Thermal inactivation of volume-sensitive K⁺,Cl⁻ cotransport and plasma membrane relief changes in human erythrocytes.

Previously, we reported that in mammalian erythrocytes irreversible annealing of spectrin heterodimers at 49-50 °C abolished cell volume-dependent regulation of ion carriers, thus suggesting an implication of a two-dimensional (2D) membrane carcass in volume sensing and/or signal transduction. To further examine this hypothesis, we employed atomic force microscopy. This method revealed folded membrane relief of fixed human erythrocytes with an average wave height of 3-5 nm covered by globular structures with a diameter of 40-50 nm and an average height of 1-2 nm. Erythrocyte swelling caused by reduction of medium osmolality decreased the height of membrane surface waves by 40 % and increased K(+),Cl(-) cotransport by approximately sixfold. Both volume-sensitive changes of membrane relief and activity of K(+),Cl(-) cotransporter were abolished by a 10-min preincubation at 50 °C. Our results strongly suggest that volume-dependent alterations of the human erythrocyte membrane relief are caused by reorganization of the 2D spectrin-actin network contributing to regulation of the activity of volume-sensitive ion transporters.

CFTR fails to inhibit the epithelial sodium channel ENaC expressed in Xenopus laevis oocytes.

The cystic fibrosis transmembrane conductance regulator (CFTR) plays a crucial role in regulating fluid secretion by the airways, intestines, sweat glands and other epithelial tissues. It is well established that the CFTR is a cAMP-activated, nucleotide-dependent anion channel, but additional functions are often attributed to it, including regulation of the epithelial sodium channel (ENaC). The absence of CFTR-dependent ENaC inhibition and the resulting sodium hyperabsorption were postulated to be a major electrolyte transport abnormality in cystic fibrosis (CF)-affected epithelia. Several ex vivo studies, including those that used the Xenopus oocyte expression system, have reported ENaC inhibition by activated CFTR, but contradictory results have also been obtained. Because CFTR-ENaC interactions have important implications in the pathogenesis of CF, the present investigation was undertaken by our three independent laboratories to resolve whether CFTR regulates ENaC in oocytes and to clarify potential sources of previously reported dissimilar observations. Using different experimental protocols and a wide range of channel expression levels, we found no evidence that activated CFTR regulates ENaC when oocyte membrane potential was carefully clamped. We determined that an apparent CFTR-dependent ENaC inhibition could be observed when resistance in series with the oocyte membrane was not low enough or the feedback voltage gain was not high enough. We suggest that the inhibitory effect of CFTR on ENaC reported in some earlier oocyte studies could be attributed to problems arising from high levels of channel expression and suboptimal recording conditions, that is, large series resistance and/or insufficient feedback voltage gain.

Evaluation of rapid volume changes of substrate-adherent cells by conventional microscopy 3D imaging.

Precise measurement of rapid volume changes of substrate-adherent cells is essential to understand many aspects of cell physiology, yet techniques to evaluate volume changes with sufficient precision and high temporal resolution are limited. Here, we describe a novel imaging method that surveys the rapid morphology modifications of living, substrate-adherent cells based on phase-contrast, digital video microscopy. Cells grown on a glass substrate are mounted in a custom-designed, side-viewing chamber and subjected to hypotonic swelling. Side-view images of the rapidly swelling cell, and at the end of the assay, an image of the same cell viewed from a perpendicular direction through the substrate, are acquired. Based on these images, off-line reconstruction of 3D cell morphology is performed, which precisely measures cell volume, height and surface at different points during cell volume changes. Volume evaluations are comparable to those obtained by confocal laser scanning microscopy (DeltaVolume < or = 14%), but our method has superior temporal resolution limited only by the time of single-image acquisition, typically approximately 100 ms. The advantages of using standard phase-contrast microscopy without the need for cell staining or intense illumination to monitor cell volume make this system a promising new tool to investigate the fundamentals of cell volume physiology.

Purinergic-induced ion current in monolayers of C7-MDCK cells: role of basolateral and apical ion transporters.

