Indo-1 can simultaneously detect Ba2+ entry and Ca2+ blockade at a plasma membrane calcium channel

The fluorescent chelator Indo-1 can make simultaneous determinations of two intracellular ion concentrations, such as [Ca²⁺] and [Cd²⁺], or [Ca²⁺] and [Ba²⁺], in a normal cell suspension. The second ion can be detected even if its spectrum when bound to Indo-1 is same as for the calcium-bound or the ion-free Indo-1, as long as there is a change in height. This is because the mathematical analysis uses not only the spectral shape, but also takes into account increases in total signal intensity. For maximum accuracy, whole spectra were analyzed. When 3 mM [Ba²⁺] was added to a B cell line that had been stimulated with anti-immunoglobulin to open receptor operated calcium channels, there was a sudden drop in 400 nm Indo-1 fluorescence. Spectral analysis showed that this was due to a drop in intracellular [Ca²⁺], which was consistent with blockage of the receptor-operated calcium current by extracellular Ba²⁺. The conductance for Ba²⁺ was also observable as a slow rise in total fluorescence. There was also a slow increase in intracellular [Ca²⁺] as barium accumulated in the cell, which was tentatively attributed to blockage of the plasma membrane calcium pump by intracellular Ba²⁺.     

Calcium and plant action potentials

Abstract. Under normal conditions the action potential in Characeae is dependent on the presence of both Cl⁻ and Ca²⁺. Cl⁻ seems to play a straightforward part as a transient depolarizing flow. The role of Ca²⁺, however, is emerging as an increasingly complex one: there are Ca²⁺ concentration changes in the cytoplasm, as well as transient Ca²⁺ currents across the plasmalemma and possibly the tonoplast. In most Characeae Ca²⁺ is necessary for the Cl⁻ channel to function, and it is also involved in the cessation of the cytoplasmic streaming observed at the time of excitation.
The function of Ca²⁺ at the time of the action potential is being revealed by experimental techniques of increasing sophistication. The development of these methods and possible associated artefacts are considered.     

Ranolazine inhibits shear sensitivity of endogenous Na+ current and spontaneous action potentials in HL-1 cells

Na_V1.5 is a mechanosensitive voltage-gated Na⁺ channel encoded by the gene SCN5A, expressed in cardiac myocytes and required for phase 0 of the cardiac action potential (AP). In the cardiomyocyte, ranolazine inhibits depolarizing Na⁺ current and delayed rectifier (I_Kr) currents. Recently, ranolazine was also shown to be an inhibitor of Na_V1.5 mechanosensitivity. Stretch also accelerates the firing frequency of the SA node, and fluid shear stress increases the beating rate of cultured cardiomyocytes in vitro. However, no cultured cell platform exists currently for examination of spontaneous electrical activity in response to mechanical stimulation. In the present study, flow of solution over atrial myocyte-derived HL-1 cultured cells was used to study shear stress mechanosensitivity of Na⁺ current and spontaneous, endogenous rhythmic action potentials. In voltage-clamped HL-1 cells, bath flow increased peak Na⁺ current by 14 ± 5%. In current-clamped cells, bath flow increased the frequency and decay rate of AP by 27 ± 12% and 18 ± 4%, respectively. Ranolazine blocked both responses to shear stress. This study suggests that cultured HL-1 cells are a viable in vitro model for detailed study of the effects of mechanical stimulation on spontaneous cardiac action potentials. Inhibition of the frequency and decay rate of action potentials in HL-1 cells are potential mechanisms behind the antiarrhythmic effect of ranolazine.     

