皮质酮对体外培养的海马神经元延迟整流钾电流的影响

目的：探讨应激激素皮质酮对海马神经元延迟整流钾电流的影响。方法：膜片钳全细胞记录测量原代培养大鼠海马神经元膜的钾离子电流。结果：在皮质酮的作用下,海马神经元膜的钾离子电流幅度明显下调,激活阈电位升高。结论：过量皮质酮激素可能通过影响延迟整流钾通道损伤海马神经元。     

Shared requirement for dynein function and intact microtubule cytoskeleton for normal surface expression of cardiac potassium channels

Potassium channels at the cardiomyocyte surface must eventually be internalized and degraded, and changes in cardiac potassium channel expression are known to occur during myocardial disease. It is not known which trafficking pathways are involved in the control of cardiac potassium channel surface expression, and it is not clear whether all cardiac potassium channels follow a common pathway or many pathways. In the present study we have surveyed the role of retrograde microtubule-dependent transport in modulating the surface expression of several cardiac potassium channels in ventricular myocytes and heterologous cells. The disruption of microtubule transport in rat ventricular myocytes with nocodazole resulted in significant changes in potassium currents. A-type currents were enhanced 1.6-fold at +90 mV, rising from control densities of 20.9 +/- 2.8 to 34.0 +/- 5.4 pA/pF in the nocodazole-treated cells, whereas inward rectifier currents were reduced by one-third, perhaps due to a higher nocodazole sensitivity of Kir channel forward trafficking. These changes in potassium currents were associated with a significant decrease in action potential duration. When expressed in heterologous human embryonic kidney (HEK-293) cells, surface expression of Kv4.2, known to substantially underlie A-type currents in rat myocytes, was increased by nocodazole, by the dynein inhibitor erythro-9-(2-hydroxy-3-nonyl) adenine hydrochloride, and by p50 overexpression, which specifically interferes with dynein motor function. Peak current density was 360 +/- 61.0 pA/pF in control cells and 658 +/- 94.5 pA/pF in cells overexpressing p50. The expression levels of Kv2.1, Kv3.1, human ether-a-go-go-related gene, and Kir2.1 were similarly increased by p50 overexpression in this system. Thus the regulation of potassium channel expression involves a common dynein-dependent process operating similarly on the various channels.     

Ionic channels in a line of embryonal carcinoma cells induced to undergo neuronal differentiation.

The gigaseal patch clamp technique was used to investigate the electrophysiological properties of a line of embryonal carcinoma cells (PCC4) that were induced to undergo neuronal differentiation. A large increase in number of voltage-dependent potassium and sodium channels was observed during differentiation. The pharmacology and kinetics of the macroscopic sodium and potassium currents in the differentiated cells closely resembled those of the rapid inward sodium current and the delayed rectifier, respectively. The kinetic behavior of single-channel potassium currents was consistent with the properties of the macroscopic delayed rectifier current.     

Detection of potassium currents and regulation of multidrug resistance by potassium channels in human gastric cancer cells

The present study aimed to investigate the potassium currents and further explore the role of potassium channels in drug response of gastric cancer cells. By patch-clamp technique, potassium currents of human gastric cancer cell SGC7901 were recorded in the mode of voltage clamp. Both 4-aminopyridine (4-AP) and tetraethylammonium (TEA) could almost completely block this current. The chemotherapeutic drugs, adriamycin or 5-fluorouracil could significantly increase the K(+) current density on SGC7901 cells in a dose-dependent manner. 4-AP or TEA was found to restrain adriamycin-induced apoptosis and enhance multidrug-resistant phenotype of SGC7901 cells. Up-regulation of Kv1.5, which has been found widely expressed in gastric cancer cells including SGC7901, increased the K(+) current density and sensitivity of SGC7901 cells to multiple chemotherapeutic drugs, whereas down-regulation of Kv1.5 enhanced the drug-resistant phenotype of SGC7901 cells. In conclusion, potassium channels may exert regulatory effects on multidrug resistance by regulating drug-induced apoptosis in gastric cancer cells.     

