Regulatory volume decrease in the presence of HCO3- by single osteosarcoma cells UMR-106-01.

The technique for the simultaneous recording of cell volume changes and pHi in single cells was used to study the role of HCO3- in regulatory volume decrease (RVD) by the osteosarcoma cells UMR-106-01. In the presence of HCO3-, steady state pHi is regulated by Na+/H+ exchange, Na+ (HCO3-)3 cotransport and Na(+)-independent Cl-/HCO3- exchange. Following swelling in hypotonic medium, pHi was reduced from 7.16 +/- 0.02 to 6.48 +/- 0.02 within 3.4 +/- 0.28 min. During this period of time, the cells performed RVD until cell volume was decreased by 31 +/- 5% beyond that of control cells (RVD overshoot). Subsequently, while the cells were still in hypotonic medium, pHi slowly increased from 6.48 +/- 0.02 to 6.75 +/- 0.02. This increase in pHi coincided with an increase in cell volume back to normal (recovery from RVD overshoot or hypotonic regulatory volume increase (RVI)). The same profound changes in cell volume and pHi after cell swelling were observed in the complete absence of Cl- or Na+, providing HCO3- was present. On the other hand, depolarizing the cells by increasing external K+ or by inhibition of K+ channels with quinidine, Ba2+ or tetraethylammonium prevented the changes in pHi and RVD. These findings suggest that in the presence of HCO3-, RVD in UMR-106-01 cells is largely mediated by the conductive efflux of K+ and HCO3-. Removal of external Na+ but not Cl- prevented the hypotonic RVI that occurred after the overshoot in RVD. Amiloride had no effect, whereas pretreatment with 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) strongly inhibited hypotonic RVI. Thus, hypotonic RVI is mediated by a Na+(out)-dependent, Cl(-)-independent and DIDS-inhibitable mechanism, which is indicative of a Na+(HCO3-)3 cotransporter. This is the first evidence for the involvement of this transporter in cell volume regulation. The present results also stress the power of the new technique used in delineating complicated cell volume regulatory mechanisms in attached single cells.     

Cytosolic pH regulation in osteoblasts. Regulation of anion exchange by intracellular pH and Ca2+ ions

Measurements of cytosolic pH (pHi) 36Cl fluxes and free cytosolic Ca2+ concentration ([Ca2+]i) were performed in the clonal osteosarcoma cell line UMR-106 to characterize the kinetic properties of Cl-/HCO3- (OH-) exchange and its regulation by pHi and [Ca2+]i. Suspending cells in Cl(-)-free medium resulted in rapid cytosolic alkalinization from pHi 7.05 to approximately 7.42. Subsequently, the cytosol acidified to pHi 7.31. Extracellular HCO3- increased the rate and extent of cytosolic alkalinization and prevented the secondary acidification. Suspending alkalinized and Cl(-)-depleted cells in Cl(-)-containing solutions resulted in cytosolic acidification. All these pHi changes were inhibited by 4',4',-diisothiocyano-2,2'-stilbene disulfonic acid (DIDS) and H2DIDS, and were not affected by manipulation of the membrane potential. The pattern of extracellular Cl- dependency of the exchange process suggests that Cl- ions interact with a single saturable external site and HCO3- (OH-) complete with Cl- for binding to this site. The dependencies of both net anion exchange and Cl- self-exchange fluxes on pHi did not follow simple saturation kinetics. These findings suggest that the anion exchanger is regulated by intracellular HCO3- (OH-). A rise in [Ca2+]i, whether induced by stimulation of protein kinase C-activated Ca2+ channels, Ca2+ ionophore, or depolarization of the plasma membrane, resulted in cytosolic acidification with subsequent recovery from acidification. The Ca2+-activated acidification required the presence of Cl- in the medium, could be blocked by DIDS, and H2DIDS and was independent of the membrane potential. The subsequent recovery from acidification was absolutely dependent on the initial acidification, required the presence of Na+ in the medium, and was blocked by amiloride. Activation of protein kinase C without a change in [Ca2+]i did not alter pHi. Likewise, in H2DIDS-treated cells and in the absence of Cl-, an increase in [Ca2+]i did not activate the Na+/H+ exchanger in UMR-106 cells. These findings indicate that an increase in [Ca2+]i was sufficient to activate the Cl-/HCO3- exchanger, which results in the acidification of the cytosol. The accumulated H+ in the cytosol activated the Na+/H+ exchanger. Kinetic analysis of the anion exchange showed that at saturating intracellular OH-, a [Ca2+]i increase did not modify the properties of the extracellular site. A rise in [Ca2+]i increased the apparent affinity for intracellular OH- (or HCO3-) of both net anion and Cl- self exchange. These results indicate that [Ca2+]i modifies the interaction of intracellular OH- (or HCO3-) with the proposed regulatory site of the anion exchanger in UMR-106 cells.     

