Ionic events during the volume response of human peripheral blood lymphocytes to hypotonic media. I. Distinctions between volume-activated Cl- and K+ conductance pathways

Intercellular water exchanges trigger soliton-like waves in multicellular systems

Oscillations and waves are ubiquitous in living cellular systems. Generations of these spatio-temporal patterns are generally attributed to some mechanochemical feedbacks. Here, we treat cells as open systems, i.e., water and ions can pass through the cell membrane passively or actively, and reveal a new origin of wave generation. We show that osmotic shocks above a shock threshold will trigger self-sustained cell oscillations and result in long-range waves propagating without decrement, a phenomenon that is analogous to the excitable medium. The travelling wave propagates along intercellular osmotic pressure gradient and its wave speed scales with the magnitude of intercellular water flows. Furthermore, we also find that the travelling wave exhibits several hallmarks of solitary waves. Together, our findings predict a new mechanism of wave generation in living multicellular systems. The ubiquity of intercellular water exchanges implies that this mechanism may be relevant to a broad class of systems.

Volume-regulated anion channel--a frenemy within the brain

The volume-regulated anion channel (VRAC) is a ubiquitously expressed yet highly enigmatic member of the superfamily of chloride/anion channels. It is activated by cellular swelling and mediates regulatory cell volume decrease in a majority of vertebrate cells, including those in the central nervous system (CNS). In the brain, besides its crucial role in cellular volume regulation, VRAC is thought to play a part in cell proliferation, apoptosis, migration, and release of physiologically active molecules. Although these roles are not exclusive to the CNS, the relative significance of VRAC in the brain is amplified by several unique aspects of its physiology. One important example is the contribution of VRAC to the release of the excitatory amino acid neurotransmitters glutamate and aspartate. This latter process is thought to have impact on both normal brain functioning (such as astrocyte-neuron signaling) and neuropathology (via promoting the excitotoxic death of neuronal cells in stroke and traumatic brain injury). In spite of much work in the field, the molecular nature of VRAC remained unknown until less than 2 years ago. Two pioneer publications identified VRAC as the heterohexamer formed by the leucine-rich repeat-containing 8 (LRRC8) proteins. These findings galvanized the field and are likely to result in dramatic revisions to our understanding of the place and role of VRAC in the brain, as well as other organs and tissues. The present review briefly recapitulates critical findings in the CNS and focuses on anticipated impact on the LRRC8 discovery on further progress in neuroscience research.

Activation of Na+/H+ and K+/H+ exchange by calyculin A in Amphiuma tridactylum red blood cells: implications for the control of volume-induced ion flux activity

Alteration in cell volume of vertebrates results in activation of volume-sensitive ion flux pathways. Fine control of the activity of these pathways enables cells to regulate volume following osmotic perturbation. Protein phosphorylation and dephosphorylation have been reported to play a crucial role in the control of volume-sensitive ion flux pathways. Exposing Amphiuma tridactylu red blood cells (RBCs) to phorbol esters in isotonic medium results in a simultaneous, dose-dependent activation of both Na(+)/H(+) and K(+)/H(+) exchangers. We tested the hypothesis that in Amphiuma RBCs, both shrinkage-induced Na(+)/H(+) exchange and swelling-induced K(+)/H(+) exchange are activated by phosphorylation-dependent reactions. To this end, we assessed the effect of calyculin A, a phosphatase inhibitor, on the activity of the aforementioned exchangers. We found that exposure of Amphiuma RBCs to calyculin-A in isotonic media results in simultaneous, 1-2 orders of magnitude increase in the activity of both K(+)/H(+) and Na(+)/H(+) exchangers. We also demonstrate that, in isotonic media, calyculin A-dependent increases in net Na(+) uptake and K(+) loss are a direct result of phosphatase inhibition and are not dependent on changes in cell volume. Whereas calyculin A exposure in the absence of volume changes results in stimulation of both the Na(+)/H(+) and K(+)/H(+) exchangers, superimposing cell swelling or shrinkage and calyculin A treatment results in selective activation of K(+)/H(+) or Na(+)/H(+) exchange, respectively. We conclude that kinase-dependent reactions are responsible for Na(+)/H(+) and K(+)/H(+) exchange activity, whereas undefined volume-dependent reactions confer specificity and coordinated control.

Inhibition of the antigen-induced activation of RBL-2H3 cells by charybdotoxin and cetiedil

Quinidine and Ba(2+), non-selective K(+)-channel blockers, have previously been shown to inhibit antigen-induced mediator (beta-hexosaminidase) release from RBL-2H3 cells, a mucosal-type mast cell line. We therefore used selective blockers of Ca(2+)-activated and other K(+) channels to determine if there was a role for these channels in antigen-induced mediator release. Charybdotoxin and cetiedil dose-dependently inhibited beta-hexosaminidase release with IC(50) values of 133 nM and 84 microM, respectively. Charybdotoxin also inhibited the repolarization phase of the antigen-induced biphasic change in the membrane potential (IC(50) 84 nM), antigen-stimulated 86Rb(+)-efflux and increase in free intracellular calcium, [Ca(2+)](i). Iberiotoxin, margatoxin, apamin and tetraethylammonium had no effect on beta-hexosaminidase release. These results suggest that K(+) conductances play a significant role in mediator release from RBL-2H3, that these conductances are of the intermediate conductance Ca(2+)-activated K(+) channel (IK(Ca)) type, and that they are somewhat similar to those which have been described in red blood cells, though they are much less sensitive to clotrimazole.

