Separate,Ca2+-activated K+ and Cl− transport pathways in Ehrlich ascites tumor cells

Summary The net loss of KCl observed in Ehrlich ascites cells during regulatory volume decrease (RVD) following hypotonic exposure involves activation of separate conductive K⁺ and Cl^– transport pathways. RVD is accelerated when a parallel K⁺ transport pathway is provided by addition of gramicidin, indicating that the K⁺ conductance is rate limiting. Addition of ionophore A23187 plus Ca²⁺ also activates separate K⁺ and Cl^– transport pathways, resulting in a hyperpolarization of the cell membrane. A calculation shows that the K⁺ and Cl^– conductance is increased 14-and 10-fold, respectively. Gramicidin fails to accelerate the A23187-induced cell shrinkage, indicating that the Cl^– conductance is rate limiting. An A23187-induced activation of⁴²K and³⁶Cl tracer fluxes is directly demonstrated. RVD and the A23187-induced cell shrinkage both are: (i) inhibited by quinine which blocks the Ca²⁺-activated K⁺ channel. (ii) unaffected by substitution of NO ₃ ^– or SCN^– for Cl^–, and (iii) inhibited by the anti-calmodulin drug pimozide. When the K⁺ channel is blocked by quinine but bypassed by addition of gramicidin, the rate of cell shrinkage can be used to monitor the Cl^– conductance. The Cl^– conductance is increased about 60-fold during RVD. The volume-induced activation of the Cl^– transport pathway is transient, with inactivation within about 10 min. The activation induced by ionophore A23187 in Ca²⁺-free media (probably by release of Ca²⁺ from internal stores) is also transient, whereas the activation is persistent in Ca²⁺-containing media. In the latter case, addition of excess EGTA is followed by inactivation of the Cl^– transport pathway. These findings suggest that a transient increase in free cytosolic Ca²⁺ may account for the transient activation of the Cl^– transport pathway. The activated anion transport pathway is unselective, carrying both Cl^–, Br^–, NO ₃ ^– , and SCN^–. The anti-calmodulin drug pimozide blocks the volume- or A23187-induced Cl^– transport pathway and also blocks the activation of the K⁺ transport pathway. This is demonstrated directly by⁴²K flux experiments and indirectly in media where the dominating anion (SCN^–) has a high ground permeability. A comparison of the A23187-induced K⁺ conductance estimated from⁴²K flux measurements at high external K⁺, and from net K^– flux measurements suggests single-file behavior of the Ca²⁺-activated K⁺ channel. The number of Ca²⁺-activated K⁺ channels is estimated at about 100 per cell.     

Different physiological mechanisms control isovolumetric regulation and regulatory volume decrease in chick embryo cardiomyocytes

Cultured chick embryo cardiac myocytes submitted to a 180 mOsm/kg hyposmotic solution swell present a regulatory volume decrease (RVD). This RVD is mediated by a Ca(2+)influx followed by a 40% loss of total taurine content accompanied by the loss of lesser amounts of other osmolytes. Kidney cells respond to a gradual change in osmolality by maintaining their volume at the initial level. This is termed isovolumetric regulation (IVR), which may activate regulatory processes other than those observed with sudden changes in osmolality. When cardiac myocytes were exposed to a gradual change in osmolality, they show a partial IVR which is not dependent upon extracellular Ca(2+). Potassium channel blockers, quinidine and Ba(2+), and the chloride channel blocker, diphenylamine-2-carboxylate (DPC), compromise IVR in our model. Tritiated taurine loss and total intracellular K(+)contents were analyzed in cultured cardiomyocytes submitted to a gradual change in osmolality. The cultured cells lost approximately 10% of their taurine and 35% of their total K(+). These findings suggest that different compensatory mechanisms are activated when cells are exposed to stepwise and gradual changes in osmolality. Inorganic osmolytes (through conductive pathways) are preferentially mobilized during the physiological and/or patho-physiological IVR situation, perhaps reflecting energetic conservation in response to a less traumatic event for the cardiac myocytes.     

Fluoxetine Inhibits K+ Transport Pathways (K+ Efflux, Na+-K+-2Cl− Cotransport, and Na+ Pump) Underlying Volume Regulation in Corneal Endothelial Cells