This study examines purinergic modulation of short-circuit current (I(SC)) in monolayers of C7- and C11-MDCK cells resembling principal and intercalated cells from collecting ducts. In C7 monolayers, basolateral and apical application of ATP led to similar elevation of I(SC), consisting of a transient phase with maximal I(SC) increment of approximately 10 microA/cm2 terminating in 2-3 min, and a sustained phase with maximal I(SC) less than 2 microA/cm2 and terminating in 10 min. ATP-induced I(SC) was insensitive to the presence of Na+, Cl- and inhibitors of K+ (Ba2+, charibdotoxin (ChTX), clotrimazole (CLT), apamin) and Na + (amiloride) channels in the mucosal solution. Inhibitors of Cl- channels, DIDS and NPPB, added to apical membranes at a concentration of 100 microM, did not affect ATP-induced I(SC), whereas at 500 microM, NPPB inhibited it by 70-80%. Substitution of Cl- with NO3- in serosal medium decreased ATP-induced I(SC) by 2-3-fold and elevation of [K+]o from 6 to 60 mM changed its direction. Basolateral NPPB inhibited I(SC) by 10-fold with ED50 of approximately 30 microM, whereas ChTX (50 nM) and CLT (2 microM) diminished this parameter by 30-50%. Suppression of Na+, K+, Cl- cotransport with bumetanide did not affect the transient phase of ATP-induced I(SC) and slightly diminished its sustained phase. ATP increased ouabainand bumetanide-resistant K+ (86Rb) influx across the basolateral membrane by 7-8-fold, which was partially inhibited with ChTX and CLT. ATP-treated C11 cells exhibited negligible I(SC), and their presence did not affect I(SC) triggered by ATP in C7 cells. Thus, our results show that transcellular ion current in ATP-treated C7 cells is mainly caused by the coupled function of apical and basolateral anion transporters providing transient Cl- secretion. These transporters possess different sensitivities to anion channel blocker NPBB and are under the control of basolateral K+ channels(s) inhibited by ChTX and CLT.

Swelling-induced K(+) fluxes in vascular smooth muscle cells are mediated by charybdotoxin-sensitive K(+) channels.

This study examines the relative contributions of K-Cl cotransport and K(+) channels to swelling-induced K(+) fluxes in vascular smooth muscle cells (VSMC). DIOA known as a potent inhibitor of erythrocyte K-Cl cotransport exerts diverse side-effects on VSMC and can not be used to analyze the role of this carrier in swelling-induced K(+) fluxes. Other inhibitors of K-Cl cotransport (furosemide, okadaic acid and calyculin A) did not affect K(+) fluxes in VSMC triggered by swelling. Swelling-induced K(+) fluxes in VSMC were also not affected by K(+) channel blockers such as TEA, glibenclamide and apamin, but were blocked by Ba(2+) and charybdotoxin (ChTX), a potent inhibitor of Ca(2+)- and voltage-gated K(+) channels. Swelling-induced K(+) influx in VSMC was diminished in Ca(2+)-free medium and in cells loaded with Ca(2+) chelator BAPTA, but was not accompanied by detectable elevation of [Ca(2+)](i). In contrast to Ca(2+)-induced hyperpolarization of erythrocytes triggered by activation of intermediate conductance Ca(2+)-gated K(+) channels (IK(Ca)), neither clotrimazole nor calmodulin antagonists (R24571, trifluoroperazine, fluphenazine) affected swelling-induced K(+) influx in VSMC. In conclusion, K(+) fluxes triggered in swollen VSMC are mediated by Ba(2+)- and ChTX-sensitive K(+) channels. These channels are distinct from IK(Ca) expressed in erythrocytes. Their molecular origin and systems involved in the swelling-induced Ca(2+)(i)-independent signal transduction pathway need further investigation.

Downregulation of epithelial sodium channel (ENaC) by CFTR co-expressed in Xenopus oocytes is independent of Cl- conductance.

