminopyridine.This work was supported by a grant from the NIH (NS-17510) to W.F.G. and a NRSA award to T.S. (GM-09921).     

Calciseptine, a Ca2+ Channel Blocker, Has Agonist Actions on L-type Ca2+ Currents of Frog and Mammalian Skeletal Muscle

Calciseptine is a natural peptide consisting of 60 amino acids with four disulfide bonds. The peptide is a natural L-type Ca²⁺-channel blocker in heart and other systems, but its actions in skeletal muscle have not been previously described. The aim of this study is to characterize the effects of calciseptine on L-type Ca²⁺ channels of skeletal muscle and on contraction. Whole-cell, patch-clamp experiments were performed to record Ca²⁺ currents (I _Ca) from mouse myotubes, whereas Vaseline-gap voltage-clamp experiments were carried out to record I _Ca from frog skeletal muscle fibers. We found that calciseptine acts as a channel agonist in skeletal muscle, increasing peak I _Ca by 37% and 49% in these two preparations. Likewise, the peptide increased intramembrane charge movement, though it had little effect on contraction. The molecular analysis of the peptide indicated the presence of a local, electrostatic potential that resembles that of the 1,4-dihydropyridine agonist Bay K 8644. These observations suggest that calciseptine shares the properties of 1,4-dihydropyridine derivatives in modulating the permeation of divalent cations through L-type channels. Received: 18 December 2000/Revised: 16 July 2001     

A Long-Term Blockade of L-Type Calcium Currents Upregulates the Number of Ca2+ Channels in Skeletal Muscle

The effects of a long-term blockade of L-type Ca²⁺ channels on membrane currents and on the number of dihydropyridine binding sites were investigated in skeletal muscle fibers. Ca²⁺ currents (I _Ca) and intramembrane charge movement were monitored using a voltage-clamp technique. The peak amplitude of I _Ca increased by more than 40% in fibers that were previously incubated for 24 hr in solutions containing the organic Ca²⁺ channel blocker nifedipine or in Ca²⁺-free conditions. A similar incubation period with Cd²⁺, an inorganic blocker, produced a moderate increase of 20% in peak I _Ca. The maximum mobilized charge (Q _max) increased by 50% in fibers preincubated in Ca²⁺-free solutions or in the presence of Cd²⁺. Microsomal preparations from frog skeletal muscle were isolated by differential centrifugation. Preincubation with Cd²⁺ prior to the isolation of the microsomal fraction doubled the number of ³H-PN200-110 binding sites and produced a similar increase in the values of the dissociation constant. The increase in the number of binding sites is consistent with the increase in the peak amplitude of I _Ca as well as with the increase in Q _max. Received: 31 August 1998/Revised: 7 December 1998     

