Voltage-dependent sodium and calcium currents in acutely isolated adult rat trigeminal root ganglion neurons

Voltage-dependent sodium (INa) and calcium (ICa) currents in small (<30 microM) neurons from adult rat trigeminal root ganglia were characterized with a standard whole cell patch-clamp technique. Two types of INa showing different sensitivity to tetrodotoxin (TTX) were recorded, which showed marked differences in their activating and inactivating time courses. The activation and the steady-state inactivation kinetics of TTX-resistant INa were more depolarized by about +20 and +30 mV, respectively, than those of TTX-sensitive INa. Voltage-dependent ICa was recorded under the condition that suppressed sodium and potassium currents with 10 mM Ca2+ as a charge carrier. Depolarizing step pulses from a holding potential of -80 mV evoked two distinct inward ICa, low-voltage activated (LVA) and high-voltage activated (HVA) ICa. LVA ICa was first observed at -60 to -50 mV and reached a peak at about -30 mV. Amiloride (0.5 mM) suppressed approximately 60% of the LVA ICa, whereas approximately 10% of HVA ICa was inhibited by the same concentration of the amiloride. LVA ICa was far less affected by the presence of external Cd2+ or the replacement of Ca2+ by 10 Ba2+ than HVA ICa. The omega-conotoxin GVIA (omega-CgTx), an N-type ICa blocker, suppressed approximately 65% of the whole cell HVA ICa at the concentration of 1 microM. The omega-CgTx-resistant HVA ICa was sensitive to nifedipine (10 microM), a dihydropyridine (DHP) calcium channel antagonist, which produced an additional blockade by approximately 25% of the drug-free control ( approximately 70% of the omega-CgTx-resistant ICa). The combination of 10 microM nifedipine and 1 microM omega-CgTx left approximately 13% of the drug-free control ICa unblocked. The DHP agonist S(-)-BayK8644 (5 microM) shifted the activation of the HVA ICa to more negative potentials and increased its maximal amplitude. Additionally, S(-)-BayK8644 caused the appearance of a slowed component of the tail current. These results clearly demonstrate that the presence of two types of sodium channels, TTX sensitive and resistant, and three types of calcium channels, T, L, and N type, in the small-sized adult rat trigeminal ganglion neurons.     

大鼠骨髓间质干细胞诱导分化为心肌样细胞膜电流的研究

目的： 研究大鼠骨髓间质干细胞（MSCs）诱导分化为心肌样细胞膜电流的状态。方法： 按文献方法进行MSCs的诱导培养和鉴定。诱导后培养4周，用全细胞膜片钳技术，检测胞膜电流，并与未经诱导分化的MSCs进行比较。结果： 未经诱导分化的MSCs不表达内向电流，只表达外向钾电流。MSCs经5-aza诱导后表达心肌特异性肌钙蛋白T，记录到2种膜内向电流，分别为钠电流（I_Na）和L-型钙电流（I_Ca），以及3种外向钾电流，包括瞬间外向钾电流（I_to），超快速激活延迟整流钾电流（I_kur）及缓慢激活延迟整流钾电流（I_ks）。与未经诱导分化的MSCs相比，诱导后MSCs的钾电流以I_kur和I_ks为主。结论： 经5-aza诱导后，MSCs可分化成具有电压依赖性内向I_Na、I_Ca和外向I_to、I_kur、I_ks的心肌样细胞。     

Voltage-gated calcium currents in isolated retinal ganglion cells of the cat.

Voltage-gated calcium current (ICa) was recorded from retinal ganglion cells dissociated from the adult cat under the voltage-clamp condition using a patch pipette in the whole cell configuration. ICa was isolated from the voltage-dependent potassium and sodium currents by ion substitution and selective blockers. ICa was activated by depolarization of the cell from a holding potential (Vh) of -97 mV to more positive voltages than -57 mV. All recorded cells showed similar voltage dependence of ICa activation: 50% activation at about -23 mV. Current-voltage (I-V) relationship of ICa showed a symmetrical bell-shape with a single peak at around -7 mV. The I-V curve recorded with Vh of -57 mV was nearly identical to that obtained with Vh of -97 mV. During a depolarizing command, the amplitude of ICa gradually decreased. Inactivation of ICa depended on Ca influx into the cell. ICa became more sustained either when the extracellular Ca was replaced by Ba, or when the cell was loaded with 30 mM EGTA. Nifedipine (10(-4) M) inhibited ICa reversibly. Effects of Bay K 8644 were bimodal: augmentation at a low concentration (10(-8) M) and suppression at a high concentration (10(-4) M). All these characteristics are identical to the previous findings for the high-threshold (L-type) ICa. The type of ICa recorded from the retinal ganglion cells in the adult cat is different from those in newborn rats.     

