Na(+)-current expression in rat hippocampal astrocytes in vitro: alterations during development

1. With the use of whole-cell patch-clamp recording. Na(+)-current expression was studied in hippocampal astrocytes in vitro, individually identified by filling with Lucifer yellow (LY) and staining for glial fibrillary acidic protein (GFAP) and vimentin. 2. The proportion of astrocytes that express Na+ currents in rat hippocampal cultures changes during development in vitro and decreases from approximately 75% at day 1 to approximately 30% after 10 days in culture. 3. The sodium currents expressed in astrocytes can be differentiated into two types on the basis of kinetics. At early times in culture the time course of Na+ currents is fast in both onset and decay with an average decay time constant of 1.27 ms, whereas after 6 days Na+ currents become comparatively slow and decayed with an average time constant of 1.86 ms. 4. As with the time-course of Na+ currents, the two age groups of astrocytes (i.e., days 1-5 and day 6 and older) differ with respect to their steady-state inactivation characteristics. Early after plating and up to day 5, the midpoint of the steady-state inactivation curve is close to -60 mV, as also observed in hippocampal neurons of various ages; in contrast, after 6 days in culture the curve is shifted by approximately 25 mV toward more hyperpolarized potentials with a midpoint close to -85 mV. 5. In contrast to h infinity-curves, current-voltage (I-V) curves of Na(+)-current activation were identical in all astrocytes studied and did not change with time in culture. 6. In astrocytes expressing Na+ currents, current densities (average of 35 pA/pF on day 1) decreased throughout the first 5 days and were almost abolished around days 4 and 5 in culture. Beginning on day 6, however, current densities increased again and maintained a steady level (average of 14 pA/pF) for the duration of the time period in culture (20 days). This biphasic time course closely correlates with the time course of changes in Na(+)-current kinetics and steady-state inactivation. 7. These data suggest that Na+ currents in cultured hippocampal astrocytes show characteristic changes with increasing time in culture. During the first 4-5 days in culture, hippocampal astrocytes display Na+ currents with properties similar to those of hippocampal neurons. Our data further suggest that Na+ currents with distinctive, "glial-type" characteristics are only expressed in hippocampal astrocytes after 6 days in culture.     

Ion channels in spinal cord astrocytes in vitro. I. Transient expression of high levels of Na+ and K+ channels.

1. Na+ and K+ channel expression was studied in cultured astrocytes derived from P--0 rat spinal cord using whole cell patch-clamp recording techniques. Two subtypes of astrocytes, pancake and stellate, were differentiated morphologically. Both astrocyte types showed Na+ channels and up to three forms of K+ channels at certain stages of in vitro development. 2. Both astrocyte types showed pronounced K+ currents immediately after plating. Stellate but not pancake astrocytes additionally showed tetrodotoxin (TTX)-sensitive inward Na+ currents, which displayed properties similar to neuronal Na+ currents. 3. Within 4-5 days in vitro (DIV), pancake astrocytes lost K(+)-current expression almost completely, but acquired Na+ currents in high densities (estimated channel density approximately 2-8 channels/microns2). Na+ channel expression in these astrocytes is approximately 10- to 100-fold higher than previously reported for glial cells. Concomitant with the loss of K+ channels, pancake astrocytes showed significantly depolarized membrane potentials (-28.1 +/- 15.4 mV, mean +/- SD), compared with stellate astrocytes (-62.5 +/- 11.9 mV, mean +/- SD). 4. Pancake astrocytes were capable of generating action-potential (AP)-like responses under current clamp, when clamp potential was more negative than resting potential. Both depolarizing and hyperpolarizing current injections elicited overshooting responses, provided that cells were current clamped to membrane potentials more negative than -70 mV. Anode-break spikes were evoked by large hyperpolarizations (less than -150 mV). AP-like responses in these hyperpolarized astrocytes showed a time course similar to neuronal APs under conditions of low K+ conductance. 5. In stellate astrocytes, AP-like responses were not observed, because the K+ conductance always exceeded Na+ conductance by at least a factor of 3. Thus stellate spinal cord astrocyte membranes are stabilized close to EK as previously reported for hippocampal astrocytes. 6. It is concluded that spinal cord pancake astrocytes are capable of synthesizing Na+ channels at densities that can, under some conditions, support electrogenesis. In vivo, however, AP-like responses are unlikely to occur because the cells' resting potential is too depolarized to allow current activation. Thus the absence of electrogenesis in astrocytes may be explained by two mechanisms: 1) a low Na-to-K conductance ratio, as in stellate spinal cord astrocytes and in other previously studied astrocyte preparations; or, 2) as described in detail in the companion paper, a mismatch between the h infinity curve and resting potential, which results in Na+ current inactivation in spinal cord pancake astrocytes.     