Ionic mechanisms for the antiarrhythmic action of cinnamophilin in rat heart

We investigated the electrophysiological effect and antiarrhythmic potential of cinnamophilin (Cinn), a thromboxane A₂ antagonist isolated fromCinnamomum philippinense, on rat cardiac tissues. Action potential and ionic currents in single rat ventricular cells were examined by current clamp or voltage clamp in a whole-cell configuration. In 9 episodes of ischemia-reperfusion arrhythmia, 10 µM Cinn converted 6 of them to normal sinus rhythm. Cinn suppressed the maximal rate of rise of the action potential upstroke (V_max) and prolonged the action potential duration at 50% repolarization (APD₅₀). Voltage clamp study showed that the suppression of V_max by Cinn was associated with an inhibition of sodium inward current (I_Na, IC₅₀=10.0 ± 0.4 µM). At 30 µM, V_1/2 for the steady-state inactivation curve of I_Na was shifted from –84.1 ± 0.2 to –93.0 ± 0.5 mV. Cinn also reduced calcium inward current (I_Ca) dose-dependently with an IC₅₀ value of 9.5 ± 0.3 µM. Cinn (10 µM) reduced the I_Ca with a negative shift of V_1/2 for the steady-state inactivation curve of I_Ca from –32.2 ± 0.3 to –50.7 ± 0.4 mV. The prolongation of APD₅₀ was associated with an inhibition of the integral of potassium outward current with IC₅₀ values between 4.8 and 7.1 µM. At 10 µM, Cinn reduced I_Na without a negative shift of its voltage-dependent steady-state inactivation curves. The inhibition of transient outward current (I_to) by Cinn (3–30 µM) was associated with an acceleration of its time constant of inactivation and negative shift of its potential-dependent steady-state inactivation curves. The equilibrium dissociation constant (K_d) of Cinn to inhibit open state I_to channels, as calculated from the time constant of developing block, was 18.3 µM. The time constant of recovery of I_to from inactivation state was unaffected by Cinn. The rate constant for the relief from the depolarization-dependent block of I_to was calculated to be 23.9 ms. As compared with its effect on I_to, Cinn exerted about half the potency to block I_Na and I_Ca. These results indicate that the inhibition of I_Na, I_Ca and I_to may contribute to the antiarrhythmic activity of Cinn against ischemia-reperfusion arrhythmia.     

Altered Ca2+ signaling in skeletal muscle fibers of the R6/2 mouse,a model of Huntington’s disease

Huntington’s disease (HD) is caused by an expanded CAG trinucleotide repeat within the gene encoding the protein huntingtin. The resulting elongated glutamine (poly-Q) sequence of mutant huntingtin (mhtt) affects both central neurons and skeletal muscle. Recent reports suggest that ryanodine receptor–based Ca²⁺ signaling, which is crucial for skeletal muscle excitation–contraction coupling (ECC), is changed by mhtt in HD neurons. Consequently, we searched for alterations of ECC in muscle fibers of the R6/2 mouse, a mouse model of HD. We performed fluorometric recordings of action potentials (APs) and cellular Ca²⁺ transients on intact isolated toe muscle fibers (musculi interossei), and measured L-type Ca²⁺ inward currents on internally dialyzed fibers under voltage-clamp conditions. Both APs and AP-triggered Ca²⁺ transients showed slower kinetics in R6/2 fibers than in fibers from wild-type mice. Ca²⁺ removal from the myoplasm and Ca²⁺ release flux from the sarcoplasmic reticulum were characterized using a Ca²⁺ binding and transport model, which indicated a significant reduction in slow Ca²⁺ removal activity and Ca²⁺ release flux both after APs and under voltage-clamp conditions. In addition, the voltage-clamp experiments showed a highly significant decrease in L-type Ca²⁺ channel conductance. These results indicate profound changes of Ca²⁺ turnover in skeletal muscle of R6/2 mice and suggest that these changes may be associated with muscle pathology in HD.     

Interpretation of relevance of sodium–calcium exchange in action potential of diabetic rat heart by mathematical model

Sarcolemmal Na⁺–Ca²⁺ exchange plays a central role in ion transport of the myocardium and the current carried with it contributes to the late phase of the action potential (AP) besides the contribution of outward K⁺-currents. In this study, the mathematical model for AP of the diabetic rat ventricular myocytes [34] was modified and used for the diabetic rat papillary muscle. We used our experimentally measured values of two K⁺-currents; transient outward current, I_to and steady-state outward current, I_ss, as well as L-type Ca²⁺-current, I_CaL, then compared with the simulated values. We have demonstrated that the prolongation in the AP of the papillary muscle of the diabetic rats are not due to the alteration of I_CaL but mainly due to the inhibition of the K⁺-currents and also the Na⁺–Ca²⁺ exchanger current, I_Na–Ca. In combination with our experimental data on sodium-selenite-treated diabetic rats, our simulation results provide new information concerning plausible ionic mechanisms, and second a possible positive effect of selenium treatment on the altered I_Na–Ca for the observed changes in the AP duration of streptozotocin-induced diabetic rat heart. (Mol Cell Biochem 269: 121–129, 2005)     

