Sodium Flux in Necturus Proximal Tubule under Voltage Clamp

Na transport and electrical properties of Necturus renal proximal tubules were analyzed, in vivo, by a voltage clamp method which utilizes an axial electrode in the tubule lumen for passage of current and simultaneous determination of net fluid (or Na) flux by the split droplet method. When the average spontaneous transepithelial potential difference of –8 mv (lumen negative) was reduced to zero by current passage, net Na flux doubled from a mean of 107 to 227 pmoles/cm² per sec. The relationship between flux and potential over the range –25 to +10 mv was nonlinear, with flux equilibrium at –15 mv and droplet expansion at more negative values. Calculated Na permeability at flux equilibrium was 7.0 x 10^–6 cm/sec. Voltage transients, similar to those caused by intraepithelial unstirred layers, were observed at the end of clamping periods. Tubular electrical resistance measured by brief square or triangle wave pulses (<100 msec) averaged 43 ohm cm². The epithelial current-voltage relationship was linear over the range –100 to +100 mv, but displayed marked hysteresis during low frequency (<0.04 Hz) triangle wave clamps. The low transepithelial resistance and large opposing unidirectional ion fluxes suggest that passive ionic movements occur across extracellular shunt pathways, while the voltage transients and current-voltage hysteresis are consistent with the development of a local osmotic gradient within epithelium.     

Computed Membrane Currents in Cardiac Purkinje Fibers during Voltage Clamps

Recent measurements have indicated that some of the cardiac cell electrical capacitance is in series with a resistance. The computations of currents in a voltage clamp presented below show that, in this case, there is a danger that capacitive transient currents recorded during voltage clamp experiments may be confused with currents arising through rapid active membrane conductance changes. Secondly, a voltage clamp technique aimed at avoiding capacitive transients, namely the linear or ramp clamp, has recently been introduced. An attempt has been made here to evaluate the usefulness of ramp clamps in studying membrane electrical properties, by computing ramp clamp results and considering the difficulties in reconstructing the original model from these results. It is concluded that such a reconstruction is not feasible.     

Solutions for transients in arbitrarily branching cables: II. Voltage clamp theory

Analytical solutions are derived for arbitrarily branching passive neurone models with a soma and somatic shunt, for synaptic inputs and somatic voltage commands, for both perfect and imperfect somatic voltage clamp. The solutions are infinite exponential series. Perfect clamp decouples different dendritic trees at the soma: each exponential component exists only in one tree; its time constant is independent of stimulating and recording position within the tree; its amplitude is the product of a factor constant over that entire tree and factors dependent on stimulating and recording positions. Imperfect clamp to zero is mathematically equivalent to voltage recording with a shunt. As the series resistance increases, different dendritic trees become more strongly coupled. A number of interesting response symmetries are evident. The solutions reveal parameter dependencies, including an insensitivity of the early parts of the responses to specific membrane resistivity and somatic shunt, and an approximately linear dependence of the slower time constants on series resistance, for small series resistances. The solutions are illustrated using a “cartoon” representation of a CA1 pyramidal cell and a two-cylinder + soma model.     

Hindered diffusion in excised membrane patches from retinal rod outer segments.

Excised inside-out membrane patches are useful for studying the cGMP-activated ion channels that generate the electrical response to light in retinal rod cells. We show that strong ionic current across a patch changes the driving force on the current by altering the ionic concentration near the surface membrane, an effect somewhat like that first described by Frankenhaeuser and Hodgkin (1956) in squid axons. The dominant concentration change occurs in the solution adjacent to the cytoplasmic (inner) surface of the membrane, where diffusion is impaired by intracellular material that adheres to the patch during excision. The magnitude and time course of the ionic changes are consistent with the expected volume of this material and with an effective diffusion coefficient about an order of magnitude less than that in free solution. Methods are described for correcting current transients observed in voltage clamp experiments, so that channel gating kinetics can be obtained without contamination by changes in driving force. We suggest that restricted diffusion may occur in patches excised from other types of cells and influence rapid kinetic measurements.     

