Transient potassium currents in slow muscle fibers.

Transient changes in potassium conductance in chronically depolarized slow muscle fibers have been studied using a voltage clamp method. The transient behavior included current decays from initial to steady state for hyperpolarizing and depolarizing voltage clamp steps. A two-pulse voltage clamp sequence (conditioning step followed by test step) showed the initial potassium test current to depend sigmoidally on conditioning potential implicating the involvement of a membrane-bound charged group in regulating potassium current.     

Activation of cell membrane potassium conductance by mercury in cultured renal epithelioid (MDCK) cells

To elucidate mechanisms of mercury toxicity, the cell membrane potential has been determined continuously in cultured kidney (MDCK)-cells during reversible application of mercury ions to extracellular perfusate. Exposure of the cells to 1 microM mercury ions is followed by rapid, sustained, and slowly reversible hyperpolarization of the cell membrane, increase of cell membrane potassium selectivity, and decrease of cell membrane resistance. Thus, mercury ions enhance the potassium conductance of the cell membrane. Half maximal hyperpolarizing effect is elicited by approximately 0.2 microM. Higher concentrations of mercury ions (greater than 10 microM) eventually depolarize the cell membrane. At extracellular calcium activity reduced to less than 0.1 microM, 1 microM mercury ions still leads to a sustained hyperpolarization and increase of potassium selectivity of the cell membrane. As evident from fluorescence measurements, 10 microM, but not 1 microM mercury ions leads to a rapid increase of intracellular calcium activity. Pretreatment of the cells with either pertussis toxin or cholera toxin does not blunt the hyperpolarizing effect of mercury ions. In conclusion, mercury ions activate the potassium conductance by a mechanism independent of increase of intracellular calcium activity and of cholera toxin- or pertussis toxin-sensitive G-proteins. This activation of potassium conductance may account for early effects of mercury intoxication, such as kaliuresis.     

Intracellular and voltage clamp studies of capsaicin induced effects on a sensory neuron model

The acute effects of capsaicin (CAP) were studied on membrane properties, the action potential (AP) and the membrane ionic currents in the giant serotoninergic neuron of the cerebral ganglion (MCC) in the snail of Helix pomatia L. CAP (30-300 microM) depolarized the MCC, decreased the amplitude, the rate of rise and the rate of fall of the action potential. CAP prolonged the AP-duration, increased the membrane slope resistance, decreased the hyperpolarizing afterpotential and the posttetanic hyperpolarization both in normal and Na-free media. All the effects were reversible and could be evoked repeatedly. CAP attenuated the outward membrane currents with decreasing potency in the sequence of the transient potassium (IA) voltage-dependent potassium (IK), Ca-dependent potassium (IC) and leakage currents (IL). CAP decreased or increased the peak amplitude of the Ca-current (ICa), depending on the extracellular Ca concentration. CAP increased the inactivation of the ICa, decreased the Ca-conductance (GCa) in normal and high Ca solutions and shifted the Ca-equilibrium potential (VCa) to more positive voltage in 30 mM Ca-solution. CAP decreased the electrically activated Na-current and blocked the acetylcholine (ACh) activated increase in Na-K conductances. It is concluded that CAP profoundly affects the electrically and some transmitter-activated cationic conductances. Further studies are needed to clarify the significance of these changes with respect to the mechanism of the selective neurotoxic effects of CAP.     

Ion mechanisms of hyperpolarizing afterpotentials accompanying epileptic discharges in neocortical neurons

Hyperpolarizing afterpotentials of penicillin-induced (local application) paroxysmal depolarizing shifts (PDS) in neurons of the sensorimotor cortex of the cat were studied. The pattern of membrane conductance changes within different segments of hyperpolarization and the data on the role of various ion currents in its generation allow us to conclude that hyperpolarizing afterpotentials accompanying PDS are of a composite nature and include the following components: (i) the initial component provided by an increased membrane permeability to chloride ions (presumably a synaptic GABA_A response); (ii) the second component resulting predominantly from a potassium current and representing presumably a GABA_B response; and (iii) the final component comprising mainly a calcium-activated potassium current. These components are present in all neurons, are not clearly demarcated as separate waves, and partially overlap with each other, thus forming a prolonged hyperpolarizing deflection of the potential.     