Calcium current kinetics in young and aged human cultured myotubes

There is evidence that the complex process of sarcopenia in human aged skeletal muscle is linked to the modification of mechanisms controlling Ca²⁺ homeostasis. To further clarify this issue, we assessed the changes in the kinetics of activation and inactivation of T- and L-type Ca²⁺ currents in in vitro differentiated human myotubes, derived from satellite cells of healthy donors aged 2, 12, 76 and 86 years. The results showed an age-related decrease in the occurrence of T- and L-type currents. Moreover, significant age-dependent alterations were found in L-(but not T) type current density, and activation and inactivation kinetics, although an interesting alteration in the kinetics of T-current inactivation was observed. The T- and L-type Ca²⁺ currents play a crucial role in regulating Ca²⁺ entry during satellite cells differentiation and fusion into myotubes. Also, the L-type Ca²⁺ channels underlie the skeletal muscle excitation–contraction coupling mechanism. Thus, our results support the hypothesis that the aging process could negatively affect the Ca²⁺ homeostasis of these cells, by altering Ca²⁺ entry through T- and L-type Ca²⁺ channels, thereby putting a strain on the ability of human satellite cells to regenerate skeletal muscle in elderly people.     

Depressant effects of prostacyclin in human atrial fibers and cardiomyocytes

The aim of this study was to characterize the electropharmacological effects of prostacyclin (PGI₂) in human atrial fibers and cardiomyocytes. Atrial tissues obtained from the hearts of 28 patients undergoing corrective cardiac surgery were used. Transmembrane action potentials were recorded using a conventional microelectrode technique, and twitch force by a transducer. Effects of PGI₂ (1 nM–10 µM) on action potential characteristics and contraction of atrial fibers were evaluated in normal [K]_o (4 mM) and high [K]_o (27 mM) in the absence and presence of cardiotonic agents. In addition, atrial and ventricular myocytes were isolated enzymatically from atrial tissues and hearts of 4 patients undergoing cardiac transplant. The effects of PGI₂ on Na- and Ca-dependent inward currents (I_Na and I_Ca) of cardiomyocytes were tested. In 9 human atrial fibers showing fast-response action potentials (mean dV/dt_max = 101 ± 15 Vs^–1) in 4 mM [K]_o, PGI₂ did not influence dV/dt_max of phase 0 depolarization even at 1 µM. However, at a concentration as low as 10 nM, PGI₂ depressed spontaneous rhythms or slow-response action potentials in high-K-depolarized fibers. PGI₂ also depressed delayed afterdepolarizations and aftercontractions induced by cardiotonic agents. In isolated cardiomyocytes, PGI₂ reduced I_Ca but not I_Na. The present findings show that, in human atrial fibers and cardiomyocytes, PGI₂ induces greater depressant effects on the slow-response action potential, I_Ca and triggered activity than on the fast-response action potential. It is suggested that PGI₂ may act through a selective reduction of transmembrane Ca influx.     

Separation of ionic currents in the somatic membrane of frog sensory neurons

Summary Electrical properties of isolated frog primary afferent neurons were examined by suction pipette technique, which combines internal perfusion with current or voltage clamp using a switching circuit with a single electrode. When K⁺ in the external and internal solutions was totally replaced with Cs⁺, extremely prolonged Ca spikes, lasting for 5 to 10 sec, and Na spikes, having a short plateau phase of 10 to 15 msec, were observed in Na⁺-free and Ca²⁺-free solutions, respectively. Under voltage clamp, Ca²⁺ current (I _Ca) appeared at around –30 mV and maximum peak current was elicited at about 0 mV. With increasing test pulses to the positive side,I _Ca became smaller and flattened but did not reverse. Increases of [Ca] _o induced a hyperbolic increase ofI _Ca and also shifted itsI-V curve along the voltage axis to the more positive direction. Internal perfusion of F^– blockedI _Ca time-dependently. The Ca channel was permeable to foreign divalent cations in the sequence ofI _Ca>I _Ba>I _SrI _Mn>I _Zn. Organic Ca-blockers equally depressed the divalent cation currents dose- and time-dependently without shifting theI-V relationships, while inorganic blockers suppressed these currents dose-dependently and the inhibition appeared much stronger in the order ofI _Ba=I _Sr>I _Ca>I _Mn=I _Zn.     