Rabbit oocyte maturation: changes of membrane resistance, capacitance, and the frequency of spontaneous transient depolarizations

Immature oocytes from rabbits were examined with electrophysiological techniques to determine if their membrane properties change during maturation. The input resistance increased and input capacitance decreased during maturation, although no significant change in membrane potential was observed. The changes observed were consistent with a decrease of corona radiata-oocyte electrical coupling accompanying maturation. Spontaneous transient depolarizations were recorded from immature oocytes surrounded by corona radiata, but not from mature ova. Each event consisted of a rapid depolarization, sustained for 1-100 sec, and a slow repolarization to the resting potential. Spontaneous inward currents with a time course similar to the spontaneous transient depolarizations occurred when the oocyte's membrane potential was held constant by voltage clamp. The frequency with which spontaneous transient depolarizations occurred decreased during maturation. These findings are consistent with a model in which spontaneous depolarizations originate in corona radiata cells and are detected in the oocyte via electrical coupling.     

Effects of physostigmine on the voltage dependent ionic conductances of skeletal muscle fibres

The voltage dependent ionic conductances were studied by analysing the phase plane trajectories of action potentials evoked by electrical stimulation of the sartorius muscles of the frog (Rana esculenta). The delayed outward potassium current was measured also under voltage clamp conditions on muscle fibres of either the frog (Rana esculenta) or Xenopus laevis. On analysing the effect of physostigmine decreasing the peak amplitude, the rate of both the rising and falling phases of the action potentials, it was revealed that the alkaloid at a concentration of 1 mmol/l reduced significantly both the delayed potassium conductance and the outward ionic current values during the action potentials. The inhibition of sodium conductance and inward ionic current was less expressed. The maximum value of delayed potassium conductance measured under voltage clamp conditions was decreased by 1 mmol/l physostigmine. The time constant determined from the development of delayed potassium conductance was increased at a given membrane potential. The voltage vs. n relationship describing the membrane potential dependence of the delayed rectifier was not influenced by physostigmine. It has been concluded that physostigmine changes the time course of the action potentials by decreasing the value of both voltage dependent ionic conductances and by slowing down their kinetics. It is discussed that results obtained from the phase plane analysis of complex pharmacological effects can only be accepted with some restrictions.     

pH-Dependent electrical properties and buffer permeability of theNecturus renal proximal tubule cell

Summary Necturus kidneys were perfused with Tris-buffered solutions at three different pH values, i.e. 7.5, 6.0 and 9.0. A significant drop in fluid absorption occurred at pH 6.0, whereas pH 9.0 did not increase volume flow significantly. When acute unilateral, i.e. either in the lumen or the peritubular capillaries, and bilateral pH changes were elicited in both directions from 7.5 to 9.0 at a constant Tris-butyrate buffer concentration, both peritubular membrane potential differenceV ₁ and transepithelial potential differenceV ₃ hyperpolarized, independently of the side where the change in pH was brought about. Acid perfusions at pH 6.0 caused a similar response but of opposite sign. Analysis of the potential changes shows that pH influences not only the electromotive force and resistance of the homolateral membrane, but also the electrical properties of the paracellular path. Interference of pH with Na, Cl or K conductance was assessed. Any appreciable role for sodium or chloride was excluded, whereas the potassium transference number (t _K) of the peritubular membrane increased 16% in alkaline pH. However, this increase accounts only for 19 to 36% of the observed hyperpolarization. Since changes in Tris-butyrate buffer concentration at constant pH do not affect V₁ or V₃ considerably, the hyperpolarization in pH 9 cannot be explained by an elevation in internal pH only, or by a Tris-H⁺ ion diffusion potential only. The role of the permeability of the buffers: bicarbonate, butyrate and phosphate, in determining electrical membrane parameters was evaluated. Transport numbers of the buffer anions ranked as follows:t _HCO3>t _butyrate>t _phosphate. It is concluded that modulation of membrane potential by extracellular pH is mediated primarily by a change in peritubular cell membranet _K and additionally by membrane currents carried by buffer anions.     

Time-Resolved Analysis of Signals Involved in Systemic Induction of Pin2 Gene Expression

The systemic induction of proteinase inhibitor genes in tomato plants is mediated either by electrical signals, hydraulic signals or chemical messengers. In the present study we analyzed the effects of mechanical wounding, heat treatment and electrical current application on wild-type tomato plants (Lycopersicon esculentum Mill, cv Moneymaker) and ABA-deficient mutants of tomato (sitiens). Kinetic studies revealed that systemic Pin2 gene expression could be slightly induced by the fast transient membrane potential change which left the damaged leaf within 30–60s after wounding. Moreover, a signal leaving the damaged tissue between 2 and 4 minutes after wounding was responsible for a significant amplification of Pin2 gene expression. This signal could either be a decrease in turgor pressure, which occurred 3–4min after treatment, or a slow electrical transient. In addition, mechanical wounding and electrical current seem to involve ABA to induce changes in membrane potential and to promote Pin2 gene expression. In contrast, heat triggers fast and slow electrical transients leading to an induction of Pin2 gene expression within the plant independently of ABA. Turgor pressure, in turn, is presumably adjusted in relation to ionic movements across the membrane, elucidated by membrane potential recordings. In conclusion, wound-induced changes in membrane potential seem to be dependent on the endogenous level of ABA. These shifts in membrane potentials, in turn, are involved in regulation of turgor pressure within the plant.     