Ranolazine inhibits shear sensitivity of endogenous Na+ current and spontaneous action potentials in HL-1 cells

Na_V1.5 is a mechanosensitive voltage-gated Na⁺ channel encoded by the gene SCN5A, expressed in cardiac myocytes and required for phase 0 of the cardiac action potential (AP). In the cardiomyocyte, ranolazine inhibits depolarizing Na⁺ current and delayed rectifier (I_Kr) currents. Recently, ranolazine was also shown to be an inhibitor of Na_V1.5 mechanosensitivity. Stretch also accelerates the firing frequency of the SA node, and fluid shear stress increases the beating rate of cultured cardiomyocytes in vitro. However, no cultured cell platform exists currently for examination of spontaneous electrical activity in response to mechanical stimulation. In the present study, flow of solution over atrial myocyte-derived HL-1 cultured cells was used to study shear stress mechanosensitivity of Na⁺ current and spontaneous, endogenous rhythmic action potentials. In voltage-clamped HL-1 cells, bath flow increased peak Na⁺ current by 14 ± 5%. In current-clamped cells, bath flow increased the frequency and decay rate of AP by 27 ± 12% and 18 ± 4%, respectively. Ranolazine blocked both responses to shear stress. This study suggests that cultured HL-1 cells are a viable in vitro model for detailed study of the effects of mechanical stimulation on spontaneous cardiac action potentials. Inhibition of the frequency and decay rate of action potentials in HL-1 cells are potential mechanisms behind the antiarrhythmic effect of ranolazine.     

兔肺静脉肌袖心肌细胞动作电位的特性和一些离子流机制

研究兔肺静脉肌袖心肌细胞（cardiomyocytes from rabbit pulmonary vein sleeves, PVC）动作电位的特性和一些离子流机制——内向整流钾电流（IKl）、瞬时外向钾电流（ITo）和非选择性阳离子流（I NSCC）,并与左心房心肌细胞（left atrial cardiomyocytes,LAC）进行比较。采用全细胞膜片钳技术,记录动作电位和上述各离子流。发现PVC动作电位时程（action potential duration,APD）较LAC的明显延长,并可以诱发出第二平台反应。PVC上存在I NSCC. PVC的IKl、I To和I NSCC电流密度均较LAC的明显减小。PVC和LAC存在复极离子流的差异,这种差异构成了两者动作电位差异的基础,进而可能成为肺静脉肌袖致心律失常特性的重要离子流机制。     

Sodium channels contribute to action potential generation in canine and human pancreatic islet B cells

Summary Pancreatic islet B cells depolarize and display trains of action potentials in response to stimulatory concentrations of glucose. Based on data from rodent islets these action potentials are considered to be predominantly Ca²⁺ dependent. Here we describe Na⁺-dependent action potentials and Na⁺ currents recorded from canine and human pancreatic islet B cells. Current-clamp recording using the nystatin perforated-patch technique demonstrates that B cells from both species display tetrodotoxin-sensitive Na⁺ action potentials in response to modest glucose-induced depolarization. In companion whole-cell voltage-clamp experiments on canine B cells, the underlying Na⁺ current displays steep voltage-dependent activation and inactivation over the range of –50 to –40 mV. The Na⁺ current is sensitive to tetrodotoxin block with aK ₁=3.2nm and has a reversal potential which changes with [Na⁺] _o as predicted by the Nernst equation. These results suggest that a voltage-dependent Na⁺ current may contribute significantly to action potential generation in some species outside the rodent family.     

Activation and Two Modes of Blockade by Strontium of Ca2+-activated K+ Channels in Goldfish Saccular Hair Cells

Effects of internal Sr²⁺ on the activity of large-conductance Ca²⁺-activated K⁺ channels were studied in inside-out membrane patches from goldfish saccular hair cells. Sr²⁺ was approximately one-fourth as potent as Ca²⁺ in activating these channels. Although the Hill coefficient for Sr²⁺ was smaller than that for Ca²⁺, maximum open-state probability, voltage dependence, steady state gating kinetics, and time courses of activation and deactivation of the channel were very similar under the presence of equipotent concentrations of Ca²⁺ and Sr²⁺. This suggests that voltage-dependent activation is partially independent of the ligand. Internal Sr²⁺ at higher concentrations (>100 μM) produced fast and slow blockade both concentration and voltage dependently. The reduction in single-channel amplitude (fast blockade) could be fitted with a modified Woodhull equation that incorporated the Hill coefficient. The dissociation constant at 0 mV, the Hill coefficient, and zd (a product of the charge of the blocking ion and the fraction of the voltage difference at the binding site from the inside) in this equation were 58–209 mM, 0.69–0.75, 0.45–0.51, respectively (n = 4). Long shut events (slow blockade) produced by Sr²⁺ lasted ∼10–200 ms and could be fitted with single-exponential curves (time constant, τ_l−s) in shut-time histograms. Durations of burst events, periods intercalated by long shut events, could also be fitted with single exponentials (time constant, τ_b). A significant decrease in τ_b and no large changes in τ_l−s were observed with increased Sr²⁺ concentration and voltage. These findings on slow blockade could be approximated by a model in which single Sr²⁺ ions bind to a blocking site within the channel pore beyond the energy barrier from the inside, as proposed for Ba²⁺ blockade. The dissociation constant at 0 mV and zd in the Woodhull equation for this model were 36–150 mM and 1–1.8, respectively (n = 3).     

