Adenosine induces dephosphorylation of myosin II regulatory light chain in cultured bovine corneal endothelial cells.

PURPOSE: Dephosphorylation of the myosin II regulatory light chain (MLC) promotes barrier integrity of cellular monolayers through relaxation of the actin cytoskeleton. This study has investigated the influence of adenosine (ADO) on MLC phosphorylation in cultured bovine corneal endothelial cells (BCEC). METHODS: MLC phosphorylation was assessed by urea-glycerol gel electrophoresis and immunoblotting. Elevation of cAMP in response to agonists of A2b receptors (subtype of P1 purinergic receptors) was confirmed by phosphorylation of the cAMP response element binding protein (CREB), which was determined by Western blotting. Activation of MAP kinases (i.e. activated ERK1 and ERK2) was assessed by Western blotting to examine their influence on MLC phosphorylation. Transepithelial electrical resistance (TER) of cells grown on porous filters was measured to assess the altered barrier integrity. RESULTS: Exposure to ADO (200 microm; 30 min) and N-ethyl (carboxamido) adenosine (NECA; 50 microm; 30 min), known agonists of A2b receptors, induced phosphorylation of CREB similar to forskolin (FSK, 20 microm; 30 min), a direct activator of adenylate cyclase. Exposure to ADO, NECA, and FSK led to dephosphorylation of MLC by 51, 40, and 47%, respectively. ADO-induced dephosphorylation was dose-dependent with as much as 31% dephosphorylation at 1 microm ADO. CGS-21680, a selective A2a agonist, neither induced MLC dephosphorylation nor CREB phosphorylation. ADO phosphorylated MAP kinases which could be prevented by exposure to the MAP kinase-specific inhibitor, U0126 (10 microM). NECA and FSK also induced ERK1 and ERK2 activation similar to ADO. Exposure to U0126 inhibited MLC phosphorylation under basal conditions by 17%. ADO-induced MLC dephosphorylation was enhanced by a simultaneous exposure to U0126 (25% increase in dephosphorylation). Exposure to ADO caused an increase in TER from 17 to 22 ohms cm2. CONCLUSIONS: (1) CREB phosphorylation in response to ADO and NECA, which indicates activation of the cAMP-PKA axis, suggests expression of A2b receptors in BCEC. (2) ERK1 and ERK2, activated by cAMP and A2b receptors, promote MLC phosphorylation. However, the net result of cAMP elevation is MLC dephosphorylation, presumably because the competing pathways involving inactivation of MLCK and/or ROCK are dominant (Rho-associated coiled coil-containing protein kinase or Rho kinase). (3) Consistent with MLC dephosphorylation, exposure to ADO increases TER, which suggests increased barrier integrity.

Hypotonic cell swelling stimulates permeability to cAMP in a rat colonic cell line.

This study characterized the membrane permeability to cAMP in a cell line derived from the rat colon (CC531(mdr+)) by comparison of fluxes of 3H-cAMP, 3H-8-bromo-cAMP, 3H-taurine, 3H-adenosine and 3H-5'AMP under various experimental conditions including cell membrane depolarization and hypotonic cell swelling. Cell volume was modified by changing the osmolality and composition of the extracellular medium. Incubation in iso- and hypotonic KCl media induced graded increases in cell volume and stable activation of volume-sensitive channels that was reflected in an increased efflux of 3H-taurine. Incubation in hypotonic KCl solution also enhanced the efflux of 3H-8-Br-cAMP (a non-hydrolysable analogue of cAMP). Both the efflux of 3H-taurine and of 3H-8-Br-cAMP were inhibited by 5-nitro-2-(3-phenylpropylamino)benzoate (NPPB, 100 microM) suggesting the involvement of volume-sensitive anion channels. To gain further insight into the route mediating cAMP permeability, the uptakes of 3H-cAMP, 3H-8-Br-cAMP and 3H-taurine were determined over short (5-min) periods. Uptakes of these substrates demonstrated close similarities: comparable increases were observed that correlated with the increases in cell volume in iso- and hypoosmotic KCl media; they were inhibited strongly by NPPB (100 microM) and metabolic inhibitors (deoxyglucose, 20 mM together with the mitochondrial uncoupler carbonylcyanide p-(trifluoromethoxy)phenylhydrazone, FCCP, 10 microM) while barely reduced by dipyridamole (100 microM) and they were not affected by adenosine (1 mM). In contrast, the uptakes of 3H-adenosine and 3H-5'AMP had strikingly different properties; they were insensitive to cell swelling; barely inhibited by NPPB (100 microM) and metabolic inhibitors (deoxyglucose and FCCP) while strongly reduced by dipyridamole (100 micro M). Unlike the uptakes of 3H-cAMP, 3H-8-Br-cAMP and 3H-taurine, the uptakes of 3H-adenosine and 3H-5'AMP were reduced in Na(+)-free media, suggesting the presence in this cell line of two different adenosine carriers, one sodium-dependent and one sodium-independent. Taken together the present data show that in this rat colonic cell line, cAMP permeability is increased by cell swelling in hypotonic KCl medium and inhibited by NPPB and metabolic inhibitors. The similarity of these characteristics to those of taurine permeability suggests the involvement of a volume-sensitive anion pathway.