Ion channels in spinal cord astrocytes in vitro. II. Biophysical and pharmacological analysis of two Na+ current types.

1. Na+ currents expressed in astrocytes cultured from spinal cord were studied by whole cell patch-clamp recording. Two subtypes of astrocytes, pancake and stellate cells, were morphologically differentiated and showed expression of Na+ channels at densities that are unusually high for glial cells (2-8 channels/microns2) and comparable to cultured neurons. 2. Na+ currents in stellate and pancake astrocytes were comparable to neuronal Na+ currents with regard to Na(+)-current activation (tau m) and inactivation (tau h) time constants, which were equally fast in both astrocyte types. However, they differed with respect to voltage dependence of activation, and current-voltage (I-V) curves were approximately 10 mV more positive in stellate cells (-11.1 +/- 5.6 mV, mean +/- SD) than in pancake cells (19.7 +/- 4.5 mV). Steady-state activation (m infinity curves) was 16 mV more negative in pancake (mean V1/2 = -48.8 mV) than in stellate cells (mean V1/2 = -32.7 mV). 3. Steady-state inactivation (h infinity curves) of Na+ currents was distinctly different in the two astrocyte types. In stellate astrocytes h infinity curves had midpoints close to -65 mV (-64.6 +/- 6.5 mV), similar to most cultured neurons. In pancake astrocytes h infinity-curves were approximately 25 mV more negative, with midpoints close to -85 mV (84.5 +/- 9.5 mV). 4. The two forms of Na+ currents were additionally distinguishable by their sensitivity to tetrodotoxin (TTX). Na+ currents in stellate astrocytes were highly TTX sensitive [half-maximal inhibition (Kd) = 5.7 nM] whereas Na+ currents in pancake astrocytes were relatively TTX resistant, requiring 100- to 1,000-fold higher concentrations for blockage (Kd = 1,007 nM). 5. Na+ currents were fit by the Hodgkin-Huxley (HH) model. In pancake astrocytes, as in squid gigant axons, Na(+)-current kinetics could be well described with an m3h model, whereas in stellate astrocytes Na+ currents were better described with higher-order power terms for activation (m). On average, best fits were obtained using an m4h model. 6. Pancake astrocytes were capable of generating action-potential (AP)-like responses under current clamp whereas stellate astrocytes were not. The h infinity curve for APs shows that membrane potentials more negative than -70 mV are required to allow these responses to occur.(ABSTRACT TRUNCATED AT 400 WORDS)     

Blocking and modifying actions of octanol on Na channels in frog myelinated nerve

The actions of externally applied n-octanol on Na channels in myelinated frog nerve fibres were studied under voltage clamp conditions. Upon octanol application peak Na inward currents declined in two phases: 90% of the reduction occurred in less than 2 min but a steady-state was reached only after 15 min. During washout the currents came to a stable level within 10 min. The reduction of Na inward currents by octanol was dependent on the amplitude and duration of prepotentials. At the resting potential (VH = 0 mV) 0.4 mM octanol reduced peak Na inward currents at V = 60 mV by 50%. After a prepulse of -60 mV and 50 ms duration Na currents decreased only by 20%. At a hyperpolarizing holding potential of VH = -28 mV 0.7 mM octanol reduced peak inward Na currents to one half. Octanol depressed Na currents at all potentials by approximately the same factor. The Na reversal potential VNa remained unchanged. 0.7 mM external octanol shifted the Na activation curve m infinity (V) by 5 mV to more positive and the inactivation curve h infinity (V) by 14 mV to more negative potentials. The midpoint slopes of both curves were reduced. The time constants of Na activation and inactivation at small depolarizations were decreased. The conductance gamma of a single Na channel and the number No of conducting Na channels per node were determined from nonstationary Na current fluctuations. 0.7 mM octanol increased gamma by a factor of 1.6 and reduced No by a factor of 0.34. It is concluded that octanol blocks some Na channels and modifies the remaining unblocked channels.     