Defective regulatory interactions between the cystic fibrosis conductance regulator (CFTR) and the epithelial sodium channel (ENaC) have been implicated in the elevated Na+ transport rates across cystic fibrosis airway epithelium. It has recently been proposed that ENaC downregulation by CFTR depends on the ability of CFTR to conduct Cl- into the cell and is negligible when Cl- flows out of the cell. To study the mechanisms of this downregulation we have measured amiloride-inhibitable Na+ current (Iamil) in oocytes co-expressing rat ENaC and human wild-type CFTR. In oocytes voltage-clamped to -60 mV, stimulating CFTR with 1 mm IBMX reduced Iamil by up to 80%, demonstrating that ENaC is inhibited when Cl- is conducted out of the cell. Decreasing the level of CFTR stimulation in a single oocyte, decreased both the degree of Iamil downregulation and the CFTR-mediated plasma membrane Cl- conductance, suggesting a direct correlation. However, Iamil downregulation was not affected when Cl- flux across oocyte membrane was minimized by holding the oocyte membrane potential near the Cl- reversal potential (67% +/- 10% inhibition at -20 mV compared to 79% +/- 4% at -60 mV) demonstrating that Iamil downregulation was independent of the amount of current flow through CFTR. Studies with the Ca2+-sensitive photoprotein aequorin showed that Ca2+ is not involved in Iamil downregulation by CFTR, although Ca2+ injection into the cytoplasm did inhibit Iamil. These results demonstrate that downregulation of ENaC by CFTR depends on the degree of CFTR stimulation, but does not involve Ca2+ and is independent of the direction and magnitude of Cl- transport across the plasma membrane.

A Ca2+- and voltage-dependent cation channel in the nuclear envelope of red beet.

The patch-clamp technique was applied to study ion conductances in various configurations of the nuclear envelope of non-enzyme-treated red beet (Beta vulgaris L.) nuclei. With excised patches a non-selective cation channel was observed, that was activated by micromolar concentrations of Ca2+ on the nucleoplasmic side of the envelope. The channel activity was also voltage-dependent and the voltage threshold of channel activation changed with the nucleoplasmic Ca2+ concentration. The most prominent conductance level was 110+/-22 pS with 150 mM KCl in the bath and pipette. The channel was permeable to small cations: permeabilities relative to K+ were PK congruent with PNa=1, PCs=0.3, but PCl=0.09. Calcium ions also permeated the channel with PCa=0.43, estimated from reversal potential, or 0.14, estimated from conductance ratio. Zn2+ (1 mM) when applied to the cytoplasmic side of the envelope blocked the channel activity completely, while amiloride (2 mM) reduced the channel current by 86% from the nucleoplasmic side. The properties of the whole-nucleus current (voltage-, time- and Ca2+-dependence) paralleled those observed with excised patches. The channel may provide a Ca2+-regulated pathway for passive diffusion of cations across the nuclear envelope and thus may play an important role in Ca2+-dependent nuclear processes ranging from gene transcription to apoptosis.

Evidence for the distinct nature of F2-isoprostane receptors from those of thromboxane A2.

In rat glomeruli and mesangial cells, the thromboxane A2 (TxA2) mimetic, U-46,619, but not 8-iso-prostaglandin F2alpha (8-iso-PGF2alpha), reduced glomerular inulin space and increased inositol 1,4,5-trisphosphate production, effects abolished by SQ-29,548. In competitive binding studies using 8-iso-[3H]PGF2alpha or [3H]SQ-29,548, mesangial cells displayed TxA2 binding sites but not ones for 8-iso-PGF2alpha. In contrast, rat aortic smooth muscle cells possessed specific binding sites for both TxA2 and 8-iso-PGF2alpha and displayed functional responses to both agonists, such as time- and dose-dependent activation of mitogen-activated protein kinases. In these cells, the mean dissociation constant value for the isoprostane receptor was 31.8 +/- 5.7 nM. When human TxA2 receptor cDNA was expressed in Xenopus oocytes injected with the Ca2+-specific photoprotein, aequorin, 8-iso-PGF2alpha gave much weaker responses than U-46,619. These studies provide the first radioligand binding characteristics of the F2-isoprostane receptor and demonstrate its specific and heterologous cellular localization. These studies support the distinct nature and biological significance of isoprostane receptors and provide a tool for their further molecular characterization.