Cryopreservation of postnatal rat retinal ganglion cells: persistence of voltage- and ligand-gated ionic currents.

Established methods for cryopreservation of living cells were modified for freeze-storage of postnatal retinal ganglion cells from rat. Retinal cell suspensions containing fluorescently labeled ganglion cells were frozen after addition of 8% dimethyl sulfoxide and stored at -80 degrees C for up to 66 days. Viability of identified retinal ganglion cells was assessed by their ability to take up and cleave fluorescein diacetate to fluorescein. No significant difference was found in the number of living retinal ganglion cells when cells obtained from the same dissociation were counted before and after freezing (6.65 +/- 2.37 x 10(4) vs 7.05 +/- 3.67 x 10(4) retinal ganglion cells per ml, respectively; mean +/- S.D., n = 4). In culture following cryopreservation, the cells appeared morphologically normal, and developed neurites and growth cones similar to their freshly dissociated counterparts. Since very little is known about the electrophysiology and membrane properties of neurons after cryopreservation, we used the whole-cell configuration of the patch-clamp technique to study voltage- and ligand-gated conductances in cryopreserved retinal ganglion cells. The cryopreserved retinal ganglion cells studied under current-clamp maintained resting potentials of -60.9 +/- 6.6 mV (n = 10) and upon depolarization fired action potentials. During voltage-clamp in the whole-cell mode, depolarizing voltage steps activated Na(+)-(INa), Ca(2+)-(ICa), and K(+)-currents in all cells tested (n = 122). INa could be reversibly blocked by 1 microM tetrodotoxin added to the external solution. ICa was blocked by external 250 microM Cd2+ or 3 mM Co2+. In some cells, ICa consisted of both a transient and prolonged component. The outward K(+)-current consisted of Ca(2+)-dependent and -independent components. The Ca(2+)-insensitive portion of the K+ outward current was separated into four distinct components based upon pharmacological sensitivity and biophysical properties. In many cells, a rapidly inactivating current similar to the A-type K(+)-current (IA) observed in freshly cultured retinal ganglion cells was isolated by its greater sensitivity to 4-aminopyridine (5 mM) than to tetraethylammonium (20 mM). A tetraethylammonium-sensitive current with a more prolonged time course reminiscent of IK, the delayed rectifier, was also found. When the 4-aminopyridine- and tetraethylammonium-insensitive portions of the outward current were further analysed with voltage protocols, an additional slowly decaying potassium current became apparent. The inhibitory amino acids, GABA (20 microM) and glycine (100 microM), activated chloride-selective currents that were selectively blocked by bicuculline methiodide (10 microM) and strychnine (5 microM), respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

The axon terminal of goldfish retinal horizontal cells: a low membrane conductance measured in solitary preparations and its implication to the signal conduction from the soma

