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.     

Role of potassium channels, the sodium-potassium pump and the cytoskeleton in the control of dog sperm volume

Response to osmotic shock is an important aspect of mammalian sperm physiology. In this study we recorded volume changes of dog spermatozoa at 39, 33, and 25 degrees C under isotonic conditions and following hypotonic shock. Cell volume measurements were performed electronically in saline solutions of 300 and 150 mOsmol kg(-1), and Percoll-washed preparations were compared with unwashed samples. The involvement of potassium channels in volume control was tested by treatment with quinine, while the involvement of the plasma membrane Na(+)-K+ pump was tested by treatment with ouabain. The role of the cytoskeleton was investigated by treatment with colchicine and cytochalasin D. The number of cell populations observed varied with temperature and tonicity. In both types of sperm preparations, between two and three populations were present under isotonic conditions at 25 degrees C whereas at 39 and 33 degrees C only one population was detected. Hypotonic stress at the higher temperatures caused the single population to swell, whereas at 25 degrees C it resulted in a population of cells whose modal volume was similar to that of the middle isotonic sub-population. Both quinine and the cytoskeletal inhibitors markedly increased swelling both under hypotonic conditions at 39 degrees C and under isotonic conditions at 25 degrees C. However, little or no effect of ouabain was observed. We conclude that in dog spermatozoa swelling in response to hypotonic conditions is minimised through the activity of potassium channels and the presence of an intact cytoskeletal network. Under isotonic conditions at 25 degrees C, a considerable proportion of the sperm population is already swollen; this swelling varies between individual males and appears to be due to lowered cytoskeletal and potassium channel activity.     

Osmotic Stress Alters the Intracellular Distribution of Non-erythroidal Spectrin (Fodrin) in Bovine Aortic Endothelial Cells

Cell swelling is known to result in unfolding of membrane invaginations and restructuring of F-actin. The effect of cell swelling on the intracellular distributions of other cytoskeletal proteins that constitute the submembrane cortical cytoskeleton is virtually unknown. This study focuses on the effects of cell swelling on non-erythroidal spectrin (fodrin, also known as spectrin II), a predominant component of the membrane cytoskeleton. The intracellular distribution of spectrin in vascular endothelial cells was studied by optical sectioning using a 3-D deconvolution microscopy system. Our results show that once bovine aortic endothelial cells (BAECs) reach confluency, the non-erythroidal spectrin is localized in the submembrane regions of the cells. Analysis of the intensity profiles of the non-erythroidal spectrin under isotonic and hypotonic conditions show that: (a) the width of the submembrane spectrin staining increases gradually with time within the first 5 minutes after the osmotic shock; (b) significant recovery is observed after 10 minutes even if the cells are maintained in hypotonic medium, and (c) spectrin distribution is altered by disrupting F-actin with latrunculin A but not by stabilizing F-actin with jasplakinolide. We suggest that cell swelling results in partial translocation of the submembrane spectrin to the cytosol and that it may play a major role in initiation of swelling-induced cellular events.     

Structural reaction pattern of hepatocytes following exposure to hypotonicity

Isolated rat hepatocytes were exposed to hypotonic media (225 mosmol/l) for 5 and 15 min and processed for a quantitative electron microscopic stereologic analysis. Within 5 min of hypotonicity, the hepatocyte volume increased by 25% and thereatter displayed a volume regulatory decrease leading to mean cellular volume, which was 16% above that of controls. Stereologic analysis of the major subcellular compartment, the cytosol, showed an identical change as the whole cell. In contrast to that, the mitochondrial compartment increased in volume by 30% within the first 5 min of exposure and returned by regulatory volume decrease back to values of the isotonic controls after 15 min of hypotonicity. In contrast, hypotonicity (220 mosmol/l)-stimulation of flux through mitochondrial glutaminase and the glycine cleavage enzyme complex, as assessed by ¹⁴CO₂ production from [1-¹⁴C]glutamine or [1-¹⁴C]glycine in isolated perfused rat liver persisted throughout a 15-min period of hypotonic exposure. Thus hypotonicity-induced alterations of mitochondrial metabolism apparently do not parallel the time course of mitochondrial volume changes. This suggests that persistent mitochondrial swelling is not required for functional alterations, but that the latter may be triggered by the initial swelling of mitochondria. Hypotonic exposure did not alter the nuclear volume of isolated hepatocytes. Cell membrane surface nearly doubled after 5 min of hypotonic exposure, but returned within 15 min of exposure to values observed in normotonic media. This may reflect the participation of exocytosis in hepatocyte volume regulation. © 1993 Wiley-Liss, Inc.     