External Ni2 + and ENaC in A6 cells: Na+ current stimulation by competition at a binding site for amiloride and Na+.

In cultured A6 monolayers from distal Xenopus kidney, external Ni2+ stimulated active Na+ uptake via the epithelial Na+ channel, ENaC. Transepithelial capacitance measurements ruled out exocytosis of ENaC-containing vesicles underlying the Ni2+ effect. Na+ current noise analysis was performed using the neutral Na(+) -channel blocker 6-chloro-3,5-diamino-pyrazine-2-carboxamide (CDPC) and amiloride. The analysis of CDPC-induced noise in terms of a three-state channel model revealed that Ni2+ elicits an increase in the number of open channels as well as in the spontaneous open probability. While Ni2+ had no influence on CDPC-blocker kinetics, the macroscopic and microscopic blocking kinetics of amiloride were affected. Ni2+ turned out to compete with amiloride for a putative binding site but not with CDPC. Moreover, external Na(+)--known to compete with amiloride and so producing the "self-inhibition" phenomenon--and Ni2+ exerted mutually exclusive analogous effects on amiloride kinetics. Na+ current kinetics revealed that Ni2+ prevents ENaC to be downregulated by self-inhibition. Co2+ behaved similarly to Ni2+, whereas Zn2+ did not. Attempts to disclose the chemical nature of the site reacting with Ni2+ suggested cysteine but not histidine as reaction partner.

Changes in element composition of A6 cells following hypotonic stress.

Cellular element concentrations and dry weight contents were determined in A6 epithelia using electron microprobe analysis. This was done to assess the quantitative contributions of Na, K and Cl to the regulatory volume decrease (RVD) and isovolumetric regulation (IVR) after decreasing the basolateral osmolality from 260 to 140 mosmol/kg in a stepwise or gradual way. Two minutes after inducing acute hypotonic stress the cells behaved almost like ideal osmometers, as indicated by a pronounced increase in cell height and decreases in the cellular dry weight and concentrations of all measured elements by about the same degree. Sixty minutes after inducing acute hypotonic stress the dry weight and concentrations of the impermeant elements P, Mg and Ca had returned approximately to control values, indicating normalized cell volume. Na, K and Cl concentrations, however, remained greatly reduced. The cellular amounts of Na, K and Cl diminished during RVD by approximately 31%, 24% and 46%, respectively. The dry weights and element concentrations measured 60 min after inducing acute hypotonic stress were similar to those obtained after a continuous reduction of basolateral osmolality. The cellular loss of Na and K following hypotonic stress exceeded that of Cl by about 40 mmol/kg wet wt., suggesting the exit of an other anion and/or the titration of fixed negative charges. The contribution of Na, K and Cl to total cellular osmolality increased from about 75% under control conditions to about 85% during RVD and IVR. Since only approximately 70% of the loss of cellular osmolytes necessary for the observed RVD and IVR is accounted for by the cellular exit of Na, K and Cl, other osmolytes, possibly amino acids, must leave the cells following hypotonic stress.

Functional integrity of the vesicle transporting machinery is required for complete activation of cFTR expressed in xenopus laevis oocytes.