Effects of pressure overload-induced hypertrophy on TTX-sensitive inward currents in guinea pig left ventricle

We investigated the effects of pressure overload hypertrophy on inward sodium (I _Na) and calcium currents (I _Ca) in single left ventricular myocytes to determine whether changes in these current systems could account for the observed prolongation of the action potential. Hypertrophy was induced by pressure overload caused by banding of the abdominal aorta. Whole-cell patch clamp experiments were used to measure tetrodotoxin (TTX)-sensitive inward currents. The main findings were that I _Ca density was unchanged whereas I _Na density after stepping from –80 to –30 mV was decreased by 30% (–9.0 ± 1.16 pA pF^–1 in control and –6.31 ± 0.67 pA pF^–1 in hypertrophy, p < 0.05, n= 6). Steady-state activation/inactivation variables of I _Na, determined by using double-pulse protocols, were similar in control and hypertrophied myocytes, whereas the time course of fast inactivation of I _Na was slowed (p < 0.05) in hypertrophied myocytes. In addition, action potential clamp experiments were carried out in the absence and presence of TTX under conditions where only Ca²⁺ was likely to enter the cell via TTX-sensitive channels. We show for the first time that a TTX-sensitive inward current was present during the plateau phase of the action potential in hypertrophied but not control myocytes. The observed decrease in I _Na density is likely to abbreviate rather than prolong the action potential. Delayed fast inactivation of Na⁺ channels was not sustained throughout the voltage pulse and may therefore merely counteract the effect of decreased I _Na density so that net Na⁺ influx remains unaltered. Changes in the fast I _Na do not therefore appear to contribute to lengthening of the action potential in this model of hypertrophy. However, the presence of a TTX-sensitive current during the plateau could potentially contribute to the prolongation of the action potential in hypertrophied cardiac muscle. (Mol Cell Biochem 261: 217–226, 2004)     

Expression of low voltage-activated calcium channels inXenopus oocytes

Calcium channels were expressed inXenopus oocytes by means of messenger RNA extracted from the rat thalamo-hypothalamic complex, mRNA(h). Inward barium currents,I _Ba, were recorded in Cl^–-free extracellular solution with 40 mM Ba²⁺ as a charge carrier, using two-microelectrode technique. Depolarizations from a very negative holding potential (V _h=–120 mV) began to activateI _Ba at about –80 mV; this current peaked at –30 to –20 mV and reversed at +50 mV, indicating that I _Ba may be transferred through the low voltage-activated (LVA) calcium channels. The time-dependent inactivation of the current during a prolonged depolarization to –20 mV was quite slow, followed a single exponential decay with a time constant of 1550 msec, and contained a residual component constituting 30% of the maximum amplitude. The current could not be completely inactivated at any holding potential. As expected for LVA current, a steady-state inactivation curve was shifted towards negative potentials. It could be described by the Boltzmann's equation with the half-inactivation potential of –78 mV, slope factor of 15 mV, and residual level of 0.3. ExpressedI _Ba could be blocked by flunarizine (K _d=0.42 µM), nifedipine (K _d=10 µM), and amiloride at a 500 µM concentration. Among the inorganic Ca²⁺ channel blockers, the most potent was La³⁺ (K _d=0.48 µM), while Cd²⁺ and Ni²⁺ were not very selective and almost thousand-fold less effective (K _d=0.52 mM andK _d=0.62 mM, respectively) than La³⁺. Our data show that mRNA(h) induces expression in the oocytes of almost exclusively LVA Ca²⁺ channels with voltage-dependent and pharmacological properties very similar to those observed for T-type Ca²⁺ current in native hypothalamic neurons, though kinetic properties of the expressed and natural currents are somewhat different.Neirofiziologiya/Neurophysiology, Vol. 27, No. 3, pp. 183–189, May–June, 1995.     