Volume-regulating behavior of human platelets

Human platelets exposed to hypotonic media undergo an initial swelling followed by shrinking (regulatory volume decrease [RVD]). If the RVD is blocked, the degree of swelling is in accord with osmotic behavior. The cells could swell at least threefold without significant lysis. Two methods were used to follow the volume changes, electronic sizing and turbidimetry. Changes in shape produced only limited contribution to the measurements. The RVD was very rapid, essentially complete in 2 to 8 minutes, with a rate proportional to the degree of initial cell swelling. RVD involved a loss of KCl via volume-activated conductive permeability pathways for K+ and anions, presumably Cl-. In media containing greater than 50 mM KCl, the shrinking was inhibited and with higher concentrations was reversed (secondary swelling), suggesting that it is driven by the net gradient of K+ plus Cl-. The K+ pathway was specific for Rb+ and K+ compared to Li+ and Na+. The Cl- pathway accepted NO-3 and SCN- but not citrate or SO4(2-). In isotonic medium, the permeability of platelets to Cl- appeared to be low compared to that of K+. After hypotonic swelling both permeabilities were increased, but the Cl- permeability exceeded that of K+. The Cl- conductive pathway remained open as long as the cells were swollen. RVD was incomplete unless amiloride, an inhibitor of Na+/H+ exchange, was present or unless Na+ was replaced by an impermeant cation. In addition, acidification of the cytoplasm occurred upon cell swelling. This reduction in pHi appeared to activate Na+/H+ exchange, with a resultant uptake of Na+ and reduction in the rate and amount of shrinking. Like other cells, platelets responded to hypertonic shrinking with activation of Na+/H+ exchange, but regulatory volume increase was not detectable.     

Effect of potassium depletion of Hep 2 cells on intracellular pH and on chloride uptake by anion antiport

The effect of K+ depletion of Hep 2 cells on ion fluxes, internal pH, cell volume, and membrane potential was studied. The cells were depleted of K+ by incubation in K+-free buffer with or without a preceding exposure to hypotonic medium. Efflux of K+ in cells not exposed to hypotonic medium was inhibited by furosemide or by incubation in Na+-free medium, indicating that in this case at least part of the K+ efflux occurs by Na+/K+/Cl- cotransport. After exposure to hypotonic medium, K+ efflux was not inhibited by furosemide, whereas it was partly inhibited by 4,4'-diisothiocyano-2,2'-stilbene-disulfonic acid (DIDS). Exposure to hypotonic medium induced acidification of the cytosol, apparently because of efflux of protons from intracellular acidic vesicles. When isotonicity was restored, a rebound alkalinization of the cytosol was induced, because of activation of the Na+/H+ antiporter. While hypotonic shock and a subsequent incubation in K+-free buffer rapidly depolarized the cells, depolarization occurred much more slowly when the K+ depletion was carried out by incubation in K+-free buffer alone. The cell volume was reduced in both cases. K+ depletion by either method strongly reduced the ability of the cells to accumulate 36Cl- by anion antiport, and K+-depleted cells were unable to increase the rate of 36Cl- uptake in response to alkalinization of the cytosol.     