Spinal ganglion neurons of rats--a model for the study of the central serotonin receptors

Application of 5-hydroxytryptamine (5-HT) (3 x 10(-5) M) on the rat lumbar dorsal ganglia (RDG) induced membrane depolarization with increased input resistance in 30% of neurons, hyperpolarization with decreased input resistance in 30% of neurons and mixed responses in 40% of neurons. Methysergide and amitriptyline (10(-6) M) blocked depolarizing but not hyperpolarizing effects of 5-HT. Propranolol (3 x 10(-6) M) was inactive in respect to both 5-HT responses. 5-HT depolarizing responses of RDG neurons were mediated by 5-HT2 receptors activation and decreased membrane potassium conductivity; 5-HT hyperpolarizing responses were mediated by 5-HT1A receptor activation and increased potassium conductivity. RDG neurons seem to be an interesting model for the investigation of central 5-HT receptor mechanism.     

A study of the crustacean axon repetitive response. 3. A comparison of the effect of veratrine sulfate solution and potassium-rich solutions

The crustacean single nerve fiber gives rise to trains of impulses during a prolonged depolarizing stimulus. It is well known that the alkaloid veratrine itself causes a prolonged depolarization; and consequently it was of interest to investigate the effect of this chemically produced depolarization on repetitive firing in the single axon and compare it with the effect of depolarization by an applied stimulating current or by a potassium-rich solution. It was found that veratrine depolarization, though similar in some respects to a potassium-rich depolarization of depolarizing current effect, was in many respects quite different. (1) At low veratrine concentration, less than 1 Mg%, the negative after potential following a spike action potential was prolonged and augmented. At higher concentrations or after a long period of time, veratrine caused a prolonged steady state depolarization of the membrane, the “veratrine response”. The prolonged plateau depolarization response could be elicited with or without an action potential spike by a short or long duration stimulating pulse, but only if the veratrine depolarization was prevented or offset by an applied conditioning hyperpolarizing inward current. (2) The “veratrine response” resembled the potassium-rich solution response in the plateau-like contour of the depolarization and the very low membrane resistance during this plateau phase. Like the potassium response, it was possible to obtain a typical hyperpolarizing response with an inwardly directed current pulse if applied during the plateau phase. During the negative after potential augmented with veratrine, however, this hyperpolarizing response was not observed. (3) In contrast to the potassium response, however, the “veratrine response” is intimately associated with the sodium concentration in the external medium. The depolarization in millivolts is linearly related to the log of the concentration of external sodium. Moreover, during veratrine action there is a continuous and progressive inactivation of the sodium mechanism which ultimately terminates repetitive firing and abolishes the spike action potential. Then even with conditioning hyperpolarization only the slow response may be elicited in veratrine, occasionally with a spike superimposed if sodium is present, but without repetitive firing. (4) It is concluded that veratrine action is the result of a chemical or metabolic reaction by the alkaloid in the membrane. It is suggested that veratrine may inhibit the sodium extrusion mechanism, or may itself compete for sites in the membrane with calcium and/or sodium. This explains the inhibiting effect of high calcium, the abolition of the “veratrine response” with low temperature and high calcium combined and the progressive inactivation of the sodium system.     