We expressed the human cystic fibrosis transmembrane conductance regulator (CFTR) in oocytes of the South African clawed frog Xenopus laevis. We performed simultaneous and continuous recording of membrane current (Im), conductance (Gm) and capacitance (Cm), the latter being a direct measure of membrane surface area. A cAMP-cocktail containing cAMP and isobutylmethylxanthine (IBMX) increased all parameters, demonstrating that CFTR activation was partly achieved by exocytotic delivery and insertion of preformed CFTR molecules into the plasma membrane. CFTR currents after cAMP-cocktail were correlated with the capacitance of the oocytes: oocytes with larger Cm exhibited larger currents. Expression of CFTR itself did not change the Cm of the oocytes. However, activation of CFTR with cAMP-cocktail increased Im and Gm 15- and 20-fold, respectively while membrane surface area increased by about 7%, indicating the functional insertion of preformed CFTR into the plasma membrane. While cAMP-cocktail yielded maximal CFTR stimulation, IBMX alone, but not caffeine or theophylline, was sufficient to stimulate more than half of the increases in Im and Gm as observed with cAMP-cocktail. Since Cm was not significantly stimulated by IBMX, we conclude that IBMX alone activated the CFTR channels already present in the oocyte membrane. CFTR stimulation by cAMP-cocktail was independent of external Ca2+ and ATP had no additional activating potency. The role of protein trafficking in the activation of CFTR evoked by increases of cytoplasmic cAMP was assessed by measuring the effects of brefeldin A (BFA), nocodazole and primaquine on the bioelectric parameters and membrane surface area. All these compounds that interfere with the protein trafficking machinery at different stages prevented the translocation of CFTR from intracellular pools to the plasma membrane. These data confirm and extend our previous observations that CFTR expressed in Xenopus laevis oocytes is activated via dual pathways including direct activation of CFTR already present in the membrane and exocytotic insertion of preformed CFTR channels into the membrane. Furthermore, we show that complete activation of CFTR requires an intact protein trafficking machinery.

Different activation mechanisms of cystic fibrosis transmembrane conductance regulator expressed in Xenopus laevis oocytes.

The cystic fibrosis transmembrane conductance regulator (CFTR) is a cAMP sensitive Cl- channel that is defective in cystic fibrosis (CF). The most frequent mutation, namely deltaF508-CFTR, accounts for 66% of CF. Here we show that cAMP-activation of CFTR occurs via at least two distinct pathways: activation of CFTR molecules already present in the plasma membrane and protein kinase A (PKA)-mediated vesicular transport of new CFTR molecules to the plasma membrane and functional insertion into the membrane. We investigated the mechanisms that are responsible for these activation pathways using the Xenopus laevis oocytes expression system. We expressed CFTR and recorded continuously membrane current (Im), conductance (Gm) and capacitance (Cm), which is a direct measure of membrane surface area. Expression of CFTR alone did not change the plasma membrane surface area. However, activation of CFTR with cAMP increased Im, Gm and Cm while deltaF508-CFTR-expressing oocytes showed no response on cAMP. Inhibition of protein kinase A or buffering intracellular Ca2+ abolished the cAMP-induced increase in Cm while increases of Im and Gm were still present. ATP or the xanthine derivative 8-cyclopentyl-1,3-dipropylxanthine (CPX) did not further activate CFTR. Insertion of pre-formed CFTR into the plasma membrane could be prevented by compounds that interfere with intracellular transport mechanisms such as primaquine, brefeldin A, nocodazole. From these data we conclude that cAMP activates CFTR by at least two distinct pathways: activation of CFTR already present in the plasma membrane and exocytotic delivery of new CFTR molecules to the oocyte membrane and functional insertion into it.

Involvement of protein tyrosine kinase in osmoregulation of Na(+) transport and membrane capacitance in renal A6 cells.

Renal A6 cells have been reported in which hyposmolality stimulates Na(+) transport by increasing the number of conducting amiloride-sensitive 4-pS Na(+) channels at the apical membrane. To study a possible role of protein tyrosine kinase (PTK) in the hyposmolality-induced signaling, we investigated effects of PTK inhibitors on the hyposmolality-induced Na(+) transport in A6 cells. Tyrphostin A23 (a PTK inhibitor) blocked the stimulatory action of hyposmolality on a number of the conducting Na(+) channels. Tyrphostin A23 also abolished macroscopic Na(+) currents (amiloride-sensitive short-circuit current, I(Na)) by decreasing the elevating rate of the hyposmolality-increased I(Na). Genistein (another type of PTK inhibitor) also showed an effect similar to tyrphostin A23. Brefeldin A (BFA), which is an inhibitor of intracellular translocation of protein, blocked the action of hyposmolality on I(Na) by diminishing the elevating rate of the hyposmolality-increased I(Na), mimicking the inhibitory action of PTK inhibitor. Further, hyposmolality increased the activity of PTK. These observations suggest that hyposmolality would stimulate Na(+) transport by translocating the Na(+) channel protein (or regulatory protein) to the apical membrane via a PTK-dependent pathway. Further, hyposmolality also caused an increase in the plasma (apical) membrane capacitance, which was remarkably blocked by treatment with tyrphostin A23 or BFA. These observations also suggest that a PTK-dependent pathway would be involved in the hyposmolality-stimulated membrane fusion in A6 cells.

