钾通道在培养大鼠海马神经元凋亡性容积减少中的作用

为探讨钾通道参与神经元凋亡的可能机制,在星形孢菌素（STS)诱导的培养海马神经元凋亡模型上,研究了凋亡时神经细胞容积的动态变化及钾通道在其中的作用.实验结果显示,钾通道阻断剂四乙铵或升高细胞外K⁺均能够明显抑制STS诱导的神经元凋亡,并且大电导钙激活钾通道（BK）选择性阻断剂iberiotoxin和paxilline具有同样程度的抗细胞凋亡作用,表明钾通道（可能主要是BK通道）参与了STS诱导的培养海马神经元凋亡.在STS诱导神经元凋亡的早期就出现了细胞容积的显著减少,而钾通道阻断剂或升高细胞外K⁺均可阻断该细胞容积减少.研究结果提示细胞内钾离子的外流可能参与了凋亡性细胞容积减少,这也可能是钾通道介导细胞凋亡的重要机制之一.     

Role of AQP2 during apoptosis in cortical collecting duct cells

Background information. A major hallmark of apoptosis is cell shrinkage, termed apoptotic volume decrease, due to the cellular outflow of potassium and chloride ions, followed by osmotically obliged water. In many cells, the ionic pathways triggered during the apoptotic volume decrease may be similar to that observed during a regulatory volume decrease response under hypotonic conditions. However, the pathways involved in water loss during apoptosis have been largely ignored. It was recently reported that in some systems this water movement is mediated via specific water channels (aquaporins). Nevertheless, it is important to identify whether this is a ubiquitous aspect of apoptosis as well as to define the mechanisms involved. The aim of the present work was to investigate the role of aquaporin‐2 during apoptosis in renal‐collecting duct cells. We evaluated the putative relationship between aquaporin‐2 expression and the activation of the ionic pathways involved in the regulatory volume response. Results. Apoptosis was induced by incubating cells with a hypertonic solution or with cycloheximide in two cortical collecting duct cell lines: one not expressing aquaporins and the other stably transfected with aquaporin‐2. Typical features of apoptosis were evaluated with different approaches and the water permeability was measured by fluorescence videomicroscopy. Our results show that the rate of apoptosis is significantly increased in aquaporin‐2 cells and it is linked to the rapid activation of volume‐regulatory potassium and chloride channels. Furthermore, the water permeability of cells expressing aquaporin‐2 was strongly reduced during the apoptotic process and it occurs before DNA degradation. Conclusions. These results let us propose that under apoptotic stimulation aquaporin‐2 would act as a sensor leading to a co‐ordinated activation of specific ionic channels for potassium and chloride efflux, resulting in both more rapid cell shrinkage and more rapid achievement of adequate levels of ions necessary to activate the enzymatic apoptotic cascade.     

Role of the F-actin cytoskeleton in the RVD and RVI processes in Ehrlich ascites tumor cells.

The role of the F-actin cytoskeleton in cell volume regulation was studied in Ehrlich ascites tumor cells, using a quantitative rhodamine-phalloidin assay, confocal laser scanning microscopy, and electronic cell sizing. A hypotonic challenge (160 mOsm) was associated with a decrease in cellular F-actin content at 1 and 3 min and a hypertonic challenge (600 mOsm) with an increase in cellular F-actin content at 1, 3, and 5 min, respectively, compared to isotonic (310 mOsm) control cells. Confocal visualization of F-actin in fixed, intact Ehrlich cells demonstrated that osmotic challenges mainly affect the F-actin in the cortical region of the cells, with no visible changes in F-actin in other cell regions. The possible role of the F-actin cytoskeleton in RVD was studied using 0. 5 microM cytochalasin B (CB), cytochalasin D (CD), or chaetoglobosin C (ChtC), a cytochalasin analog with little or no affinity for F-actin. Recovery of cell volume after hypotonic swelling was slower in cells pretreated for 3 min with 0.5 microM CB, but not in CD- and ChtC-treated cells, compared to osmotically swollen control cells. Moreover, the maximal cell volume after swelling was decreased in CB-treated, but not in CD- or Chtc-treated cells. Following a hypertonic challenge imposed using the RVD/RVI protocol, recovery from cell shrinkage was slower in CB-treated, but not in CD- or Chtc-treated cells, whereas the minimal cell volume after shrinkage was unaltered by either of these treatments. It is concluded that osmotic cell swelling and shrinkage elicit a decrease and an increase in the F-actin content in Ehrlich cells, respectively. The RVD and RVI processes are inhibited by 0.5 microM CB, but not by 0.5 microM CD, which is more specific for actin.     