We have studied regulatory volume responses of cultured bovine corneal endothelial cells (CBCEC) using light scattering. We assessed the contributions of fluoxetine (Prozac) and bumetanide-sensitive membrane ion transport pathways to such responses by determining K⁺ efflux and influx. Cells swollen by a 20% hypo-osmotic solution underwent a regulatory volume decrease (RVD) response, which after 6 min restored relative cell volume by 98%. Fluoxetine inhibited RVD recovery; 20 μm by 26%, and 50 μm totally. Fluoxetine had a triphasic effect on K⁺ efflux; from 20 to 100 μm it inhibited efflux 2-fold, whereas at higher concentrations the efflux first increased to 1.5-fold above the control value, and then decreased again. Cells shrunk by a 20% hyperosmotic solution underwent a regulatory volume increase (RVI) which also after 6 min restored the cell volume by 99%. Fluoxetine inhibited RVI; 20 μm by 25%, and 50 μm completely. Bumetanide (1 μm) inhibited RVI by 43%. In a Cl⁻-free medium, fluoxetine (50–500 μm) progressively inhibited bumetanide-insensitive K⁺ influx. The inhibitions of RVI and K⁺ influx induced by fluoxetine 20 to 50 μm were similar to those induced by 1 μm bumetanide and by Cl⁻-free medium. A computer simulation suggests that fluoxetine can interact with the selectivity filter of K⁺ channels. The data suggest that CBCEC can mediate RVD and RVI in part through increases in K⁺ efflux and Na-K-2Cl cotransport (NKCC) activity. Interestingly, the data also suggest that fluoxetine at 20 to 50 μm inhibits NKCC, and at 100–1000 μm inhibits the Na⁺ pump. One possible explanation for these findings is that fluoxetine could interact with K⁺-selective sites in K⁺ channels, the NKC cotransporter and the Na⁺ pump.     

Regulatory volume decrease in cardiomyocytes is modulated by calcium influx and reactive oxygen species

We investigated the role of Ca²⁺ in generating reactive oxygen species (ROS) induced by hyposmotic stress (Hypo) and its relationship to regulatory volume decrease (RVD) in cardiomyocytes. Hypo-induced increases in cytoplasmic and mitochondrial Ca²⁺. Nifedipine (Nife) inhibited both Hypo-induced Ca²⁺ and ROS increases. Overexpression of catalase (CAT) induced RVD and a decrease in Hypo-induced blebs. Nife prevented CAT-dependent RVD activation. These results show a dual role of Hypo-induced Ca²⁺ influx in the control of cardiomyocyte viability. Hypo-induced an intracellular Ca²⁺ increase which activated RVD and inhibited necrotic blebbing thus favoring cell survival, while simultaneously increasing ROS generation, which in turn inhibited RVD and induced necrosis.     

Mechanisms of cell volume regulation in the proximal segment of the Malpighian tubule of Rhodnius neglectus

The cell volume regulation of the lower segment cells of the Malpighian tubule of Rhodnius neglectus in anisosmotic media was evaluated by using videooptic techniques. When the medium osmolality was increased with addition of 100 mm mannitol the cells shrank to a minimum of 16.84±2.62% and subsequently swelled towards their initial volume undergoing a typical regulatory volume increase (RVI). Replacement of either K⁺ or Cl^? or HCO ₃ ^? by Na⁺, gluconate and phosphate, respectively, abolished the RVI response. Furthermore, the substitution of Na⁺ by tetramethylammonium (TMA⁺) in isosmotic conditions led to cellular swelling and death. Addition of either amiloride 10^?4 m, anthracene-9-COOH 5×10^?4 m, furosemide 5×10^?4 m or ethacrynic acid 5×10^?5 m, also abolished RVI. On the other hand, addition of either Ba²⁺ 10^?3 m, SITS 5× 10^?4 m, ouabain 10^?3 m or vanadate 10^?3 m, did not change the RVI response. When the tubules were incubated in hyperosmotic media with EGTA 2 mm or verapamil 10^?6 m, the RVI response was abolished. In contrast, a decrease of NaCl concentration from 129 to 79 mm induced a cell swelling to a maximum of 33.11+1.73%, but the cells maintained swollen, only partially regulating their volume. These results show that the proximal cells of Malpighian tubule of R. neglectus are able to regulate their volume in hyperosmotic but only partially regulating in hyposmotic solutions. The mechanisms in RVI involve Na⁺, K⁺, Cl^?, Ca²⁺ and HCO ₃ ^? transport pathways and a ouabain-insensitive ATPase stimulated by Na⁺. This work was supported by grants from the Fundação de Amparo à Pesquisa do Estado de São Paulo—FAPESP; Conselho Nacional de Desenvolvimento Científico e Tecnológico—CNPq e Financiadora de Projetos e Pesquisas-FINEP.     

Protein kinase C-independent correlation between P-glycoprotein expression and volume sensitivity of Cl− channel

The possible correlation between P-glycoprotein (PGP) and volume-sensitive Cl⁻ channel was examined in a pair of cell lines: a subline of the human epidermoid KB cell (KB-3-1) and the corresponding MDR1-transfected cell line (KB-G2). Western blot analysis and indirect immunofluorescence studies indicated that KB-G2, but not KB-3-1, exhibits the PGP expression. Patch-clamp whole-cell recordings showed that osmotic swelling activates Cl⁻ currents not only in PGP-expressing but also in PGP-lacking cells. The amplitude of the maximal current was indistinguishable between both cells. Activation of protein kinase C (PKC) or loading with a PKC inhibitor failed to affect the swelling-induced activation of the Cl⁻ currents in both cells. The relation between whole-cell Cl⁻ currents and cell size measured simultaneously showed that volume sensitivity of the Cl⁻ channel was augmented by the PGP expression irrespective of the activity of PKC on the plasma membrane. A similar increase in volume sensitivity of the Cl⁻ channel was also induced by the expression of the ATP hydrolysis-deficient PGP mutant, K433M. We conclude that P-glycoprotein does not represent the volume-sensitive Cl⁻ channel but that its expression modulates volume sensitivity of the Cl⁻ channel in a manner independent of its ATPase activity or of the protein kinase C activity. Received: 25 September 1996/Revised: 12 December 1996     