Effects of extracellular Mg2+ on transepithelial capacitance and Na+ transport in A6 cells under different osmotic conditions.

The electrophysiological characteristics of monolayers of cultured renal epithelial A6 cells were studied under short-circuit conditions. Replacing basolateral isosmotic (260 mOsm/kg H2O) media by hyposmotic (140 mOsm/kg H2O) solutions transiently increased the transepithelial capacitance (C(T)) by 57.3+/-2.3% after 16 min. The transepithelial Na+ current (I(Na)) increased concomitantly from 4.2+/-0.7 to 26.1+/-2.6 microA/cm2 with a time course that was noticeably slower, reaching its maximum after 60 min of hypotonicity. The transepithelial conductance (G(T)) increased synchronously with I(Na). Analysis of blocker-induced noise in I(Na), using the amiloride analogue 6-chloro-3,5-diaminopyrazine-2-carboxamide (CDPC), showed that the hypotonic shock increased Na+ channel density (N(T)) at the apical border. The presence of 10 mM Mg2+ on both sides of the epithelium suppressed the hypotonicity-induced C(T) increase to 14.3+/-0.5%, whereas the I(Na) increase was even larger than without Mg2+. Both effects of Mg2+ were located at an extracellular, basolateral site, because apical administration was without effect, whereas the acute basolateral addition of Mg2+ at the moment of the hypotonic shock was sufficient. Interaction between Mg2+ and Ca2+ influenced the behaviour of C(T). At constant osmolality (200 mOsm/kg H2O) 10 mM Mg2+ increased I(Na), leaving C(T) unaffected, whereas 10 mM Ca2+ stimulated both I(Na) and CT. In the presence of 1 mM Mg2+, however, the Ca(2+)-induced CT increase was abolished. The failure of CT to increase during stimulation of I(Na) by Mg2+ suggests that the divalent cation activates pre-existing channels in the apical membrane. Noise analysis showed that the natriferic effects of Mg2+ were also mediated by an increase in NT. The moderate initial increase in CT in the presence of Mg2+ under hypotonic conditions, occurring in parallel with increases in GT and I(Na), reflects most likely Na+ channel insertion induced by the hypotonic treatment. However, the large, transient, Mg(2+)-sensitive increase in CT, not correlated with increases in GT and I(Na), seems to be unrelated to Na+ channel recruitment.

Maitotoxin induces insertion of different ion channels into the Xenopus oocyte plasma membrane via Ca(2+)-stimulated exocytosis.

The activation of cation channels in oocytes of Xenopus laevis by the marine poison maitotoxin (MTX) was monitored as membrane current (I(m)), conductance (Gm) and membrane surface area determined by continuous measurements of membrane capacitance (Cm). When MTX (25 pM) was added to the bathing solution there was an abrupt, large increase in inward membrane currents. Current/voltage relationships (I/V curves) were linear and suggested activation of voltage-independent non-selective cation channels (NSCC). MTX-induced Ca(2+)-sensitive currents were mainly carried by Na+ and were suppressed by low (0 mM) or high (40 mM) external Ca2+ concentrations and removal of Na+. Gadolinium (Gd3+, 10-500 microM) also had inhibitory effects, demonstrating the possible involvement of stretch-activated cation channels (SACC). In a high concentration (500 microM), amiloride substantially reduced the MTX-activated current while lower amiloride concentrations (50-100 microM) stimulated the current further. Continuous measurements of Cm revealed that MTX induced exocytotic delivery and functional insertion of new channel proteins into the plasma membrane, indicated by a Ca(2+)-dependent increase in membrane surface area by around 28%. From these data we conclude that MTX activates NSCC that require relatively high concentrations of amiloride to be blocked. Furthermore, MTX possibly stimulates activation of Gd(3+)- and Ca(2+)-sensitive mechanosensitive cation channels. Stimulation of these channels is achieved by exocytotic delivery and functional insertion of new channels into the plasma membrane in a pathway that depends on the presence of extracellular Ca2+.