Osmolytes and Mechanisms Involved in Regulatory Volume Decrease Under Conditions of Sudden or Gradual Osmolarity Decrease

A decrease in external osmolarity results in cell swelling and the immediate activation of a mechanism to restore cell volume, known as regulatory volume decrease (RVD). When exposed to a gradual osmolarity decrease (GODE), some cells do not swell. This reflects the operation of an active regulatory process known as isovolumetric regulation (IVR). The mechanisms underlying IVR appear similar to those activated during RVD, namely the extrusion of K+, Cl-, amino acids, and other organic molecules. A previous study has documented IVR in cerebellar granule neurons, parallel to an early efflux of taurine and Cl-, whereas K+ efflux is delayed. In this work we briefly review the importance of amino acids in the mechanisms of cell volume control in the brain, with emphasis on IVR. We also present experiments showing the response to GODE in cerebellar astrocytes. The currents activated during GODE, recorded in the whole-cell configuration of the patch clamp technique, indicate the early activation of an anion current, followed by a more delayed cation current. A correlation between the time course of amino acid efflux during GODE and the occurrence or not of IVR in various cell types, suggest the importance of these osmolytes in the volume regulatory process in this model.     

Hypotonic shock activated Cl- and K+ pathways in human fibroblasts.

The exposure of human fibroblasts to hypotonic medium (200 mosmolal) evoked the activation of both 36Cl- influx and efflux, which were insensitive to inhibitors of the anion exchanger and of the anion/cation cotransport, and conversely were inhibited by the Cl(-)-channel blocker 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB). 36Cl- efflux was linked to a parallel efflux of 86Rb+; thus conductive K+ and Cl- pathways are activated during volume regulation in human fibroblasts. This conclusion is supported by evidence that, in hypotonic medium, 36Cl- influx and 86Rb+ efflux were both enhanced by depolarization of the plasma membrane. Depletion of the intracellular K+ content, obtained by preincubation with the ionophore gramicidin in Na(+)-free medium, had no effect on Cl- efflux in hypotonic medium. This result has been interpreted as evidence for independent activation of K+ and Cl- pathways. It is also concluded that the anion permeability is the rate-limiting factor in the response of human fibroblasts to hypotonic stress.     

Effects of hypo-osmotic stress on ATP release in isolated turbot (Scophthalmus maximus) hepatocytes

BACKGROUND INFORMATION: ATP is released from many cell types exposed to hypo-osmotic shock and is involved in RVD (regulatory volume decrease). Purinergic signalling events have been extensively investigated in mammals, but not in marine teleosteans. RESULTS: The effect of hypo-osmotic shock on ATP release was examined in isolated hepatocytes from turbot (Scophthalmus maximus), a marine flatfish. Hypo-osmotic stress (240 mOsm x kg(-1)) induced a significant increase in ATP efflux, and was inhibited by a potential CFTR (cystic fibrosis transmembrane conductance regulator) inhibitor, glibenclamide, but not by the MDR1 (multidrug resistance 1) P-glycoprotein inhibitor, verapamil. ATP efflux could be a cAMP-dependent process, as IBMX (isobutylmethylxanthine) and forskolin triggered the process under iso-osmotic conditions. Protein kinases, including protein kinase C, could also be involved, as staurosporine and chelerythrine inhibited the mechanism. Calcium could contribute to ATP efflux as ionomycin, a calcium ionophore, elicited a rapid release under iso-osmotic conditions, and chelation using EGTA abolished ATP release under hypo-osmotic conditions. RVD was partially abolished by apyrase, an ATP scavenger, and suramin, a purinoceptor antagonist. Moreover, hypo-osmotic shock induced a rise in intracellular calcium which could be involved in RVD. Since extracellular ATP triggered an increase in cellular free-calcium content under iso-osmotic conditions, our results could indicate that hypo-osmotic-induced ATP efflux contributes to RVD in turbot hepatocytes by stimulating purinergic receptors, which may lead to activation of a calcium signalling pathway. CONCLUSIONS: These data provide the first evidence of volume-sensitive ATP signalling for volume maintenance in a marine teleost fish cell type.     