Quantitation of conductance pathways in antral gastric mucosa

The magnitude of cellular and shunt conductance of Necturus gastric antral mucosa was studied by (a) comparing the cellular PD response to transepithelial PD response during changes of ionic activity in the serosal bathing solution and (b) by measurement of current spread within the epithelial sheet. Using constant product KCl changes cellular resistance was 6,788 omegacm2 and shunt resistance was 1,803 omegacm2. Deletion of HCO3- from the serosal solution produced similar but quantitatively smaller changes in PD. Using HCO3- deletion cellular resistance was 7,338 omegacm2 and shunt resistance was 1,973 omegacm2. Measurement of current spead within the mucosa avoids changing ionic gradients yet gave very similar results; cellular resistance was 8,967 omegacm2 and shunt resistance was 2,947 omegacm2. The shunt contribution to transepithelial conductance ranged from 75.2 to 79.0%. Shunt selectivity was assessed using KCl dilution potentials, where mucosal dilution gave a small change in tissue PD compatible with an anion/cation selectivity ratio of 1.16 across the shunt, whereas serosal dilution effect was dominated by a PD change across the serosal membrane of the cell.     

Calcium transients in growth cones and axons of cultured Helisoma neurons in response to conditioning factors

Accumulating evidence indicates that cytosolic calcium levels regulate growth cone motility and neurite extension. The purpose of this study was to determine if intracellular calcium levels also influence the initiation of neurite extension induced by growth-promoting factors. An in vitro preparation of axotomized neurons that can be maintained in the absence of growth-promoting factors was utilized. The distal axons of cultured Helisoma neurons plated into defined medium do not extend neurites until they are exposed to Helisoma brain-conditioned medium. This provided the opportunity to study the intracellular changes associated with neurite extension. Cytosolic calcium levels were monitored with the calcium-sensitive dye fura 2 at the distal axon. In control medium calcium levels in the distal axon were constant. However, transient elevations in cytosolic calcium in the axonal growth cone occurred after addition of conditioned medium and coincident with the initiation of neurite extension. Application of calcium channel blockers showed that the transients resulted from calcium influx across the neuronal membrane. The transients, however, were not required for neurite extension, although they did influence the rate and extent of neurite outgrowth. Simultaneous extracellular patch recordings demonstrated that the calcium transients were correlated temporally with an increase in rhythmic spontaneous electrical activity of cells, suggesting that conditioned medium influences ionic membrane properties of these neurons. © 1995 John Wiley & Sons, Inc.     

Nerve Stimulation and Electrical Properties of Frog Skin

The suitability of frog skin glands as a model for the study of secretory mechanisms in exocrine glands was explored. Periodic voltage clamp was used to determine continually the short-circuit current, chord conductance, and electromotive force of frog skin during neural and pharmacological activation of the skin glands. Both the chord conductance and the short-circuit current increased with glandular activation; the temporal dissociation of these increases suggests that there are at least two separate components to the secretory response. The sensitivity of the secretory electrical changes to changes in the ionic composition of the bathing solutions supports the notion of electrogenic chloride active transport as being basic to the activity of the exocrine glands.     