Differential G protein-mediated coupling of D2 dopamine receptors to K+ and Ca2+ currents in rat anterior pituitary cells.

In anterior pituitary cells, dopamine, acting on D2 dopamine receptors, concomitantly reduces calcium currents and increases potassium currents. These dopamine effects require the presence of intracellular GTP and are blocked by pretreatment of the cells with pertussis toxin, suggesting that one or more G protein is involved. To identify the G proteins involved in coupling D2 receptors to these currents, we performed patch-clamp recordings in the whole-cell configuration using pipettes containing affinity-purified polyclonal antibodies raised against either Go alpha, Gi3 alpha, or Gi1,2 alpha. Dialysis with Go alpha antiserum significantly reduced the inhibition of calcium currents induced by dopamine, while increase of potassium currents was markedly attenuated only by Gi3 alpha antiserum. We therefore conclude that in pituitary cells, two different G proteins are involved in the signal transduction mechanism that links D2 receptor activation to a specific modulation of the four types of ionic channels studied here.     

Ionic currents in two strains of rat anterior pituitary tumor cells

The ionic conductance mechanisms underlying action potential behavior in GH3 and GH4/C1 rat pituitary tumor cell lines were identified and characterized using a patch electrode voltage-clamp technique. Voltage-dependent sodium, calcium, and potassium currents and calcium-activated potassium currents were present in the GH3 cells. GH4/C1 cells possess much less sodium current, less voltage-dependent potassium current, and comparable amounts of calcium current. Voltage-dependent inward sodium current activated and inactivated rapidly and was blocked by tetrodotoxin. A slower-activating voltage-dependent inward calcium current was blocked by cobalt, manganese, nickel, zinc, or cadmium. Barium was substituted for calcium as the inward current carrier. Calcium tail currents decay with two exponential components. The rate constant for the slower component is voltage dependent, while the faster rate constant is independent of voltage. An analysis of tail current envelopes under conditions of controlled ionic gradients suggests that much of the apparent decline of calcium currents arises from an opposing outward current of low cationic selectivity. Voltage-dependent outward potassium current activated rapidly and inactivated slowly. A second outward current, the calcium-activated potassium current, activated slowly and did not appear to reach steady state with 185-ms voltage pulses. This slowly activating outward current is sensitive to external cobalt and cadmium and to the internal concentration of calcium. Tetraethylammonium and 4-aminopyridine block the majority of these outward currents. Our studies reveal a variety of macroscopic ionic currents that could play a role in the initiation and short-term maintenance of hormone secretion, but suggest that sodium channels probably do not make a major contribution.     

Effects of hypothalamic peptides on electrical activity and membrane currents of 'patch perforated' clamped GH3 anterior pituitary cells.

'Perforated-patch' recordings of rat anterior pituitary GH3 cells allow long and stable monitoring of electrical activity and membrane currents. Under current clamp conditions, the biphasic effect of thryotropin releasing hormone (TRH) consisting of a transient hyperpolarization followed by a longer phase of increased action potential frequency is fully preserved. Somatostatin suppresses action potential activity and antagonizes the second phase of enhanced spiking caused by TRH. Voltage clamp records of isolated currents indicate that TRH affects calcium-dependent potassium currents, but does not alter either voltage-dependent potassium or calcium currents at times and concentrations at which the electrical activity is increased.     

Effect of protein-modifying factors on sodium and potassium leakage currents of the secretory cell membranes

Potassium and sodium leakage currents decrease when pH of the surroundings is lowering. Dicyclohexylcarbodiimide, a specific reagent of the COOH-groups does not change leakage currents. Trypsin, chymotrypsin, papain and pronase increase the sodium leakage current, not altering the potassium one. Blocking agents of the SH-groups: Hg2+ and Cd2+ decrease potassium leakage current, without changing the sodium one. Results of the proteolysis testify to that the diffusion of sodium into the cells in response is accomplished through the protein components of the membrane. The action of the blocking agents of SH-groups points out that the diffusion of potassium from the cells is realized also via the protein components of the membrane.     