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.     

Hypotonic Activation of Volume-sensitive Outwardly Rectifying Anion Channels (VSOACs) Requires Coordinated Remodeling of Subcortical and Perinuclear Actin Filaments

Cell volume regulation requires activation of volume-sensitive outwardly rectifying anion channels (VSOACs). The actin cytoskeleton may participate in the activation of VSOACs but the roles of the two major actin pools remain undefined. We hypothesized that structural reorganization of both subcortical and perinuclear actin filaments (F-actin) contributes to the hypotonic activation of VSOACs. Hypotonic stress of pulmonary artery smooth muscle cells (PASMCs) was associated with reorganization of both peripheral and perinuclear F-actin, and with activation of VSOACs. Preincubation with cytochalasin D caused prominent dissociation of perinuclear, but not of subcortical F-actin. Cytochalasin D failed to induce isotonic activation and delayed the hypotonic activation of VSOACs. F-actin stabilization by phalloidin delayed both the hypotonic stress-induced dissociation of membrane-associated actin filaments and the activation kinetics of VSOACs. PKCε, which was proposed to phosphorylate and inhibit VSOACs, colocalized primarily with F-actin and the net kinase activity remained unchanged during hypotonic cell swelling. In conclusion, normal hypotonic activation of VSOACs requires disruption of peripheral F-actin but intact perinuclear F-actin; interference with this pattern of actin reorganization delays the activation kinetics of VSOACs. The cell swelling-induced peripheral actin dissociation may underlie the observed translocation of PKCε, which leads to a net decrease of PKCε inhibitory activity in submembranous sites. Thus, reorganization of actin and PKCε may establish conditions for mechano- and/or signal transduction-mediated activation of VSOACs.     

Regulation of volume-sensitive outwardly rectifying anion channels in pulmonary arterial smooth muscle cells by PKC

We tested the possible role of endogenous protein kinase C (PKC) in the regulation of native volume-sensitive organic osmolyte and anion channels (VSOACs) in acutely dispersed canine pulmonary artery smooth muscle cells (PASMC). Hypotonic cell swelling activated native volume-regulated Cl(-) currents (I(Cl.vol)) which could be reversed by exposure to phorbol 12,13-dibutyrate (0.1 microM) or by hypertonic cell shrinkage. Under isotonic conditions, calphostin C (0.1 microM) or Ro-31-8425 (0.1 microM), inhibitors of both conventional and novel PKC isozymes, significantly activated I(Cl.vol) and prevented further modulation by subsequent hypotonic cell swelling. Bisindolylmaleimide (0.1 microM), a selective conventional PKC inhibitor, was without effect. Dialyzing acutely dispersed and cultured PASMC with epsilon V1-2 (10 microM), a translocation inhibitory peptide derived from the V1 region of epsilon PKC, activated I(Cl.vol) under isotonic conditions and prevented further modulation by cell volume changes. Dialyzing PASMC with beta C2-2 (10 microM), a translocation inhibitory peptide derived from the C2 region of beta PKC, had no detectable effect. Immunohistochemistry in cultured canine PASMC verified that hypotonic cell swelling is accompanied by translocation of epsilon PKC from the vicinity of the membrane to cytoplasmic and perinuclear locations. These data suggest that membrane-bound epsilon PKC controls the activation state of native VSOACs in canine PASMC under isotonic and anisotonic conditions.     

Increase of beta-actin mRNA upon hypotonic perfusion of perfused rat liver

beta-Actin mRNA levels in livers exposed to hypotonic perfusion (from 305 to 225 mosmol/l) for one hour are increased 2-fold relative to albumin mRNA. Like albumin, glyceraldehyde-3-phosphate dehydrogenase and tyrosine aminotransferase mRNAs remain at the levels observed under normotonic conditions. The increase in beta-actin mRNA is interpreted as a cytoskeletal response due to cell swelling.     