Nicotine-induced endocytosis of amiloride-sensitive sodium channels in human nasal epithelium.

In previous studies we developed and introduced a method to examine the transport mechanisms of ions in primary cell cultures of human nasal epithelium. In the current study, substances, especially nicotine, that influence these mechanisms are investigated. Specimens of nasal and paranasal epithelium of patients treated by endonasal surgery because of chronic sinusitis (n = 217) were used as primary cell cultures. Cell cultures of smokers (n = 83) and non-smokers (n = 134) were differentiated. Transepithelial Ussing chamber measurements were performed to examine sodium channel functions and to evaluate the influence of nicotine. These examinations were accompanied by simultaneous continuous capacitance measurements. Whereas transepithelial parameters, such as short-circuit current, (Isc), potential (Vt) and resistance (Rt), in tissues derived from smokers and non-smokers showed no difference, the transepithelial conductance was reduced immediately in cell cultures with apical application of nicotine (2 mM). This decrease was accompanied by a marked reduction of epithelial surface area. In the presence of nicotine, amiloride (100 microM) completely lost its inhibitory capacity. Amiloride-insensitive sodium channels were unaffected by nicotine, as proved by Na+ substitution. Furthermore, the Na+ channel blocker was accompanied by an increase in intracellular Ca2+. We conclude that the nicotine-induced increase in intracellular calcium (Ca2+) has stimulated Ca2+-dependent protein kinase (PKC). PKC promotes endocytosis removing amiloride-sensitive Na+ channels from the cell membrane into the cell by means of vesicular transport.

Cell swelling activates stress-activated protein kinases, p38 MAP kinase and JNK, in renal epithelial A6 cells.

Osmotic shock is well recognized as one of the factors activating stress-activated protein kinases (SAPKs), p38 MAP kinase and c-Jun N-terminal kinases (JNKs). In renal epithelial A6 cells, hypo-osmotic shock transiently activated SAPKs with maximal activation at 5 min. A6 cells showed a regulatory volume decrease (RVD) after swelling when the cells were exposed to a hypo-osmotic solution. In contrast, activation of SAPKs was maintained over 90 min after hypo-osmotic shock in the presence of 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB, a Cl(-) channel blocker), which completely blocked the RVD and kept the cells continuously swelling. Exposure of the cells to a high K(+) iso-osmotic solution containing nystatin, which induces continuous cell swelling, also continuously activated SAPKs. Furthermore, membrane deformation induced by chlorpromazine activated SAPKs. These results suggest that changes in membrane tension by cell swelling or chlorpromazine, but not osmolality, are important steps for activation of SAPKs in A6 cells.

Capacitance measurements reveal different pathways for the activation of CFTR.

We used the Xenopus laevis oocyte expression system to characterize adenosine 3',5'-cyclic monophosphate (cAMP) activation of the cystic fibrosis transmembrane conductance regulator (CFTR). With conventional two-microelectrode voltage-clamp techniques, we recorded transmembrane conductance (Gm) and membrane current (Im). Using five different sine wave frequencies, we also monitored changes of the plasma membrane surface area by recording continuously membrane capacitance (Cm) under voltage-clamp conditions. Impedance spectra recorded in the frequency range 0.1-500 Hz showed that, at least up to 200 Hz, Cm is independent of the frequency. In control oocytes, cAMP (100 microM) treatment did not affect Gm or Im but evoked a small, slowly occurring increase in Cm, probably mediated by cAMP-stimulated exocytosis. However, in oocytes expressing CFTR, large simultaneous increases of Gm, Im and Cm occurred after stimulation with cAMP. Oocytes injected with the delta F508 CFTR mutant behaved like control oocytes and cAMP had no additional effects on Gm, Im or Cm. In oocytes injected with wild-type CFTR, adenosine 5'-triphosphate (ATP, 100 microM) did not activate the cAMP-induced augmentation of Im, Gm or Cm further. On the other hand, cAMP-induced increases in Cm were reduced significantly by the specific blockers of protein kinase A (PKA) KT5720 and N-[2-(methylamino-9-ethyl]-5-isoquinolinesulphonamide hydrochloride (H8), whereas the increases in Gm and Im were essentially unaffected by these agents. Reducing intracellular Ca2+ by injection of a Ca2+ chelator 1,2-bis (2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) prevented PKA-dependent exocytosis while activation of Im and Gm of already-inserted CFTR still could be detected. The specific cAMP antagonist adenosine 3',5'-cyclic monophosphothioate Rp diastereomer (RpcAMPS) completely suppressed the effects of cAMP on all parameters. These findings are consistent with the concept of different pathways of CFTR activation by cAMP: already-inserted CFTR Cl- channels are activated directly by cAMP, while traffic of CFTR proteins from an intracellular pool to the plasma membrane and functional insertion into the plasma membrane occurs via cAMP- and Ca(2+)-dependent PKA-mediated exocytosis.