Ionic events during the volume response of human peripheral blood lymphocytes to hypotonic media. II. Volume- and time-dependent activation and inactivation of ion transport pathways

Hypotonic dilution of human peripheral blood lymphocytes (PBL) induces large conductive permeabilities for K+ and Cl-, associated with the capacity of the cells to regulate their volumes. When rapid cation leakage is assured by the addition of the ionophore gramicidin, the behavior of the anion conductance pathway can be independently examined. Using this technique it is demonstrated that the volume- induced activation of Cl- transport is triggered at a threshold of approximately 1.15 X isotonic cell volume. If the volume of a cell is increased to this level or above, the Cl- transport system is activated, whereas if the volume of a swollen cell is decreased below the threshold value, the Cl- transport is inactivated. Activation and inactivation are independent of the relative volume changes and of the actual cellular Na+, K+, or Cl- concentrations, as well as of the changes in membrane potential in PBL. When net salt movement and thus volume change are inhibited by specific blockers of K+ transport (e.g., quinine, or Ca2+ depletion), volume-induced Cl- conductance shows a time-dependent inactivation, with a half-time of 5-8 min. The Cl- conductance, when activated, appears to involve an all-or-none response. In contrast, volume-induced K+ conductance is a graded response, with the increase in K+ flux being roughly proportional to the hypotonicity-induced increase in cell volume. The data indicate that during lymphocyte volume response in hypotonic media, anion conductance increases by orders of magnitude, exceeding the K+ conductance, so that the rate of the volume decrease (KCl efflux) is determined by a graded alteration in K+ conductance. When the cell volume approaches the isotonic value, it is stabilized by the inactivation of the anion conductance pathway.     

Characterization of volume-sensitive, calcium-permeating pathways in the osteosarcoma cell line UMR-106-01

Measurements of cell volume changes, free cytosolic Ca2+ concentration [( Ca2+]i) with Fura 2 and cell membrane potential with 3,3'-dipropylthiodicarbocyanine iodide were used to study the effect of cell volume change on Ca2+ influx and the membrane potential of the osteoblastic osteosarcoma cell line, UMR-106-01. Swelling the cells by hypo-osmotic stress was followed by reduction in cell volume which was markedly impaired by removal of medium Ca2+. Accordingly, cell swelling resulted in [Ca2+]i increase only in the presence of medium Ca2+. The cell swelling-activated Ca2+ entry pathway was active at resting membrane potentials, and Ca2+ influx through this pathway markedly increased upon cell hyperpolarization. A linear relationship between Ca2+ entry and the potential across the plasma membrane was observed. Thus, the volume-activated Ca2+ permeating pathway in UMR-106-01 cells has conductive properties. These pathways do not spontaneously inactivate with time when the cells are not allowed to volume regulate. The pathway can be blocked by micromolar concentrations of nicardipine and La3+ but display very low sensitivity to diltiazem and verapamil. Activation of the volume-sensitive, Ca2+ permeating pathway was not dependent on an increase in [Ca2+]i. Likewise, activation of the pathway was independent of a change in membrane potential between -85 and -3 mV. The increase in [Ca2+]i resulted in hyperpolarization of the cells, probably due to activation of Ca2+-activated K+ channels. The volume-sensitive pathways were partially active under isotonic conditions. Their activity was inhibited by cell shrinkage and increased by cell swelling. The pathways were sensitive to small changes in cell volume, particularly around a medium osmolarity of 310 mosM.     