How external osmolarity affects the activity of the contractile vacuole complex, the cytosolic osmolarity and the water permeability of the plasma membrane in Paramecium multimicronucleatum

The rate of fluid expulsion, R(CVC), from the contractile vacuole complex (CVC) of Paramecium multimicronucleatum was estimated from the volume of the contractile vacuoles (CVs) immediately before the start of fluid discharge and from the time elapsing between discharges. The R(CVC) increased when the cell was exposed to a strongly hypotonic solution and decreased in a weakly hypotonic solution. When the cell was exposed to an isotonic or a hypertonic solution, R(CVC) fell to zero. The time constant, tau, used to describe the change in R(CVC) in response to a change in external osmolarity shortened after a short-term exposure to a strongly hypotonic solution and lengthened after a short-term exposure to a less hypotonic solution. A remarkable lengthening of tau occurred after a short-term exposure to isotonic or hypertonic solution. Under natural conditions, mechanisms for controlling R(CVC) are effective in maintaining the cytosolic osmolarity hypertonic within a narrow concentration range despite changes in the external osmolarity, which is normally hypotonic to the cytosol. Cells exposed to an isotonic or hypertonic solution resumed CV activity when left in the solution for 12 h. The cytosolic osmolarity was found to increase and to remain hypertonic to the external solution. This will permit cells to continue to acquire water. The increase in the cytosolic osmolarity occurred in a stepwise fashion, rather than linearly, as the external osmolarity increased. That is, the cytosolic osmolarity first remained more-or-less constant at an increased level until the external osmolarity exceeded this level. Thereupon, the cytosolic osmolarity increased to a new higher level in 12 h, so that the cytosol again became hypertonic to the external solution and the cells resumed CV activity. These results imply that the cell needs to maintain water segregation activity even after it has been exposed to an isotonic or hypertonic environment. This supports the idea that the CVC might be involved not only in the elimination of excess cytosolic water but also in the excretion of some metabolic waste substances.

Functional significance of cell volume regulatory mechanisms

To survive, cells have to avoid excessive alterations of cell volume that jeopardize structural integrity and constancy of intracellular milieu. The function of cellular proteins seems specifically sensitive to dilution and concentration, determining the extent of macromolecular crowding. Even at constant extracellular osmolarity, volume constancy of any mammalian cell is permanently challenged by transport of osmotically active substances across the cell membrane and formation or disappearance of cellular osmolarity by metabolism. Thus cell volume constancy requires the continued operation of cell volume regulatory mechanisms, including ion transport across the cell membrane as well as accumulation or disposal of organic osmolytes and metabolites. The various cell volume regulatory mechanisms are triggered by a multitude of intracellular signaling events including alterations of cell membrane potential and of intracellular ion composition, various second messenger cascades, phosphorylation of diverse target proteins, and altered gene expression. Hormones and mediators have been shown to exploit the volume regulatory machinery to exert their effects. Thus cell volume may be considered a second message in the transmission of hormonal signals. Accordingly, alterations of cell volume and volume regulatory mechanisms participate in a wide variety of cellular functions including epithelial transport, metabolism, excitation, hormone release, migration, cell proliferation, and cell death.

Volume regulation of spermatozoa by quinine-sensitive channels

Bovine spermatozoa were shown to exhibit rapid regulatory volume decrease (RVD) when exposed to hypotonic saline media. This quinine- and quinidine-sensitive regulatory volume decrease was coincident with K+ release due to stretch-activation of inhibitor-specific presumptive K+ channels. The regulatory volume decrease response was much faster than a similar phenomenon observed in human peripheral blood lymphocytes. Studies on volume changes in different electrolyte and nonelectrolyte media suggested that: (1) this inhibitor-specific channel could also be a nonspecific pore in the spermatozoal membrane for nonelectrolytes below 150 daltons; (2) subpopulations (of nearly equal size) of the spermatozoa differ in the expression of the pore; (3) capacitation abolishes this distinction between subpopulations of spermatozoa; and (4) the general case of RVD for other mammalian spermatozoa was also established.

Membrane mechanisms and intracellular signalling in cell volume regulation

Recent work on selected aspects of the cellular and molecular physiology of cell volume regulation is reviewed. First, the physiological significance of the regulation of cell volume is discussed. Membrane transporters involved in cell volume regulation are reviewed, including volume-sensitive K+ and Cl- channels, K+, Cl- and Na+, K+, 2Cl- cotransporters, and the Na+, H+, Cl-, HCO3-, and K+, H+ exchangers. The role of amino acids, particularly taurine, as cellular osmolytes is discussed. Possible mechanisms by which cells sense their volumes, along with the sensors of these signals, are discussed. The signals are mechanical changes in the membrane and changes in macromolecular crowding. Sensors of these signals include stretch-activated channels, the cytoskeleton, and specific membrane or cytoplasmic enzymes. Mechanisms for transduction of the signal from sensors to transporters are reviewed. These include the Ca(2+)-calmodulin system, phospholipases, polyphosphoinositide metabolism, eicosanoid metabolism, and protein kinases and phosphatases. A detailed model is presented for the swelling-initiated signal transduction pathway in Ehrlich ascites tumor cells. Finally, the coordinated control of volume-regulatory transport processes and changes in the expression of organic osmolyte transporters with long-term adaptation to osmotic stress are reviewed briefly.

The role of sulfhydryl groups in D-aspartate and rubidium release from neonatal rat primary astrocyte cultures

We have recently demonstrated that both methylmercury (MeHg) and mercuric chloride (MC) induce D-aspartate release from neonatal rat primary astrocyte cultures maintained in isotonic conditions. In the present study, we compare several other sulfhydryl-(-SH) selective alkylating reagents [methyl methanethiosulfonate (MMTS), N-ethylmaleimide (NEM), and iodoacetamide (IA)] in isotonic, as well as hypotonic conditions to discern the functional importance of -SH groups in [3H]D-aspartate and 86rubidium (86Rb) release from astrocytes. Treatment of astrocytes (5 min) in isotonic buffer with the hydrophobic reagent NEM (10 microM) caused a marked increase in 86Rb release but had no effect on [3H]D-aspartate release. Neither IA-, nor MMTS-treatment (both at 10 microM) induced increase in [3H]D-aspartate or 86Rb release in isotonic buffer. In hypotonic condition (-50 mM Na+), astrocytes were most sensitive to MC exposure (5 microM), exhibiting an increase in both [3H]D-aspartate and 86Rb efflux. The hydrophobic compounds MMTS and NEM, and the hydrophilic -SH modifying reagent, IA, attenuated the hypotonic-induced efflux of [3H]D-aspartate, in the absence of an effect on 86Rb release. These observations are consistent with a critical role for -SH groups both in basal (i.e. isotonic) and hypotonic-induced release of D-aspartate and Rb from astrocytes. Lack of uniformity of these effects may be attributed to site-specificity, related to the physicochemical properties of these -SH alkylating reagents.