The cole-moore effect in nodal membrane of the frogRana ridibunda: Evidence for fast and slow potassium channels

Summary The K conductance (g _K) kinetics were studied in voltage-clamped frog nodes (Rana ridibunda) in double-pulse experiments. The Cole-Moore translation forg _K–t curves associated with different initial potentials (E) was only observed with a small percentage of fibers. The absence of the translation was found to be caused by the involvement of an additional, slow,g _K component. This component cannot be attributed to a multiple-state performance of the K channel. It can only be accounted for by a separate, slow K channel, the fast channel being the same as then ⁴ K channel inR. pipiens.The slow K channel is characterized by weaker sensitivity to TEA, smaller density, weaker potential (E) dependence, and somewhat more negativeE range of activation than the fast K channel. According to characteristics of the slow K system, three types of fibers were found. In Type I fibers (most numerous) the slow K channel behaves as ann ⁴ HH channel. In Type II fibers (the second largest group found) the slow K channel obeys the HH kinetics within a certainE range only; beyond this range the exponential decline of the slowg _K component is preceded by anE-dependent delay, its kinetics after the delay being the same as those in Type I fibers. In Type III fibers (rare) the slow K channel is lacking, and it is only in these fibers that the Cole-Moore translation of the measuredg _K–t curves can be observed directly.The physiological role of the fast and slow K channel in amphibian nerves is briefly discussed.     

Developmental changes in the calcium currents in embryonic chick ventricular myocytes

Summary Using the patch-clamp technique, we recorded whole-cell calcium current from isolated cardiac myocytes dissociated from the apical ventricles of 7-day and 14-day chick embryos. In 70% of 14-day cells after 24 hr in culture, two component currents could be separated from totalI _Ca activated from a holding potential (V _h) of –80 mV. L-type current (I _L) was activated by depolarizing steps fromV _h –30 or –40 mV. The difference current (I _T) was obtained by subtractingI _L, fromI _Ca.I _T could also be distinguished pharmacologically fromI _L in these cells.I _T was selectively blocked by 40–160 m Ni²⁺, whereasI _L was suppressed by 1 m D600 or 2 m nifedipine. The Ni²⁺-resistant and D600-resistant currents had activation thresholds and peak voltages that were near those ofI _T andI _L defined by voltage threshold, and resembled those in adult mammalian heart. In 7-day cells,I _T andI _L could be distinguished by voltage threshold in 45% (S cells), while an additional 45% of 7-day cells were nonseparable (NS) by activation voltage threshold. Nonetheless, in mostNS cells,I _Ca was partly blocked by Ni²⁺ and by D600 given separately, and the effects were additive when these agents were given together. Differences among the cells in the ability to separateI _T andI _L by voltage threshold resulted largely from differences in the position of the steady-state inactivation and activation curves along the voltage axis. In all cells at both ages in which the steady-state inactivation relation was determined with a double-pulse protocol, the half-inactivation potential (V _1/2) of the Ni²⁺-resistant currentI _L averaged –18 mV. In contrast,V _1/2 of the Ni²⁺-sensitiveI _T was –60 mV in 14-day cells, –52 mV in 7-dayS cells, and –43 mV in 7-day NS cells. The half-activation potential was near –2 mV forI _L at both ages, but that ofI _T was –38 mV in 14-day and –29 mV in 7-day cells. Maximal current density was highly variable from cell to cell, but showed no systematic differences between 7-day and 14-day cells. These results indicate that the main developmental change that occurs in the components ofI _Ca is a negative shift with, embryonic age in the activation and inactivation relationships ofI _T along the voltage axis.     