Two types of potassium current in rabbit cultured Schwann cells

Voltage-gated outward currents were studied in rabbit cultured Schwann cells with the 'whole-cell' configuration of the patch-clamp method. Four components of such currents were identified. The first, which was abolished by replacement of the external chloride ions by the large impermeant anion gluconate, was identified as a chloride current. The second and third were identified as potassium currents. One type of potassium current was reduced substantially by either 4-aminopyridine (4-AP) or tetraethylammonium ion (TEA). Its sensitivity to blocking by 4-AP was highly voltage-dependent: the equilibrium dissociation constant (K) was threefold greater when measured at +10 mV than when measured at -40 mV (where it was about 80 microM). The second type of potassium current was relatively insensitive to 4-AP, but was blocked by TEA. The TEA sensitivity of the two types of potassium currents was similar and displayed no obvious voltage-dependence (K approximately 200 microM). The fourth component of current was not reduced by 4-AP or TEA at concentrations less than 10 mM. Whether or not this last component is a potassium current is unclear.     

Developmental change in calcium-activated chloride current during the differentiation of Xenopus spinal neurons in culture.

The duration and ionic dependence of action potentials change during the differentiation of embryonic amphibian spinal neurons both in vivo and in culture. The development of sodium, calcium, and potassium currents has been characterized in these cells and the shortening of the action potential has been shown to depend to a great extent on developmental changes of potassium currents. Previous evidence suggests that a chloride current may also be present in these embryonic neurons. Chloride currents were investigated with intracellular current-clamp and single-electrode and whole-cell voltage-clamp techniques. Most neurons exhibited a calcium-activated chloride current (ICl(Ca] that contributed to the postdepolarization following the action potential recorded in the absence of sodium and potassium currents. This current appeared to decrease in density and its deactivation rate increased during the first day in culture. Its incidence also declined during this period. A much larger Ca(2+)-dependent Cl- current was also observed in a subset of neurons after 24 hr, but was absent at earlier stages of development. The results suggest the presence of two Cl- currents with different developmental fates. The early current probably contributes to the repolarization of long calcium-dependent action potentials at initial stages of neuronal development, when potassium currents are small, and may serve to reduce the extent of repetitive firing.     

EPSP amplification and the precision of spike timing in hippocampal neurons

The temporal precision with which EPSPs initiate action potentials in postsynaptic cells determines how activity spreads in neuronal networks. We found that small EPSPs evoked from just subthreshold potentials initiated firing with short latencies in most CA1 hippocampal inhibitory cells, while action potential timing in pyramidal cells was more variable due to plateau potentials that amplified and prolonged EPSPs. Action potential timing apparently depends on the balance of subthreshold intrinsic currents. In interneurons, outward currents dominate responses to somatically injected EPSP waveforms, while inward currents are larger than outward currents close to threshold in pyramidal cells. Suppressing outward potassium currents increases the variability in latency of synaptically induced firing in interneurons. These differences in precision of EPSP-spike coupling in inhibitory and pyramidal cells will enhance inhibitory control of the spread of excitation in the hippocampus.     

Distribution of Kv1-like potassium channels in the electromotor and electrosensory systems of the weakly electric fish Apteronotus leptorhynchus

The electromotor and electrosensory systems of the weakly electric fish Apteronotus leptorhynchus are model systems for studying mechanisms of high-frequency motor pattern generation and sensory processing. Voltage-dependent ionic currents, including low-threshold potassium currents, influence excitability of neurons in these circuits and thereby regulate motor output and sensory filtering. Although Kv1-like potassium channels are likely to carry low-threshold potassium currents in electromotor and electrosensory neurons, the distribution of Kv1 alpha subunits in A. leptorhynchus is unknown. In this study, we used immunohistochemistry with six different antibodies raised against specific mammalian Kv1 alpha subunits (Kv1.1-Kv1.6) to characterize the distribution of Kv1-like channels in electromotor and electrosensory structures. Each Kv1 antibody labeled a distinct subset of neurons, fibers, and/or dendrites in electromotor and electrosensory nuclei. Kv1-like immunoreactivity in the electrosensory lateral line lobe (ELL) and pacemaker nucleus are particularly relevant in light of previous studies suggesting that potassium currents carried by Kv1 channels regulate neuronal excitability in these regions. Immunoreactivity of pyramidal cells in the ELL with several Kv1 antibodies is consistent with Kv1 channels carrying low-threshold outward currents that regulate spike waveform in these cells (Fernandez et al., J Neurosci 2005;25:363-371). Similarly, Kv1-like immunoreactivity in the pacemaker nucleus is consistent with a role of Kv1 channels in spontaneous high-frequency firing in pacemaker neurons. Robust Kv1-like immunoreactivity in several other structures, including the dorsal torus semicircularis, tuberous electroreceptors, and the electric organ, indicates that Kv1 channels are broadly expressed and are likely to contribute significantly to generating the electric organ discharge and processing electrosensory inputs.     