1. Mechanical dissociation of the enzyme-treated goldfish retina yielded somata and axon terminals of horizontal cells. The membrane properties of these solitary axon terminals were investigated using the whole-cell patch-clamp technique. 2. Axon terminals had a large input resistance, comparable to the seal resistance (approximately 30 G omega). Most axon terminals (greater than 80%) showed a nearly linear current-voltage relation between -60 and +10 mV, where the slope conductance was as small as 5 muS/cm2. Some axon terminals showed a shallow negative slope conductance in the same potential range. 3. The membrane current consisted of two components: transient and sustained. The transient component was carried by sodium ions, and the sustained component was a mixture of calcium and potassium currents. The sodium current (INa) was activated by depolarization of beyond -45 mV and was maximal (approximately 60 pA) at -10 mV. It was blocked by 5 microM tetrodotoxin and disappeared in Na+-free medium. The maximum amplitude of INa was less than 10% of INa of the soma. 4. A small calcium current (less than 6 pA) was isolated in a small proportion of cells, with an amplitude approximately 5% of the calcium current evoked in the soma under the identical recording conditions. 5. A small amount of potassium current through the anomalous rectifier was induced in the axon terminal when the membrane potential was below -60 mV. Its conductance was 15-20 muS/cm2, only 1/20 of the estimate in the soma. Other types of potassium currents were not detected. 6. It is concluded that the soma and the axon terminal have a similar set of membrane currents, but the specific membrane conductance of the axon terminal is extremely low. The signal conductivity from soma to axon terminal was assessed using a passive cable model together with numerical values obtained from the present experiments. Although the membrane conductance of the connecting axon was not measurable directly, the calculation strongly suggests that low conductance of the axon terminal membrane minimizes the leakage of signals arriving electrotonically through the thin connecting axon, even if the membrane conductance of the axon was overestimated as being identical to the soma membrane. 7. These results can explain why light-evoked responses recorded from the axon terminal are similar in amplitude as well as in waveform to those recorded from the soma, despite the lack of direct inputs from photoreceptors.     

Two types of voltage-gated K(+) currents in dissociated heart ventricular muscle cells of the snail Lymnaea stagnalis

We have used a combination of current-clamp and voltage-clamp techniques to characterize the electrophysiological properties of enzymatically dissociated Lymnaea heart ventricle cells. Dissociated ventricular muscle cells had average resting membrane potentials of -55 +/- 5 mV. When hyperpolarized to potentials between -70 and -63 mV, ventricle cells were capable of firing repetitive action potentials (8.5 +/- 1.2 spikes/min) that failed to overshoot 0 mV. The action potentials were either simple spikes or more complex spike/plateau events. The latter were always accompanied by strong contractions of the muscle cell. The waveform of the action potentials were shown to be dependent on the presence of extracellular Ca(2+) and K(+) ions. With the use of the single-electrode voltage-clamp technique, two types of voltage-gated K(+) currents were identified that could be separated by differences in their voltage sensitivity and time-dependent kinetics. The first current activated between -50 and -40 mV. It was relatively fast to activate (time-to-peak; 13.7 +/- 0.7 ms at +40 mV) and inactivated by 53.3 +/- 4.9% during a maintained 200-ms depolarization. It was fully available for activation below -80 mV and was completely inactivated by holding potentials more positive than -40 mV. It was completely blocked by 5 mM 4-aminopyridine (4-AP) and by concentrations of tetraethylammonium chloride (TEA) >10 mM. These properties characterize this current as a member of the A-type family of voltage-dependent K(+) currents. The second voltage-gated K(+) current activated at more depolarized potentials (-30 to -20 mV). It activated slower than the A-type current (time-to-peak; 74.1 +/- 3.9 ms at +40 mV) and showed little inactivation (6.2 +/- 2.1%) during a maintained 200-ms depolarization. The current was fully available for activation below -80 mV with a proportion of the current still available for activation at potentials as positive as 0 mV. The current was completely blocked by 1-3 mM TEA. These properties characterize this current as a member of the delayed rectifier family of voltage-dependent K(+) currents. The slow activation rates and relatively depolarized activation thresholds of the two K(+) currents are suggestive that their main role is to contribute to the repolarization phase of the action potential.     

On the relationship between\dot V_{\max } of slow responses and Ca-current availability in whole-cell clamped guinea pig heart cells

The relationship between Ca current availability and maximum rate of rise (V max) of slow responses was determined in the same single guinea pig ventricular heart cell under voltage and current clamp conditions (whole-cell clamp technique). The results are as follows. (1) Cell capacitance measured in 32 cells from the current response to a fast ramp voltage-clamp pulse (119.6 +/- 4.6 pF, mean +/- SE) or from Vmax values at a holding potential of -50 or -40 mV (118.6 +/- 5.3 pF) are identical. (2) In control conditions ([Ca]o 1.8, [K]o 4 and [Cs]i 140 mM), voltage-dependence of steady-state inactivation of Ca current (ICa) or Vmax are similar up to -35 mV. However, Vmax significantly (P less than 0.005) underestimates ICa availability at more positive potentials. At -30 mV, ICa and Vmax amplitudes represent respectively 35.6 and 22.4% (n = 14) of their maximum value. (3) In the presence of 50 nM isoprenaline, Vmax and the underlying ICa are respectively increased by 79.2 +/- 13.8% and 71.2 +/- 13.8% (n = 15). No statistically significant deviation from linearity is then observed. (4) When Vmax amplitude is expressed as a function of ICa density, an almost linear relationship is observed for Vmax values between 0 and 25 V/s. Vmax is then best described by the equation: Vmax (V/s) = 1.043 ICa (pA/pF) -0.514 (46 cells). (5) We conclude that, under conditions that minimize outward currents, Vmax of slow responses accurately measures ICa amplitude, except when ICa is decreased to less than 40% of its maximum control amplitude (i.e., below 4 pA/pF). At that point, Vmax underestimates ICa.     