Different contributions of calcium channel subtypes to electrical excitability of chromaffin cells in rat adrenal slices

We characterized the ionic currents underlying the cellular excitability and the Ca²⁺‐channel subtypes involved in action potential (AP) firing of rat adrenal chromaffin cells (RCCs) preserved in their natural environment, the adrenal gland slices, through the perforated patch‐clamp recording technique. RCCs prepared from adrenal slices exhibit a resting potential of ?54 mV, firing spontaneous APs (2–3 spikes/s) generated by the opening of Na⁺ and Ca²⁺‐channels, and terminated by the activation of voltage and Ca²⁺‐activated K⁺‐channels (BK). Ca²⁺ influx via L‐type Ca²⁺‐channels is involved in reaching threshold potential for AP firing, and is responsible for activation of BK‐channels contributing to AP‐repolarization and afterhyperpolarization, whereas P/Q‐type Ca²⁺‐channels are involved only in the repolarization phase. BK‐channels carry total outward current during AP‐repolarization. Blockade of L‐type Ca²⁺‐channels reduces BK‐current ~60%, whereas blockade of N‐ or P/Q‐type produces little effect. This study demonstrates that Ca²⁺ influx through L‐type Ca²⁺‐channels plays a key role in modulating the threshold potential from RCCs in situ.

     

Blockade of sensory neuron action potentials by a static magnetic field in the 10 mT range

To characterize the inhibitory effect of a static magnetic field, action potentials (AP) were elicited by intracellular application of 1 ms depolarizing current pulses of constant amplitude to the somata of adult mouse dorsal root ganglion neurons in monolayer dissociated cell culture. During the control period, <5% of stimuli failed to elicit AP. During exposure to an ?11 mT static magnetic field at the cell position produced by an array of four permanent center-charged neodymium magnets of alternating polarity (MAG-4A), 66% of stimuli failed to elicit AP. The number of failures was maximal after about 200-250 s in the field and returned gradually to baseline over 400–600 s. A direct or indirect effect on the conformation of AP generating sodium channels could account for these results because (I) failure was preceded often by reduction of maximal rate of rise, an indirect measure of sodium current; (2) recovery was significantly prolonged in more than one-half of neurons that were not stimulated during exposure to the MAG-4A field; and (3) resting membrane potential, input resistance, and chronaxie were unaffected by the field. The effect was diminished or prevented by moving the MAG-4A array along the X or Z axis away from the neuron under study and by increasing the distance between magnets in the XY plane. Reduction of AP firing during exposure to the ?0.1 mT field produced by a MAG-4A array of micromagnets was about the same as that produced by a MAG-4A array of the large magnets above. The ?28 mT field produced at cell position by two magnets of alternating polarity and the ?88 mT field produced by a single magnet had no significant effect on AP firing. These findings suggest that field strength alone cannot account for AP blockade. © 1995 Wiley-Liss, Inc.     