Development of gap junctions in hippocampal astrocytes: evidence that whole cell electrophysiological phenotype is an intrinsic property of the individual cell

Gap junction communication between astrocytes is prevalent and has been proposed to be involved in several astrocyte functions. One such proposal involves gap junctions in potassium spatial buffering. However, little is known about the developmental time course of gap junction coupling and how much the syncytium affects whole cell measurements of ion currents. Our previous work described three types of hippocampal astrocyte, each with a distinct electrophysiological profile when recorded in whole cell voltage-clamp mode. In the current study we correlated post-whole cell recording immunohistochemistry for GLAST and the spread of injected dye from the recorded cell with the measured electrophysiological phenotype to quantify cell coupling of astrocytes and the type of astrocyte coupled, in the rat hippocampus. We found that passive astrocytes, which predominate after 3 wk postnatally, have much lower membrane resistances (Rm) and are more frequently dye coupled and to more cells, than outwardly and variably rectifying astrocytes that predominate in early postnatal development. Dye coupling in GLAST(+) cells was first detected in the first postnatal week and the degree of coupling peaked before the complete transition to the low Rm, passive electrophysiological type. Also, the degree of dye coupling did not correlate with the passive electrophysiological phenotype. Passive cells were also detected after pretreatment with a gap junction inhibitor. Further evidence that cell coupling does not contribute to the mature astrocyte electrophysiological phenotype came from recording of excised membrane patches, which predominantly corresponded to the ion channel expression profiles of their cells of origin. These findings imply that in the hippocampus, interastrocyte cell coupling likely contributes little to the overall whole cell current profile of diverse glia, and the electrophysiological passivity reflects the intrinsic ion channel expression of the mature astrocyte.     

Calcium oscillations in type-1 astrocytes, the effect of a presenilin 1 (PS1) mutation

Stimulation of type-1 astrocytes, by a number of agonists, has been shown to increase cytosolic Ca2+ concentrations in an oscillatory manner. However, it is unknown how these are driven or altered by aging, injury or disease. Therefore, we characterized the signaling properties of rat type-1 astrocytes in monolayer cultures. Ca2+ responses were recorded in astrocytes stimulated with ATP or glutamate. Oscillations were evident in cultures at 3 days in vitro (DIV 3) with a peak percentage (26%) of cells responding by DIV 7. The presence or absence of serum in the culture medium did not influence this percentage. Likewise, long-term culture (DIV 30+) did not increase the oscillating cell numbers. ATP was found to have a more potent effective dose (50 microM) than glutamate (10 mM). Membrane potential was recorded with fluorescent voltage-sensitive dye (membrane potential dye for FLIPR) and was similar regardless of the culture age and intracellular Ca2+ response. This suggests that mechanisms associated with the intracellular release of Ca2+ from endogenous Ca2+ stores, rather than ion fluxes across the plasma membrane, may contribute to the oscillations in the astrocytes. In order to identify a possible pathological significance of this response, we transfected astrocytes with wild-type presenilin (PS1) as well as PS1 harboring a mutation linked to familial Alzheimer's disease (FAD). PS mutation expressing astrocytes oscillated at lower ATP and glutamate concentrations when compared to wild-type PS1 expressing astrocytes. This indicates that PS1 mutation may introduce aberrations in the intracellular Ca2+ mobilization in astrocytes contributing to the accelerated pathogenesis in FAD.     

Block of Na channels in the membrane of myelinated nerve by benzocaine

The actions of the neutral local anesthetic benzocaine on Na channels were studied in voltage-clamp experiments on single myelinated nerve fibres of the frog by measurements of sodium currents, asymmetry currents, and sodium current fluctuations. 2. 1 mM benzocaine reduced the peak Na currents during various depolarizations V between 20 and 120 nV to 63% of their control values but did not change the time constant of Na activation. 3. 1 mM benzocaine altered asymmetry currents during 1 ms pulses V between 20 and 120 mV in the same was as the early Na currents: It reduced the amplitude to 64% but did not affect the kinetics of the currents. 4. The charge displacement of the asymmetry current during the pulse (Qon) was compared with the charge displacement after the pulse (Qoff). Without benzocaine the relative charge Qoff/Qon Declined to a constant level (0.42 at V = 40mV, 0.25 at V = 100 mV) with increasing pulse durations. In the presence of 1 mM benzocaine the charges Qoff after pulses to V = 40 or 100 mV are almost independent of pulse duration and approximately equal to the control Qoff values after 5.6 ms pulses. Thus, the immobilizations caused by Na inactivation and benzocaine are not additive. 5. Na currents and Na-current fluctuations were recorded during depolarizations V between 24 and 48 mV in the presence of 0.1 mM benzocaine and 7 microM Anemonia toxin II. A lower limit of 8.6 pS was derived for the conductance of a single Na channel. The value agrees with other estimates of the conductance of Na channels which had not been treated by local anesthetics. This suggests an "all-or-none blocking" of Na channels by benzocaine.     