Volume-Sensitive Chloride Channels are Involved in Maintenance of Basal Cell Volume in Human Acute Lymphoblastic Leukemia Cells

Chloride channels are expressed ubiquitously in different cells. However, the activation and roles of volume-activated chloride channels under normal isotonic conditions are not clarified, especially in lymphatic cells. In this study, the activation of basal and volume-activated chloride currents and their roles in maintenance of basal cell volume under isotonic conditions were investigated in human acute lymphoblastic leukemia Molt4 cells. The patch-clamp technique and time-lapse image analysis were employed to record whole-cell currents and cell volume changes. Under isotonic conditions, a basal chloride current was recorded. The current was weakly outward-rectified and volume-sensitive and was not inactivated obviously in the observation period. A 47% hypertonic bath solution and the chloride channel blockers NPPB and tamoxifen suppressed the current. Exposure of cells to 47% hypotonic bath solution activated further the basal current. The hypotonicity-activated current possessed properties similar to those of the basal current and was inhibited by NPPB, tamoxifen, ATP and hypertonic bath solution. Furthermore, extracellular hypotonic challenges swelled the cells and induced a regulatory volume decrease (RVD). Extracellular applications of NPPB, tamoxifen and ATP swelled the cells under isotonic conditions and inhibited the RVD induced by hypotonic cell swelling. The results suggest that some volume-activated chloride channels are activated under isotonic conditions, resulting in the appearance of the basal chloride current, which plays an important role in the maintenance of basal cell volume in lymphoblastic leukemia cells. Chloride channels can be activated further to induce a regulatory volume recovery when cells are swollen.     

Hypotonic Challenge of Endothelial Cells Increases Membrane Stiffness with No Effect on Tether Force

Regulation of cell volume is a fundamental property of all mammalian cells. Multiple signaling pathways are known to be activated by cell swelling and to contribute to cell volume homeostasis. Although cell mechanics and membrane tension have been proposed to couple cell swelling to signaling pathways, the impact of swelling on cellular biomechanics and membrane tension have yet to be fully elucidated. In this study, we use atomic force microscopy under isotonic and hypotonic conditions to measure mechanical properties of endothelial membranes including membrane stiffness, which reflects the stiffness of the submembrane cytoskeleton complex, and the force required for membrane tether formation, reflecting membrane tension and membrane-cytoskeleton attachment. We find that hypotonic swelling results in significant stiffening of the endothelial membrane without a change in membrane tension/membrane-cytoskeleton attachment. Furthermore, depolymerization of F-actin, which, as expected, results in a dramatic decrease in the cellular elastic modulus of both the membrane and the deeper cytoskeleton, indicating a collapse of the cytoskeleton scaffold, does not abrogate swelling-induced stiffening of the membrane. Instead, this swelling-induced stiffening of the membrane is enhanced. We propose that the membrane stiffening should be attributed to an increase in hydrostatic pressure that results from an influx of solutes and water into the cells. Most importantly, our results suggest that increased hydrostatic pressure, rather than changes in membrane tension, could be responsible for activating volume-sensitive mechanisms in hypotonically swollen cells.     

Effect of arachidonic acid,fatty acids,prostaglandins, and leukotrienes on volume regulation in Ehrlich ascites tumor cells

Summary Arachidonic acid inhibits the cell shrinkage observed in Ehrlich ascites tumor cells during regulatory volume decrease (RVD) or after addition of the Ca ionophore A23187 plus Ca. In Na-containing media, arachidonic acid increases cellular Na uptake under isotonic as well as under hypotonic conditions. Arachidonic acid also inhibits KCl and water loss following swelling in Na-free, hypotonic media even when a high K conductance has been ensured by addition of gramicidin. In isotonic, Na-free medium arachidonic acid inhibits A23187 + Ca-induced cell shrinkage in the absence but not in the presence of gramicidin. It is proposed that inhibition of RVD in hypotonic media by arachidonic acid is caused by reduction in the volume-induced Cl and K permeabilities as well as by an increase in Na permeability and that reduction in A23187 + Ca-induced cell shrinkage is due to a reduction in K permeability and an increase in Na permeability. The A23187 + Ca-activated Cl permeability in unaffected by arachidonic acid. PGE₂ inhibits RVD in Na-containing, hypotonic media but not in Na-free, hypotonic media, indicating a PGE₂-induced Na uptake. PGE₂ has no effect on the volume-activated K and Cl permeabilities. LTB₄, LTC₄ and LTE₄ inhibit RVD insignificantly in hypotonically swollen cells. LTD₄, more-over, induces cell shrinkage in steady-state cells and accelerates the RVD following hypotonic exposure. The effect of LTD₄ even reflects a stimulating effect on K and Cl transport pathways. Thus none of the leukotrienes show the inhibitory effect found for arachidonic acid on the K and Cl permeabilities. The RVD response in hypotonic, Na-free media is, on the other hand, also inhibited by addition of the unsaturated oleic, linoleic, linolenic and palmitoleic acid, even in the presence of the cationophor gramicidin. The saturated arachidic and stearic acid had no effect on RVD. It is, therefore, suggested that a minor part of the inhibitory effect of arachidonic acid on RVD in Na-containing media is via an increased synthesis of prostaglandins and that the major part of the arachidonic acid effect on RVD in Na-free media, and most probably also in Na-containing media, is due to the inhibition of the volume-induced K and Cl transport pathways, caused by a nonspecific detergent effect of an unsaturated fatty acid.     