Dramatic magnesium efflux induced by high potassium in rat thymocytes

When incubated in 150 mM KCl, rat thymocytes exhibited a very important magnesium efflux (11.4 +/- 0.7 mmoles/liter cells/20 min, n = 29), about 90 times higher than the physiological magnesium efflux catalyzed by the Na-Mg exchanger (0.126 +/- 0.093 mmoles/liter cells/20 min). Cells remained viable (trypan blue test) and membrane integrity was shown by the absence of an increase in sodium permeability. K(+)-induced magnesium efflux exhibited the following properties: (i) it required the presence of external chloride; (ii) it was fully blocked by DIOA, a selective KCl-cotransporter inhibitor (IC(50) = 35 microm); and (iii) it was associated to a progressive increase in cell volume via the DIOA-sensitive K-Cl cotransporter. Such cell swelling seems to play a causal role, because (i) hypertonic media (+400 mM sucrose) abolished K(+)-induced magnesium efflux and (ii) hypotonic Ringer media (205 mOsm) increased both cell volume and magnesium efflux (from a basal value of 0.35 +/- 0.03 mmoles/liter cells/20 min up to 1.44 +/- 0.24 mmoles/liter cells/20 min), even in the presence of DIOA. In conclusion, high potassium induced a dramatic release of intracellular magnesium from rat thymocytes. Such a phenomenon was, at least in part, caused by cell swelling via the DIOA-sensitive K-Cl cotransporter. The nature of the magnesium transport mechanism and its role in the transduction signal of K-Cl cotransporter activation by cell swelling deserve further investigation.     

Inhibition of Na+/K+-ATPase may be one mechanism contributing to potassium efflux and cell shrinkage in CD95-induced apoptosis

To investigate the involvement of K⁺ efflux in apoptotic cell shrinkage, we monitored efflux of the K⁺ congener,⁸⁶ Rb⁺, and cell volume during CD95-mediated apoptosis in Jurkat cells. An anti-CD95 antibody caused apoptosis associated with intracellular GSH depletion, a significant increase in ⁸⁶Rb⁺ efflux, and a decrease in cell volume compared with control cells. Preincubating Jurkat cells with Val-Ala-Asp-chloromethylketone (VAD-cmk), an inhibitor of caspase proteases, prevented the observed ⁸⁶Rb⁺ efflux and cell shrinkage induced by the anti- CD95 antibody. A wide range of inhibitors against most types of K⁺ channels could not inhibit CD95-mediated efflux of⁸⁶ Rb⁺, however, the uptake of⁸⁶ Rb⁺ by Jurkat cells was severely compromised when treated with anti-CD95 antibody. Uptake of⁸⁶ Rb⁺ in Jurkat cells was sensitive to ouabain (a specific Na⁺/K⁺-ATPase inhibitor), demonstrating Na⁺/K⁺-ATPase dependent K⁺ uptake. Ouabain induced significant⁸⁶ Rb⁺ efflux in untreated cells, as well as it seemed to compete with⁸⁶ Rb⁺ efflux induced by the anti-CD95 antibody, supporting a role for Na⁺/K⁺-ATPase in the CD95-mediated⁸⁶ Rb⁺ efflux. Ouabain treatment of Jurkat cells did not cause a reduction in cell volume, although together with the anti-CD95 antibody, ouabain potentiated CD95-mediated cell shrinkage. This suggests that the observed inhibition of Na⁺+/K⁺-ATPase during apoptosis may also facilitate apoptotic cell shrinkage.     