The role of swelling-induced anion channels during neuronal volume regulation

Regulation of cell volume is an essential function of most mammalian cells. In the cells of the central nervous system, maintenance of cell osmolarity and, hence, volume, is particularly crucial because of the restrictive nature of the skull. Cell volume regulation involves a variety of pathways, with considerable differences between cell types. One common pathway activated during hypo-osmotic stress involves chloride (Cl⁻) channels. However, hypo-osmotically stimulated anion permeability can be regulated by a diverse array of second messengers. Although neuronal swelling can occur in a number of pathological and nonpathological conditions, our understanding of neuronal volume regulation is limited. This article summarizes our current understanding of the role of anion channels during neuronal volume regulation.     

Ca2+/Calmodulin Kinase II and Decreases in Intracellular pH are Required to Activate K+ Channels After Substantial Swelling in Villus Epithelial Cells

To assess the activation of the charybdotoxin-insensitive K⁺ channel responsible for Regulatory Volume Decrease (RVD) after substantial volume increases, we measured intracellular pH (pH _i ), intracellular calcium ([Ca²⁺] _i ) and inhibitors of kinases and phosphoprotein phosphatases in guinea pig jejunal villus enterocytes in response to volume changes. Fluorescence spectroscopy was used to measure pH _i and [Ca²⁺] _i of cells in suspension, loaded with 2,7,bis-carboxyethyl-5-6-carboxyfluorescein and Indo-1, respectively, and cell volume was assessed using electronic cell sizing. A modest 7% volume increase or substantial 15 to 20% volume increase caused [Ca²⁺] _i to increase proportionately but the 7% increase caused alkalinization while the larger increases resulted in acidification of ≃0.14 pH units. Following a 15% volume increase, 1-N-0-bis (5-isoquinoline-sulfonyl)-N-methyl-l-4-phenyl-piperazine (KN-62, 50 μm), an inhibitor of Ca²⁺/calmodulin kinase II, blocked RVD. Gramicidin (0.5 μm) bypassed this inhibition suggesting that the K⁺ channel had been affected by the KN-62. RVD after a modest 7% volume increase was not influenced by KN-62 unless the cell was acidified. Okadaic acid, an inhibitor of phosphoprotein phosphatases 1 and 2A, accelerated RVD after a 20% volume increase; inhibition of RVD generated by increasing the K⁺ gradient was bypassed by okadaic acid. Tyrosine kinase inhibitor, genistein (100 μm) had no effect on RVD after 20% volume increases. We conclude that activation of charybdotoxin-insensitive K⁺ channels utilized for RVD after substantial (>7%) `nonphysiological' volume increases requires phosphorylation mediated by Ca²⁺/calmodulin kinase II and that increases in cytosolic acidification rather than larger increases in [Ca²⁺] _i are a critical determinant of this activation. Received: 30 March 1999/Revised: 6 July 1999     

A contractile vacuole complex is involved in osmoregulation in Trypanosoma cruzi

Acidocalcisomes are dense, acidic organelles with a high concentration of phosphorus present as pyrophosphate and polyphosphate complexed with calcium and other cations. Acidocalcisomes have been linked to the contractile vacuole complex in Chlamydomonas reinhardtii, Dictyostelium discoideum, and Trypanosoma cruzi. A microtubule- and cyclic AMP-mediated fusion of acidocalcisomes to the contractile vacuole complex in T. cruzi results in translocation of aquaporin and the resulting water movement which, in addition to swelling of acidocalcisomes, is responsible for the volume reversal not accounted for by efflux of osmolytes. Polyphosphate hydrolysis occurs during hyposmotic stress, probably increasing the osmotic pressure of the contractile vacuole and facilitating water movement.     

Effects of hyposmotic stress on exocytosis in isolated turbot, Scophthalmus maximus, hepatocytes

The effect of hyposmotic shock on exocytosis was examined in isolated hepatocytes of turbot, a marine flatfish, using the molecular probe FM1-43. Sudden exposure to a reduced osmolality caused an increase in cell exocytic activity related to the osmotic gradient between intra- and extracellular fluids. Cytoskeletal microtubules could contribute to this hyposmotic-induced exocytosis since colchicine inhibited the process. Protein kinase C, phosphatidylinositol-3 kinase, phospholipases A2, C and D could constitute key enzymes in the mechanism since their inhibition by specific agents altered the hyposmotic-induced exocytic activity. Moreover, arachidonic acid and derivates from the 5-lipoxygenase pathway as well as calcium could participate in the process. As regulatory volume decrease (RVD) exhibited by turbot hepatocytes following hyposmotic stimulation involves similar features, a potential role of exocytosis in volume regulation is suggested. In particular, exocytosis could serve RVD by contributing to ATP release since this latter process similarly appeared to be phospholipase D-dependent and related to the osmotic gradient. This study provides the first evidence of a volume-sensitive exocytosis that could aim at volume constancy in a marine teleost fish cell type.