Developmental changes in voltage-activated potassium currents of rat retinal ganglion cells.

Ca2(+)-independent voltage-activated potassium currents were investigated during the differentiation of rat retinal ganglion cells. Whole-cell patch-clamp recordings of Ca2(+)-independent voltage-activated potassium currents and their individual current components, i.e. a sustained, tetraethylammonium-sensitive current, a transient, 4-aminopyridine-sensitive current, and a slowly decaying current that was blocked by Ba2+, revealed distinct ontogenetic modifications in current densities and in activation and inactivation parameters. All three current types were expressed simultaneously at embryonic day 17/18 and were present in all retinal ganglion cells thereafter without showing any significant changes until the end of the first postnatal week. Ca2(+)-independent voltage-activated potassium current densities then increased strongly from postnatal day 8 onwards. Tetraethylammonium-sensitive current density increased about eightfold from 74 pA/pF in embryonic stages to 586 pA/pF in adult cells, whereas the transient potassium currents blocked by 4-aminopyridine increased only about 2.5-fold from 174 pA/pF to 442 pA/pF. The Ba2(+)-sensitive current increased simultaneously from 35 pA/pF to 332 pA/pF. The much higher increase in the sustained current components during retinal ganglion cell differentiation accounted for the changes in decay kinetics of Ca2(+)-independent voltage-activated potassium current observed in later postnatal stages. Alterations in current densities were paralleled by pronounced changes in current kinetics. From postnatal day 8 onwards, activation of Ca2(+)-independent voltage-activated potassium current was right-shifted for about 10 mV owing to a shift in tetraethylammonium-sensitive current-activation, whereas activation of other K+ components remained unaltered. Tetraethylammonium-sensitive current steady-state inactivation was incomplete at all developmental stages. About 50% of the tetraethylammonium-sensitive current elicited by a depolarization to +36 mV did not inactivate after prepulse potentials positive to -10 mV. In contrast, transient potassium current blocked by 4-aminopyridine almost fully inactivated during embryonic stages, whereas in adult retinal ganglion cells about 40% of this current component did not inactivate after prepulse potentials positive to -20 mV. Parallel investigation of the resting membrane potential during retinal ganglion cells differentiation showed an exponential increase from -3 mV at embryonic day 15/16 when no voltage-activated ion currents were expressed to a final value of -58 mV at postnatal day 8. These results show that fundamental potassium current modifications occur relatively late in retinal ganglion cell development and only after the resting potential is at its final value.     

Block of sodium channels by tyramine and its analogue (N-feruloyl tyramine) in frog ventricular myocytes.

Pharmacological effects of tyramine and its analogue, N-feruloyl tyramine (NFT), on sodium and calcium currents in frog ventricular myocytes were examined using the whole-cell voltage-clamp technique. To improve the temporal and spatial control of the membrane potential, sodium currents (INa) were recorded in 45.5 mM [Na+]o at 10 degrees C. Both tyramine and NFT (1-100 microM) induced a concentration-dependent decrease in INa evoked from a holding potential of -80 mV without affecting a change in either the time to peak or the time constant for the falling phase of INa. Similarly the reversal potential for INa remained unchanged at a value close to that predicted from the Nernst equation. The finding that both tyramine and NFT decreased INa when activated maximally, from a holding potential of -120 mV, indicates that the amplitude of INa can be reduced independently of a change in the kinetics of the current. In addition, tyramine (100 microM) shifted the membrane potential for half maximal inactivation (Vh) of the steady-state inactivation (h infinity)-curve from -74 to -84 mV without affecting its slope. In contrast, NFT failed to affect the h infinity-curve. The calcium current (ICa) recorded in the presence of 0.3 microM TTX was not affected by either 100 microM tyramine or NFT. We concluded that tyramine directly blocks Na channel by shifting h infinity-curve and by suppressing maximum Na channel conductance, while NFT suppresses only maximum Na channel conductance.     