Isolation and kinetic analysis of inward currents in neuroblastoma cells

The suction pipette method for combined voltage clamp and intracellular dialysis was applied to isolate the two components of voltage-gated inward current across membranes of NIE-115 neuroblastoma cells. In order to analyze the kinetic behavior of the Na+ and Ca2+ channels responsible for generating these components, current through K+ channels was effectively blocked by substituting impermeant Cs+ for internal and external K+. Block was confirmed independently by examining the effects of the application of external tetraethylammonium or Cd2+; and comparing the time course of Ca2+ tail currents with the decay of current during a maintained depolarization. Na+ currents studied at 8-10 degrees C, developed as a fourth order process giving a maximum e-fold conductance change for a 3 mV depolarization, with half activation occurring at -10 mV. The instantaneous current-voltage relationship was linear. Time constants of the activation parameter (m) varied from 0.5 ms (-50 mV) to 3-4 ms (-10 to -40 mV) at 10 degrees C. Inactivation (h) was a first order process having a time constant between 4 ms (+10 to +60 mV) and 225 ms (-60 mV). Steady-state inactivation for Na+ channels attained a value of 0.5 at -50 mV. A slow inactivation process, however, also is involved in gating of Na+ channels, and has a time course at least two orders of magnitude slower than that for h. The temperature sensitivity of Na+ currents was found to be similar to that found for other preparations. Ca2+ currents were studied at 24-29 degrees C in the presence of internal ethyleneglycolbis-(aminoethylether)-tetra-acetate (EGTA) and an external Ca2+ concentration of 20 mM. Ca2+ channel activation could also be described by a fourth order process giving an e-fold conductance change for a 5-6 mV change in potential and the half activation potential of -13 mV. Internal EGTA (20 mM) did not abolish inactivation of Ca2+ currents and no recovery from inactivation caused by a prepulse could be measured as the prepulse potential approached the null potential for Ca2+ influx. Time constants of both activation and inactivation of Ca2+ channels were measured between -20 and +50 mV. Currents through K+ channels could be completely eliminated by substitution of K+ with Cs+, although a residual non-linear leakage current remained, in addition to currents through the Na+ and Ca2+ channels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pharmacology of a slowly inactivating outward current in hippocampal CA3 pyramidal neurons

The pharmacology of a slowly inactivating outward current was examined using whole cell patch-clamp recordings in CA3 pyramidal cells of guinea pig hippocampal slices. The current had a low activation threshold (about -60 mV) and inactivated slowly (time constant of 3.4 +/- 0.5 s at -50 mV) and completely at membrane voltages depolarized to -50 mV. The slowly inactivating outward current was mainly mediated by K+ with a reversal potential close to the equilibrium potential for K+. The slowly inactivating outward current had distinct pharmacological properties: its time course was not affected by extracellular Cs+ (1 mM) or 4-AP (1-5 mM)-broad spectrum inhibitors of K+ currents and of inactivating K+ currents, respectively. The presence of extracellular Mn2+ (0.5-1 mM), which suppresses several Ca2+ -dependent K+ currents, also did not affect the slowly inactivating outward current. The current was partially suppressed by TEA (50 mM) and was blocked by intracellular Cs+ (134 mM). In addition, intracellular QX-314 (5 mM), a local anesthetic derivative, inhibited this current. The slowly inactivating outward current with its low activation threshold should be operational at the resting potential. Our results suggest that the transient outward current activated at subthreshold membrane potentials in hippocampal pyramidal cells consists of at least three components. In addition to the well-described A- and D-currents, the slowest decaying component reflects the time course of a distinct current, suppressible by QX-314.     