金褐霉素（Aureofuscin）在人工脂双层形成的离子通道

本工作利用双室系统观察了金褐霉素对平板脂双层(Planar lipid bilayer)的作用。双室系统包括一个带直径为700μm 小孔的 Teflon 薄膜中隔,和由它隔开的两个充满盐溶液的小室。用脂双层(成膜液为卵磷脂和胆固醇的正癸烷溶液,重量比4∶1)覆盖小孔,在电压箝位下,研究脂双层的电学和通透性质。记录金褐霉素产生的电导变化和单通道电流。实验观察到,在将金褐霉素(终浓度10—20μg/ml)加入小室,20min 左右可记录出通道样活动噪音,脂双层膜电阻下降。它们的发生不依赖于跨膜电位差和离子浓度梯度的存在。将加入的金褐霉素的浓度降低至1.4μg/ml,可获得离散的单位电导涨落的记录。在对称100mmol/L 的 KCl 溶液中,这种单通道活动的优势电导为4—6pS。通过改变两小室的离子浓度,测定平衡电位,可由 Goldmann-Hodgkin-Katz 电场方程推算出通道的离子选择性。结果表明,金褐霉素在脂双层形成的离子通道对 K~+比对 Cl~有较高的通透性(P_K:P_(Ol)≈5.2)。这些结果为金褐霉素增加神经末梢的递质释放,降低肌细胞膜电位,以及为它在临床上的抑菌作用提供了解释。     

A quantitative model of the cardiac ventricular cell incorporating the transverse-axial tubular system

The role of the transverse-axial tubular system (TATS) in electrical activity of cardiac cells has not been investigated quantitatively. In this study a mathematical model including the TATS and differential distribution of ionic transfer mechanisms in peripheral and tubular membranes was described. A model of ventricular cardiac cell described by Jafri et al. (1998) was adopted and slightly modified to describe ionic currents and Ca2+ handling. Changes of concentrations in the lumen of the TATS were computed from the total of transmembrane ionic fluxes and ionic exchanges with the pericellular medium. Long-term stability of the model was attained at rest and under regular stimulation. Depletion of Ca2+ by 12.8% and accumulation of K+ by 4.7% occurred in the TATS-lumen at physiological conditions and at a stimulation frequency of 1 Hz. The changes were transient and subsided on repolarization within 800 ms (Ca2+) and 300 ms (K+). Nevertheless, the course of action potentials remained virtually unaltered. Simulations of voltage clamp experiments demonstrated that variations in tubular ionic concentrations were detectable as modulation of the recorded membrane currents.     

Effects of bimoclomol, the novel heat shock protein coinducer, in dog ventricular myocardium

The effects of the novel HSP-coinducer bimoclomol was studied on action potentials, ionic currents and [Ca2+]i transients in isolated canine ventricular myocytes using conventional microelectrode techniques and whole cell voltage clamp combined with fluorescent [Ca2+]i measurements. Contractility was studied in right ventricular trabeculae. All preparations were paced with a frequency of 0.2 Hz. Bimoclomol (100 microM) shortened action potential duration measured at 50% repolarization, but lengthened action potentials at the 90% repolarization level, decreased action potential amplitude and maximum depolarization velocity in a reversible manner. In voltage clamped myocytes, the drug activated a steady-state outward current at positive membrane potentials leaving the peak inward current unaffected. [Ca2+]i transients, measured under voltage clamp control, were increased in amplitude and had accelerated decay kinetics in the presence of the compound, in addition to reduction of diastolic [Ca2+]i. Bimoclomol significantly decreased the force of contraction in right ventricular trabeculae. Comparison of present data to previous results indicate that the cardiac effects of bimoclomol strongly depend on actual experimental conditions. The reduced contractility in spite of the increased amplitude of [Ca2+]i transients suggests that 100 microM bimoclomol may decrease calcium sensitivity of the contractile apparatus.     

Changes in electrical properties of muscle membrane systems during decoupling and recoupling induced by glycerol.

In isolated muscle fibres of the frog and of the crayfish the following electrical parameters were determined during the glycerol procedure from the voltage transients at 20 degrees C: the sarcoplasmic resistivity, Ri; the membrane resistance, Rm; the series tubular resistance, Rs; the surface membrane capacity, Cm; the tubular membrane capacity CT. No significant changes were found in fibres equilibrated with glycerol (G) saline. During the washout of glycerol only Ri and Cm remained unchanged. In reversibly decoupled crayfish fibres (300 mM-G) CT decreased to 70%, Rs increased to 175% and Rm increased to 200% of the control values. The changed parameters returned to control values upon reapplication of glycerol. In irreversibly decoupled fibres (500 and 600 mM-G) the changes in CT and Rs were more pronounced; and Rm was decreased. The resting potential remained constant with few mV. In frog fibres the changes in electrical parameters were in the same direction except the decrease of Rm during reversible decoupling (150 mM-G). The corresponding changes in reversible and irreversibly (300 mM-G) detubulated fibres were as follows: CT--60 (80) %; Rs--10 (14) times; Rm--50 (35) %.     