Gradients of expression of calcium and potassium currents in frog crista ampullaris

In the present work we studied the intraregional expression of voltage-dependent Ca2+ and K+ currents in hair cells of frog crista ampullaris. The currents were recorded in situ from sensory cells of the peripheral region, the most populated region of the crista, by using the whole-cell variant of the patch-clamp technique. Voltage-clamp recordings revealed that the calcium current (I(Ca)) and the outward potassium currents of I(A), I(K) I(KCa) types and the inward rectifier potassium current of I(K1) type exhibited a significant gradient of density (pA/pF) along the region. I(A) density was maximal in cells located at the beginning of the peripheral region and decreased gradually becoming very small at the opposite end. All the other currents showed an opposite gradient of expression. Current-clamp experiments showed that the voltage behaviour of hair cells changed in relation to cell position. Cells located at the beginning of the peripheral region showed large depolarizations from the resting potential (close to -45 mV) which are consistent with the presence of small I(K) and I(KCa), and an I(A) largely inactivated at rest. These cells also exhibited slowly developing and large hyperpolarizations that approached passive ones, due to the lack of I(K1). In contrast, cells located at the opposite side of the region showed smaller depolarizations and hyperpolarizations from the resting potential (close to -65 mV), due to the presence of large I(K) and I(KCa), and I(K1), respectively. The possible role of the intraregional variation of Ca2+ and K+ currents in both hair cell function and afferent discharge properties is discussed.     

Effects of endothelin-1 on calcium and potassium currents in undiseased human ventricular myocytes

Endothelins have been reported to exert a wide range of electrophysiological effects in mammalian cardiac cells. These results are controversial and human data are not available. Our aim was to study the effects of endothelin-1 (ET-1, 8 nmol/l) on the L-type calcium current (ICa-L) and various potassium currents (rapid component of the delayed rectifier, IKr; transient outward current, Ito; and the inward rectifier K current, IK1) in isolated human ventricular cardiomyocytes. Cells were obtained from undiseased donor hearts using collagenase digestion via the segment perfusion technique. The whole-cell configuration of the patch-clamp technique was applied to measure ionic currents at 37 degrees C. ET-1 significantly decreased peak ICa-L from 10.2+/-0.6 to 6.8+/-0.8 pA/pF at +5 mV (66.7% of control, P<0.05, n=5). This reduction of peak current was accompanied by a lengthening of inactivation. The voltage dependence of steady-state activation and inactivation was not altered by ET- 1. IKr, measured as tail current amplitudes at 40 mV, decreased from 0.31+/-0.02 to 0.06+/-0.02 pA/pF (20.3% of control, P<0.05, n=4) after exposure to ET-1. ET-1 failed to change the peak amplitude of Ito, measured at +50 mV (9.3+/-4.6 and 9.0+/-4.4 pA/pF before and after ET-1, respectively), or steady-state IK1 amplitude, measured at the end of a 400-ms hyperpolarization to -100 mV (3.6+/-1.4 and 3.7+/-1.4 pA/pF, n=4). The present results indicate that in undiseased human ventricular myocytes ET-1 inhibits both ICa-L and IKr; however, the degree of suppression of the two currents is different.     

心房颤动患者内向整流性钾电流及Kir2.1 mRNA表达水平的研究

目的：研究心房颤动(房颤，AF)患者心房肌细胞内向整流性钾电流(Ik1)密度及Kir2.1(编码Ik1)mRNA表达水平，初步探讨慢性AF患者心房肌电生理重构机制。方法： 胶原酶Ⅱ两步酶解法分离心房肌细胞，膜片钳全细胞记录法记录离子电流；半定量逆转录聚合酶链反应方法检测心房组织Kir2.1 mRNA表达水平。结果： (1)AF患者心房肌细胞Ik1在超极化状态显著高于窦性心律(SR)组，在膜电位-120 mV时AF组Ik1增加34.04%(P＜0.05)，在-30 mV-+10 mV时其外向电流成分显著增加；(2)以GAPDH为内参标基因，AF组和SR组心房肌Kir2.1 mRNA相对表达量无显著差异(P＜0.05)。结论： AF患者右心房肌细胞Ik1密度在超极化状态显著增加是其电生理重构的重要离子基础之一；AF患者心房肌Kir2.1 mRNA表达水平无显著改变，推测Ik1重构为转录后调节。     