Cell shrinkage and monovalent cation fluxes: role in apoptosis

The loss of cell volume or cell shrinkage has been a morphological hallmark of the programmed cell death process known as apoptosis. This isotonic loss of cell volume has recently been term apoptotic volume decrease or AVD to distinguish it from inherent volume regulatory responses that occurs in cells under anisotonic conditions. Recent studies examining the intracellular signaling pathways that result in this unique cellular characteristic have determined that a fundamental movement of ions, particularly monovalent ions, underlie the AVD process and plays an important role on controlling the cell death process. An efflux of intracellular potassium was shown to be a critical aspect of the AVD process, as preventing this ion loss could protect cells from apoptosis. However, potassium plays a complex role as a loss of intracellular potassium has also been shown to be beneficial to the health of the cell. Additionally, the mechanisms that a cell employs to achieve this loss of intracellular potassium vary depending on the cell type and stimulus used to induce apoptosis, suggesting multiple ways exist to accomplish the same goal of AVD. Additionally, sodium and chloride have been shown to play a vital role during cell death in both the signaling and control of AVD in various apoptotic model systems. This review examines the relationship between this morphological change and intracellular monovalent ions during apoptosis.     

Cell volume regulation in liver

The maintenance of liver cell volume in isotonic extracellular fluid requires the continuous supply of energy: sodium is extruded in exchange for potassium by the sodium/potassium ATPase, conductive potassium efflux creates a cell-negative membrane potential, which expelles chloride through conductive pathways. Thus, the various organic substances accumulated within the cell are osmotically counterbalanced in large part by the large difference of chloride concentration across the cell membrane. Impairment of energy supply leads to dissipation of ion gradients, depolarization and cell swelling. However, even in the presence of ouabain the liver cell can extrude ions by furosemide-sensitive transport in intracellular vesicles and subsequent exocytosis. In isotonic extracellular fluid cell swelling may follow an increase in extracellular potassium concentration, which impairs potassium efflux and depolarizes the cell membrane leading to chloride accumulation. Replacement of extracellular chloride with impermeable anions leads to cell shrinkage. During excessive sodium-coupled entry of amino acids and subsequent stimulation of sodium/potassium-ATPase by increase in intracellular sodium activity, an increase in cell volume is blunted by activation of potassium channels, which maintain cell membrane potential and allow for loss of cellular potassium. Cell swelling induced by exposure of liver cells to hypotonic extracellular fluid is followed by regulatory volume decrease (RVD), cell shrinkage induced by reexposure to isotonic perfusate is followed by regulatory volume increase (RVI). Available evidence suggests that RVD is accomplished by activation of potassium channels, hyperpolarization and subsequent extrusion of chloride along with potassium, and that RVI depends on the activation of sodium hydrogen ion exchange with subsequent activation of sodium/potassium-ATPase leading to the respective accumulation of potassium and bicarbonate. In addition, exposure of liver to anisotonic perfusates alters glycogen degradation, glycolysis and probably urea formation, which are enhanced by exposure to hypertonic perfusates and depressed by hypotonic perfusates.     

Contribution of organic and inorganic osmolytes to volume regulation in rat brain cells in culture

In this work we examined the time course and the amount released, by hyposmolarity, for the most abundant free amino acids (FAA) in rat brain cortex astrocytes and neurons in culture. The aim was to evaluate their contribution to the process of cell volume regulation. Taurine, glutamate, andd-aspartate in the two types of cells, -alanine in astrocytes and GABA in neurons were promptly released by hyposmolarity, reaching a maximum within 1–2 min. after an osmolarity change. A substantial amount of the intracellular pool of these amino acids was mobilized in response to hyposmolarity. The amount released in media with osmolarity reduced from 300 mOsm to 150 mOsm or 210 mOsm, represented 50%–65% and 13%–31%, respectively, of the total amino acid content in cells. In both astrocytes and neurons, the efflux of glutamine and alanine was higher under isosmotic conditions and increased only marginally during hyposmotic conditions.⁸⁶Rb⁺, used as tracer for K⁺, was released from astrocytes, 30% and 11%, respectively, in hyposmotic media of 150 mOsm or 210 mOsm but was not transported in neurons. From these results it was calculated that FAA contribute 54% and inorganic ions 46% to the process of volume regulation in astrocytes exposed to a 150 mOsm hyposmotic medium. This contribution was 55% for FAA and 45% for K⁺ and Cl^– in cells exposed to 210 mOsm hyposmotic solutions. These results indicate that the contribution of FAA to the process of cell volume regulation is higher in astrocytes than in other cell types including renal and blood cells.Special issue dedicated to Dr. Claude Baxter.     

