Purinergic signalling - a possible mechanism for KCNQ1 channel response to cell volume challenges.

AIM: A number of K(+) channels are regulated by small, fast changes in cell volume. The mechanisms underlying cell volume sensitivity are not known, but one possible mechanism could be purinergic signalling. Volume activated ATP release could trigger signalling pathways that subsequently lead to ion channel stimulation and cell volume back-regulation. Our aim was to investigate whether volume sensitivity of the voltage-gated K(+) channel, KCNQ1, is dependent on ATP release and regulation by purinergic signalling. METHODS: We used Xenopus oocytes heterologously expressing human KCNQ1, KCNE1, water channels (AQP1) and P2Y2 receptors. ATP release was monitored by a luciferin-luciferase assay and ion channel conductance was recorded by two-electrode voltage clamp. RESULTS: The luminescence assay showed that oocytes released ATP in response to mechanical, hypoosmotic stimuli and hyperosmotic stimuli. Basal ATP release was approx. three times higher in the KCNQ1 + AQP1 and KCNQ1 injected oocytes compared to the non-injected ones. Exogenously added ATP (0.1 mm) did not have any substantial effect on volume-induced KCNQ1 currents. Nevertheless, apyrase decreased all currents by about 50%. Suramin inhibited about 23% of the KCNQ1 volume sensitivity. Expression of P2Y2 receptors stimulated endogenous Cl(-) channels, but it also led to 68% inhibition of the KCNQ1 currents. Adenosine (0.1 mm) also inhibited the KCNQ1 currents by about 56%. CONCLUSION: Xenopus oocytes release ATP in response to mechanical stimuli and cell volume changes. Purinergic P2 and P1 receptors confer some of the KCNQ1 channel volume sensitivity, although endogenous adenosine receptors and expressed P2Y2 receptors do so in the negative direction.

Chemosensory function of amphibian skin: integrating epithelial transport, capillary blood flow and behaviour.

Terrestrial anuran amphibians absorb water across specialized regions of skin on the posterioventral region of their bodies. Rapid water absorption is mediated by the insertion of aquaporins into the apical membrane of the outermost cell layer. Water moves out of the epithelium via aquaglyceroporins in the basolateral membrane and into the circulation in conjunction with increased capillary blood flow to the skin and aquaporins in the capillary endothelial cells. These physiological responses are activated by intrinsic stimuli relating to the animals' hydration status and extrinsic stimuli relating to the detection of osmotically available water. The integration of these processes has been studied using behavioural observations in conjunction with neurophysiological recordings and studies of epithelial transport. These studies have identified plasma volume and urinary bladder stores as intrinsic stimuli that activate the formation of angiotensin II (AII) to stimulate water absorption behaviour. The coordinated increase in water permeability and capillary blood flow appears to be mediated primarily by sympathetic stimulation of beta adrenergic receptors, although the neurohypopyseal hormone arginine vasotocin (AVT) may also play a role. Extrinsic stimuli relate primarily to the ionic and osmotic properties of hydration sources. Toads avoid NaCl solutions that have been shown to be harmful in acute exposure, approx. 200-250 mm. The avoidance is partially attenuated by amiloride raising the hypothesis that the mechanism for salt detection by toads resembles that for salt taste in mammals that take in water by mouth. In this model, depolarization of the basolateral membrane of taste cells is coupled to afferent neural stimulation. In toad skin we have identified innervation of skin epithelial cells by branches of spinal nerves and measured neural responses to NaCl solutions that elicit behavioural avoidance. These same concentrations produce depolarization of the basolateral membrane in isolated epithelial preparations. As with salt taste in mammals, the neural responses and depolarization of basolateral membrane potential are partially inhibited by amiloride. In addition, toads are more tolerant of sodium gluconate solution which is consistent with the phenomenon in mammalian taste physiology termed the anion paradox in which sodium salts with larger molecular weight anions produce a reduced intensity of salt taste. Finally, toads also avoid concentrated solutions of a non-electrolyte, mannitol, which differs from NaCl solutions in not affecting transepithelial conductance and requires a longer time to depolarize the basolateral membrane. Osmotic stimuli may mediate sensory processes for longer term detection of conditions with low water potential while ionic stimuli are more important for shorter term analysis of rehydration sources.