CFTR-independent ATP release from epithelial cells triggered by mechanical stimuli.

Cystic fibrosis transmembrane conductance regulator (CFTR)-mediated ATP efflux has been proposed as an autocrine mechanism for regulating chloride secretion through other types of chloride channels. Although we found in previous studies that wild-type CFTR channels bathed with high-ATP solutions do not conduct ATP at rates that can be measured with the patch-clamp technique, those experiments would not have detected very small or electroneutral ATP fluxes through CFTR or ATP efflux through other pathways that might be regulated by CFTR. To examine these possibilities, we have now used a sensitive luciferase luminometric assay to measure ATP efflux from epithelial and nonepithelial cell lines. Adenosine 3',5'-cyclic monophosphate (cAMP) stimulation did not raise external ATP concentration above the background noise in any of the cell lines tested [T84, Calu-3, 9HTEo- and sigma CFTE29o- (colonic and airway human epithelial cells, respectively), NIH/3T3 fibroblasts, and Chinese hamster ovary cells], and variations in ATP release were not correlated with CFTR expression. The rate of ATP release was unaffected by cAMP but was exquisitely sensitive to mechanical perturbations in both CFTR expressing and nonexpressing cells. Mechanically induced, CFTR-independent ATP release may be a physiologically relevant mechanism of epithelial regulation, which has not previously been fully appreciated.

Regulation of the CFTR chloride channel from humans and sharks.

The cystic fibrosis transmembrane conductance regulator (CFTR) in an ATP-dependent channel which mediates cAMP-stimulated chloride secretion by epithelia, particularly those of the pancreas, airways, and intestine. CFTR homologues have been found in all higher vertebrates examined to date and also in some lower vertebrates, although only the human, shark, and Xenopus genes have been heterologously expressed and shown to generate protein kinase A-activated Cl channels. Once phosphorylated, CFTR channels require hydrolyzable nucleotides to be active, but they can be locked in an open burst state when exposed to mixtures of ATP and its hydrolysis-resistant analogue AMP-PNP. This locking requires low-level phosphorylation at unidentified sites that are not among the ten "strong" (dibasic) PKA consensus sequences on CFTR. Mutagenesis of the dibasic PKA sites, which reduces in vitro phosphorylation by > 98%, reduces open probability (Po) by about 50% whilst having no effect on burst duration. Thus, incremental phosphorylation of these sites under normal conditions does not increase Po by slowing down ATP hydrolysis and stabilizing the open burst state, although locking does strictly require low-level phosphorylation at one or more cryptic sites. In addition to serving as a Cl channel, there is compelling evidence that CFTR inhibits the amiloride-sensitive, epithelial sodium channel (ENaC). The mechanism of coupling is not known but most likely involves physical interactions between the channels, perhaps mediated by an intermediate protein that impinges on other transport proteins. CFTR does not function as a conductive channel for ATP; however, extracellular ATP does regulate epithelial channels through activation of P2U purinergic receptors and, after being hydrolyzed extracellularly, through activation of adenosine receptors which elevate cAMP.

Detection of intracellular calcium elevations in Xenopus laevis oocytes: aequorin luminescence versus electrophysiology.

Detection of receptor expression in Xenopus oocytes often relies upon functional coupling to second messengers such as Ca2+ or cyclic adenosine monophosphate. To detect intracellular Ca2+, electrophysiological measurement of the endogenous Ca(2+)-activated chloride current (ICl(Ca)) is often used (Dascal, 1987). An alternative utilizes the Ca2+ sensing, bioluminescent protein aequorin (Parker and Miledi(1986) Proc. R. Soc. Lond. B, 228: 307-315; Giladi and Spindel (1991) BioTechniques, 10: 744-747). In the present study the sensitivities of aequorin and electrophysiology for detecting receptor-mediated Ca2+ transients were compared. Assays were performed on the same batches of oocytes using either animal serum or ligands of exogenous receptors to generate inositol 1,4,5-trisphosphate (InsP3) and ultimately elevate intracellular Ca2+. Signal amplitudes were controlled by titrating the concentration of animal serum, or titrating the amount of receptor mRNA injected. Both assays detected signals with high concentrations of animal serum, or with high receptor density. However, aequorin signals were not detected in experiments with average ICl(Ca) current amplitudes below 200 nA. To further evaluate the differences between these two techniques, membrane current and bioluminescence were measured simultaneously. Results of these studies suggest that the signals differ due to the spatial distribution of aequorin, the chloride channels, and the calcium release sites.