Intrinsic theta-frequency membrane potential oscillations in hippocampal CA1 interneurons of stratum lacunosum-moleculare

The ionic conductances underlying membrane potential oscillations of hippocampal CA1 interneurons located near the border between stratum lacunosum-moleculare and stratum radiatum (LM) were investigated using whole cell current-clamp recordings in rat hippocampal slices. At 22 degrees C, when LM cells were depolarized near spike threshold by current injection, 91% of cells displayed 2-5 Hz oscillations in membrane potential, which caused rhythmic firing. At 32 degrees C, mean oscillation frequency increased to 7.1 Hz. Oscillations were voltage dependent and were eliminated by hyperpolarizing cells 6-10 mV below spike threshold. Blockade of ionotropic glutamate and GABA synaptic transmission did not affect oscillations, indicating that they were not synaptically driven. Oscillations were eliminated by tetrodotoxin, suggesting that Na+ currents generate the depolarizing phase of oscillations. Oscillations were not affected by blocking Ca2+ currents with Cd2+ or Ca2+-free ACSF or by blocking the hyperpolarization-activated current (Ih) with Cs+. Both Ba2+ and a low concentration of 4-aminopyridine (4-AP) reduced oscillations but TEA did not. Theta-frequency oscillations were much less common in interneurons located in stratum oriens. Intrinsic membrane potential oscillations in LM cells of the CA1 region thus involve an interplay between inward Na+ currents and outward K+ currents sensitive to Ba2+ and 4-AP. These oscillations may participate in rhythmic inhibition and synchronization of pyramidal neurons during theta activity in vivo.     

A threshold sodium current in pyramidal cells in rat hippocampus

Maintained, inward currents were activated by small depolarizations from the resting membrane potential (-50 to -60 mV) in voltage-clamped, pyramidal neurons in rat hippocampal slices. The currents were apparently Na currents as they were blocked by tetrodotoxin or removal of extracellular Na and were not affected by Cd. They showed little decrease in amplitude during prolonged depolarizations. The increase in Na conductance with depolarization was sigmoidal, with half-maximum conductance at about -50 mV, and saturated at -20 to -30 mV. This 'threshold' Na current may be involved in setting patterns of repetitive firing of action potentials.     

Extent of intercellular calcium wave propagation is related to gap junction permeability and level of connexin-43 expression in astrocytes in primary cultures from four brain regions.

Astrocytes are coupled via gap junctions, predominantly formed by connexin-43 proteins, into cellular networks. This coupling is important for the propagation of intercellular calcium waves and for the spatial buffering of K+. Using the scrape-loading/dye transfer technique, we studied gap junction permeability in rat astrocytes cultured from four different brain regions. The cultures were shown to display regional heterogeneity with the following ranking of the gap junction coupling strengths: hippocampus = hypothalamus > cerebral cortex = brain stem. Similar relative patterns were found in connexin-43 messenger RNA and protein levels using solution hybridization/RNase protection assay and western blots, respectively. The percentages of the propagation area of mechanically induced intercellular calcium waves for cortical, brain stem and hypothalamic astrocytes compared with hippocampal astrocytes were approximately 77, 42, and 52, respectively. Thus, the extent of calcium wave propagation was due to more than just gap junctional permeability as highly coupled hypothalamic astrocytes displayed relatively small calcium wave propagation areas. Incubation with 5-hydroxytryptamine decreased and incubation with glutamate increased the calcium wave propagation area in hippocampal (67% and 170% of the control, respectively) and in cortical astrocytes (82% and 163% of the control, respectively). Contrary to hippocampal and cortical astrocytes, the calcium wave propagation in brain stem astrocytes was increased by 5-hydroxytryptamine incubation (158% of control), while in hypothalamic astrocytes, no significant effects were seen. Similar effects from 5-hydroxytryptamine or glutamate treatments were observed on dye transfer, indicating an effect on the junctional coupling strength. These results demonstrate a strong relationship between connexin-43 messenger RNA levels, protein expression, and gap junction permeability among astroglial cells. Furthermore, our results suggest heterogeneity among astroglial cells from different brain regions in intercellular calcium signaling and in its differential modulation by neurotransmitters, probably reflecting functional requirements in various brain regions.     