Influence of membrane physical state on lysosomal potassium ion permeability

Lysosomal permeability to potassium ions is an important property of the organelle. Influence of the membrane physical state on the potassium ion permeability of isolated lysosomes was assessed by measuring the membrane potential with bis(3-propyl-5-oxoisoxazol-4-yl)pentamethine oxonol and monitoring the lysosomal proton leakage with p-nitrophenol. The membrane fluidity of lysosomes was modulated by treatment with membrane fluidizer benzyl alcohol and rigidifier cholesteryl hemisuccinate. Changes in the membrane order were examined by steady-state fluorescence anisotropy of 1,6-diphenyl-1,3,5-hexatriene. The measurements of membrane potential and proton leakage demonstrated that the permeability of lysosomes to potassium ions increased with rigidification of their membranes by cholesteryl hemisuccinate treatment at 37 degrees C, and decreased with fluidization of their membranes by benzyl alcohol treatment at 2 degrees C. The changes in ion permeability could be recovered by fluidizing the rigidified membranes and rigidifying the fluidized membranes. The results suggest that the physical states of lysosomal membranes play an important role in the regulation of their K(+) permeability.     

Different effects of blocked potassium channels on action potentials, accommodation, adaptation and anode break excitation in human motor and sensory myelinated nerve fibres: computer simulations

 Action potentials and electrotonic responses to 300-ms depolarizing and hyperpolarizing currents for human motor and sensory myelinated nerve fibres have been simulated on the basis of double cable models. The effects of blocked nodal or internodal potassium (fast or slow) channels on the fibre action potentials, early and late adaptations to 30-ms suprathreshold slowly increasing depolarizing stimuli have been examined. The effects of the same channels on accommodation after the termination of a prolonged (100 ms) hyperpolarizing current pulse have also been investigated. By removing the nodal fast potassium conductance the action potentials of the sensory fibres are considerably broader than those of the motor neurons. For both types of fibres, the blocked nodal slow potassium channels have a substantially smaller effect on the action potential repolarization. When the suprathreshold depolarizing current intensity is increased, the onset of the spike burst occurs sooner, which is common in the behaviour of the fibres. The most striking differences in the burst activity during early adaptation have been found between the fibres when the nodal fast potassium channels are blocked. The results obtained confirm the fact that the motor fibres adapt more quickly to sustained depolarizing current pulses than the sensory ones. The results also show that normal human motor and sensory fibres cannot be excited by a 100-ms hyperpolarizing current pulse, even at the threshold level. When removing the potassium channels in the nodal or internodal axolemma, the posthyperpolarization increase in excitability is small, which is common in the behaviour of the fibres. However, anode break excitation can be simulated in the fibres with simultaneous removal of the potassium channels under the myelin sheath, and this is more pronounced in the human sensory fibres than in motor fibres. This phenomenon can also be found when the internodal and some of the nodal (fast or slow) potassium channels are simultaneously blocked. Received: 8 November 1999 / Accepted in revised form: 29 February 2000     

Potassium Ions and the Inhibitory Process in the Crayfish Stretch Receptor

The effect of the absence of potassium in the bathing solution on the synaptic inhibitory potentials of the crayfish stretch receptor has been studied. The inhibitory potentials were increased in size, i.e. became more hyperpolarizing, in the absence of potassium. Since the resting potential of the cell is increased in the absence of potassium, the alteration of the inhibitory potentials implies that the potassium conductance of the membrane is increased. While other ions, e.g. Cl^-, may also be involved, it seems that the membrane potential during inhibition is mainly dominated by K⁺.     

Nitrendipine-induced inhibition of calcium influx in a human T-cell clone: role of cell depolarization.

An increase in intracellular calcium concentration stimulated by anti-CD2 or CD3 antibodies has been measured with Fura-2 in P28 cells, a human CD4+ T cell clone. This intracellular calcium increase was sensitive to membrane potential changes, being increased when the cells were hyperpolarized and decreased when they were depolarized. The intracellular calcium increase was inhibited by nitrendipine (1-50 microM). Nitrendipine also induced a depolarization of the cells, due to the blockade of a potassium conductance. The inhibition of the calcium increase caused by nitrendipine could be partially reversed by hyperpolarizing the cells with valinomycin. It is concluded that the effects of nitrendipine on potassium channels may account for a large part of the inhibition that nitrendipine exerts on the calcium increase elicited by CD2 or CD3 stimulation.     