Kinetic dissection of two distinct proton binding sites in Na+/H+ exchangers by measurement of reverse mode reaction

We examined the effect of intracellular acidification on the reverse mode of Na+/H+ exchange by measuring 22Na+ efflux from 22Na+-loaded PS120 cells expressing the Na+/H+ exchanger (NHE) isoforms NHE1, NHE2, and NHE3. The 5-(N-ethyl-N-isopropyl)amiloride (EIPA)- or amiloride-sensitive fraction of 22Na+ efflux was dramatically accelerated by cytosolic acidification as opposed to thermodynamic prediction, supporting the concept that these NHE isoforms are activated by protonation of an internal binding site(s) distinct from the H+ transport site. Intracellular pH (pHi) dependence of 22 Na+ efflux roughly exhibited a bell-shaped profile; mild acidification from pHi 7.5 to 7 dramatically accelerated 22Na+ efflux, whereas acidification from pHi 6.6 gradually decreased it. Alkalinization above pHi 7.5 completely suppressed EIPA-sensitive 22Na+ efflux. Cell ATP depletion and mutation of NHE1 at Arg440 (R440D) caused a large acidic shift of the pHi profile for 22Na+ efflux, whereas mutation at Gly455 (G455Q) caused a significant alkaline shift. Because these mutations and ATP depletion cause correspondingly similar effects on the forward mode of Na+/H+ exchange, it is most likely that they alter exchange activity by modulating affinity of the internal modifier site for protons. The data provide substantial evidence that a proton modifier site(s) distinct from the transport site controls activities of at least three NHE isoforms through cooperative interaction with multiple protons.     

Regulatory volume decrease in alveolar macrophages: cation loss is not correlated with changes in membrane recycling

Alveolar macrophages regain their normal volume after swelling in hypo-osmotic solutions. This process, termed regulatory volume decrease (RVD), is initiated 3-5 minutes after exposure of cells to hypo-osmotic solutions, and by 30 min, near-normal volumes are attained. Volume decrease does not occur at 0 degrees C or in solutions in which Na+ has been replaced by K+, or Cl- by the impermeant anion gluconate. These results, as well as direct measurement of intracellular cations, indicate that decreases in cell volume result primarily from the loss of K+ and Cl- and are similar to RVD in lymphocytes. Kinetic analysis of cation loss, both by directly measuring changes in intracellular cation content and by assaying rubidium efflux, showed that cation loss occurred immediately upon media dilution. The rate of cation loss fit first-order kinetics and preceded both the initiation of volume decrease and the maximum increase in surface receptor number. These results suggest that the cation transporters responsible for RVD are located at the cell surface and that regulation of activity is not dependent on alterations in membrane movement.     

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.     

Volume-induced increase of anion permeability in human lymphocytes

Peripheral blood mononuclear cells (PBM) readjust their volumes after swelling in hypotonic media. This regulatory volume decrease (RVD) is associated with a loss of cellular K+ and is thought to be promoted by an increased permeability to this ion. In contrast, no change in volume was observed when K+ permeability of PBM in isotonic media was increased to comparable or higher levels using valinomycin. Moreover, valinomycin-induced 86Rb+ loss in K+-free medium was considerably slower than in K+-rich medium. These results suggest that anion conductance limits net salt loss in isotonic media. Direct measurements of relative conductance confirmed that in volume-static cells, anion conductance is lower than that of K+. In volume-regulating cells depolarization occurred presumably as a result of increased anion conductance. Accordingly, the efflux of 36Cl from PBM was markedly increased by hypotonic stress. Since both membrane potential and intracellular 36Cl concentration are reduced in hypotonically swollen cells, the increased efflux is probably due to a change in Cl- permeability. Anions and cations seem to move independently through the volume-induced pathways: the initial rate of 86Rb uptake in swollen cells was not affected by replacement of external Cl- by SO=4; conversely, 36Cl fluxes were unaffected by substitution of K+ by Na+. The data indicate that anion conductance is rate-determining in salt and water loss from PBM. An increase in anion conductance is suggested to be the critical step of RVD of human PBM.     