焦亚硫酸钠对大鼠海马CA1区神经元钠电流的影响

目的：探讨SO2 及其体内衍生物（亚硫酸盐和亚硫酸氢盐）对中枢神经元钠通道的影响。 方法: 采用全细胞膜片钳技术研究了焦亚硫酸钠（SMB）对大鼠海马CA1区神经元钠电流的影响及超氧化物歧化酶(SOD)、过氧化氢酶(CAT)及谷胱甘肽过氧化物酶(GPx)相应的保护作用。 结果： ① 焦亚硫酸钠可剂量依赖性地增大全细胞钠电流，剂量为2 μmol/L和20 μmol/L时，钠电流分别增大（22.36±3.28）% 和（65.05±5.75）%（n=10）。② 10　μmol/L的焦亚硫酸钠不影响钠电流的激活过程，却非常显著地影响其失活过程，使失活曲线显著右移，作用前后的半数失活电压分别为（-82.38±0.54）mV和（-69.39±0.41）mV (n=10, P<0.01), 但失活曲线的斜率因子未见改变。③ SOD(1×106 U/L)、CAT(2×106 U/L) 及GPx (1×104 U/L) 均可使SMB（10 μmol/L）增大的钠电流部分恢复。 结论： SMB增大钠电流并抑制其失活过程，从而影响神经细胞的兴奋性，这一效应可能与硫中心或氧中心自由基的损伤作用有关。     

Voltage-dependent potassium channels in activated rat microglia.

1. Voltage-dependent currents of untreated (proliferating) and lipopolysaccharide (LPS)-treated rat microglial cells in culture were recorded using the whole-cell patch-clamp technique. 2. Membrane potentials showed prominent peaks at -35 mV and -70 mV. Membrane potentials of LPS-treated cells alternated between the two values. This may be due to a negative slope region of the I-V relation resulting in two zero current potentials. 3. From a holding potential of -70 mV, hyperpolarizing steps evoked an inwardly rectifying current both in proliferating and in LPS-treated cells, while depolarizing steps below -50 mV evoked an outwardly rectifying current only in LPS-treated microglia. The currents were K+ selective, as indicated by their reversal potential of approximately 0 mV in symmetric K+ concentrations (150 mM both intra- and extracellularly) and the reversal potential of the outward tail currents of approximately -90 mV at a normal extracellular K+ concentration (4.5 mM). 4. The activation of the outward current could be fitted by Hodgkin-Huxley-type n4 kinetics. The time constant of activation depended on voltage. 5. The inactivation of the inward and outward currents could be fitted by a single exponential. The time constant of the inward current inactivation was dependent on voltage, whereas the time constant of the outward current inactivation was virtually independent of voltage, except near the threshold of activation. Recovery of the outward from inactivation was slow and could be fitted by two exponentials. Responses to depolarizing steps were stable at 0.125 Hz, but greatly decreased from the first to the second pulse at 1 Hz. 6. The inactivation of the inward, but not of the outward, current disappeared in a low Na(+)-containing medium (5 mM). The inward current was selectively inhibited by extracellular Cs+ and Ba2+. The outward current was selectively inhibited by Cd2+, 4-aminopyridine and charybdotoxin. Replacement of intracellular K+ by an equimolar concentration of Cs+, and the extracellular application of tetraethylammonium and quinine inhibited both currents. 7. An increase of extracellular Ca2+ from 2 to 20 mM resulted in outwardly rectifying K+ channels activating at more positive potentials. Omission of Ca2+ from the extracellular medium had the opposite effect. When the intracellular free Ca2+ was increased from 0.01 to 1 microM, the outward current amplitudes were depressed. The Ca2+ ionophore A23187 had a similar effect. 8. LPS-treated microglial cells possess inwardly and outwardly rectifying K+ channels. The physiological and pharmacological characteristics of these two channel populations are markedly different.(ABSTRACT TRUNCATED AT 400 WORDS)     

Initial uncoordinated expression of three types of voltage-gated currents in cultured Xenopus myocytes.

The expression of three types of voltage-gated ionic currents, namely the Na+ inward current, K+ outward rectifier current and K+ inward rectifier current, was examined in cultured developing Xenopus myocytes. In the population of myocytes, the Na+ inward current and K+ outward rectifier current appeared at around 32 h after fertilization (stage 27) and gradually increased during the period of observation, up to more than 44 h after fertilization (stage 33/34). The developmental time course of these two types of currents was similar. However, during the transition period individual myocytes did not necessarily express these two types of currents in a coordinated fashion. Some myocytes had a large Na+ inward current and small K+ outward rectifier current or vice versa. The K+ inward rectifier current was observed in some cells earlier than stage 27 and also gradually increased during the observation period. The initial expression of this current was not correlated with the K+ outward rectifier current or with the Na+ inward current.     