Voltage gated ionic channels in rat cultured astrocytes, reactive astrocytes and an astrocyte-oligodendrocyte progenitor cell

Astrocytes (both type 1 and type 2), cultured from the central nervous system of newborn or 7 day old rats show voltage gated sodium and potassium channels that are activated when the membrane is depolarized to greater than -40 mV. The sodium channels in these cells have an h-infinity curve similar to that of nodal membranes but the activation (peak current-voltage) curves are shifted along the voltage axis by about +30 mV. These sodium currents are blocked only by high concentrations of tetrodotoxin. The voltage activated potassium currents in both types of astrocyte show at least two components; an inactivating component that is suppressed at holding potentials of greater than -40 mV and a persistent, non-inactivating current. Several types of single channel currents were observed in outside-out membrane patches from type 2 astrocytes. One type of potassium channel showed inactivation on depolarization and may contribute to the whole-cell inactivating current. In contrast, oligodendrocytes showed no obvious voltage gated membrane channels. The properties of the type 2 astrocyte-oligodendrocyte progenitor cell were investigated in two ways: 1) by examination of cells just beginning to differentiate along the "electrically silent" oligodendrocyte pathway or 2) by recording from progenitor cells cultured for 24 hours in the presence of cycloheximide to block the appearance of new membrane channels. In both cases, voltage gated inward (sodium) and outward (potassium) currents were noted. The outward current response showed both an inactivating and a non-inactivating component. Similar voltage activated inward and outward membrane currents were noted in reactive astrocytes freshly isolated (3-6 hours) from lesioned areas of adult rat brains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ionic currents in avian granulosa cells

Transmembrane ionic currents have been recorded in single granulosa cells from the laying hen using the whole-cell patch-clamp technique. Under voltage-clamp conditions, depolarizing voltage steps evoked currents composed of a fast inactivating inward component and a delayed outward component. The former was activated at voltages more positive than -50 mV and was fully inactivated within 500 ms. It was blocked by D600 (methoxyverapamil) and by cobalt, suggesting that it is a calcium current. The latter displayed inward rectification and did not inactivate during long duration pulses. It was blocked by tetraethylammonium indicating that it is a potassium current. This is the first evidence of the existence of potassium and calcium transmembrane currents in granulosa cells.     

Pandinus imperator scorpion venom blocks voltage-gated potassium channels in GH3 cells

We examined the effects of Pandinus imperator scorpion venom on voltage-gated potassium channels in cultured clonal rat anterior pituitary cells (GH3 cells) using the gigohm-seal voltage-clamp method in the whole-cell configuration. We found that Pandinus venom blocks the voltage-gated potassium channels of GH3 cells in a voltage-dependent and dose-dependent manner. Crude venom in concentrations of 50-500 micrograms/ml produced 50-70% block of potassium currents measured at -20 mV, compared with 25-60% block measured at +50 mV. The venom both decreased the peak potassium current and shifted the voltage dependence of potassium current activation to more positive potentials. Pandinus venom affected potassium channel kinetics by slowing channel opening, speeding deactivation slightly, and increasing inactivation rates. Potassium currents in cells exposed to Pandinus venom did not recover control amplitudes or kinetics even after 20-40 min of washing with venom-free solution. The concentration dependence of crude venom block indicates that the toxins it contains are effective in the nanomolar range of concentrations. The effects of Pandinus venom were mimicked by zinc at concentrations less than or equal to 0.2 mM. Block of potassium current by zinc was voltage dependent and resembled Pandinus venom block, except that block by zinc was rapidly reversible. Since zinc is found in crude Pandinus venom, it could be important in the interaction of the venom with the potassium channel. We conclude that Pandinus venom contains toxins that bind tightly to voltage-dependent potassium channels in GH3 cells. Because of its high affinity for voltage-gated potassium channels and its irreversibility, Pandinus venom may be useful in the isolation, mapping, and characterization of voltage-gated potassium channels.     