Cell volume regulation in human neutrophils: 2-(aminomethyl)phenols as Cl- channel inhibitors

When subjected to hypotonic stress, human peripheral neutrophils initially swell due to rapid water entry and thereafter recover toward the normal cell size (approximately 330 microns 3). Neutrophils do not behave as perfect osmometers: when resuspended in half-isotonic medium (150 mosM), they swell by only approximately 40% rather than doubling in size as predicted for ideal behavior. As with lymphocytes, restoration to the normal cell size involves the net loss of K+ and Cl- from the cytosol through independent conductance pathways. Volume regulation is sensitive to 0.4-1 mM of quinine, UK-5099, 3,5-diiodosalicylate (DISA), MK-473 (an indanyloxyacetate derivative), and to MK-447 [a 2-(aminomethyl)phenol]. From correlation of drug effects on the time course of cell volume recovery and the associated volume-activated 86Rb+ and 36Cl- fluxes, it was evident that quinine blocked only K+ channels, whereas MK-447 acted as a selective inhibitor of Cl- channels. In contrast, UK-5099, DISA, and MK-473 were nonspecific in that the compounds displayed comparable suppressive effects on all three parameters. Structure-activity relationships in the MK-447 series revealed the critical elements of the molecule responsible for drug potency. In particular, the importance of the neighboring ionizable 1-hydroxyl and 2-aminomethyl groups and the formation of secondary ring structures for biological activity is emphasized. The most potent derivative thus far identified, termed analogue A [inhibitor constant (Ki) approximately 16 microM], had a potency approximately sixfold greater than that of the parent compound (Ki approximately 90 microM). These findings define the mechanism of action of a relatively new class of agents that behave as inhibitors of swelling-activated Cl- channels in these cells.

Rabbit esophageal cells possess K+ channels: effect of hyposmotic stress on channel activity

BACKGROUND

In many cell types, basolateral K+ channels are important in maintaining transepithelial Na+ absorption and regulatory volume decrease (RVD) after hyposmolar stress. However, in the esophagus the effect of K+ transport in maintaining baseline short-circuit current (SCC) (Na+ absorption) and RVD is unknown.

METHODS

Ussing chambers were used to evaluate changes in SCC of rabbit esophageal mucosa in response to serosal Ba2+ (4 mmol/L), quinine (1 mmol/L), and increasing serosal [K+]. To determine whether K+ channel(s) are activated in RVD, changes in SCC in response to serosal hyposmolarity (156 mOsm) were assessed in the presence or absence of serosal quinine.

RESULTS

Serosal Ba2+, quinine, or increased serosal [K+] caused a decline in baseline SCC. Serosal hyposmolarity caused an increase in SCC that was not blocked by mucosal application of amiloride (10(-4) mmol/L). In contrast, serosal quinine completely blocked the hyposmolar-induced increase in SCC.

CONCLUSIONS

These studies suggest that rabbit esophageal cells possess Ba(2+)- and quinine-sensitive basolateral K+ channel(s) that are active under baseline conditions. Potassium conductance(s) also appear to be activated by external serosal hyposmolarity and may be involved in the process of RVD.

A review of the electrophysiological, pharmacological and single channel properties of heart ventricle muscle cells in the snail Lymnaea stagnalis

Although a considerable body of information has accumulated describing the pharmacological properties of a wide range of molluscan muscle types, the physiological bases underlying these properties have not been thoroughly investigated. At present, little is known about the types of ion channels and their regulation in molluscan muscle cell membranes. Voltage-clamp, and more recently, patch-clamp techniques have revealed molluscan muscles possess a complex array of channel types with various pharmacological and electrophysiological properties. The gating properties of these channels and their modulation by chemical agents, however, are still poorly understood. This review summarizes some aspects of molluscan muscle function with particular reference to the heart ventricle muscle of the pond snail, Lymnaea stagnalis.

Volume-dependent regulation of sodium and potassium fluxes in cultured vascular smooth muscle cells: dependence on medium osmolality and regulation by signalling systems

To identify ion transport systems involved in the maintenance of vascular smooth muscle cell volume the effects of incubation medium osmolality and ion transport inhibitors on the volume and 86Rb and 22Na transport in cultured smooth muscle cells from rat aorta (VSMC) have been studied. A decrease of medium osmolality from 605 to 180 mosm increased intracellular water volume from 0.6 to 1.3 microliters per 10(6) cells. Under isosmotic conditions, cell volume was decreased by ouabain (by 10%, P less than 0.005) but was not influenced by bumetanide, furosemide, EIPA and quinidine. These latter compounds were also ineffective in cell volume regulation under hypotonic buffer conditions. Under hyperosmotic conditions, cell volume was decreased by bumetanide (by approximately 7%, P less than 0.05) and by ethylisopropyl amiloride (by approximately 13%, P less than 0.005). Ouabain-sensitive 86Rb influx was decreased by 30-40% under hypoosmotic conditions. An increase in medium osmolality from 275 to 410 mosm resulted in an approximately eightfold increase in bumetanide-inhibited 86Rb influx and 86Rb efflux. The (ouabain and bumetanide)-insensitive component of 86Rb influx was not dependent on the osmolality of the incubation medium. However (ouabain and bumetanide)-insensitive 86Rb efflux was increased by approximately 1.5-2 fold in VSMC incubated in hypotonic medium. Ethylisopropyl amiloride-inhibited 22Na influx was increased by approximately sixfold following osmotic-shrinkage of VSMC. The data show that both Na+/H+ exchange and Na+/K+/2Cl- cotransport may play a major role in the regulatory volume increase in VSMC. Basal and shrinkage-induced activities of Na+/K+/2Cl- cotransport in VSMC were similarly sensitive to inhibition by either staurosporin, forskolin, R24571 or 2-nitro-4-carboxyphenyl N,N-diphenylcarbomate (NCDC). In contrast basal and shrinkage-induced Na+/K+/2Cl- cotransport were differentially inhibited by NaF (by 30 and 65%, respectively), suggesting an involvement of guanine nucleotide binding proteins in the volume-sensitive activity of this carrier. Neither staurosporin, forskolin, R24571 nor NCDC influenced shrinkage-induced Na+/H+ exchange activity. NaF increased Na+/H+ exchanger activity under both isosmotic and hyperosmotic conditions. These data demonstrate that different intracellular signalling mechanisms are involved in the volume-dependent activation of the Na+/K+/2Cl- cotransporter and the Na+/H+ exchanger.