Neuroepithelial progenitors generate and propagate non-neuronal action potentials across the spinal cord

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Different roles attributed to Cav1 channel subtypes in spontaneous action potential firing and fine tuning of exocytosis in mouse chromaffin cells

This study examines the Cav1 isoforms expressed in mouse chromaffin cells and compares their biophysical properties and roles played in cell excitability and exocytosis. Using immunocytochemical and electrophysiological techniques in mice lacking the Cav1.3α1 subunit (Cav1.3(-/-) ) or the high sensitivity of Cav1.2α1 subunits to dihydropyridines, Cav1.2 and Cav1.3 channels were identified as the only Cav1 channel subtypes expressed in mouse chromaffin cells. Cav1.3 channels were activated at more negative membrane potentials and inactivated more slowly than Cav1.2 channels. Cav1 channels, mainly Cav1.2, control cell excitability by functional coupling to BK channels, revealed by nifedipine blockade of BK channels in wild type (WT) and Cav1.3(-/-) cells (53% and 35%, respectively), and by the identical change in the shape of the spontaneous action potentials elicited by the dihydropyridine in both strains of mice. Cav1.2 channels also play a major role in spontaneous action potential firing, supported by the following evidence: (i) a similar percentage of WT and Cav1.3(-/-) cells fired spontaneous action potentials; (ii) firing frequency did not vary between WT and Cav1.3(-/-) cells; (iii) mostly Cav1.2 channels contributed to the inward current preceding the action potential threshold; and (iv) in the presence of tetrodotoxin, WT or Cav1.3(-/-) cells exhibited spontaneous oscillatory activity, which was fully abolished by nifedipine perfusion. Finally, Cav1.2 and Cav1.3 channels were essential for controlling the exocytotic process at potentials above and below -10 mV, respectively. Our data reveal the key yet differential roles of Cav1.2 and Cav1.3 channels in mediating action potential firing and exocytotic events in the neuroendocrine chromaffin cell.     

Fatigue-induced changes in muscle fiber action potentials estimated by wavelet analysis

We aimed to investigate fatigue-induced changes in the spectral parameters of slow (SMF) and fast fatigable muscle fiber (FMF) action potentials using discrete wavelet (DWT) and fast Fourier (FFT) transforms. Intracellular potentials were recorded during repetitive stimulation of isolated muscle fibers immersed in Ca²⁺-enriched medium, while extracellular potentials were obtained from muscle fibers pre-exposed to electromagnetic microwaves (MMW, 2.45 GHz, 20 mW/cm²). The changes in the frequency distribution of the action potentials during the period of uninterrupted fiber activity were used as criteria for fatigue assessment. The wavelet coefficients’ changes in the calculated frequency scales demonstrated a contribution of the increased [Ca²⁺]₀ to an earlier compression of the frequency spectrum towards lower ranges. Root mean square (RMS) analysis of the wavelet coefficients calculated from SMF potentials showed a reduction of the higher frequencies (scale 1) by 90% in elevated [Ca²⁺]₀ vs. 55% in controls and an increase of low frequencies (scale 5) by 323% vs. 187%, respectively. For FMF potentials a decrease of 71% vs. 59% for high frequencies (scale 1, elevated [Ca²⁺]₀ vs. control) and an increase of 386% vs. 295% in scale 5, respectively, were observed. MMW pre-exposure resulted in increased muscle fiber resistance to fatigue. The fatigue-induced decrease of potential high frequencies (SMF: 59% vs. 96%, MMW vs. control; FMF: 30% vs. 92%, respectively), and the increase of low frequencies (SMF: 200% vs. 207%, MMW vs. control; FMF: 93% vs. 314%, respectively) were significantly smaller and delayed in exposed muscle fibers. Data from RMS analysis indicate that DWT provides a reliable method for estimation of muscle fatigue onset and progression.     