Presumptive neurons derived by differentiation of a human embryonal carcinoma cell line exhibit tetrodotoxin-sensitive sodium currents and the capacity for regenerative responses

Cloned human embryonal carcinoma cells (NTERA-2 cl.D1) differentiate into neuron-like cells upon exposure to retinoic acid. Using whole-cell patch-clamp techniques, these putative neurons exhibited rapidly activating and inactivating inward currents upon depolarization as well as outward currents. The electrical characteristics and tetrodotoxin (TTX) sensitivity of the inward currents suggest that they were sodium currents. By contrast, only outward potassium currents were seen in the undifferentiated stem cells. Under current clamp conditions, the neuron-like cells showed regenerative responses. The peaks of these responses never exceeded the O-mV level, perhaps due to the low mean inward current density of 93.8 +/- 17.8 (SEM) microA/cm2:n = 9. The electrophysiological characteristics of these human teratocarcinoma-derived neuron-like cells were consistent with our previous identification of these cells as neurons, but suggest that they may resemble immature embryonic, rather than adult, neurons.     

The dependence of calcium-activated potassium currents on membrane potential.

Previous experiments on cholinergic synapses in chick cochlear hair cells have shown that calcium entering through acetylcholine-activated synaptic channels in turn activates calcium-dependent potassium currents, resulting in synaptic inhibition. In voltage-clamp experiments such currents would be expected to increase with depolarization (as the driving force for potassium entry is increased) and then decrease towards zero as the membrane approaches the calcium equilibrium potential (when calcium entry is suppressed). In the hair cells, however, such currents approached zero at about +20 mV, more than 170 mV negative to the calcium equilibrium potential. Another feature of the synapse is its post-junctional morphology: a uniform 20 nm cleft is formed between the postsynaptic membrane and the outermost membrane of an underlying cisterna. Here we present a model in which synaptic activation results in calcium influx into the subsynaptic cleft and thence into the bulk of the cytoplasm. The model suggests that the voltage dependence of the calcium-activated potassium current can be accounted for by only two basic assumptions: (i) entry of calcium through the activated synaptic channels by simple diffusion; and (ii) activation of the potassium channels by the cooperative action of four calcium ions. In addition, the model suggests that during activation the calcium concentration in the restricted subsynaptic space can reach levels adequate to activate the potassium channels, without requiring additional, more complicated, considerations (for example, secondary calcium release from the cisterna).     

Calcium channels of amphibian stomach and mammalian aorta smooth muscle cells.

Whole-cell and single-channel calcium currents were studied using single smooth muscle cells enzymatically-isolated from stomach of Amphiuma tridactylum and from guinea-pig aorta. These cells have a high specific resistance and can sustain calcium action potentials after suppression of potassium currents. Dialyzed Amphiuma smooth muscle cells had calcium currents which were stable for several hours whereas the calcium currents of aortic cells ran down quickly. Single channel calcium currents in cell-attached patches behaved similarly for the two cell types. Calcium channel conductance in 110 mM barium was 12 pS and the mean open time was 1.4 ms at a nominal membrane potential of +10 mV. Exposure of both cell types to BAY K8644 resulted in a dramatic prolongation of the calcium channel open times and a shift in the probability of opening to more negative potentials. Low-threshold calcium channels were not identified in the extensively studied amphibian cells. High-threshold calcium channels therefore appear to be the primary pathway for the calcium influx that produces contraction in these smooth muscle cells.