A study of passive potassium efflux from human red blood cells using ion-specific electrodes

Summary Using ion-specific electrodes, the potassium leakage induced by ouabain in human erythrocytes can be measured continuously and precisely near physiological conditions. Upon small additions of isotonic sucrose solution to a suspension of red cells in physiological saline the passive potassium efflux increases proportionally to the chloride ratio. The same result is obtained upon addition of hypertonic sucrose solution, suggesting that neither osmolarity nor intracellular concentrations have any influence on the passive potassium efflux. The independence of the potassium efflux and osmolarity can be verified by addition of a penetrating substance like glucose to the cell suspension. Adding water or hypertonic sodium chloride solution shows that the potassium efflux increases slightly in more concentrated salt solutions. Inasmuch as it can be interpreted as a pure ionic strength effect, this result supports the hypothesis of independence of potassium efflux and intracellular concentrations. The results of this investigation together with other studies show that the passive permeability of the human red blood cell to potassium depends uniquely on the membrane potential near physiological conditions, while it depends on parameters such as pH or concentrations for large membrane potentials. This suggests that two different mechanisms of transport might be involved: one would control the permeability under normal conditions; the other would represent a leak through the route normally used by anions and become important only under extreme conditions.     

持续性细胞皱缩在人上皮细胞凋亡过程中的必要性

持续性细胞皱缩是凋亡发生的一个主要标志。近期研究发现细胞皱缩在细胞凋亡过程中并不是一个被动的次要事件。在各种细胞中,包括人上皮细胞,凋亡因子（apoptogen）刺激后马上发生全细胞皱缩,又称为凋亡性容积减小（apoptotic　volumede　crease,AVD）,继而发生caspase激活、DNA片段化、细胞破裂死亡。K^＋和Cl^-通道的激活导致KCl外流,诱导AVD发生。抑制AVD发生可以抑制细胞凋亡。AVD与调节性容积增加（regulatory　volume　increase,RVI）异常相伴发生时,人上皮性HeLa细胞发生持续性细胞皱缩。RVI功能受损时,高渗本身就能诱导HeLa细胞持续性细胞皱缩,继而凋亡。即使在正常渗透压、无凋亡因子刺激的情况下,将HeLa细胞置于缺乏Na^＋或Cl。的溶液也会导致细胞持续性皱缩,继而凋亡。因此,AVD诱导和RVI异常所导致的持续性细胞皱缩是人上皮细胞发生凋亡的首要条件。     

Amiloride-sensitive sodium transport in lamprey red blood cells: evidence for two distinct transport pathways

To determine Na+/H+ exchange in lamprey erythrocyte membranes, the cells were acidified to pH(i) 6.0 using the K+/H+ ionophore nigericin. Incubation of acidified erythrocytes in a NaCl medium at pH 8.0 caused a considerable rise in 22Na+ influx and H+ efflux during the first 1 min of exposure. In addition, exposure of acidified red cells to NaCl medium was associated with rapid elevation of intracellular Na+ content. The acid-induced changes in Na+ influx and H+ efflux were almost completely inhibited by amiloride and dimethylamiloride. In native lamprey erythrocytes, amiloride-sensitive Na+ influx progressively increased as the osmolality of incubation medium was increased by addition of 100, 200, or 300 mmol/l sucrose. Unexpectedly, the hypertonic stress induced a small, yet statistically significant decrease in intracellular Na+ content in these cells. The reduction in the cellular Na+ content increased with hypertonicity of the medium. The acid- and shrinkage-induced Na+ influxes were inhibited by both amiloride and 5-(N-ethyl-N-isopropyl)-amiloride (EIPA) in a dose-dependent manner. For both blockers, the half-maximal inhibitory values (IC50) were much greater for the shrinkage-induced (44 and 15 micromol/l for amiloride and EIPA, respectively) than for the acid-induced Na+ influx (5.1 and 3.3 micromol/l, respectively). The data obtained are the first demonstration of the presence of a Na+/H+ exchanger with high activity in acidified (pH(i) 6.0) lamprey red blood cells (on average, 512 +/- 56 mmol/l cells/h, n = 13). The amiloride-sensitive Na+ influxes produced by hypertonic cell shrinkage and acid load are likely to be mediated by distinct ion transporters in these cells.     