Depletion and accumulation of potassium in the extracellular clefts of cardiac Purkinje fibers during voltage clamp hyperpolarization and depolarization: experiments in sodium-free bathing media

Voltage clamp hyperpolarization and depolarization result in currents consistent with depletion and accumulation of potassium in the extracellular clefts o cardiac Purkinje fibers exposed to sodium-free solutions. Upon hyperpolarization, an inward current that decreased with time (id) was observed. The time course of tail currents could not be explained by a conductance exhibiting voltage-dependent kinetics. The effect of exposure to cesium, changes in bathing media potassium concentration and osmolarity, and the behavior of membrane potential after hyperpolarizing pulses are all consistent with depletion of potassium upon hyperpolarization. A declining outward current was observed upon depolarization. Increasing the bathing media potassium concentration reduced the magnitude of this current. After voltage clamp depolarizations, membrane potential transiently became more positive. These findings suggest that accumulation of potassium occurs upon depolarization. The results indicate that changes in ionic driving force may be easily and rapidly induced. Consequently, conclusions based on the assumption that driving force remains constant during the course of a voltage step may be in error.     

Electrochemical potentials of potassium in skeletal muscle under different metabolic states.

Intracellular potassium and membrane potential were measured simultaneously by means of double-barrelled liquid ion-exchange microelectrodes in single fibers of rat thigh muscle in vivo in rats maintained in seven different metabolic states. The K+ equilibrium potential (EK) was more negative than the simultaneously measured membrane potential (Em) in the normal state by 18.4 mV. K+ loading, acute and chronic, resulted in depolarization of Em due to increased serum K+ (hyperkalemia) with no increase in intracellular K+. K+ depletion resulted in hyperpolarization of Em as plasma K+ decreased proportionately more than intracellular K+. Low Na+ diet had no effect. Intracellular K+ was decreased in acute acidosis but not in the chronic state. Thus K+ depletion and acute acidosis are associated with intracellular K+ decrease. The fact that hyperpolarization exists in the former and not the latter is a reflection that hypokalemia accompanies the former condition. The hyperpolarizing states of K+ depletion and chronic acidosis are accompanied by decreased excitability and muscle weakness.     

Analysis of bursting in a thalamic neuron model

We extend a quantitative model for low-voltage, slow-wave excitability based on the T-type calcium current (Wang et al. 1991) by juxtaposing it with a Hodgkin-Huxley-like model for fast sodium spiking in the high voltage regime to account for the distinct firing modes of thalamic neurons. We employ bifurcation analysis to illustrate the stimulus-response behavior of the full model under both voltage regimes. The model neuron shows continuous sodium spiking when depolarized sufficiently from rest. Depending on the parameters of calcium current inactivation, there are two types of low-voltage responses to a hyperpolarizing current step: a single rebound low threshold spike (LTS) upon release of the step and periodic LTSs. Bursting is seen as sodium spikes ride the LTS crest. In both cases, we analyze the LTS burst response by projecting its trajectory into a fast/slow phase plane. We also use phase plane methods to show that a potassium A-current shifts the threshold for sodium spikes, reducing the number of fast sodium spikes in an LTS burst. It can also annihilate periodic bursting. We extend the previous work of Rose and Hindmarsh (1989a–c) for a thalamic neuron and propose a simpler model for thalamic activity. We consider burst modulation by using a neuromodulator-dependent potassium leakage conductance as a control parameter. These results correspond with experiments showing that the application of certain neurotransmitters can switch firing modes. Received: 18 July 1993/Accepted in revised form: 22 January 1994     