Regulatory interaction of ATP Na+ and Cl- in the turnover cycle of the NaK2Cl cotransporter

To probe the mechanism by which intracellular ATP, Na+, and Cl- influence the activity of the NaK2Cl cotransporter, we measured bumetanide-sensitive (BS) 86Rb fluxes in the osteosarcoma cell line UMR- 106-01. Under physiological gradients of Na+, K+, and Cl-, depleting cellular ATP by incubation with deoxyglucose and antimycin A (DOG/AA) for 20 min at 37 degrees C reduced BS 86Rb uptake from 6 to 1 nmol/mg protein per min. Similar incubation with 0.5 mM ouabain to inhibit the Na+ pump had no effect on the uptake, excluding the possibility that DOG/AA inhibited the uptake by modifying the cellular Na+ and K+ gradients. Loading the cells with Na+ and depleting them of K+ by a 2-3- h incubation with ouabain or DOG/AA increased the rate of BS 86Rb uptake to approximately 12 nmol/mg protein per min. The unidirectional BS 86Rb influx into control cells was approximately 10 times faster than the unidirectional BS 86Rb efflux. On the other hand, at steady state the unidirectional BS 86Rb influx and efflux in ouabain-treated cells were similar, suggesting that most of the BS 86Rb uptake into the ouabain-treated cells is due to K+/K+ exchange. The entire BS 86Rb uptake into ouabain-treated cells was insensitive to depletion of cellular ATP. However, the influx could be converted to ATP-sensitive influx by reducing cellular Cl- and/or Na+ in ouabain-treated cells to impose conditions for net uptake of the ions. The BS 86Rb uptake in ouabain-treated cells required the presence of Na+, K+, and Cl- in the extracellular medium. Thus, loading the cells with Na+ induced rapid 86Rb (K+) influx and efflux which, unlike net uptake, were insensitive to cellular ATP. Therefore, we suggest that ATP regulates a step in the turnover cycle of the cotransporter that is required for net but not K+/K+ exchange fluxes. Depleting control cells of Cl- increased BS 86Rb uptake from medium-containing physiological Na+ and K+ concentrations from 6 to approximately 15 nmol/mg protein per min. The uptake was blocked by depletion of cellular ATP with DOG/AA and required the presence of all three ions in the external medium. Thus, intracellular Cl- appears to influence net uptake by the cotransporter. Depletion of intracellular Na+ was as effective as depletion of Cl- in stimulating BS 86Rb uptake.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of separate K+ and Cl- channels and of Na+/Cl- cotransport in volume regulation in Ehrlich cells

Cells resuspended in hypotonic medium initially swell as nearly perfect osmometers, but later recover their volume with an associated KCl loss. This regulatory volume decrease (RVD) is unaffected when nitrate is substituted for Cl- or if bumetanide or 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) is added. It is inhibited by quinine, Ba2+, low pH, anticalmodulin drugs, and depletion of intracellular Ca2+. It is accelerated by the Ca2+ ionophore A23187, or by a sudden increase in external Ca2+ and at high pH. A net KCl loss is also seen after addition of ionophore A23187 in isotonic medium. Similarities are demonstrated between the KCl loss seen after addition of A23187 and the KCl loss seen during RVD. It is proposed that separate conductive K+ and Cl- channels are activated during RVD by release of Ca2+ from internal stores, and that the effect is mediated by calmodulin. After restoration of tonicity the cells shrink initially, but recover their volume with an associated KCl uptake. This regulatory volume increase (RVI) is inhibited when NO3- is substituted for Cl-, and is also inhibited by furosemide or bumetanide, but it is unaffected by DIDS. The unidirectional Cl-flux ratio is compatible with either a coupled uptake of Na+ and Cl-, or an uptake via a K+/Na+/2Cl- cotransport system. No K+ uptake was found, however, in ouabain-poisoned cells where a bumetanide-sensitive uptake of Na+ and Cl- in nearly equimolar amounts was demonstrated. Therefore, it is proposed that the primary process during RVI is an activation of an otherwise quiescent Na+/Cl- cotransport system with subsequent replacement of Na+ by K+ via the Na+/K+ pump. There is a marked increase in the rate of pump activity in the absence of a detectable increase in intracellular Na+ concentration.     