Passive ionic properties of frog retinal pigment epithelium.

The isolated pigment epithelium and choroid of frog was mounted in a chamber so that the apical surfaces of the epithelial cells and the choroid were exposed to separate solutions. The apical membrane of these cells was penetrated with microelectrodes and the mean apical membrane potential was --88 mV. The basal membrane potential was depolarized by the amount of the transepithelial potential (8--20 mV). Changes in apical and basal cell membrane voltage were produced by changing ion concentrations on one or both sides of the tissue. Although these voltage changes were altered by shunting and changes in membrane resistance, it was possible to estimate apical and basal cell membrane and shunt resistance, and the relative ionic conductance Ti of each membrane. For the apical membrane: TK approximately equal to 0.52, THCO3 approximately equal to 0.39 and TNa approximately equal to 0.05, and its specific resistance was estimated to be 6000--7000 omega cm2. For the basal membrane: TK approximately equal to 0.90 and its specific resistance was estimated to be 400--1200 omega cm2. From the basal potassium voltage responses the intracellular potassium concentration was estimated at 110 mM. The shunt resistance consisted of two pathways: a paracellular one, due to the junctional complexes and another, around the edge of the tissue, due to the imperfect nature of the mechanical seal. In well-sealed tissues, the specific resistance of the shunt was about ten times the apical plus basal membrane specific resistances. This epithelium, therefore, should be considered "tight". The shunt pathway did not distinguish between anions (HCO--3, Cl--, methylsulfate, isethionate) but did distinguish between Na+ and K+.     

Selective ion changes during spontaneous mitochondrial transients in intact astrocytes

The bioenergetic status of cells is tightly regulated by the activity of cytosolic enzymes and mitochondrial ATP production. To adapt their metabolism to cellular energy needs, mitochondria have been shown to exhibit changes in their ionic composition as the result of changes in cytosolic ion concentrations. Individual mitochondria also exhibit spontaneous changes in their electrical potential without altering those of neighboring mitochondria. We recently reported that individual mitochondria of intact astrocytes exhibit spontaneous transient increases in their Na(+) concentration. Here, we investigated whether the concentration of other ionic species were involved during mitochondrial transients. By combining fluorescence imaging methods, we performed a multiparameter study of spontaneous mitochondrial transients in intact resting astrocytes. We show that mitochondria exhibit coincident changes in their Na(+) concentration, electrical potential, matrix pH and mitochondrial reactive oxygen species production during a mitochondrial transient without involving detectable changes in their Ca(2+) concentration. Using widefield and total internal reflection fluorescence imaging, we found evidence for localized transient decreases in the free Mg(2+) concentration accompanying mitochondrial Na(+) spikes that could indicate an associated local and transient enrichment in the ATP concentration. Therefore, we propose a sequential model for mitochondrial transients involving a localized ATP microdomain that triggers a Na(+)-mediated mitochondrial depolarization, transiently enhancing the activity of the mitochondrial respiratory chain. Our work provides a model describing ionic changes that could support a bidirectional cytosol-to-mitochondria ionic communication.     

Time-dependent transients in an ionically based mathematical model of the canine atrial action potential

Ionically based cardiac action potential (AP) models are based on equations with singular Jacobians and display time-dependent AP and ionic changes (transients), which may be due to this mathematical limitation. The present study evaluated transients during long-term simulated activity in a mathematical model of the canine atrial AP. Stimulus current assignment to a specific ionic species contributed to stability. Ionic concentrations were least disturbed with the K(+) stimulus current. All parameters stabilized within 6-7 h. Inward rectifier, Na(+)/Ca(2+) exchanger, L-type Ca(2+), and Na(+)-Cl(-) cotransporter currents made the greatest contributions to stabilization of intracellular [K(+)], [Na(+)], [Ca(2+)], and [Cl(-)], respectively. Time-dependent AP shortening was largely due to the outward shift of Na(+)/Ca(2+) exchange related to intracellular Na(+) (Na) accumulation. AP duration (APD) reached a steady state after approximately 40 min. AP transients also occurred in canine atrial preparations, with the APD decreasing by approximately 10 ms over 35 min, compared with approximately 27 ms in the model. We conclude that model APD and ionic transients stabilize with the appropriate stimulus current assignment and that the mathematical limitation of equation singularity does not preclude meaningful long-term simulations. The model agrees qualitatively with experimental observations, but quantitative discrepancies highlight limitations of long-term model simulations.