Cell volume regulation in renal cortical cells

Both proximal renal tubule cells and cultured Madin-Darby canine kidney (MDCK) cells are capable of regulating their volume in hypotonic media. Regulatory cell volume decrease in proximal straight tubules is impaired by barium, amiloride and acetazolamide and depends on the presence of bicarbonate and of sodium, whereas it is unaffected by complete removal of extracellular chloride. The observations may point to parallel loss of potassium through potassium channels as well as of bicarbonate and sodium via a bicarbonate-sodium cotransport. Alternatively, potassium/hydrogen ion exchange or potassium bicarbonate cotransport could be involved. In MDCK cells, exposure to hypotonic media apparently leads to the activation of an anion channel, while potassium conductance is rather decreased. In both proximal tubules and MDCK cells, volume regulatory decrease is possibly triggered by leucotrienes, which may be released during cell swelling. Cell volume is altered in a variety of conditions even at isotonic extracellular fluid and cell volume-regulatory mechanisms are likely to participate in regulation of renal transepithelial transport.     

Effect of hypotonic shock on cultured pavement cells from freshwater or seawater rainbow trout gills

The effect of hypotonic shock on cultured pavement gill cells from freshwater (FW)- and seawater (SW)-adapted trout was investigated. Exposure to 2/3rd strength Ringer solution produced an increase in cell volume followed by a slow regulatory volume decrease (RVD). The hypotonic challenge also induced a biphasic increase in cytosolic Ca(2+) with an initial peak followed by a sustained plateau. Absence of external Ca(2+) did not modify cell volume under isotonic conditions, but inhibited RVD after hypotonic shock. [Ca(2+)](i) response to hypotonicity was also partially inhibited in Ca-free bathing solutions. Similar results were obtained whether using cultured gill cells prepared from FW or SW fishes. When comparing freshly isolated cells with cultured gill cells, a similar Ca(2+) signalling response to hypotonic shock was observed regardless of the presence or absence of Ca(2+) in the solution. In conclusion, gill pavement cells in primary culture are able to regulate cell volume after a cell swelling and express a RVD response associated with an intracellular calcium increase. A similar response to a hypotonic shock was recorded for cultured gill cells collected from FW and SW trout. Finally, we showed that calcium responses were physiologically relevant as comparable results were observed with freshly isolated cells exposed to hypoosmotic shock.     

Importance of cytoskeletal elements in volume regulatory responses of trout hepatocytes

The role of cytoskeletal elements in volume regulation was studied in trout hepatocytes by investigating changes in F-actin distribution during anisotonic exposure and assessing the impact of cytoskeleton disruption on volume regulatory responses. Hypotonic challenge caused a significant decrease in the ratio of cortical to cytoplasmic F-actin, whereas this ratio was unaffected in hypertonic saline. Disruption of microfilaments with cytochalasin B (CB) or cytochalasin D significantly slowed volume recovery following hypo- and hypertonic exposure in both attached and suspended cells. The decrease of net proton release and the intracellular acidification elicited by hypotonicity were unaltered by CB, whereas the increase of proton release in hypertonic saline was dramatically reduced. Because amiloride almost completely blocked the hypertonic increase of proton release and cytoskeleton disruption diminished the associated increase of intracellular pH (pH(i)), we suggest that F-actin disruption affected Na(+)/H(+) exchanger activity. In line with this, pH(i) recovery after an ammonium prepulse was significantly inhibited in CB-treated cells. The increase of cytosolic Na(+) under hypertonic conditions was not diminished but, rather, enhanced by F-actin disruption, presumably due to inhibited Na(+)-K(+)-ATPase activity and stimulated Na(+) channel activity. The elevation of cytosolic Ca(2+) in hypertonic medium was significantly reduced by CB. Altogether, our results indicate that the F-actin network is of crucial importance in the cellular responses to anisotonic conditions, possibly via interaction with the activity of ion transporters and with signalling cascades responsible for their activation. Disruption of microtubules with colchicine had no effect on any of the parameters investigated.     