Intracellular pH shifts in cultured kidney (A6) cells: effects on apical Na+ transport.

We report, for the epithelial Na+ channel (ENaC) in A6 cells, the modulation by cell pH (pHc) of the transepithelial Na+ current (INa), the current through the individual Na+ channel (i), the open Na+ channel density (No), and the kinetic parameters of the relationship between I(Na) and the apical Na+ concentration. The i and N) were evaluated from the Lorentzian INa noise induced by the apical Na+ channel blocker 6-chloro-3, 5-diaminopyrazine-2-carboxamide. pHc shifts were induced, under strict and volume-controlled experimental conditions, by apical/basolateral NH4Cl pulses or basolateral arrest of the Na+/H+ exchanger (Na+ removal; block by ethylisopropylamiloride) and were measured with the pH-sensitive probe 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein. The changes in pHc were positively correlated to changes in INa and the apically dominated transepithelial conductance. The sole pHc-sensitive parameter underlying INa was No. Only the saturation value of the INa kinetics was subject to changes in pHc. pHc-dependent changes in No may be caused by influencing Po, the ENaC open probability, or/and the total channel number, NT = No/Po.

Secretory apical Cl- channels in A6 cells: possible control by cell Ca2+ and cAMP.

Distal kidney cells (A6) from Xenopus laevis were cultured to confluency on porous supports. Tissues were mounted in Ussing-type chambers to measure short-circuit current (Isc), transepithelial conductance and capacitance, and to analyse the fluctuation in Isc. In the absence of apical NaCl, but with normal basolateral NaCl Ringer's solution, extracellular addition of ATP, oxytocin, a membrane-permeant cAMP derivative, and forskolin produced a transient increase of the electrical parameters. Noise analysis revealed a spontaneous Lorentzian component. All responses depend strictly on the presence of basolateral Cl- and are caused by the activation of an apical (CFTR type) Cl- permeability. Repetitive treatment with ATP (or oxytocin) resulted in refractoriness. ATP and oxytocin acted antagonistically, whereas cAMP and ATP had additive effects. Incubation with the vesicular Ca2+ pump inhibitor thapsigargin or application of the Ca2+ channel blocker nifedipine elicited finite but variable Cl- channel activity. After treatment with nifedipine or thapsigargin, the response to oxytocin was severely impaired. We speculate that not only cAMP but also cell Ca2+ plays a crucial role in the activation of CFTR in A6. Ca2+ may be multifunctional but the rise in capacitance (apical area) observed with all stimulants strongly suggests its involvement in, and contribution to, exocytosis in the process of the CFTR-mediated transcellular Cl- movements.

Forskolin increases apical sodium conductance in cultured toad kidney cells (A6) by stimulating membrane insertion.

The role of membrane traffic in the stimulation of apical Na+ permeability caused by increases in cytoplasmic cyclic AMP was assessed by measuring the effects of forskolin on transepithelial capacitance (CT), transepithelial conductance (GT), and short-circuit current (Isc) in A6 cultured toad kidney cells. Apical water permeability was probed by recording cell volume changes after reducing the osmolality of the apical bath. We found that forskolin does not increase the osmotic water permeability of the apical membrane of A6 cells, and thus does not stimulate the insertion of water channels. Comparison of the effects of forskolin and insulin on Na+ transport demonstrated that both agents produce reversible increases in CT, GT and Isc. GT and CT increased proportionally during the rising phase of the insulin response. However, a non-linear relationship between both parameters was recorded when forskolin was given in NaCl Ringer's solution. The relationship between CT and GT became linear after the effects of forskolin on Cl- conductances were eliminated by substituting Cl- by an impermeant anion. In contrast, in Cl--containing Na+-free solutions, the non-linearity became more pronounced. Successive additions of insulin and forskolin caused additive increases in CT. Because increases in CT and Na+ transport occurred in the absence of stimulation of water permeability and increases of CT and GT were directly proportional when Na+ was the major permeating ion across the apical membrane, we suggest that the increase in apical Na+ permeability in the presence of either forskolin or insulin is due to the insertion of channels residing in intracellular pools. In contrast, the increased Cl- permeability caused by forskolin may be related to the activation of channels already present in the membrane.