Ca2+-activated chloride channel activity during Ca2+ alternans in ventricular myocytes

Cardiac alternans, defined beat-to-beat alternations in contraction, action potential (AP) morphology or cytosolic Ca transient (CaT) amplitude, is a high risk indicator for cardiac arrhythmias. We investigated mechanisms of cardiac alternans in single rabbit ventricular myocytes. CaTs were monitored simultaneously with membrane currents or APs recorded with the patch clamp technique. A strong correlation between beat-to-beat alternations of AP morphology and CaT alternans was observed. During CaT alternans application of voltage clamp protocols in form of pre-recorded APs revealed a prominent Ca²⁺-dependent membrane current consisting of a large outward component coinciding with AP phases 1 and 2, followed by an inward current during AP repolarization. Approximately 85% of the initial outward current was blocked by Cl^? channel blocker DIDS or lowering external Cl^? concentration identifying it as a Ca²⁺-activated Cl^? current (I_CaCC). The data suggest that I_CaCC plays a critical role in shaping beat-to-beat alternations in AP morphology during alternans.     

Evidence for a calcium-dependent outward conductance in endocrine cells of the cockroach, Diploptera punctata

Abstract The cell membranes of the corpora allata of the cockroach Diploptera punctata contain voltage-dependent calcium channels. Depolarizing current injection into cells of the corpora allata in the presence of the calcium channel blockers, cadmium, cobalt or verapamil allows the production of multiple action potentials, as does treatment with the intracellular calcium chelator, BAPTA/AM. These results suggest that calcium currents are involved both in decreasing the excitability and in activating an outward current in cells of the corpora allata. Electrophysiological measurements also suggest a concomitant reduction in outward conductance following the multiple action potentials produced in the presence of the channel blockers or BAPTA/ AM. We hypothesize that the calcium current may play an important role in the regulation of intracellular calcium concentration and Juvenile Hormone biosynthesis.     

Modulation of the voltage sensor of L-type Ca2+ channels by intracellular Ca2+

Both intracellular calcium and transmembrane voltage cause inactivation, or spontaneous closure, of L-type (CaV1.2) calcium channels. Here we show that long-lasting elevations of intracellular calcium to the concentrations that are expected to be near an open channel (>/=100 microM) completely and reversibly blocked calcium current through L-type channels. Although charge movements associated with the opening (ON) motion of the channel's voltage sensor were not altered by high calcium, the closing (OFF) transition was impeded. In two-pulse experiments, the blockade of calcium current and the reduction of gating charge movements available for the second pulse developed in parallel during calcium load. The effect depended steeply on voltage and occurred only after a third of the total gating charge had moved. Based on that, we conclude that the calcium binding site is located either in the channel's central cavity behind the voltage-dependent gate, or it is formed de novo during depolarization through voltage-dependent rearrangements just preceding the opening of the gate. The reduction of the OFF charge was due to the negative shift in the voltage dependence of charge movement, as previously observed for voltage-dependent inactivation. Elevation of intracellular calcium concentration from approximately 0.1 to 100-300 microM sped up the conversion of the gating charge into the negatively distributed mode 10-100-fold. Since the "IQ-AA" mutant with disabled calcium/calmodulin regulation of inactivation was affected by intracellular calcium similarly to the wild-type, calcium/calmodulin binding to the "IQ" motif apparently is not involved in the observed changes of voltage-dependent gating. Although calcium influx through the wild-type open channels does not cause a detectable negative shift in the voltage dependence of their charge movement, the shift was readily observable in the Delta1733 carboxyl terminus deletion mutant, which produces fewer nonconducting channels. We propose that the opening movement of the voltage sensor exposes a novel calcium binding site that mediates inactivation.     

Regulation of Ca2+ influx in myocardial cells by beta adrenergic receptors,cyclic nucleotides,and phosphorylation

Calcium channels in the heart play a major role in cardiac function. These channels are modulated in a variety of ways, including protein phosphorylation. Cyclic AMP-mediated phosphorylation is the best understood phosphorylation mechanism which regulates calcium influx into cardiac cells. Binding of an agonist (e.g., a catecholamine) to the appropriate receptor stimulates production of cyclic AMP by adenylate cyclase. The cyclic AMP may subsequently bind to and activate a cyclic AMP-dependent protein kinase, which then can phosphorylate a number of substrates, including the calcium channel (or a closely-associated regulatory protein). This results in stimulation of the calcium channels, greater calcium influx, and increased contractility. The cyclic AMP system is not the only protein kinase system in the heart. Thus, the possibility exists that other protein kinases may also regulate the calcium channels and, hence, cardiac function. Recent evidence suggests that cyclic GMP-mediated phosphorylation may play a role opposite to cyclic AMP-mediated phosphorylation, i.e., inhibition of the calcium current rather than stimulation. Other recent evidence also suggests that a calcium/calmodulin-dependent protein kinase and calcium/phospholipid-dependent protein kinase (protein kinase C) may also regulate the myocardial calcium channels. Thus, protein phosphorylation may be a general mechanism whereby calcium channels and cardiac function are modulated under a variety of conditions.     