Activation of ion transport pathways by changes in cell volume

Swelling-activated K+ and Cl- channels, which mediate RVD, are found in most cell types. Prominent exceptions to this rule include red cells, which together with some types of epithelia, utilize electroneutral [K(+)-Cl-] cotransport for down-regulation of volume. Shrinkage-activated Na+/H+ exchange and [Na(+)-K(+)-2 Cl-] cotransport mediate RVI in many cell types, although the activation of these systems may require special conditions, such as previous RVD. Swelling-activated K+/H+ exchange and Ca2+/Na+ exchange seem to be restricted to certain species of red cells. Swelling-activated calcium channels, although not carrying sufficient ion flux to contribute to volume changes may play an important role in the activation of transport pathways. In this review of volume-activated ion transport pathways we have concentrated on regulatory phenomena. We have listed known secondary messenger pathways that modulate volume-activated transporters, although the evidence that volume signals are transduced via these systems is preliminary. We have focused on several mechanisms that might function as volume sensors. In our view, the most important candidates for this role are the structures which detect deformation or stretching of the membrane and the skeletal filaments attached to it, and the extraordinary effects that small changes in concentration of cytoplasmic macromolecules may exert on the activities of cytoplasmic and membrane enzymes (macromolecular crowding). It is noteworthy that volume-activated ion transporters are intercalated into the cellular signaling network as receptors, messengers and effectors. Stretch-activated ion channels may serve as receptors for cell volume itself. Cell swelling or shrinkage may serve a messenger function in the communication between opposing surfaces of epithelia, or in the regulation of metabolic pathways in the liver. Finally, these transporters may act as effector systems when they perform regulatory volume increase or decrease. This review discusses several examples in which relatively simple methods of examining volume regulation led to the discovery of transporters ultimately found to play key roles in the transmission of information within the cell. So, why volume? Because it's functionally important, it's relatively cheap (if you happened to have everything else, you only need some distilled water or concentrated salt solution), and since it involves many disciplines of experimental biology, it's fun to do.

Volume regulation in rat pheochromocytoma cultured cells submitted to hypoosmotic conditions

The mechanisms at work in cell volume regulation have been studied in PC12 cultured cells. Results show, for the first time to our knowledge, that the volume readjustment process occurring after application of a hypoosmotic saline is sensitive to amiloride, IBMX and forskoline. The process is also inhibited by quinine hydrochloride and trifluoperazine. Volume readjustment is concomtant with a decrease in K+ and Cl- intracellular levels. The decrease in K+ level can be related to an assymetrical change in the fluxes in and out of the ion as shown by flux kinetics studies using Rb86. These results are interpreted considering that the control of the activity of the ion channel pathways associated with volume readjustment in PC12 cells may implicate the Ca(2+)-calmodulin - cAMP system.

Volume regulation in mouse pancreatic beta-cells is mediated by a furosemide-sensitive mechanism

A possible role for loop diuretic-sensitive Cl-/cation cotransport in volume regulation in the pancreatic beta-cells was investigated by measuring 86Rb+ efflux from beta-cell-rich pancreatic islets as well as the size of isolated beta-cells under different osmotic conditions. Lowering the osmolarity to 262 mosM (83% of control) resulted in a rapid cell swelling which was followed by regulatory volume decrease (RVD). RVD was completely inhibited by furosemide (1 mM), an inhibitor of Cl-/cation co-transport. The hypotonic medium (262 mosM) induced a rapid and strong increase in 86Rb+ efflux from beta-cell-rich mouse pancreatic islets and the furosemide-sensitive portion of the efflux was significantly increased. A slightly less hypotonic medium (285 mosM, 90% of control) induced only cell swelling and no RVD. With this medium only a marginal increase in 86Rb+ efflux was observed. Increasing the osmolarity by adding 50 mM NaCl (final osmolarity: 417 mosM, 132% of control) induced a rapid cell shrinkage but no regulatory volume increase (RVI). When the osmolarity was increased from a slightly hypotonic medium (262 mosM) to an isotonic medium (317 mosM) an initial cell shrinkage was followed by RVI. This RVI was inhibited by 1 mM furosemide. The data suggest that RVD as well as RVI in the beta-cells are mediated by loop diuretic-sensitive cotransport of chloride and cations and that these cells show a threshold for hypotonic stimulation of RVD.