一氧化氮和K+通道参与乙酰胆碱引起的大鼠离体输精管平滑肌细胞超极化

本文旨在探讨大鼠新鲜离体输精管平滑肌细胞中乙酰胆碱（acetylcholine,ACh）引起超极化反应的机制,采用细胞内微电极记录技术和细胞内荧光标记技术研究ACh对大鼠输精管不同走行方向平滑肌细胞的作用。用尖端含0．1％碘化吡啶（propidium iodide,PI）的记录电极标记电生理记录后的平滑肌细胞,其中37个为外层纵行细胞,17个为内层环行细胞。它们的平均静息膜电位分别为（-53．56±3．88）mV和（-51．62±4．27）mV,膜输入阻抗分别为（2245．60±372．50）MQ和（2101．50±513．50）MQ。ACh引起的膜超极化反应是浓度依赖性的,EC50为36 μmol／L。ACh引起的超极化反应可被非选择性的毒草碱（muscarinic receptor,M）受体阻断剂阿托品（atropine,1 μmol／L）和选择性的M3受体阻断剂diphenylacetoxy-N-methylpiperidine-methiodide（DAMP,100nmol/L）阻断。ACh引起的超极化还能被一氧化氮合酶抑制剂L-硝基-精氨酸甲酯（N-nitro-L-arginine methylester,L．NAME,300μmol／L）阻断,并可被ATP敏感的钾通道阻断剂glipizide（5μmol／L）或内向整流钾通道阻断剂钡离子（50μmol／L）部分阻断。Glipizide和钡离子联合使用可完全阻断ACh引起的超极化反应。上述结果表明：ACh通过作用于大鼠输精管平滑肌细胞膜上的M3受体引起超极化反应,一氧化氮、ATP敏感性钾通道和内向整流钾通道参与了ACh引起的超极化反应。     

Hyperpolarizing potentials in guinea pig hippocampal CA3 neurons

There is a bewildering variety of hyperpolarizing potentials which control activity in hippocampal pyramidal cells. These include an inhibitory postsynaptic potential (IPSP) with early and late components, voltage- and calcium-dependent potassium conductances, a voltage-dependent potassium conductance modulated by muscarinic agents (the M-current), and a complex and poorly understood afterhyperpolarization following epileptiform bursts. In hippocampal CA3 pyramidal cells, mossy fiber stimulation elicits an IPSP which is made up of two readily separable components. Using the in vitro slice preparation, we investigated the underlying ionic basis of these IPSP components and compared them to other hyperpolarizing potentials characteristic of the CA3 neurons. Intracellular recordings were obtained and then tissue was exposed to bathing medium low in chloride concentration or high in potassium concentration; the ion "blockers" EGTA (intracellular); tetraethylammonium (TEA) (intra- and extracellular), and barium and cobalt (extracellular); and the gamma-aminobutyric acid (GABA)/chloride antagonists penicillin, bicuculline and picrotoxin.     

Effect of potassium leakage on reversible aggregation of human erythrocytes

Changes in the aggregation of human erythrocytes caused by polydextrane were studied under conditions influencing the rate of potassium leakage from cells to medium. It was shown that aggregation decreases as the leakage of potassium ions increases and is completely abolished at leakage rates higher than 2.5-3.0 mmol/l of erythrocytes per hour. The involvement of nonequilibrial electrokinetic phenomena in the inhibition of erythrocyte aggregation by ionic fluxes across erythrocyte surface is discussed. It is proposed that potassium leakage affects the erythrocyte sedimentation rate in clinical investigations.     

An odorant-suppressed Cl– conductance in lobster olfactory receptor cells

Odorants evoke an outward current in cultured lobster olfactory receptor neurons voltage clamped at -60 mV. The reversal potential of the outward current is independent of the reversal potential of potassium, but shifts with imposed changes in the reversal potential of chloride. The slope of the current-voltage relationship is negative, suggesting that the current is mediated by the odorant suppressing a steady-state conductance. Anthracene-9-carboxylic acid, a specific chloride channel blocker, reversibly inhibits the steady-state conductance. Local application of odorants to the outer dendrites evokes a hyperpolarizing receptor potential in lobster olfactory receptor neurons current-clamped at -70 mV in situ. Consistent with the current characterized in the cultured cells, hyperpolarizing receptor potentials in some cells are voltage sensitive, blocked by anthracene-9-carboxylic acid and associated with a decrease in membrane conductance. These results support the hypothesis that odorants suppress a steady-state chloride conductance in lobster olfactory receptor neurons. Evidence that the chloride conductance can coexist with a 4-aminopyridine-blockable potassium conductance reported earlier in these cells suggests that two distinct mechanisms can mediate odorant-evoked inhibition in lobster olfactory receptor neurons.     