A critical period of prehearing spontaneous Ca2+ spiking is required for hair‐bundle maintenance in inner hair cells

Sensory‐independent Ca²⁺ spiking regulates the development of mammalian sensory systems. In the immature cochlea, inner hair cells (IHCs) fire spontaneous Ca²⁺ action potentials (APs) that are generated either intrinsically or by intercellular Ca²⁺ waves in the nonsensory cells. The extent to which either or both of these Ca²⁺ signalling mechansims are required for IHC maturation is unknown. We find that intrinsic Ca²⁺ APs in IHCs, but not those elicited by Ca²⁺ waves, regulate the maturation and maintenance of the stereociliary hair bundles. Using a mouse model in which the potassium channel Kir2.1 is reversibly overexpressed in IHCs (Kir2.1‐OE), we find that IHC membrane hyperpolarization prevents IHCs from generating intrinsic Ca²⁺ APs but not APs induced by Ca²⁺ waves. Absence of intrinsic Ca²⁺ APs leads to the loss of mechanoelectrical transduction in IHCs prior to hearing onset due to progressive loss or fusion of stereocilia. RNA‐sequencing data show that pathways involved in morphogenesis, actin filament‐based processes, and Rho‐GTPase signaling are upregulated in Kir2.1‐OE mice. By manipulating in vivo expression of Kir2.1 channels, we identify a “critical time period” during which intrinsic Ca²⁺ APs in IHCs regulate hair‐bundle function.     

The Ba2+ sensitivity of the Na+-induced Ca2+ efflux in heart mitochondria: the site of inhibitory action

The Na+-induced Ca2+ release from rat heart mitochondria was measured in the presence of Ruthenium red. Ba2+ effectively inhibited the Na+-induced Ca2+ release. At 10 mM Na+ 50% inhibition was reached by 1.51 +/- 0.48 (S.D., n = 8) microM Ba2+ in the presence of 0.1 mg/ml albumin and by 0.87 +/- 0.25 (S.D., n = 3) microM Ba2+ without albumin. In order to inhibit, it was not required that Ba2+ ions enter the matrix. 140Ba2+ was not accumulated in the mitochondrial matrix space; further, in contrast to liver mitochondria, Ba2+ inhibition was immediate. The Na+-induced Ca2+ release was inhibited by Ba2+ non-competitively, with respect of the extramitochondrial Na+. The double inhibitor titration of the Na+-Ca2+ exchanger with Ba2+ in the presence and absence of extramitochondrial Ca2+ revealed that the exchanger possesses a common binding site for extramitochondrial Ca2+ and Ba2+, presumably the regulatory binding site of the Na+-Ca2+ exchanger, which was described by Hayat and Crompton (Biochem. J. 202 (1982) 509-518). All these observations indicate that Ba2+ acts at the cytoplasmic surface of the inner mitochondrial membrane. The inhibitory properties of Ba2+ on the Na+-dependent Ca2+ release in heart mitochondria are basically different from those found on Na+-independent Ca2+ release in liver mitochondria (Lukács, G.L. and Fonyó, A. (1985) Biochim. Biophys. Acta 809, 160-166).     