Red cell volume regulation: the pivotal role of ionic strength in controlling swelling-dependent transport systems.

A volume increase of trout erythrocytes can be induced either by beta-adrenergic stimulation of a Na+/H+ antiport in an isotonic medium (isotonic swelling) or by suspending red cells in an hypotonic medium (hypotonic swelling). In both cases cells regulate their volume by a loss of osmolytes via specific pathways. After hypotonic swelling several volume-dependent pathways were activated allowing K+, Na+, taurine and choline to diffuse. All these pathways were fully inhibited by furosemide and inhibitors of the anion exchanger (DIDS, niflumic acid), and the K+ loss was mediated essentially via a 'Cl(-)-independent' pathway. After isotonic swelling, the taurine, choline and Na+ pathways were practically not activated and the K+ loss was strictly 'Cl(-)-dependent'. Thus cellular swelling is a prerequisite for activation of these pathways but, for a given volume increase, the degree of activation and the degree of anion-dependence of the K+ pathway depend on the nature of the stimulus, whether hormonal or by reduction of osmolality. It appears that the pattern of the response induced by hormonal stimulation is not triggered by either cellular cAMP (since it can be reproduced in the absence of hormone by isotonic swelling in an ammonium-containing saline) or by the tonicity of the medium in which swelling occurs since after swelling in an isotonic medium containing urea, the cells adopt the regulatory pattern normally observed after hypotonic swelling. We demonstrated that the stimulus is the change in cellular ionic strength induced by swelling: when ionic strength drops, the cells adopt the hypotonic swelling pattern; when ionic strength increases, the isotonic swelling pattern is activated. To explain this modulating effect of ionic strength a speculative model is proposed, which also allows the integration of two further sets of experimental results: (i) all the volume-activated transport systems are blocked by inhibitors of the anion exchanger and (ii) a Cl(-)-dependent, DIDS-sensitive K+ pathway can be activated in static volume trout red cells (i.e., in the absence of volume increase) by the conformational change of hemoglobin induced by the binding of O2 or CO to the heme.     

Ion channels activated by osmotic and mechanical stress in membranes of opossum kidney cells

Summary For patch-clamp measurements cultured kidney (OK) cells were exposed to osmotic and mechanical stress. Superfusion of a cell in whole cell configuration with hypotonic media (190 mOsm) evokes strong depolarization, which is reversible by returning to the isotonic bath medium. In the cell-attached configuration the exposure to hypotonic media evokes up to six ion channels of homogeneous single-channel properties in the membrane patch. Subsequently, the channels became activated after a time lag of a few seconds. At an applied membrane potential of 0 mV, the corresponding membrane current is directed inward and shows a transient behavior in the time range of minutes. In the same membrane patch these ion channels can be activated by application of negative hydrostatic pressure. The channel has a single-channel conductance of about 22 pS and is permeable to Na⁺ and K⁺ as well as to Cl^–. It is suggested that volume regulation involves mechanoreceptor-operated ion channels.     