Patch-clamp study of the calcium-dependent chloride current in AtT-20 pituitary cells

1. Voltage-clamp recordings were made from cultured AtT-20 pituitary cells using the whole-cell patch-clamp technique. Cells were perfused internally with Cs+ to block K+ currents and bathed externally with either 1 microM tetrodotoxin or with tetraethylammonium (TEA) as a Na+ substitute to block voltage-activated Na+ currents. 2. Depolarizing voltage steps from a holding potential of -80 mV to potentials positive to -30 mV evoked two currents: a fast inward current that activated between -30 and +70 mV and a slowly activating current (designated "slow step current") that was inward between -30 and near 0 mV (the Cl- equilibrium potential) and outward positive to about 0 mV. Repolarization to -80 mV revealed a slowly decaying, inward tail current, whose magnitude with respect to step potential closely matched the current-voltage relationship of the voltage-activated Ca2+ current. 3. Activation of the fast inward current, slow step current, and tail current, was prevented by extracellular application of Cd2+ or removal of extracellular Ca2+. Replacement of extracellular Ca2+ with Ba2+ potentiated the fast inward current but blocked the slow step and tail currents. Intracellular perfusion with greater than 1 mM of the Ca2+ chelators ethyleneglycol-bis(beta-aminoethylether)-N,N'-tetraacetic acid (EGTA) or [1,2-bis(2)aminophenoxy]ethane N,N,N',N'-tetraacetic acid (BAPTA) prevented activation of the slow step and tail currents, but not the fast inward current. 4. The reversal potential of the slow inward current was sensitive to changes in the Cl- equilibrium potential but not to substitution of TEA for Na+. The slow step current, but not the fast inward current, was partially blocked by the Cl- channel blocker, 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid. 5. These data indicate that both the slow inward tail current and the slowly activating, reversible step current were a Ca2+-dependent Cl- current, similar to that described in other neuronal and nonneuronal cell types. The fast inward current was a voltage-activated Ca2+ current, described previously in these and other cells. 6. In the absence of intracellular EGTA, the tail current decayed with complex kinetics, its time course apparently dependent on the magnitude of the voltage-activated Ca2+ current. In the presence of 200 microM intracellular EGTA, the tail current decayed significantly faster and often decayed exponentially.     

Ca and Na selectivity of the active membrane of rabbit AV nodal cells

The atrioventricular (AV) node is thought to have a slow ionic channel. These experiments were designed to measure the relative contributions of Na and Ca ions to inward currents in the AV nodal cells of rabbit heart superfused with Tyrode solution. The effects of tetrodoxin (TTX), Mn2+, and verapamil observed in this study were in agreement with reports by others. The overshoot of AV nodal (N) cells was related to external Ca, with a slope of 12 mV/decade, unchanged by addition of TTX. Similar dependence of overshoot on external Na was seen, with a slope of 20 mV/decade. The slope did not change on addition of TTX. Total removal of either Na or Ca from the solution abolished excitability. Using a constant field equation, we estimated relative permeability (P) of the membrane at the time of maximal overshoot to be PCa/PNa congruent to 60 similar to or approximately 100 and PK/PNa congruent to 1. Relative contributions of these ions to the currents were estimated as ICa congruent to 17%, INa congruent to 33% (inward currents), and IK congruent to 50% (outward current). In conclusion, AV nodal cells have "slow inward-current channels" that are selective for Ca over Na ions.     