The lateral intercellular space as osmotic coupling compartment in isotonic transport.

Solute-coupled water transport and isotonic transport are basic functions of low- and high-resistance epithelia. These functions are studied with the epithelium bathed on the two sides with physiological saline of similar composition. Hence, at transepithelial equilibrium water enters the epithelial cells from both sides, and with the reflection coefficient of tight junction being larger than that of the interspace basement membrane, all of the water leaves the epithelium through the interspace basement membrane. The common design of transporting epithelia leads to the theory that an osmotic coupling of water absorption to ion flow is energized by lateral Na(+)/K(+) pumps. We show that the theory accounts quantitatively for steady- and time dependent states of solute-coupled fluid uptake by toad skin epithelium. Our experimental results exclude definitively three alternative theories of epithelial solute-water coupling: stoichiometric coupling at the molecular level by transport proteins like SGLT1, electro-osmosis and a 'junctional fluid transfer mechanism'. Convection-diffusion out of the lateral space constitutes the fundamental problem of isotonic transport by making the emerging fluid hypertonic relative to the fluid in the lateral intercellular space. In the Na(+) recirculation theory the 'surplus of solutes' is returned to the lateral space via the cells energized by the lateral Na(+)/K(+) pumps. We show that this theory accounts quantitatively for isotonic and hypotonic transport at transepithelial osmotic equilibrium as observed in toad skin epithelium in vitro. Our conclusions are further developed for discussing their application to solute-solvent coupling in other vertebrate epithelia such as small intestine, proximal tubule of glomerular kidney and gallbladder. Evidence is discussed that the Na(+) recirculation theory is not irreconcilable with the wide range of metabolic cost of Na(+) transport observed in fluid-transporting epithelia.

Proton pump activity is required for active uptake of chloride in isolated amphibian skin exposed to freshwater.

Net proton secretion and unidirectional chloride fluxes were measured in isolated skin of toads ( Bufo bufo) and frogs ( Rana esculenta) mounted in an Ussing chamber and exposed to a Ringer's solution on the serosal side and a freshwater-like solution (1-3 mM Cl(-)) on the external side. Active proton secretion was 34.2+/-2.0 pmol.cm(-2).s(-1) ( n=18) in frog skin, and 16.7+/-1.7 pmol.cm(-2).s(-1) ( n=10) in toad skin. Proton secretion by toad skin was dependent on the transepithelial potential ( V(T)), and an amiloride-insensitive short-circuit current was stimulated by exogenous CO(2)/HCO(3)(-), indicating the presence of a rheogenic proton pump. Cl(-) influx was 37.4+/-7.5 pmol.cm(-2).s(-1) ( n=14) in frog skin and 19.5+/-3.5 pmol.cm(-2).s(-1) ( n=11) in toad skin. In toad skin, the mean Cl(-) flux ratio was larger than expected for simple electro-diffusion. In 8 of 11 sets of paired skins, influx was greater than the efflux indicating active uptake of Cl(-). Cl(-) influx in toad skin was unaffected by large perturbations (100-150 mV) of V(T), which was accomplished by adding amiloride to the outer bath under open circuit conditions. A component of the Cl(-) efflux seemed to be dependent on V(T). 4,4'-Diisothiocyanato-stilbene-2,2'-disulfonic acid (DIDS; 0.3 mM or 1.3 mM) inhibited Cl(-) influx and, surprisingly, increased Cl(-) efflux in toad skin. Influx and efflux of Cl(-) in toad skin were highly dependent on the external [Cl(-)] in the freshwater range (0.1-4 mM). (36)Cl(-) influx decreased whereas the total Cl(-) efflux increased as a function of external [Cl(-)]. These data indicate the presence of a DIDS-sensitive, electroneutral carrier mechanism with an external binding site for Cl(-). Ethoxzolamide (100 micro M), an inhibitor of carbonic anhydrase, reduced proton secretion and Cl(-) influx in frog skin. Concanamycin A (0.1-10 micro M), a specific vacuolar-type proton pump (V-ATPase) inhibitor, significantly reduced proton secretion in frog skin. In addition, concanamycin A (1 micro M) significantly reduced Cl(-) influx in frog skin. We suggest that the active proton secretion and Cl(-) influx are coupled. We hypothesise that an apical V-ATPase is capable of energising active Cl(-) uptake in fresh water by creating a favourable gradient for an apical HCO(3)(-) exit in exchange for external Cl(-). The data also suggest that a carbonic anhydrase activity provides H(+) and HCO(3)(-) for apically co-expressed proton pumps and Cl(-)/HCO(3)(-) exchangers.