Cell swelling activates cloned Ca(2+)-activated K(+) channels: a role for the F-actin cytoskeleton

Cloned Ca(2+)-activated K(+) channels of intermediate (hIK) or small (rSK3) conductance were expressed in HEK 293 cells, and channel activity was monitored using whole-cell patch clamp. hIK and rSK3 currents already activated by intracellular calcium were further increased by 95% and 125%, respectively, upon exposure of the cells to a 33% decrease in extracellular osmolarity. hIK and rSK3 currents were inhibited by 46% and 32%, respectively, by a 50% increase in extracellular osmolarity. Cell swelling and channel activation were not associated with detectable increases in [Ca(2+)](i), evidenced by population and single-cell measurements. In addition, inhibitors of IK and SK channels significantly reduced the rate of regulatory volume decrease (RVD) in cells expressing these channels. Cell swelling induced a decrease, and cell shrinkage an increase, in net cellular F-actin content. The swelling-induced activation of hIK channels was strongly inhibited by cytochalasin D (CD), in concentrations that caused depolymerization of F-actin filaments, indicating a role for the F-actin cytoskeleton in modulation of hIK by changes in cell volume. In conclusion, hIK and rSK3 channels are activated by cell swelling and inhibited by shrinkage. A role for the F-actin cytoskeleton in the swelling-induced activation of hIK channels is suggested.     

Volume Control by Muscle Fibers of the Blue Crab : Volume readjustment in hypotonic salines

Single isolated muscle fibers from the walking legs of the blue crab, Callinectes sapidus act as Boyle-van't Hoff osmometers with an osmotically inactive volume of 33 %. Fibers in hypotonic salines undergo a spontaneous volume readjustment toward the initial volumes of the cells found in isotonic salines. The volume readjustment is initiated by the increase in cell volume in hypotonic salines and appears to be dependent on the duration of exposure of the fiber to external sodium, the sodium concentration, and the pH of the external medium. The volume-readjusted cells continue to behave as osmometers, but with an increased relative osmotically inactive volume and a decreased internal resistivity. The decreases in cell volumes appear to be, in large part, due to losses of osmotically active nonelectrolytes from the cells.     

KCl loss and cell shrinkage in the ehrlich ascites tumor cell induced by hypotonic media, 2-deoxyglucose and propranolol

Ehrlich ascites tumor cells lose KCl and shrink after swelling in hypotonic media and in response to the addition of 2-deoxyglucose, propranolol, or the Ca²⁺ ionophore, A23187, plus Ca²⁺ in isotonic media. All of these treatments activate cell shrinkage via a pathway with the following characteristics: (1) the KCl loss responsible for cell shrinkage does not alter the membrane potential; (2) NO₃^? does not substitute for Cl^?; (3) the net KCl movements are not inhibited by quinine or DIDS; and (4) early in this study furosemide was effective in inhibiting cell shrinkage but this sensitivity was subsequently lost. This evidence suggests that the KCl loss in these cells occurs via a cotransport mechanism. In addition, hypotonic media and the other agents used here stimulate a Cl^? -Cl^? exchange, a net loss of K⁺ and a net gain of Na⁺ which are not responsible for cell shrinkage. The Ehrlich cell also appears to have a Ca²⁺-activated, quinine-sensitive K⁺ conductive pathway but this pathway is not part of the mechanism by which these cells regulate their volume following swelling or shrink in isotonic media in response to 2-deoxyglucose or propranolol. Shrinkage by the loss of K⁺ through the Ca²⁺ stimulated pathway appears to be limited by Cl^? conductive movements; for when NO₃^?, an anion demonstrated here to have a higher conductive movement than Cl^?, is substituted for Cl^?, the cells will shrink when the Ca²⁺-stimulated K⁺ pathway is activated.     

Ionic basis of volume regulation in mammalian cells following osmotic shock

Previous studies with mammalian cultured cells have shown that volume regulation in hypotonic medium requires active Na transport. In the present study, determinations of intracellular Na and K content were made in cultured mouse lymphoblasts during the process of swelling and subsequent shrinking (volume regulation) in hypotonic medium. Na and K content were measured in cells in which the shrinking phase was inhibited by the cardiac glycoside, ouabain. In osmotically-shocked cells, an initial permeability increase to K, and not Na, was observed, which allowed K to diffuse out rapidly, down its gradient. Na, meanwhile, rapidly flowed inward with water entry during the swelling process, and was later lost with the same kinetics as the cell shrinkage. This loss of Na was prevented in the presence of ouabain. The results imply that volume regulation is achieved by pumping Na gained during swelling out of the cells, while any K taken up by the pump is rapidly lost through a more permeable membrane. The loss of osmotically active Na, presumably with accompanying anions, allows water to passively diffuse down its osmotic gradient, reducing cell volume subsequent to the initial passive swelling, during which K was rapidly lost.