Corticostatic peptides cause nifedipine-sensitive volume reduction in jejunal villus enterocytes

We studied cell-volume changes caused by adding corticostatin (CS) or defensin-like peptides to villus enterocytes isolated in suspension from guinea pig jejunum. Guinea pig CS (10(-9) M) added to villus cells in Na(+)-containing medium reduced volume, but immediate cell swelling was caused by 10(-6) M guinea pig CS. In Na(+)-free N-methyl-D-glucamine-containing medium 10(-9) M guinea pig CS accelerated the initial rate of shrinkage compared with cells in N-methyl-D-glucamine-containing medium alone as well as causing greater cell shrinkage. Guinea pig CS-stimulated cell shrinkage was prevented by a Ca2(+)-channel blocker--5 microM nifedipine, by chelation of extracellular Ca2+ with 100 microM EGTA, or by omega-conotoxin (10(-9) M). The Ca2+ ionophore A23187 (2.5 microM) reduced volume when added to villus cells in N-methyl-D-glucamine-containing medium; this action was prevented by EGTA, or quinine--an inhibitor of K+ conductance, or 9-anthracenecarboxylic acid--a Cl- channel blocker, suggesting that the volume reduction occurred because K+ and Cl- conductances were activated. Guinea pig CS-stimulated volume reduction was also prevented by 100 microM quinine or 9-anthracenecarboxylic acid. We conclude that jejunal villus enterocytes possess a Ca2(+)-activated Cl- conductance and a K+ conductance that need not be stretch-activated. Corticostatic peptides cause volume reduction in villus cells by activating L-type Ca2+ channels; other defensin-like peptides were without effect.

Aldosterone and PCO2 enhance K-dependent chloride absorption in rat distal colon

We have previously demonstrated that, in the absence of Na+ in vitro, the rate of colonic K+ absorption is increased by increasing PCO2. Chronic secondary hyperaldosteronism induced by dietary Na-depletion further stimulated K+ absorption under these conditions. Because the observed increments in CO2-dependent K+ absorption were not accompanied by corresponding changes in short-circuit current, macroscopic electroneutrality must have been maintained either by anion absorption or by cation secretion. Colonic Cl- absorption is known to respond to increased PCO2 both in vivo and in vitro, but its response under Na-free conditions and the relationship to K+ absorption have not been examined. To determine the relationship of Cl- absorption to K+, we measured unidirectional fluxes of 36Cl and the response to PCO2 in voltage-clamped segments of rat distal colon. Our findings indicate that the rate of Cl- absorption is increased by increasing CO2, both in the presence and absence of Na+. Under Na-free conditions, Cl- absorption is inhibited by acetazolamide and by the absence of K+;K+ absorption (86Rb or 42K flux) is inhibited in a reciprocal fashion by the absence of Cl-. The rates of K+ and Cl- absorption are similar in controls and after secondary hyperaldosteronism due to a Na-deficient diet. These findings suggest that K- and Cl- absorption are closely coupled under Na-free conditions, most likely due to the operation of parallel, aldosterone-responsive H(+)-K+ and Cl(-)-HCO3- exchange pathways.

The response of chloride transport to cyclic AMP, calcium and hypotonic shock in normal and cystic fibrosis fibroblasts

It has widely been established that Cl- transport is defective in cystic fibrosis fibroblasts. In the present study, the effect of elevation of intracellular concentration of cyclic AMP and calcium on the efflux of Cl- from human fibroblasts has been investigated. Cyclic AMP analogs (8-bromo cAMP and dibutyryl cAMP) and a beta agonist (isoproterenol) induced only a weak stimulation (5-10%) of Cl- efflux. Conversely, elevation of cytoplasmic calcium concentration produced by addition of the Ca2+ ionophore A23187 in the efflux medium, did not affect Cl- efflux. Our data indicate that the response of Cl- efflux to elevation of cAMP and calcium is similar in normal and cystic fibrosis fibroblasts. Exposure to hypotonic medium induced a significant stimulation of Cl- efflux in fibroblasts from both normal and cystic fibrosis individuals. Substitution of Cl- in the medium by gluconate and the subsequent addition of furosemide did not inhibit the effect of hypotonicity, indicating the involvement of a conductive pathway for Cl- transport, which was insensitive to oligomicin C.

Characteristics of the volume- and chloride-dependent K transport in human erythrocytes homozygous for hemoglobin C

In human red cells homozygous for hemoglobin C (CC), cell swelling and acid pH increase K efflux and net K loss in the presence of ouabain (0.1 mM) and bumetanide. We report herein, that K influx is also dependent on cell volume in CC cells: cell swelling induces a marked increase in the maximal rate (from 6 to 18 mmol/liter cell X hr) and in the affinity for external K (from 77 +/- 16 mM to 28 +/- 3 mM) of K influx. When the external K concentration is varied from 0 to 140 mM. K efflux from CC and normal control cells is unaffected. Thus, K/K exchange is not a major component of this K movement. K transport through the pathway of CC cells is dependent on the presence of chloride or bromide; substitution with nitrate, acetate or thiocyanate inhibits the volume- and pH-dependent K efflux. When CC cells are separated according to density, a sizable volume-dependent component of K efflux can be identified in all the fractions and is the most active in the least dense fraction. N-ethylmaleimide (NEM) markedly stimulates K efflux from CC cells in chloride but not in nitrate media, and this effect is present in all the fractions of CC cells separated according to density. The persistence of this transport system in denser CC cells suggests that not only cell age, but also the presence of the positively charged C hemoglobin is an important determinant of the activity of this system. These data also indicate that the K transport pathway of CC cells is not an electrodiffusional process and is coupled to chloride.

Chloride transport in human fibroblasts is activated by hypotonic shock

Incubation of human skin fibroblasts in hypotonic media induced the activation of 36Cl- efflux which was roughly proportional to the decrease in the osmolality of the media. The efflux of 36Cl- was insensitive to DIDS plus furosemide and inhibited by addition of a Cl- channel blocker such as 5-nitro-2-(3-phenyl propylamino) benzoic acid (NPPB). We propose that a conductive pathway for Cl- transport, almost silent in isotonic conditions, is activated by exposing human fibroblasts to hypotonic shock, this conclusion being supported by evidence that also 36Cl- influx was enhanced by hypotonic medium.