CFTR channels expressed in CHO cells do not have detectable ATP conductance.

The cystic fibrosis transmembrane conductance regulator (CFTR) is a cAMP-activated, ATP-dependent chloride channel which may have additional functions. Recent reports that CFTR mediates substantial electrodiffusion of ATP from epithelial cells have led to the proposal that CFTR regulates other ion channels through an autocrine mechanism involving ATP. The aim of this study was to determine the ATP conductance of wild-type CFTR channels stably expressed in Chinese hamster ovary cells using patch clamp techniques. In the cell-attached configuration with 100 mM Mg middle dot ATP or Tris middle dot ATP solution in the pipette and 140 mM NaCl in the bath, exposing cells to forskolin caused the activation of a low-conductance channel having kinetics resembling those of CFTR. Single channel currents were negative at the resting membrane potential (Vm), consistent with net diffusion of Cl from the cell into the pipette. The transitions decreased in amplitude, but did not reverse direction, as Vm was clamped at increasingly positive potentials to enhance the driving force for inward ATP flow (>+80 mV). In excised patches, single channel currents did not reverse under essentially biionic conditions (Clin/ATPout or ATPin/Clout), although PKA-activated currents were clearly visible in the same patches at voltages where they would be carried by chloride ions. Moreover, with NaCl solution in the bath and a mixture of ATP and Cl in the pipette, the single channel I/V curve reversed at the predicted equilibrium potential for chloride. CFTR channel currents disappeared when patches were exposed to symmetrical ATP solutions and were restored by reexposure to Cl solution. Finally, in the whole-cell configuration with NaCl in the bath and 100 mM MgATP or TrisATP in the pipette, cAMP-stimulated cells had time-independent, outwardly rectifying currents consistent with CFTR selectivity for external Cl over internal ATP. Whole-cell currents reversed near Vm = -55 mV under these conditions, however the whole cell resistance measured at -100 mV was comparable to that of the gigaohm seal between the plasma membrane and glass pipette (7 Gomega). We conclude that CFTR does not mediate detectable electrodiffusion of ATP.

Failure of the cystic fibrosis transmembrane conductance regulator to conduct ATP.

The cystic fibrosis transmembrane conductance regulator (CFTR) is a chloride ion channel regulated by protein kinase A and adenosine triphosphate (ATP). Loss of CFTR-mediated chloride ion conductance from the apical plasma membrane of epithelial cells is a primary physiological lesion in cystic fibrosis. CFTR has also been suggested to function an an ATP channel, although the size of the ATP anion is much larger than the estimated size of the CFTR pore. ATP was not conducted through CFTR in intact organs, polarized human lung cell lines, stably transfected mammalian cell lines, or planar lipid bilayers reconstituted with CFTR protein. These findings suggest that ATP permeation through the CFTR is unlikely to contribute to the normal function of CFTR or to the pathogenesis of cystic fibrosis.

Detection of adenylate cyclase-coupled receptors in Xenopus oocytes by coexpression with cystic fibrosis transmembrane conductance regulator.

To detect heterologous expression of receptors coupled via G proteins to the stimulation of adenylate cyclase in Xenopus laevis oocytes, the receptor of interest is coexpressed with the cystic fibrosis transmembrane conductance regulator (CFTR)--a cAMP-dependent Cl- channel. The binding of an agonist to the expressed receptor stimulates adenylate cyclase resulting in intracellular cAMP elevation, which in turn activates the CFTR. The CFTR-mediated Cl- current response is then measured using the standard two-electrode voltage-clamp technique. This method has allowed us to detect functional expression in oocytes of the human EP2 and IP prostanoid receptors. This method should prove valuable for expression and identification of putative G protein-coupled receptors signaling through stimulation of adenylate cyclase, for structure/function studies, and for analysis of receptor antagonists and agonists.