Apelin-13对大鼠缺血心室肌细胞瞬时钠电流的影响

 目的：观察apelin对正常和缺血心室肌细胞瞬时钠电流（INa）的影响以及其对室性心律失常和心脏功能的影响。方法：应用Landgendorff逆灌流系统酶解分离大鼠左室心肌细胞,采用全细胞膜片钳技术观察大鼠左室心肌细胞INa,通过改变电极外液的方法来模拟正常/缺血细胞状态,分正常组（N组）、正常apelin组（N+A组）、缺血组（I组）和缺血apelin组（I+A组）（各组n=10）,分别观察apelin-13对正常/模拟缺血心室肌细胞INa的影响;另建立Langendorff灌流离体缺血大鼠心脏模型分为4组（各组n=4）：N组、N+A组、I组、I+A组,观察apelin-13对各组大鼠离体灌流心脏模型心功能和室性心律失常的影响。结果：Apelin-13（100 nmol/L）在N+A 组和I+A组均能增加INa幅度,I-V曲线分析显示N+A组比N组INa幅度增大32%［（-86±13）pA/pF］,I+A组比I组INa幅度增大18% ［（-52±15）pA/pF］;然而I-V曲线分析Apelin-13并未改变最大传导速度,N、N＋A、I和I+A组分别为（3.2±0.2）pS/pF、（3.1±0.3）pS/pF、（2.9±0.1）pS/pF和（2.8±0.4）pS/pF（P＞0.05）;各组的半激活电压（V1/2）分别为（-21.9±0.6）mV、（-28.7±0.3）mV、（-30.5±0.7）mV和（-36.8±0.2）mV;Boltzmann曲线各组斜率分别为5.6±0.3、 5.1±0.4、 4.3±0.3和4.9±0.6（P＞0.05）;V1/2值N+A组比N组改变（-5.9±0.8）mV,I+A组V1/2比I组改变（-7.7±1.3）mV（P＜0.05）。室性心律失常开始时间、室性心动过速持续时间、心室颤动持续时间及心律失常评分情况,N+A组与N组比较、I+A组与I组比较差异无统计学意义（P＞0.05）;N+A组LVEDP低于N组,LVDP高于N组,dp/dtmax和dp/dtmin高于N组;I+A组LVEDP低于I组,LVDP高于I组,dp/dtmax和dp/dtmin高于I组;以β-肌动蛋白（β-actin）作为内参照,4组β-actin表达水平差异无统计学意义,4组Na+通道蛋白Vα亚单位的表达灰度值分别为28.8±3.6、 29.4±4.1、 30.1±2.9和31.3±3.8,组间差异无统计学意义。结论：Apelin-13可能是通过改变Na+通道门控特性增加INa峰值,使正常和缺血组心室肌细胞Na+通道更容易开放。Apelin-13对缺血相关室性心律失常无影响,对正常和缺血心肌均有正性肌力作用。     

A-type potassium currents dominate repolarisation of neonatal rat primary auditory neurones in situ.

Spiral ganglion neurones provide the afferent innervation to cochlear hair cells. Little is known of the molecular physiological processes associated with the differentiation of these neurones, which occurs up to and beyond hearing onset. We have identified novel A-type (inactivating) potassium currents in neonatal rat spiral ganglion neurones in situ, which have not previously been reported from the mammalian cochlea, presumably as a consequence of altered protein expression associated with other preparations. Under whole-cell voltage clamp, voltage steps activated both A-type and non-inactivating outward currents from around -55 mV. The amplitude of the A-type currents was dependent on the holding potential, with steady-state inactivation relieved at hyperpolarised potentials. At -60 mV (close to the resting potential in situ) the currents were approximately 30% enabled. The inactivation kinetics and the degree of inactivation varied between cells, suggesting heterogeneous expression of multiple inactivating currents. A-type currents provided around 60% of total conductance activated by depolarising voltage steps from the resting potential, and were very sensitive to bath-applied 4-aminopyridine (0.01-1 mM). Tetraethylammonium (0.1-30 mM) also blocked the majority of the A-type currents, and the non-inactivating outward current, but left residual fast inactivating A-type current. Under current clamp, neurones fired single tetrodotoxin-sensitive action potentials. 4-Aminopyridine relieved the A-type current mediated stabilisation of membrane potential, resulting in periodic small amplitude action potentials.This study provides the first electrophysiological evidence for A-type potassium currents in neonatal spiral ganglion neurones and shows that these currents play an integral role in primary auditory neurone firing.     