Role of chloride in potassium transport through a K-Cl cotransport system in human red blood cells

In this paper, we report experiments demonstrating the coupling of Cl and K movements in a volume-dependent K-Cl cotransport system in human red blood cells. We show that an outwardly directed Cl gradient can promote net K efflux against an inwardly directed K gradient at constant membrane potential. Red blood cell membrane potential was kept constant by using anions that are not transported through the K-Cl cotransport system but that are more permeable than Cl (NO3 and SCN). Under these conditions, when the activities of band 3 (capnophorin)-mediated anion exchange and of the carbonic anhydrase have been inhibited, it is possible to maintain a Cl gradient at constant membrane potential. Similar data were obtained in human red blood cells (least dense fraction from normal subjects and whole blood from patients with homozygous hemoglobin S disease), in rabbit red blood cells, and in low-K sheep red blood cells. These data confirm that the volume-dependent Cl-dependent K movement in these cells operates through coupled K-Cl cotransport.

A stretch-activated K+ channel sensitive to cell volume

The role of K+ channels in cell osmoregulation was investigated by using the patch-clamp technique. In cell-attached patches from Necturus proximal tubule, the short-open-time K+ channel at the basolateral membrane could be stretch-activated by pipette suction, where a negative pressure of 6 cm H2O (588.6 Pa) was sufficient to increase the open probability of the channel by a factor of 4.0 +/- 0.8 (n = 7 tubules). A 50% reduction in bath osmolarity increased cell volume by 66 +/- 10% and increased the K+-channel open probability by a factor of 5.8 +/- 1.4 (n = 7) in the same cell-attached patches that were activated by pipette suction. A kinetic analysis indicates one open state and at least two closed states for this epithelial K+ channel. Both suction and swelling shorten the longest time constant of the closed-time distribution by a factor of 3, without significant effect on either the mean open time or the shorter closed-state time constant. The similar effect of suction and swelling is consistent with the hypothesis that stretch-activated K+ channels mediate the increase in macroscopic K+ conductance that occurs during osmoregulation of amphibian proximal tubules. Calculations based on a simple model indicate that small increments in cell volume could produce statistically significant increases in K+-channel activity.

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.

Characterization of chloride uptake in Drosophila Kc cells

Drosophila Kc cells use at least two mechanisms for chloride uptake. These transport systems can be distinguished by their kinetic properties and by their differential sensitivity to various drugs. One transport system predominates at [Cl-]o below 30 mM and is greater than fivefold more sensitive to disulfonic stilbenes than the second system. At [Cl-]o above 30 mM, the predominant uptake mechanism is inhibited by vanadate and nitrate.

Ca2+ sensitivity of volume-regulatory K+ and Cl- channels in cultured human epithelial cells

1. During exposure to a hypotonic solution, cultured human epithelial cells (Intestine 407) exhibited a regulatory volume decrease (RVD) after initial osmotic swelling. 2. The volume readjustment was slowed by elevating the extracellular K+ concentration and facilitated by reducing the extracellular Cl- concentration. Not only putative K+ channel blockers, quinine and Ba2+, but also a stilbene derivative Cl- channel blocker (SITS) inhibited the RVD. 3. The volume recovery of hypoosmotically swollen cells was very much suppressed by the deprivation of extracellular Ca2+ ions or by chelation of cytosolic Ca2+ ions with Quin-2 loaded within the cells. 4. Biphasic membrane potential changes were associated with the RVD process at low extracellular K+ and Cl- concentrations. The initial hyperpolarizing response was inhibited by quinine and Ba2+, whereas the late depolarizing response was inhibited by SITS. The deprivation of extracellular Ca2+ inhibited the initial hyperpolarizing phase but not the late depolarizing phase. 5. Two-microelectrode voltage clamp studies showed that the initial hyperpolarization and late depolarization were associated with quinine-sensitive outward currents and SITS-sensitive inward currents, respectively. The reversal potentials estimated from the current-voltage curves were about -80 mV for the initial response and -27 mV for the late response. Tenfold changes in the K+ and Cl- concentrations shifted these reversal potentials by 50 mV for the initial response and by 42 mV for the late response. 6. Under whole-cell recordings, similar current changes were observed in the cells exposed to a hypotonic solution, when the intracellular Ca2+ ions were moderately buffered with 1 mM-EGTA in the dialysing solution filled in a patch pipette. When most Ca2+ ions were chelated with 10 mM-EGTA in the pipette solution, the initial outward current as well as the corresponding hyperpolarization was suppressed, but the late current associated with the depolarizing phase was preserved. 7. Intracellular Ca2+ injections induced an increase in the quinine-sensitive K+ conductance but failed to activate the Cl- conductance. 8. It is concluded that both K+ and Cl- channels are involved in the regulatory volume decrease, and that the former channel is exclusively activated by elevation of the cytosolic Ca2+ concentration in the epithelial cells.

Effects of cell volume changes on membrane ionic permeabilities and sodium transport in frog skin (Rana ridibunda)