Voltage-dependent sodium channels in human small-cell lung cancer cells: Role in action potentials and inhibition by lambert-eaton syndrome IgG

Sodium channels of human small-cell lung cancer (SCLC) cells were examined with whole-cell and single-channel patch clamp methods. In the tumor cells from SCLC cell line NCI-H146, the majority of the voltage-gated Na⁺ channels are only weakly tetrodotoxin (TTX)-sensitive (K _d =215 mm). With the membrane potential maintained at –60 to –80 mV, these cells produced all-or-nothing action potentials in response to depolarizing current injection (>20 pA). Similar all-ornothing spikes were also observed with anodal break excitation. Removal of external Ca²⁺ did not affect the action potential production, whereas 5 m TTX or substitution of Na⁺ with choline abolished it. Action potentials elicited in the Ca²⁺-free condition were reversibly blocked by 4 mm MnCl₂ due to the Mn²⁺-induced inhibition of voltage-dependent sodium currents (I _Na). Therefore, Na⁺ channels, not Ca²⁺ channels, underlie the excitability of SCLC cells. Whole-cell I _Na was maximal with step-depolarizing stimulations to 0 mV, and reversed at +45.2 mV, in accord with the predicted Nernst equilibrium potential for a Na⁺-selective channel. I _Na evoked by depolarizing test potentials (–60 to +40 mV) exhibited a transient time course and activation/ inactivation kinetics typical of neuronal excitable membranes; the plot of the Hodgkin-Huxley parameters, m and h, also revealed biophysical similarity between SCLC and neuronal Na⁺ channels. The single channel current amplitude, as measured with the inside-out patch configuration, was 1.0 pA at –20 mV with a slope conductance of 12.1 pS. The autoantibodies implicated in the Lambert-Eaton myasthenic syndrome (LES), which are known to inhibit I _Ca and I _Na in bovine adrenal chromaffin cells, also significantly inhibited I _Na in SCLC cells. These results indicate that (i) action potentials in human SCLC cells result from the regenerative increase in voltage-gated Na⁺ channel conductance; (ii) fundamental characteristics of SCLC Na⁺ channels are the same as the classical sodium channels found in a variety of excitable cells; and (iii) in some LES patients, SCLC Na⁺ channels are an additional target of the pathological IgG present in the patients' sera.Department of Biomedical EngineeringThis study was supported by National Institutes of Health grant NS18607 and a research grant from the Muscular Dystrophy Association. Dr. Y.I. Kim is the recipient of a Javits Neuroscience Investigator Award from the National Institute of Neurological Disorder and Stroke.     

Regulation of excitation-secretion coupling by thyrotropin-releasing hormone (TRH): Evidence for TRH receptor-ion channel coupling in cultured pituitary cells

Summary The electrophysiological and secretory properties of a well-studied clonal line of rat anterior pituitary cells (GH₃) have been compared with a new line of morphologically distinct cells derived from it (XG-10). The properties of the latter cells differ from the parent cells in that they do not have receptors for thyrotropin-releasing hormone and their basal rate of secretion is substantially higher (ca. three- to fivefold). While both cell types generate Ca⁺⁺ spikes, the duration of the spike in XG-10 cells (ca. 500 msec) is about 2 orders of magnitude longer than that in GH₃ cells (5–10 msec). The current-voltage characteristics of the two cell types are markedly different; the conductance of GH₃ cells is at least 20-fold higher than XG-10 cells when cells are depolarized to more positive potentials than the threshold for Ca⁺⁺ spikes (–35 mV). While treatment of GH₃ cells with the secretagogues tetraethylammonium chloride or thyrotropin-releasing hormone decreases the conductance in this voltage region to approximately the same as that for XG-10 cells, the electrophysiological and secretory properties of XG-10 cells are unaffected by treatment with either of these agents. Results of this comparative study suggest that XG-10 cells lack tetraethylammonium-sensitive K⁺ channels. The parallel loss of thyrotropin-releasing hormone receptor binding activity and of a K⁺ channel in XG-10 cells implies that the thyrotropin-releasing hormone receptor may be coupled with, or be an integral part of, this channel. Apparently thyrotropin-releasing hormone, like tetraethylammonium chloride, acts by inhibiting K⁺ channels resulting in a prolongation of the action potential, promoting Ca⁺⁺ influx and subsequently enhancing hormone secretion.