Rat hippocampal neurons in culture: Ca2+ and Ca2+-dependent K+ conductances

Rat hippocampal neurons grown in dissociated cell culture were studied in a medium containing 1 microM tetrodotoxin (TTX) and 25 mM tetraethylammonium (TEA), which eliminated the Na+ and K+ conductances normally activated by depolarizing current injections. In this medium depolarizing current pulses evoked depolarizing regenerative potentials and afterhyperpolarizations in most cells. Both of these events were blocked by close application of Co2+ or Cd2+. These events resemble Ca2+ spikes reported previously in hippocampal pyramidal cells. The membrane potential at which these Ca2+ spikes could be triggered and the rheobase current necessary were dependent on the potential at which the cell was conditioned: the more depolarized the holding potential, the more negative the absolute potential at which a spike could be triggered and the less rheobase current required. The duration of these Ca2+ spikes was also sensitive to the holding potential: the more depolarized the holding level, the longer the duration of the triggered spikes. The amplitude and duration of the Ca2+ spikes were enhanced in a reversible manner by 0.5-1.0 mM 4-aminopyridine (4-AP) delivered in the vicinity of the cell. Two-electrode voltage-clamp analysis of cells studied in TTX, TEA-containing medium revealed an inward current response that peaked in 25-50 ms during depolarizing commands. This response first became detectable during commands to -30 mV. It peaked in amplitude during commands to -10 mV and was enhanced in medium containing elevated [Ca2+]0. It was blocked by either 20 mM Mg2+, 0.2 mM Cd2+, 5 mM Co2+, or 5 mM Mn2+. These results have led us to identify this inward current response as ICa2+. 4-AP enhanced the magnitude and duration of ICa2+ independent of the drug's depressant effects on a transient K+ current also observed under these same experimental conditions. In many but not all cells the Ca2+ spike was followed by a long-lasting hyperpolarization associated with an increase in membrane conductance. This was blocked by Co2+. Under voltage clamp ICa2+ was followed by a slowly developing outward current response that was attenuated by Co2+ or Cd2+. These properties observed under current- and voltage-clamp recording conditions are superficially similar to those previously reported for Ca2+-dependent K+ conductance mechanisms (IC) recorded in these and other membranes. Long-lasting tail currents following activation of IC inverted in the membrane potential range for the K+ equilibrium potential found in these cells.     

Ionic currents underlying fast action potentials in the obliquely striated muscle cells of the octopus arm

The octopus arm provides a unique model for neuromuscular systems of flexible appendages. We previously reported the electrical compactness of the arm muscle cells and their rich excitable properties ranging from fast oscillations to overshooting action potentials. Here we characterize the voltage-activated ionic currents in the muscle cell membrane. We found three depolarization-activated ionic currents: 1) a high-voltage-activated L-type Ca(2+) current, which began activating at approximately -35 mV, was eliminated when Ca(2+) was substituted by Mg(2+), was blocked by nifedipine, and showed Ca(2+)-dependent inactivation. This current had very rapid activation kinetics (peaked within milliseconds) and slow inactivation kinetics (tau in the order of 50 ms). 2) A delayed rectifier K(+) current that was totally blocked by 10 mM TEA and partially blocked by 10 mM 4-aminopyridine (4AP). This current exhibited relatively slow activation kinetics (tau in the order of 15 ms) and inactivated only partially with a time constant of ~150 ms. And 3) a transient A-type K(+) current that was totally blocked by 10 mM 4AP and was partially blocked by 10 mM TEA. This current exhibited very fast activation kinetics (peaked within milliseconds) and inactivated with a time constant in the order of 60 ms. Inactivation of the A-type current was almost complete at -40 mV. No voltage-dependent Na(+) current was found in these cells. The octopus arm muscle cells generate fast (~3 ms) overshooting spikes in physiological conditions that are carried by a slowly inactivating L-type Ca(2+) current.     