1. Membrane potential and conductances and short-circuit current were continuously measured with microelectrodes and conventional electrophysiological techniques in a stripped preparation of frog skin epithelium. The effects of the removal of chloride or sodium ions and the concentration or dilution of the serosal (inner) bathing solution were studied. 2. Chloride- or sodium-free solutions produced a cell depolarization of about 30 mV in parallel with a fall in the short-circuit current. Mucosal and serosal membrane conductances both decreased and the sodium permeability of the mucosal barrier was calculated to fall to about one-half its value in standard Ringer solution. The observed decrease in the short-circuit current is probably related to the combined effect of the decrease in sodium permeability and the decrease in the driving force across the mucosal membrane. 3. The removal of chloride or sodium ions reduced the depolarization caused by serosal perfusion with high-potassium solutions (50 mM-KCl). The ratio of the change in cell membrane potential under short-circuit conditions to the change in the potassium equilibrium potential (delta Ec(s.c.)/delta EK), was 0.59 in standard Ringer solution and 0.26 and 0.24 after the removal of chloride or sodium respectively. The depolarizing effect of barium-containing solutions (2 mM-BaCl2) was also markedly reduced in chloride- or sodium-free solutions, suggesting a decrease of the potassium selectivity of the serosal membrane in these conditions. 4. Increasing the osmolality of the serosal bathing solution produced similar effects, i.e. cell depolarization, fall in the short-circuit current and membrane conductances and reduction of the depolarizing effect of high-potassium and barium solutions. On the contrary, dilution of the serosal bath produced the opposite effects, consistent with an increase in the serosal permeability to potassium. 5. The effects of chloride- or sodium-free solutions were reversed by the dilution of the serosal bath. Cells repolarized when exposed to low-osmolality solutions after being in the absence of serosal chloride or sodium. The repolarization ran in parallel with the restoration of the short-circuit current and the potassium selectivity of the serosal membrane. 6. The results show that the effects produced by the removal of sodium or chloride ions from the serosal bathing solution are most probably mediated by a reduction in cell volume. Cell volume changes would lead to changes in the serosal membrane selectivity to potassium and thus to changes in cell membrane potential and sodium transport.(ABSTRACT TRUNCATED AT 400 WORDS)

Molecular signaling mechanisms in T-lymphocyte activation pathways: a review and future prospects

Understanding of the molecular mechanisms which drive the complex activation responses of T lymphocytes was previously limited. However, current studies in lymphocytes, and in other cells, have indicated the involvement of several secondary messenger or signal systems, and recent progress in elucidating the relevant pathways has been extraordinarily rapid. This review therefore attempts to provide an overview of these processes--including the effects of Ca2+, hydrolysis of phospholipids, arachidonic acid, Ca2+/phospholipid-dependent and tyrosine kinases, calmodulin, cyclic nucleotides, ion channels, and adherent cells--and their roles in weaving a subtle and highly responsive web of regulatory signals.

Electrodiffusion of Cl- and K+ in epithelial membranes reconstituted into planar lipid bilayers

An electrodiffusive permeability for Cl-, its activation by low extracellular Cl--concentrations and the interaction between electrodiffusive fluxes of Cl- and K+ are demonstrated in the ventricular membranes from the epithelium of the bovine choroid plexus. Membranes were fused into artificial lipid bilayers formed at the tip of micropipettes. What is thought to be the cytoplasmic side of the membrane (the trans-side or the inside of pipette) was clamped at negative potentials (0 to -90 mV). Under these conditions the current was discrete, fluctuating less than 2 pA. With Cl- as the only conducting ion on the two sides we observed a small electrodiffusive permeability which was reduced by bumetanide or furosemide by 62%. When the outside solution was rendered Cl--free then the permeability to Cl- increased by a factor of 2-5; this activation was reduced by bumetanide or furosemide by about 80%. We observed an interaction between inwards movements of K+ and outwards movements of Cl- via the activated permeability: The total current was smaller than the sum of the expected inward K+-current and the expected outward activated Cl--current. Bumetanide or furosemide increased the total current; apparently the loss of current carried by Cl- was smaller than the gain in current carried by K+. The presence of K+ on both sides of the membrane was a condition for this interaction.

The effects of chloride ions on electrodiffusion in the membrane of a leaky epithelium. Studies of intact tissue by microelectrodes

The electrodiffusive permeability for Cl-, its dependence on low extracellular Cl--concentrations and the interaction between the movements of Cl- and K+ were investigated in the ventricular membrane of epithelial cells from the choroid plexus of Necturus maculosus. Cells were probed with ion-selective microelectrodes sensitive to Cl-, K+ and H+. The initial effects of abrupt changes in the Cl--concentration (Cl-v) and/or the K+-concentration (K+v) of the ventricular solution were investigated. The effect of changing the membrane potential by changing K+v was twofold: It caused an electrodiffusive flux of Cl- via a permeability of 1.3 X 10(-6) cm s-1. This permeability together with the K+-permeability of the ventricular membrane (24 X 10(-6) cm s-1) determined the membrane potential in the given steady state within a few mV. The other effect of the depolarization was an increase in the intracellular concentration of HCO-3 which in turn caused an influx of Cl- via electroneutral Cl-/HCO-3 exchange. The Cl--permeability was reduced by more than 60% and the neutral exchange by more than 90% by furosemide. The effect of decreases in Clv was a tenfold increase of the electrodiffusive Cl--permeability of the ventricular membrane to 12.2 X 10(-6) cm s-1 and also a tenfold increase in the permeability to K+. This activation was reduced by two thirds by furosemide, and by depolarizations of the cell by high K+v. In the given steady state the HCO-3/Cl- exchanger at the ventricular membrane transports at a rate of 300 pmol cm-2 s-1 and moves Cl- into the cell and HCO-3 into the ventricular solution. Thus the epithelium alkalinizes the cerebrospinal fluid at a rate which is about three times faster than the net transport rate of Na+.

Enhancement of conductive anion permeability in cultured cells by cetiedil

Cetiedil, a drug that is reported to block K+-channels, substantially increases the conductive C1- permeability of Chinese hamster ovary (CHO) cells. The permeability was monitored by volume changes in cells treated with gramicidin to increase the cation permeability. Under this circumstance, increases in Cl- conductances result in volume changes detectable by electronic sizing, with the direction determined by the gradients of the permeating ions. In NaCl or KCl media, swelling occurs, but in N-methylglucamine chloride, shrinking. The increases in Cl- conductance could also be measured as an increased 36Cl- flux or by changes in membrane potential (measured by fluorescence of a potential-sensitive dye) toward the Cl- equilibrium potential. The effect of cetiedil was concentration dependent, with maximal effect at 50 microM. The anion specificity for the conductance was NO3- greater than Cl- = Br- much greater than SO4-2 or isethionate. A number of other drugs that influence transport activities had no effect on Cl- conductance. The cetiedil effect on Cl- conductance was observed in one other cell line, but was absent in several other cell types. The cetiedil-induced Cl- conductance in CHO cells appears to involve a different pathway than that induced by exposure to hypotonic medium.