Caspase independent/dependent regulation of K(+), cell shrinkage, and mitochondrial membrane potential during lymphocyte apoptosis.

The loss of cell volume is a fundamental feature of apoptosis. We have previously shown that DNA degradation and caspase activity occur only in cells which have shrunken as a result of potassium and sodium efflux (Bortner, C. D., Hughes, F. M., Jr., and Cidlowski, J. A. (1997) J. Biol. Chem. 272, 32436-32442). Furthermore, maintaining a normal intracellular potassium concentration represses the cell death process by inhibiting the activity of apoptotic nucleases and suppressing the activation of effector caspases (Hughes, F. M., Jr., Bortner, C. D. Purdy, G. D., and Cidlowski, J. A. (1997) J. Biol. Chem. 272, 30567-30576). We have now investigated the relationship between cell shrinkage, ion efflux, and changes in the mitochondrial membrane potential, in addition to the role of caspases in these apoptotic events. Treatment of Jurkat cells with a series of inducers which act via distinct signal transduction pathways, resulted in all of the cell death characteristics including loss of cell viability, cell shrinkage, K(+) efflux, altered mitochondrial membrane potential, and DNA fragmentation. Interestingly, only cells which shrunk had a loss of mitochondrial membrane potential and the other apoptotic characteristics. Treatment of Jurkat cells with an anti-Fas antibody in the presence of the general caspase inhibitor z-VAD, abrogated these features. In contrast, when Jurkat cells were treated with either the calcium ionophore A23187 or thapsigargin, z-VAD failed to prevent cell shrinkage, K(+) efflux, or changes in the mitochondrial membrane potential, while effectively inhibiting DNA degradation. Treatment of Jurkat cells with various apoptotic agents in the presence of either the caspase-3 inhibitor DEVD, or the caspase-8 inhibitor IETD also blocked DNA degradation, but failed to prevent other characteristics of apoptosis. Together these data suggest that the cell shrinkage, K(+) efflux, and changes in the mitochondrial membrane potential are tightly coupled, but occur independent of DNA degradation, and can be largely caspase independent depending on the particular signal transduction pathway.     

Intracellular acidification by inhibition of the Na+/H+-exchanger leads to caspase-independent death of cerebellar granule neurons resembling paraptosis

Potassium withdrawal is commonly used to induce caspase-mediated apoptosis in cerebellar granule neurons in vitro. However, the underlying and cell death-initiating mechanisms are unknown. We firstly investigated potassium efflux through the outward delayed rectifier K+ current (Ik) as a potential mediator. However, tetraethylammoniumchloride, an inhibitor of Ik, was ineffective to block apoptosis after potassium withdrawal. Since potassium withdrawal reduced intracellular pH (pHi) from 7.4 to 7.2, we secondly investigated the effects of intracellular acidosis. To study intracellular acidosis in cerebellar granule neurons, we inhibited the Na+/H+ exchanger (NHE) with 4-isopropyl-3-methylsulfonylbenzoyl-guanidine methanesulfonate (HOE 642) and 5-(N-ethyl-N-isopropyl)-amiloride. Both inhibitors concentration-dependently induced cell death and potentiated cell death after potassium withdrawal. Although inhibition of the NHE induced cell death with morphological criteria of apoptosis in light and electron microscopy including chromatin condensation, positive TUNEL staining and cell shrinkage, no internucleosomal DNA cleavage or activation of caspases was detected. In contrast to potassium withdrawal-induced apoptosis, cell death induced by intracellular acidification was not prevented by insulin-like growth factor-1, cyclo-adenosine-monophosphate, caspase inhibitors and transfection with an adenovirus expressing Bcl-XL. However, cycloheximide protected cerebellar granule neurons from death induced by potassium withdrawal as well as from death after treatment with HOE 642. Therefore, the molecular mechanisms leading to cell death after acidification appear to be different from the mechanisms after potassium withdrawal and resemble the biochemical but not the morphological characteristics of paraptosis.     