正常大鼠心室肌细胞钠、钙和钾离子流记录和特点

目的研究正常Sprague—Dawley大鼠外膜、中膜和内膜心室肌细胞钠离子电流（INa）、L-型钙离子电流（ICa-L）、瞬时外向钾离子电流（I60）、延迟整流性钾离子电流（IK）、内向整流性钾离子电流（IK1）的特点。方法采用酶消化法获得大鼠外膜、中膜和内膜心室肌细胞,以全细胞膜片钳技术记录心室肌细胞INa、ICa-L、Ito、IK和IK1。结果外膜至内膜心室肌细胞Ito电流密度逐渐减小,而外膜至内膜心室肌细胞INa、ICa-L、IK和IK1的电流密度无差异（P〉0．05）。结论大鼠心室肌细胞Ito存在分层差别,INa、ICa-L、IK和IK1不存在分层差别。     

Voltage-gated sodium currents in isolated retinal ganglion cells of the cat: relation between the inactivation kinetics and the cell type.

Ganglion cells in the cat retina were retrogradely labeled by injecting a fluorescent dye (DiI) into either the lateral geniculate nucleus (LGN) or the superior colliculus (SC). Cells were then dissociated enzymatically from the retinal tissue. LGN-projecting ganglion cells consisted of 2 different populations, one with small and the other with large somata, which were identified as W and X cells, respectively. SC-projecting cells consisted of a single group of cells with small somata, identified as W cells. The voltage-gated sodium current (INa) was recorded from isolated ganglion cells under the voltage-clamp condition using a patch pipette in the whole cell configuration. INa was identified by reversible tetrodotoxin block. INa was activated by depolarization of the cell from the holding potential (Vh) of -95 mV to membrane voltages (Vm) more positive than -45 mV. The maximum INa was recorded at around -15 mV. INa flowed outward at Vm more positive than +65 mV. The reversal potential of INa became more negative voltages with low extracellular Na concentration ([Na+]o) with a relation of 58 mV for a 10-fold change in [Na+]o. INa was inactivated with a few milliseconds. Once inactivated, INa recovered by holding the cell membrane hyperpolarized. While the voltage dependence of INa activation and steady-state inactivation were constant from cell to cell, the time course of recovery was not. Cells with a large soma showed a rapid recovery, while cells with a small soma showed slow recovery. Thus, the rate of recovery is faster for X cells than for W cells. Perhaps this helps to explain the 'sluggish' firing of the latter cell type.     

Developmental regulation of calcium channel-mediated currents in retinal glial (Müller) cells

Whole cell voltage-clamp recordings of freshly isolated cells were used to study changes in the currents through voltage-gated Ca(2+) channels during the postnatal development of immature radial glial cells into Müller cells of the rabbit retina. Using Ba(2+) or Ca(2+) ions as charge carriers, currents through transient low-voltage-activated (LVA) Ca(2+) channels were recorded in cells from early postnatal stages, with an activation threshold at -60 mV and a peak current at -25 mV. To increase the amplitude of currents through Ca(2+) channels, Na(+) ions were used as the main charge carriers, and currents were recorded in divalent cation-free bath solutions. Currents through transient LVA Ca(2+) channels were found in all radial glial cells from retinae between postnatal days 2 and 37. The currents activated at potentials positive to -80 mV and displayed a maximum at -40 mV. The amplitude of LVA currents increased during the first postnatal week; after postnatal day 6, the amplitude remained virtually constant. The density of LVA currents was highest at early postnatal days (days 2-5: 13 pA/pF) and decreased to a stable, moderate level within the first three postnatal weeks (3 pA/pF). A significant expression of currents through sustained, high-voltage-activated Ca(2+) channels was found after the third postnatal week in approximately 25% of the investigated cells. The early and sole expression of transient currents at high-density may suggest that LVA Ca(2+) channels are involved in early developmental processes of rabbit Müller cells.