Transepithelial capacitance decrease reveals closure of lateral interspace in A6 epithelia.

A sine wave method was used to measure transepithelial capacitance (CT) at 4.1 kHz (CHFT ). Model calculations show that CHFT reflects the equivalent capacitance of the series arrangement of apical and basolateral membrane capacitance. Cell swelling induced by reducing the basolateral osmolality from 260 to 140 mosmol/kg H2O (NaCl or sucrose removal) transiently decreased CHFT. The decrease in CHFT (DeltaCHFT ) reached its maximum 30 s after the onset of cell swelling and a complete recovery of CHFT was attained within 3-4 min. DeltaCHFT could be diminished by manoeuvres that reduced the rate or amplitude of cell swelling, i.e. lowering the temperature or treatment with low concentrations of glutaraldehyde (0.025%). DeltaCHFT increased with the magnitude of the osmotic perturbation but saturated at large volume expansions. DeltaCHFT increased with culture time. Electron micrographs showed a clear correlation between time course of CHFT changes and the closure of the lateral interspace (LIS). A striking correlation between the occurrence of CHFT recovery and the ability of the cells to develop a regulatory volume decrease (RVD) was found: Gd3+ (0.5 mM) inhibited both phenomena. The frequency dependence of CT was obtained from impedance spectra recorded over the range of 4 Hz to 22 kHz. These data agree with model calculations in which the contribution of the access resistance to the lateral membrane was included. All observations are consistent with the idea that DeltaCHFT originates from the closure of the LIS during cell swelling. The latter phenomenon increases the access resistance to the lateral membrane, which results in a marked reduction of the basolateral membrane area detected at high frequencies with capacitance measurements.

Frequency-dependent capacitance of the apical membrane of frog skin: dielectric relaxation processes.

Impedance analysis of the isolated epithelium of frog skin (northern Rana pipiens) was carried out in the frequency range between 0.1 Hz and 5.5 kHz while Na+ transport was abolished. Under these conditions, the impedance is determined almost completely by the dielectric properties of the apical membranes of the cells and the parallel shunt resistance. The modeling of the apical membrane impedance function required the inclusion of dielectric relaxation processes as originally described by. J. Chem. Phys. 9:341-351), where each process is characterized by a dielectric increment, relaxation frequency, and power law dependence. We found that the apical plasma membrane exhibited several populations of audio frequency dielectric relaxation processes centered at 30, 103, 2364, and 6604 Hz, with mean capacitive increments of 0.72, 1.00, 0.88, and 0.29 microF/cm2, respectively, that gave rise to dc capacitances of 1.95 +/- 0.06 microF/cm2 in 49 tissues. Capacitance was uncorrelated with large ranges of parallel shunt resistance and was not changed appreciably within minutes by K+ depolarization and hence a decrease in basolateral membrane resistance. A significant linear correlation existed between the dc capacitance and Na+ transport rates measured as short-circuit currents (Cadc = 0.028 Isc + 1.48; Isc between 4 and 35 microA/cm2) before inhibition of transport by amiloride and substitution of all Na+ with NMDG (N-methyl-D-glucamine) in the apical solution. The existence of dominant audio frequency capacitive relaxation processes complicates and precludes unequivocal interpretation of changes of capacitance in terms of membrane area alone when capacitance is measured at audio frequencies.

Apical Cl- channels in A6 cells.