Anomalous rectification in neurons from cat sensorimotor cortex in vitro

The ionic mechanisms underlying anomalous rectification in large neurons from layer V of cat sensorimotor cortex were studied in an in vitro brain slice. The anomalous rectification was apparent as an increase of slope conductance during membrane hyperpolarization, and the development of anomalous rectification during a hyperpolarizing current pulse was signaled by a depolarizing sag of membrane potential toward resting potential (RP). Voltage-clamp analysis revealed the time- and voltage-dependent inward current (IAR) that produced anomalous rectification. IAR reversal potential (EAR) was estimated to be approximately -50 mV from extrapolation of linear, instantaneous, current-voltage relations. The conductance underlying IAR (GAR) had a sigmoidal steady-state activation characteristic. GAR increased with hyperpolarization from -55 to -105 mV with half-activation at approximately -82 mV. The time course of both GAR and IAR during a voltage step was described by two exponentials. The faster exponential had a time constant (tau F) of approximately 40 ms; the slow time constant (tau S) was approximately 300 ms. Neither tau F nor tau S changed with voltage in the range -60 mV to -110 mV. The fast component constituted approximately 80% of IAR at each potential. Both IAR and GAR increased in raised extracellular potassium [( K+]o) and EAR shifted positive, but the GAR activation curve did not shift along the voltage axis. Solutions containing an impermeable Na+ substitute caused an initial transient decrease in IAR followed by a slower increase of IAR. Brain slices bathed in Na+-substituted solution developed a gradual increase in [K+]o as measured with K+-sensitive microelectrodes. We conclude that GAR is permeable to both Na+ and K+, but the full contribution of Na+ was masked by the slow increase of [K+]o that occurred in Na+ substituted solutions. Chloride did not appear to contribute significantly to IAR since estimates of EAR were similar in neurons impaled with microelectrodes filled with potassium chloride or methylsulfate, whereas, ECl (estimated from reversal of a GABA-induced ionic current) was approximately 30 mV more positive with the KCl-filled microelectrodes. Extracellular Cs+ caused a reversible dose- and voltage-dependent reduction of GAR, whereas intracellular Cs+ was ineffective. The parameters measured during voltage clamp were used to formulate a quantitative empirical model of IAR.(ABSTRACT TRUNCATED AT 400 WORDS)     

Calcium inward currents in internally perfused giant axons

1. Voltage clamp experiments were carried out on squid axons perfused with an isotonic solution of 25 mM-CsF + sucrose and placed in a Na-free solution of 100 mM-CaCl(2) + sucrose.2. Depolarizing voltage steps produced inward currents of 4-6 muA/cm(2) peak amplitude which decayed slightly during a 60 msec pulse; the inward current disappeared when the internal potential reached +50 to +60 mV and became outward for larger depolarizations.3. Tetrodotoxin completely blocked the inward current and part of the outward current. No inward currents were seen with 100 mM-MgCl(2) + sucrose as the external solution. Substituting acetate for external Cl(-) did not abolish the tetrodotoxin-sensitive outward currents.4. It is concluded that the inward current is carried by Ca and the tetrodotoxin-sensitive outward current by Cs ions, both moving through the Na channel.5. The reversal potential of the tetrodotoxin-sensitive current was in the average +54 mV. Raising the external Ca concentration or adding NaCl to the external solution increased the reversal potential; lowering the external Ca concentration or replacing the internal CsF by a Na salt decreased the reversal potential.6. From the reversal potentials of the tetrodotoxin-sensitive current measured with varying external and internal solutions the relative permeabilities of the Na channel were calculated as P(Ca)/P(Cs) = 1/0.6, P(Ca)/P(Na) = 1/10 to 1/7 and P(Cs)/P(Na) = 1/22 to 1/9 by means of the constant field equation. The permeability ratios suggest that under these experimental conditions the Na channel is still primarily permeable to Na ions, although its selectivity is relatively small.7. The time course of the tetrodotoxin-sensitive Ca inward current was different from the time course of the Na inward current. The Na current consisted of an initial peak followed by a more slowly decaying component, the Ca current showed only the slow component.8. The slowly inactivating tetrodotoxin-sensitive Ca inward currents give rise to the long lasting action potentials which have first been observed by Tasaki and coworkers under similar conditions.     

Voltage-dependent Na(+) currents in mammalian retinal cone bipolar cells

Voltage-dependent Na(+) channels are usually expressed in neurons that use spikes as a means of signal coding. Retinal bipolar cells are commonly thought to be nonspiking neurons, a category of neurons in the CNS that uses graded potential for signal transmission. Here we report for the first time voltage-dependent Na(+) currents in acutely isolated mammalian retinal bipolar cells with whole cell patch-clamp recordings. Na(+) currents were observed in approximately 45% of recorded cone bipolar cells but not in rod bipolar cells. Both ON and OFF cone bipolar cells were found to express Na(+) channels. The Na(+) currents were activated at membrane potentials around -50 to -40 mV and reached their peak around -20 to 0 mV. The half-maximal activation and steady-state inactivation potentials were -24.7 and -68.0 mV, respectively. The time course of recovery from inactivation could be fitted by two time constants of 6.2 and 81 ms. The amplitude of the Na(+) currents ranged from a few to >300 pA with the current density in some cells close or comparable to that of retinal third neurons. In current-clamp recordings, Na(+)-dependent action potentials were evoked in Na(+)-current-bearing bipolar cells by current injections. These findings raise the possibility that voltage-dependent Na(+) currents may play a role in bipolar cell function.