Kinetics of sodium tail current during repolarization of axon membrane normally and in the presence of scorpion toxin

The kinetics of the sodium tail current (tail I_Na) in myelinated frog nerve fibers in the region of repolarization potentials (V_r) from –40 to –70 mV has two exponential components: fast and slow. The component composition of the tail I_Na depends on V_r: with an increase in negative values of V_r the contribution of the slow component of the tail (_s) decreases, and at V_r values higher than –80 mV, the tail I_Na follows virtually one fast exponential curve. The component composition of the tail I_Na at a fixed level of V_r depends on the initial conditions: with an increase in the duration of the test pulse (V_t) the amplitude of the fast component of the tail falls much faster than the amplitude of the slow component. In that case the kinetics of the fall in amplitude of the fast component corresponds to the kinetics of inactivation of I_Na. Scorpion toxin causes slowing of the kinetics of the tail I_Na at all values of V_r, mainly on account of an increase in _s. For qualitative interpretation of the results a kinetic scheme assuming the presence of two open states of the sodium channel of the axon membrane is suggested. The hypothesis is put forward that scorpion toxin interacts with the same site of the gating mechanism of the channel as DDT and trinitrophenol.Institute of Cytology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 12, No. 5, pp. 541–549, September–October, 1980.     

Autocrine A2 in the T-System of Ventricular Myocytes Creates Transmural Gradients in Ion Transport: A Mechanism to Match Contraction with Load?

Transmural heterogeneities in Na/K pump current (I_P), transient outward K⁺-current (I_to), and Ca²⁺-current (I_CaL) play an important role in regulating electrical and contractile activities in the ventricular myocardium. Prior studies indicated angiotensin II (A2) may determine the transmural gradient in I_to, but the effects of A2 on I_P and I_CaL were unknown. In this study, myocytes were isolated from five muscle layers between epicardium and endocardium. We found a monotonic gradient in both I_p and I_to, with the lowest currents in ENDO. When AT₁Rs were inhibited, EPI currents were unaffected, but ENDO currents increased, suggesting endogenous extracellular A2 inhibits both currents in ENDO. I_P- and I_to-inhibition by A2 yielded essentially the same K_0.5 values, so they may both be regulated by the same mechanism. A2/AT₁R-mediated inhibition of I_P or I_to or stimulation of I_CaL persisted for hours in isolated myocytes, suggesting continuous autocrine secretion of A2 into a restricted diffusion compartment, like the T-system. Detubulation brought EPI I_P to its low ENDO value and eliminated A2 sensitivity, so the T-system lumen may indeed be the restricted diffusion compartment. These studies showed that 33–50% of I_P, 57–65% of I_to, and a significant fraction of I_CaL reside in T-tubule membranes where they are transmurally regulated by autocrine secretion of A2 into the T-system lumen and activation of AT₁Rs. Increased AT₁R activation regulates each of these currents in a direction expected to increase contractility. Endogenous A2 activation of AT₁Rs increases monotonically from EPI to ENDO in a manner similar to reported increases in passive tension when the ventricular chamber fills with blood. We therefore hypothesize load is the signal that regulates A2-activation of AT₁Rs, which create a contractile gradient that matches the gradient in load.     

Human Adipose Cells Have Voltage-dependent Potassium Currents

The whole-cell patch-clamp method was used to study the membrane electrical properties of human adipocyte cells obtained by differentiating from precursors of human abdominal and mammary tissues. All differentiated cells exhibited outward currents with sigmoidal activation kinetics. The outward currents showed activation thresholds between –20 to –30 mV and slow inactivation. The ionic channels underlying the macroscopic current were highly selective for K⁺. Their selectivity was for typical K⁺ channels with relative permeabilities of K⁺>NH ₄ ⁺ >Cs⁺>Na⁺. No evidence of any other type of voltage-gated channel was found. The potassium currents (I _KV) were blocked reversibly by tetraethylammonium and barium. The IC ₅₀ value and Hill coefficient of tetraethylammonium inhibition of I _KV were 0.56 mM and 1.17 respectively. These results demonstrate that human adipose cells have voltage-dependent potassium currents.     