Strophanthidin-sensitive components of potassium and sodium movements in skeletal muscle as influenced by the internal sodium concentration

"Low sodium" muscles were prepared which contained around 5 mmoles/kg fiber of intracellular sodium. "High sodium" muscles containing between 15 and 30 mmoles/kg fiber of intracellular sodium were also prepared. In low sodium muscles application of 10^-5 M strophanthidin reduced potassium influx by about 5%. Potassium efflux was unaffected by strophanthidin under these conditions. In high sodium muscles, 10^-5 M strophanthidin reduced potassium influx by 45% and increased potassium efflux by 70%, on the average. In low sodium muscles sodium efflux was reduced by 25% during application of 10^-5 M strophanthidin while in high sodium muscles similarly treated, sodium efflux was reduced by about 60%. Low sodium muscles showed a large reduction in sodium efflux when sodium ions in the Ringer solution were replaced by lithium ions. The average reduction in sodium efflux was 4.5-fold. Of the amount of sodium efflux remaining in lithium. Ringer''s solution, 40% could be inhibited by application of 10^-5 M strophanthidin. The total sodium efflux from low sodium muscles exposed to Ringer''s solution in which lithium had been substituted for sodium ions for a period of 1 hr can be fractionated as 78% Na-for-Na interchange, 10% strophanthidin-sensitive sodium pump, and 12% residual sodium efflux. It is concluded that large strophanthidin-sensitive components of sodium and potassium flux can be expected only at elevated sodium concentrations within the muscle cells.     

Adaptation by Corneal Epithelial Cells to Chronic Hypertonic Stress Depends on Upregulation of Na:K:2Cl Cotransporter Gene and Protein Expression and Ion Transport Activity

We examined the ability of SV40-immortalized human and rabbit corneal epithelial cells (HCEC and RCEC, respectively) to adapt to chronic hypertonic stress. Under isotonic conditions, in the presence of 50 μm bumetanide, proliferation measured as ³H-thymidine incorporation declined in RCEC and HCEC by 8 and 35%, respectively. After 48 hr exposure to 375 mOsm medium, RCEC proliferation fell by 19% whereas in HCEC it declined by 45%. Light scattering behavior demonstrated that both cell lines mediate nearly complete regulatory volume increase (RVI) responses to an acute hypertonic (375 mOsm) challenge, which in part depend on bumetanide-sensitive Na-K-2Cl cotransporter (NKCC) activity. Following exposing RCEC for 48 hr to 375 mOsm medium, their RVI response to an acute hypertonic challenge was inhibited by 17%. However, in HCEC this response declined by 68%. During exposure to 375 mOsm medium for up to 24 hr, only RCEC upregulated NKCC gene and protein expression as well as bumetanide-sensitive ⁸⁶Rb influx. These increases are consistent with the smaller declines in RVI and proliferation capacity occurring during this period in RCEC than in HCEC. Therefore, adaptation by RCEC to chronic hypertonic stress is dependent on stimulation of NKCC gene and protein expression and functional activity. On the other hand, under isotonic conditions, HCEC RVI and proliferation are more dependent on NKCC activity than they are in RCEC. Received: 7 March 2000/Revised: 18 May 2000     

In Vitro Studies on the Putative Function of N-acetylaspartate as an Osmoregulator

Efflux and tissue content of N-acetylaspartate (NAA) and amino acids were evaluated from cultured and acutely prepared hippocampal slices in response to changes in osmolarity. The osmoregulator taurine, but not NAA, was lost from both types of slices after moderate reductions in extracellular osmolarity (−60 mOsm) for 10–48 h. Hypoosmotic shock (−166 mOsm) for 5 min resulted in unselective efflux of several amino acids from acutely prepared slices. Notably, the efflux of taurine, but not NAA, was prominent also after the shock. Efflux of NAA was markedly enhanced by NMDA and high K⁺, in particular after the stimulation period. The high K⁺-mediated efflux was decreased by high extracellular osmolarity and a NMDA-receptor antagonist. The results indicate that NAA efflux can be induced by a sudden non-physiological decrease in extracellular osmolarity but not by prolonged more moderate changes in osmolarity. The mechanisms behind the efflux of NAA by high K⁺ are complex and may involve both swelling and activation of NMDA-receptors.     