Cloning and expression of a cDNA for the human prostanoid IP receptor.

A cDNA clone coding for a functional human prostanoid IP receptor has been isolated from a lung cDNA library. The human IP receptor consists of 386 amino acid residues with a predicted molecular mass of 40,961, and has the seven putative transmembrane domains characteristic of G-protein-coupled receptors. Challenge of Xenopus oocytes co-expressing the IP receptor and the cystic fibrosis transmembrane conductance regulator (cAMP-activated Cl- channel) with the stable prostacyclin analog iloprost resulted in specific inward Cl- currents, demonstrating that the cDNA encoded a functional IP prostanoid receptor coupled to elevation in cAMP. Radioreceptor binding studies using membranes prepared from mammalian COS cells transfected with the IP receptor cDNA showed that the rank order of potency for prostaglandins and prostaglandin analogs in competition for [3H]iloprost specific binding sites was as predicted for the IP receptor, with iloprost >> carbacyclin >> prostaglandin (PG) E2 > PGF 2 alpha = PGD2 = U46619. Northern blot analysis showed that IP mRNA was most abundantly expressed in kidney, with lesser amounts detected in lung and liver. In summary, we have cloned and expressed a cDNA for the human prostanoid IP receptor that is functionally coupled to a signaling pathway involving stimulation of intracellular cAMP production.

Cloning, functional expression, and characterization of the human prostaglandin E2 receptor EP2 subtype.

A cDNA clone encoding the human prostaglandin (PG) E2 receptor EP2 subtype has been isolated from a human lung cDNA library. The 1.9-kilobase pair cDNA, hEP2, encodes for a 488-amino acid protein with a predicted molecular mass of 53,115 and has the seven putative transmembrane domains characteristic of G protein-coupled receptors. The specific binding of [3H]PGE2 to COS cell membranes transfected with the hEP2 cDNA was of high affinity with an equilibrium dissociation constant (Kd) of 1 nM and the rank order of potency for prostaglandins in competition for [3H]PGE2 specific binding was PGE1 = PGE2 >> iloprost > PGF2 alpha > PGD2. In competition studies using more selective prostanoid-receptor agonist and antagonists, the [3H]PGE2 specific binding was competed by MB28767, an EP3 agonist, but not by the EP1-preferring antagonists AH6809 and SC19220, or by the EP2 agonist butaprost. Electrophysiological studies of Xenopus oocytes co-injected with hEP2 and cystic fibrosis transmembrane conductance regulator (cAMP-activated Cl- channel) cDNAs detected PGE2-specific inward Cl- currents, demonstrating that the hEP2 cDNA encoded a functional receptor which produced an increase in cAMP levels. Thus, we have cloned the human EP2 receptor subtype which is functionally coupled to increase in cAMP. Northern blot analysis showed that hEP2 is expressed as a 3.8-kilobase mRNA in a number of human tissues with the highest expression levels present in the small intestine.

Cloning and expression of a cDNA for the human prostanoid FP receptor.

A cDNA clone coding for a functional human prostanoid FP receptor has been isolated from a uterus cDNA library. The human FP receptor consists of 359 amino acid residues with a predicted molecular mass of 40,060, and has the seven putative transmembrane domains characteristic of G-protein-coupled receptors. Challenge of Xenopus oocytes expressing the FP receptor with 10 nM of either prostaglandin (PG) F2 alpha or the selective FP-receptor agonist fluprostenol resulted in an elevation in intracellular Ca2+. Radioreceptor binding studies using membranes prepared from mammalian COS cells transfected with the FP receptor cDNA showed that the rank order of potency for prostaglandins and prostaglandin analogs in competition for [3H]PGF2 alpha specific binding sites was as predicted for the FP receptor, with PGF2 alpha approximately fluprostenol > PGD2 > PGE2 > U46619 > iloprost. In summary, we have cloned the human prostanoid FP receptor which is functionally coupled to the Ca2+ signalling pathway.