Pharmacological dissection and distribution of NaN/Nav1.9, T-type Ca2+ currents, and mechanically activated cation currents in different populations of DRG neurons

Low voltage–activated (LVA) T-type Ca²⁺ (I_CaT) and NaN/Nav1.9 currents regulate DRG neurons by setting the threshold for the action potential. Although alterations in these channels have been implicated in a variety of pathological pain states, their roles in processing sensory information remain poorly understood. Here, we carried out a detailed characterization of LVA currents in DRG neurons by using a method for better separation of NaN/Nav1.9 and I_CaT currents. NaN/Nav1.9 was inhibited by inorganic I_Ca blockers as follows (IC₅₀, μM): La³⁺ (46) > Cd²⁺ (233) > Ni²⁺ (892) and by mibefradil, a non-dihydropyridine I_CaT antagonist. Amiloride, however, a preferential Cav3.2 channel blocker, had no effects on NaN/Nav1.9 current. Using these discriminative tools, we showed that NaN/Nav1.9, Cav3.2, and amiloride- and Ni²⁺-resistant I_CaT (AR-I_CaT) contribute differentially to LVA currents in distinct sensory cell populations. NaN/Nav1.9 carried LVA currents into type-I (CI) and type-II (CII) small nociceptors and medium-Aδ–like nociceptive cells but not in low-threshold mechanoreceptors, including putative Down-hair (D-hair) and Aα/β cells. Cav3.2 predominated in CII-nociceptors and in putative D-hair cells. AR-I_CaT was restricted to CII-nociceptors, putative D-hair cells, and Aα/β-like cells. These cell types distinguished by their current-signature displayed different types of mechanosensitive channels. CI- and CII-nociceptors displayed amiloride-sensitive high-threshold mechanical currents with slow or no adaptation, respectively. Putative D-hair and Aα/β-like cells had low-threshold mechanical currents, which were distinguished by their adapting kinetics and sensitivity to amiloride. Thus, subspecialized DRG cells express specific combinations of LVA and mechanosensitive channels, which are likely to play a key role in shaping responses of DRG neurons transmitting different sensory modalities.     

Divalent cations permeation in a Ca2+ non-conducting skeletal muscle dihydropyridine receptor mouse model

In response to excitation of skeletal muscle fibers, trains of action potentials induce changes in the configuration of the dihydropyridine receptor (DHPR) anchored in the tubular membrane which opens the Ca²⁺ release channel in the sarcoplasmic reticulum membrane. The DHPR also functions as a voltage-gated Ca²⁺ channel that conducts L-type Ca²⁺ currents routinely recorded in mammalian muscle fibers, which role was debated for more than four decades. Recently, to allow a closer look into the role of DHPR Ca²⁺ influx in mammalian muscle, a knock-in (ki) mouse model (ncDHPR) carrying mutation N617D (adjacent to domain II selectivity filter E) in the DHPRα_1S subunit abolishing Ca²⁺ permeation through the channel was generated [Dayal et al., 2017]. In the present study, the Mn²⁺ quenching technique was initially intended to be used on voltage-clamped muscle fibers from this mouse to determine whether Ca²⁺ influx through a pathway distinct from DHPR may occur to compensate for the absence of DHPR Ca²⁺ influx. Surprisingly, while N617D DHPR muscle fibers of the ki mouse do not conduct Ca²⁺, Mn²⁺ entry and subsequent quenching did occur because Mn²⁺ was able to permeate and produce L-type currents through N617D DHPR. N617D DHPR was also found to conduct Ba²⁺ and Ba²⁺ currents were strongly blocked by external Ca²⁺. Ba²⁺ permeation was smaller, current kinetics slower and Ca²⁺ block more potent than in wild-type DHPR. These results indicate that residue N617 when replaced by the negatively charged residue D is suitably located at entrance of the pore to trap external Ca²⁺ impeding in this way permeation. Because Ba²⁺ binds with lower affinity to D, Ba²⁺ currents occur, but with reduced amplitudes as compared to Ba²⁺ currents through wild-type channels. We conclude that mutations located outside the selectivity filter influence channel permeation and possibly channel gating in a fully differentiated skeletal muscle environment.     