Cation Fluxes and Permeability Changes Accompanying Bacteriophage Infection of Escherichia coli

Infection of Escherichia coli by bacteriophage T2 was accompanied by a rapid but transient increase in the rate of loss of small molecules from the bacterial cells. This transient leakage was studied with radioactive labels such as (42)K and (28)Mg. Bacteriophage-induced leakage was dependent on the ratio of phage to bacteria: the higher the multiplicity of infection, the greater the leakage. No leakage occurred at 4 C [when adsorption proceeds but injection of phage deoxyribonucleic acid (DNA) is blocked]. Leakage was caused by heavily irradiated phage as well as by normal phage; therefore, the intracellular functioning of the bacteriophage DNA was not required. This conclusion was supported by experiments which showed phage-induced leakage in the presence of chloramphenicol or sodium cyanide. Leakage could be prevented by infecting the bacteria with phage in the presence of high magnesium concentrations. Phage-induced leakage was terminated by a "sealing" reaction, after which potassium turnover by infected and uninfected cells was very similar. The sealing reaction occurred even in the presence of chloramphenicol, suggesting that the sealing is controlled by bacterial and not bacteriophage genes. We were not able to detect any effect of normal bacteriophage infection on the influx (active transport) of potassium and magnesium into the cells.     

Analysis of the effects of calcium or magnesium on voltage-clamp currents in perfused squid axons bathed in solutions of high potassium

Isolated axons from the squid, Dosidicus gigas, were internally perfused with potassium fluoride solutions. Membrane currents were measured following step changes of membrane potential in a voltage-clamp arrangement with external isosmotic solution changes in the order: potassium-free artificial seawater; potassium chloride; potassium chloride containing 10, 25, 40 or 50, mM calcium or magnesium; and potassium-free artificial seawater. The following results suggest that the currents measured under voltage clamp with potassium outside and inside can be separated into two components and that one of them, the predominant one, is carried through the potassium system. (a) Outward currents in isosmotic potassium were strongly and reversibly reduced by tetraethylammonium chloride. (b) Without calcium or magnesium a progressive increase in the nontime-dependent component of the currents (leakage) occurred. (c) The restoration of calcium or magnesium within 15–30 min decreases this leakage. (d) With 50 mM divalent ions the steady-state current-voltage curve was nonlinear with negative resistance as observed in intact axons in isosmotic potassium. (e) The time-dependent components of the membrane currents were not clearly affected by calcium or magnesium. These results show a strong dependence of the leakage currents on external calcium or magnesium concentration but provide no support for the involvement of calcium or magnesium in the kinetics of the potassium system.     

Selective modification of sodium channel gating in lobster axons by 2, 4, 6-trinitrophenol: Evidence for two inactivation mechanisms

Trinitrophernol (TNP) selectively alters the sodium conductance system of lobster giant axons as measured in current clamp and voltage clamp experiments using the double sucrose gap technique. TNP has no measurable effect on potassium currents but reversibly prolongs the time-course of sodium currents during maintained depolarizations over the full voltage range of observable currents. Action potential durations are increased also. Tm of the Hodgkin-Huxley model is not markedly altered during activation of the sodium conductance but is prolonged during removal of activation by repolarization, as observed in sodium tail experiments. The sodium inactivation versus voltage curve is shifted in the hyperpolarizing direction as is the inactivation time constant curve, measured with conditioning voltage steps. This shift speeds the kinetics of inactivation over part of the same voltage range in which sodium currents are prolonged, a contradiction incompatible with the Hodgkin-Huxley model. These results are interpreted as support for a hypothesis of two inactivation processes, one proceeding directly from the resting state and the other coupled to the active state of sodium conductance.