Short-circuit current (Isc), transepithelial conductance (Gt), electrical capacitance (CT) and the fluctuation in Isc were analyzed in polarized epithelial cells from the distal nephron of Xenopus laevis (A6 cell line). Tissues were incubated with Na+- and Cl--free solutions on the apical surface. Basolateral perfusate was NaCl-Ringer. Agents that increase cellular cAMP evoked increases in Gt, CT, Isc and generated a Lorentzian Isc-noise. The responses could be related to active, electrogenic secretion of Cl-. Arginine-vasotocin and oxytocin caused a typical peak-plateau response pattern. Stimulation with a membrane-permeant nonhydrolyzable cAMP analogue or forskolin showed stable increases in Gt with only moderate peaking of Isc. Phosphodiesterase inhibitors also stimulated Cl- secretion with peaking responses in Gt and Isc. All stimulants elicited a spontaneous Lorentzian noise, originating from the activated apical Cl- channel, with almost identical corner frequency (40-50 Hz). Repetitive challenge with the hormones led to a refractory behavior of all parameters. Activation of the cAMP route could overcome this refractoriness. All agents caused CT, a measure of apical membrane area, to increase in a manner roughly synchronous with Gt. These results suggest that activation of the cAMP-messenger route may, at least partly, involve exocytosis of a vesicular Cl- channel pool. Apical flufenamate depressed Cl- current and conductance and apparently generated blocker-noise. However, blocking kinetics extracted from noise experiments could not be reconciled with those obtained from current inhibition, suggesting the drug does not act as simple open-channel inhibitor.

Changes in actin cytoskeleton during volume regulation in C6 glial cells.

Changes in actin cytoskeleton in the C6 rat glial cell line were studied during decrease or increase (abrupt or gradual) of extracellular osmolality. Actin cytoskeleton was visualized by confocal microscopy after FITC-phalloidin labeling. G-actin, Triton-soluble F-actin and Triton-insoluble F-actin subfractions were determined by gel electrophoresis and scanning, and by DNase I inhibition assays. In control conditions C6 glial cells exhibited well-defined stress fibers and a relatively smooth cortical network. Extracellular anisosmotic changes induced a rapid actin cytoskeletal reorganization, which further progressed and was not reversed upon cell volume recovery. Hypotonic shock caused membrane ruffling and a shift towards polymerized actin, whereas hypertonicity (abrupt or gradual) led to a distinct morphological appearance of abundant short actin microfilaments with, however, no detectable alteration in actin subfractions. When anisosmotic cell volume regulation was prevented, cytoskeleton reorganization depended on the osmotic change and the experimental protocol, but was not related to the absence of volume readjustment. Therefore, although involvement of cytoskeletal alterations in transduction of volume regulatory responses cannot be excluded, it is likely that the observed changes in actin cytoskeleton in C6 glial cells are linked with, but do not initiate, cell volume regulatory processes.

Swelling-activated cation-selective channels in A6 epithelia are permeable to large cations.

Effects of basolateral monovalent cation replacements (Na+ by Li+, K+, Cs+, methylammonium, and guanidinium) on permeability to 86Rb of volume-sensitive cation channels (VSCC) in the basolateral membrane and on regulatory volume decrease (RVD), elicited by a hyposmotic shock, were studied in A6 epithelia in the absence of apical Na+ uptake. A complete and quick RVD occurred only when the cells were perfused with Na+ or Li+ saline. With both cations, hypotonicity increased basolateral 86Rb release (RblRb), which reached a maximum after 15 min and declined back to control level. When the major cation was K+, Cs+, methylammonium, or guanidinium, the RVD was abolished. Methylammonium induced a biphasic time course of cell thickness (Tc), with an initial decline of Tc followed by a gradual increase. With K+, Cs+, or guanidinium, Tc increased monotonously after the rapid initial rise evoked by the hypotonic challenge. In the presence of K+, Cs+, or methylammonium, RblRb remained high during most of the hypotonic period, whereas with guanidinium blockage of RblRb was initiated after 6 min of hypotonicity, suggesting an intracellular location of the site of action. With all cations, 0.5 mM basolateral Gd3+ completely blocked RVD and fully abolished the RblRb increase induced by the hypotonic shock. The lanthanide also blocked the additional volume increase induced by Cs+, K+, guanidinium, or methylammonium. When pH was lowered from 7. 4 to 6.0, RVD and RblRb were markedly inhibited. This study demonstrates that the VSCCs in the basolateral membrane of A6 cells are permeable to K+, Rb+, Cs+, methylammonium, and guanidinium, whereas a marked inhibitory effect is exerted by Gd3+, protons, and possibly intracellular guanidinium.