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

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 of 42K and 36Cl tracer fluxes is directly demonstrated. RVD and the A23187-induced cell shrinkage both are: inhibited by quinine which blocks the Ca2+-activated K+ channel, unaffected by substitution of NO-3 or SCN- for Cl-, and 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 by 42K 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 from 42K 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.

Active K transport across rabbit distal colon: relation to Na absorption and Cl secretion

We measured isotopic unidirectional fluxes of K to elucidate the mechanisms of active K transport across the distal colon of the rabbit. Separate pathways for active K absorption and active K secretion were detected using various transport inhibitors and stimulators. The rate and direction of net K transport depend on the activities of these two pathways. K absorption was reduced by orthovanadate (both solutions) or serosal Ba, consistent with ATPase-dependent uptake of K across the apical membrane and exit via a Ba-sensitive basolateral K conductance. K secretion was inhibited by serosal ouabain or mucosal Ba, indicating that K secretion involves basolateral uptake via the Na-K pump and apical exit via a Ba-sensitive K conductance. Active K secretion appears to be electrogenic, since inhibition by ouabain produced equivalent changes in the net K flux and short-circuit current. Addition of bumetanide to the serosal solution or the removal of either Na or Cl from the serosal solution inhibited K secretion; mucosal solution amiloride was without effect. These results indicate that this K secretory process is independent of electrogenic Na absorption but is mechanistically similar to Cl secretory processes. Both epinephrine and prostaglandin E2 (PGE2) stimulate K secretion, but only PGE2 also stimulates Cl secretion. The response to these secretogogues suggests that the mechanisms underlying K and Cl secretion are closely linked but can be regulated independently.

Single chloride channel currents from canine tracheal epithelial cells

Patch-clamp techniques were used to characterize the properties of anion-selective channels in canine tracheal epithelial cells that had been maintained in primary culture. Gigaohm seals (10-30 G omega) were obtained in single isolated cells or cells at the edge of a confluent sheet, and channels were studied in the cell attached or the inside-out, excised patch configuration. Pretreatment with isotonic KCl caused the cells to round-up and allowed us to have better success in obtaining good seals. Based on conductance, anion-cation selectivity and voltage-dependent kinetic properties, four anion channel types could be detected in symmetrical solutions of 0.15 M NaCl: (i) a 30-50 pS Cl- channel of high selectivity, active at negative potentials and inactivated by large positive potentials; (ii) an approx. 20 pS Cl- channel of high selectivity, active at positive potentials and inactivated at negative potentials; (iii) an approx. 250 pS channel of moderate selectivity (PCl/PNa = 4) that was not voltage-dependent, and (iv) an approx. 10 pS Cl- channel with characteristics similar to (iii) above, but remaining somewhat active at large negative voltages. All excised patches were exposed to relatively high calcium concentrations on the intracellular side. Channel activity was increased in tracheal cells treated with 1 mM cAMP, suggesting that at least one of these channels plays a role in the increase of the apical membrane Cl- conductance that is mediated by cAMP and elicited by agonists of active Cl- secretion.

Anion transport systems in the plasma membrane of vertebrate cells

In the case of the red blood cell, anion transport is a highly specific one-for-one exchange catalyzed by a major membrane protein known as band 3 or as capnophorin. This red cell anion-exchange system mediates the Cl-(-)HCO3- exchange responsible for most of the bicarbonate transport capacity of the blood. The rapidly expanding knowledge of the molecular biology and the transport kinetics of this specialized transport system is very briefly reviewed in Section III. Exchange diffusion mechanisms for anions are found in many cells other than erythrocytes. The exchange diffusion system in Ehrlich cells has several similarities to that in red cells. In several cell types (subsection IV-B), there is evidence that intracellular pH regulation depends on Cl-(-)HCO3- exchange processes. Anion exchange in other single cells is described in Section IV, and its role in pH regulation is described in Section VII. Anion exchange mechanism operating in parallel with, and only functionally linked to Na+-H+ or K+-H+ exchange mechanisms can also play a role in cell volume regulation as described in Section VII. In the Ehrlich ascites cell and other vertebrate cells, electroneutral anion transfer has been found to occur also by a cotransport system for cations and chloride operating in parallel with the exchange diffusion system. The cotransport system is capable of mediating secondary active chloride influx. In avian red cells, the cotransport system has been shown to be activated by adrenergic agonists and by cyclic AMP, suggesting that the cotransport is involved in regulatory processes (see subsection V-A.). In several cell types, cotransport systems are activated and play a role during volume regulation, as described in Section V and in Section VII. It is also likely that this secondary active cotransport of chloride plays a significant role for the apparently active extrusion of acid equivalents from certain cells. If a continuous influx of chloride against an electrochemical gradient is maintained by a cotransport system, the chloride disequilibrium can drive an influx of bicarbonate through the anion exchange mechanism, as described in Section VII. Finally, even the electrodiffusion of anions is shown to be regulated, and in Ehrlich cells and human lymphocytes an activation of the anion diffusion pathway plays a major role in cell volume regulation as described in Section VI and subsection VII-B.(ABSTRACT TRUNCATED AT 250 WORDS)

Anomalous permeability and stability characteristics of erythrocytes in non-electrolyte media

The permeability characteristics of the erythrocyte membrane were critically evaluated in electrolyte and non-electrolyte (sucrose) media by ion-selective electrodes and radioactive polyol fluxes as well as by the novel technique of osmometry. K+ efflux demonstrated a linear osmotic susceptibility distinct from Na+ influx upon incubation in NaCl media of various tonicities. In non-electrolyte media, acidification of the medium, large fluxes of K+, sucrose and even haemoglobin (as manifest by hypertonic disruption) were consistent with enhanced porosity of the bilayer due to the field created by surface charge density leading to density fluctuations in the bilayer.