Diclofenac Prolongs Repolarization in Ventricular Muscle with Impaired Repolarization Reserve

Background

The aim of the present work was to characterize the electrophysiological effects of the non-steroidal anti-inflammatory drug diclofenac and to study the possible proarrhythmic potency of the drug in ventricular muscle.

Methods

Ion currents were recorded using voltage clamp technique in canine single ventricular cells and action potentials were obtained from canine ventricular preparations using microelectrodes. The proarrhythmic potency of the drug was investigated in an anaesthetized rabbit proarrhythmia model.

Results

Action potentials were slightly lengthened in ventricular muscle but were shortened in Purkinje fibers by diclofenac (20 µM). The maximum upstroke velocity was decreased in both preparations. Larger repolarization prolongation was observed when repolarization reserve was impaired by previous BaCl₂ application. Diclofenac (3 mg/kg) did not prolong while dofetilide (25 µg/kg) significantly lengthened the QT_c interval in anaesthetized rabbits. The addition of diclofenac following reduction of repolarization reserve by dofetilide further prolonged QT_c. Diclofenac alone did not induce Torsades de Pointes ventricular tachycardia (TdP) while TdP incidence following dofetilide was 20%. However, the combination of diclofenac and dofetilide significantly increased TdP incidence (62%). In single ventricular cells diclofenac (30 µM) decreased the amplitude of rapid (I_Kr) and slow (I_Ks) delayed rectifier currents thereby attenuating repolarization reserve. L-type calcium current (I_Ca) was slightly diminished, but the transient outward (I_to) and inward rectifier (I_K1) potassium currents were not influenced.

Conclusions

Diclofenac at therapeutic concentrations and even at high dose does not prolong repolarization markedly and does not increase the risk of arrhythmia in normal heart. However, high dose diclofenac treatment may lengthen repolarization and enhance proarrhythmic risk in hearts with reduced repolarization reserve.     

Kinetic evidence for two Na channels in frog skeletal muscle

The kinetics of voltage-clamped sodium currents were studied in frog skeletal muscle. Sodium currents in frog skeletal muscle activate and inactivate following an initial delay in response to a depolarizing voltage pulse. Inactivation occurs via a double exponential decay exhibiting fast and slow components for virtually all depolarizing pulses used.The deactivation of Na currents exhibits two exponential components, one decaying rapidly, while the other decays slowly in time; the relative amplitude of the two components changes with the duration of the activating pulse. The two deactivation phases remain after pharmacological elimination of inactivation.In individual fibers, the percent amplitude of the slow inactivation component correlates with the percent amplitude of the slow deactivation component.Tetrodotoxin differentially blocks the slow deactivation component.These observations are interpreted as the activation, inactivation and deactivation of two subtypes (fast and slow) of Na channels.Studies of the slow deactivation phase magnitude vs the duration of the eliciting pulse provide a way to determine the kinetics of the slow Na channel in muscle.Ammonium substitution for Na in the Ringer produces a voltage dependent activation and inactivation of current which exhibits only one decay phase, and eliminates the slow decay phase of current, suggesting that adjustments of the ionic environment of the channels can mask the presence of one of the channel subtypes.