Cell volume regulation in nonrenal epithelia

Cell volume regulation occurs in both tight, Na+-transporting epithelia (e.g., frog skin) and in leaky. NaCl-transporting epithelia (e.g. amphibian gallbladder). In tight epithelia volume regulation occurs only in response to cell swelling, i.e. only regulatory volume decrease (RVD) is observed, whereas in leaky epithelia cell volume regulation has been observed in response to osmotic challenges that either swell or shrink the cells. In other words, both RVD and regulatory volume increase (RVI) are present. Both volume regulatory responses involve stimulation of ion transport in a polarized fashion: in RVD the response is basolateral KCl efflux, whereas in RVI it is apical membrane NaCl uptake. The loss of KCl during RVD appears to result in most instances from increases in basolateral electrodiffusive K+ and Cl-permeabilities. In gallbladder, concomitant activation of coupled KCl efflux may also occur. The RVI response includes activation of apical membrane cation (Na+/H+) and anion (Cl-/HCO-3) exchangers. It is presently unclear whether the net ion fluxes resulting from activation of these transporters, during either RVD or RVI, account for the measured rates of restoration of cell volume. In gallbladder epithelium, RVD is inhibited by agents which disrupt microfilaments or interfere with the Ca2+-calmodulin system. These pharmacologic effects are absent in RVI. Some steps in the chain of events resulting in either RVI or RVD have been established, but the signals involved remain largely unknown. There is reason to suspect a role of intracellular pH in the case of RVI and of membrane insertion of transporters in the case of RVD, possibly with causal roles of both intracellular Ca2+ and the cytoskeleton in the latter.     

Swelling-activated K+ efflux and regulatory volume decrease efficiency in human bronchial epithelial cells

This study describes the correlation between cell swelling-induced K+ efflux and volume regulation efficiency evaluated with agents known to modulate ion channel activity and/or intracellular signaling processes in a human bronchial epithelial cell line, 16HBE14o(-1). Cells on permeable filter supports, differentiated into polarized monolayers, were monitored continuously at room temperature for changes in cell height (T(c)), as an index of cell volume, whereas (86)Rb efflux was assessed for K+ channel activity. The sudden reduction in osmolality of both the apical and basolateral perfusates (from 290 to 170 mosmol/kg H(2)O) evoked a rapid increase in cell volume by 35%. Subsequently, the regulatory volume decrease (RVD) restored cell volume almost completely (to 94% of the isosmotic value). The basolateral (86)Rb efflux markedly increased during the hyposmotic shock, from 0.50 +/- 0.03 min(-1) to a peak value of 6.32 +/- 0.07 min(-1), while apical (86)Rb efflux was negligible. Channel blockers, such as GdCl(3) (0.5 mM), quinine (0.5 mM) and 5-nitro-2-(3-phenyl-propylamino) benzoic acid (NPPB, 100 microM), abolished the RVD. The protein tyrosine kinase inhibitors tyrphostin 23 (100 microM) and genistein (150 microM) attenuated the RVD. All agents decreased variably the hyposmosis-induced elevation in (86)Rb efflux, whereas NPPB induced a complete block, suggesting a link between basolateral K(+) and Cl(-1) efflux. Forskolin-mediated activation of adenylyl cyclase stimulated the RVD with a concomitant increase in basolateral (86)Rb efflux. These data suggest that the basolateral extrusion of K+ and Cl(-1) from 16HBE14o(-1) cells in response to cell swelling determines RVD efficiency.     