Cation transport and content in serum-stimulated CHO-773 cells. II. Late changes in rubidium influx and intracellular potassium content

Serum stimulation of stationary cultures of Chinese hamster ovary cells CHO-K1 (clone 773) is accompanied by sustained increase in ouabain-sensitive rubidium (potassium) influx which results in the elevation of intracellular potassium content from 0.5-0.6 to 0.7-0.8 mmole per gram of protein. Cytofluorometric studies of serum-stimulated CHO-773 cultures have shown that the intracellular potassium increase is necessary for successful G1----S progression. The elevation of intracellular potassium was found to occur simultaneously with the cellular protein growth. Cycloheximide (10 micrograms/ml) does not influence the early Na,K-ATPase activation induced by serum; however, it abolishes the sustained increase of both rubidium influx and intracellular potassium content. In serum stimulated cells ouabain increases the potassium efflux; this ouabain effect is not observed after S phase, when rubidium (potassium) influx decreases and intracellular potassium content stops growing.     

Potassium transport in the rabbit renal proximal tubule: Effects of barium,ouabain, valinomycin,and other ionophores

Summary Potassium fluxes in a suspension of rabbit proximal tubules were monitored using a potassium-sensitive extracellular electrode. Ouabain (10^–4 m) and barium (5mm) were used to selectively quantitate the potassium efflux pathway (105±5 nmol K⁺·mg protein^–1·min^–1) and the sodium pump-related potassium influx (108±7), respectively. These equal and opposite fluxes suggest that potassium accumulation in the cell occurs mainly through the sodium pump and that potassium efflux occurs mainly through barium-sensitive potassium channels. Thus the activity of the sodium pump (Na, K-ATPase) in the basolateral membrane of the proximal tubule is balanced by the efflux of potassium, presumably across the basolateral membrane, which has a high potassium permeability. In addition, the effect of valinomycin and other ionophores was examined on potassium fluxes and several metabolic parameters [oxygen consumption (QO₂), ATP content]. The addition of valinomycin to the tubules produced a net efflux of potassium which was quantitatively equivalent to the efflux produced by the addition of ouabain. The valinomycin-induced efflux was mainly due to the activity of valinomycin as a mitochondrial uncoupler, which indirectly inhibited the sodium pump by allowing a rapid reduction of the intracellular ATP. Amphotericin, nystatin, and monensin all produced large net releases of intracellular potassium. The action of the ionophores could be localized to the plasma or mitochondrial membrane and classified into three groups, as follows: (a) those which demonstrated full mitochondrial uncoupler activity (FCCP, valinomycin), (b) those which had no uncoupler activity (amphotericin B, nystatin); and (c) those which displayed partial uncoupler activity (monensin, nigericin).     

Regulation of Ion Fluxes,Cell Volume and Gap Junctional Coupling by cGMP in GFSHR-17 Granulosa Cells

Gap junctional communication between granulosa cells seems to play a crucial role for follicular growth and atresia. Application of the double whole-cell patch-clamp- and ratiometric fura-2-techniques allowed a simultaneous measurement of gap junctional conductance (G _j) and cytoplasmic concentration of free Ca²⁺ ([Ca²⁺]_i) in a rat granulosa cell line GFSHR-17. The voltage-dependent gating of G _j varied for different cell pairs. One population exhibited a bell-shape dependence of G _j on transjunctional voltage, which was strikingly similar to that of Cx43/Cx43 homotypic gap junction channels expressed in pairs of oocytes of Xenopus laevis. Within 15–20 min, gap junctional uncoupling occurred spontaneously, which was preceded by a sustained increase of [Ca²⁺]_i and accompanied by shrinkage of cellular volume. These responses to the whole-cell configuration were avoided by absence of extracellular Ca²⁺, blockage of K⁺ efflux, or addition of 8-bromoguanosine 3,5-cyclic monophosphate (8-Br-cGMP) to the pipette solution. Even in the absence of extracellular Ca²⁺ or blockage of K⁺ efflux, formation of whole-cell configuration generated a Ca²⁺ spike that could be suppressed by the presence of 8-Br-cGMP. We propose that intracellular cGMP regulates Ca²⁺ release from intracellular Ca²⁺ stores, which activates sustained Ca²⁺ influx, K⁺ efflux and cellular shrinkage. We discuss whether gap junctional conductance is directly affected by cGMP or by cellular shrinkage and whether gap junctional coupling and/or cell shrinkage is involved in the regulation of apoptotic/necrotic processes in granulosa cells.