Involvements of the ABC protein ABCF2 and α-actinin-4 in regulation of cell volume and anion channels in human epithelial cells

After osmotic swelling, cell volume is regulated by a process called regulatory volume decrease (RVD). Although actin cytoskeletons are known to play a regulatory role in RVD, it is not clear how actin‐binding proteins are involved in the RVD process. In the present study, an involvement of an actin‐binding protein, α‐actinin‐4 (ACTN4), in RVD was examined in human epithelial HEK293T cells. Overexpression of ACTN4 significantly facilitated RVD, whereas siRNA‐mediated downregulation of endogenous ACTN4 suppressed RVD. When the cells were subjected to hypotonic stress, the content of ACTN4 increased in a 100,000 × g pellet, which was sensitive to cytochalasin D pretreatment. Protein overlay assays revealed that ABCF2, a cytosolic member of the ABC transporter superfamily, is a binding partner of ACTN4. The ACTN4‐ABCF2 interaction was markedly enhanced by hypotonic stimulation and required the NH₂‐terminal region of ABCF2. Overexpression of ABCF2 suppressed RVD, whereas downregulation of ABCF2 facilitated RVD. We then tested whether ABCF2 has a suppressive effect on the activity of volume‐sensitive outwardly rectifying anion channel (VSOR), which is known to mediate Cl^? efflux involved in RVD, because another ABC transporter member, CFTR, was shown to suppress VSOR activity. Whole‐cell VSOR currents were largely reduced by overexpression of ABCF2 and markedly enhanced by siRNA‐mediated depletion of ABCF2. Thus, the present study indicates that ACTN4 acts as an enhancer of RVD, whereas ABCF2 acts as a suppressor of VSOR and RVD, and suggests that a swelling‐induced interaction between ACTN4 and ABCF2 prevents ABCF2 from suppressing VSOR activity in the human epithelial cells. J. Cell. Physiol. 227: 3498–3510, 2012. © 2012 Wiley Periodicals, Inc.     

Roles of volume-activated Cl- currents and regulatory volume decrease in the cell cycle and proliferation in nasopharyngeal carcinoma cells

OBJECTIVES: Previously it has been shown, that the volume-activated plasma membrane chloride channel is associated with regulatory volume decrease (RVD) of cells and may play an important role in control of cell proliferation. We have demonstrated that both expression of the channel and RVD capacity are actively regulated in the cell cycle. In this study, we aimed to further study the role of the volume-activated chloride current and RVD in cell cycle progression and overall in cell proliferation. MATERIALS AND METHODS: Whole-cell currents, RVD, cell cycle distribution, cell proliferation and cell viability were measured or detected with the patch-clamp technique, the cell image analysis technique, flow cytometry, the MTT assay and the trypan blue assay respectively, in nasopharyngeal carcinoma cells (CNE-2Z cells). RESULTS: The Cl- channel blockers, 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB) and tamoxifen, inhibit the volume-activated chloride current, RVD and proliferation of CNE-2Z cells in a dose-dependent manner. Analysis of relationships between the current, RVD and cell proliferation showed that both the current and RVD were positively correlated with cell proliferation. NPPB (100 microM) and tamoxifen (20 microM) did not significantly induce cell death, but inhibited cell proliferation, implying that the blockers may inhibit cell proliferation by affecting cell cycle progression. This was verified by the observation that tamoxifen (20 microM) and NPPB (100 microM) inhibited cell cycle progress and arrested cells at the G0/G1 phase boundary. CONCLUSIONS: Activity of the volume-activated chloride channel is one of the important factors that regulate the passage of cells through the G1 restriction point and that the Cl- current associated with RVD plays an important role in cell proliferation.