Expression of cystic fibrosis transmembrane conductance regulator in the skin of the toad, Bufo bufo and possible role for Cl- transport across the heterocellular epithelium.

Evidence is discussed that apical CFTR Cl- channels of mitochondria-rich (MR) cells of Bufo bufo skin conduct beta-adrenergic receptor-activated Cl- currents. Ussing chambers studies revealed the following selectivity sequence of the receptor activated conductance, Cl- > Br- > NO3- > I-. With ion selective microelectrode-techniques, it was shown that receptor-coupled Cl- channels are not located in principal cells. A small conductance (7-10 pS) CFTR-like Cl- channel is located in the apical plasma membrane of MR cells. Short life times of sealed patches prevented detailed study of its selectivity to other halide ions and its molecular regulation. With monoclonal hCFTR-antibodies, selective expression in MR cells of the targeted antigens could be demonstrated. A transcript of CFTR was amplified in the skin, and a bbCFTR cDNA clone was generated from toad skin mRNA that exhibits 89% amino acid identity with the human homologue. The frequency of obtaining channels in patch clamp studies was too low for accounting quantitatively for the macroscopic conductance. Since MR cells were isolated by trypsin, and a putative extracellular loop of the deduced bbCFTR protein contains a target peptide bond for trypsin, enzyme treatment may have destroyed apical CFTR molecules.

Role of mitochondria-rich cells for passive chloride transport, with a discussion of Ussing's contribution to our understanding of shunt pathways in epithelia.

A non-invasive method is applied for studying ion transport by single isolated epidermal mitochondria-rich (MR) cells. MR cells of toad skin (Bufo bufo) were prepared by trypsin (or pronase) treatment of the isolated epithelium bathed in Ca2+-free Ringer. Glass pipettes were pulled and heat- polished to obtain a tip of 2-4 mm with parallel walls and low tip resistances. The neck of an MR-cell was sucked into the tip of the pipette for being 'clamped mechanically' by the heat-polished glass wall. In this configuration the apical cell membrane faces the pipette solution while the major neck region and the cell body are in the electrically grounded bath. With Ringer in bath and pipette, transcellular voltage clamp currents were composed of an ohmic (I(leak)) and a dynamic (I(dynamic)) component. The dynamic component was studied by stepping the transcellular potential (Vp) from a holding value of +50 mV to the hyperpolarizing region (50 > Vp > or = -100 mV). The steady state I(dynamic)-Vp relationship was strongly outward rectified with I(dynamic) being practically zero for Vp > 0 mV. At Vp = -100 mV, MR cells isolated by trypsin or pronase generated a steady-state I(dynamic) of,-2.72 +/- 0.40 nA/cell (N = 21 MR cells). Continuous superfusion of the MR cell during recording increased the current to -7.99 +/- 1.48 nA/cell (N = 10 MR cells). The time course of the reversible activation of G(dynamic) varied among cells, but was usually sigmoid with T1/2 decreasing with Vp (-25 > or = Vp > or = -100 mV). T1/2 was in the order of 10 sec at Vp = -100 mV. The single-MR-cell currents recorded in this study are fully compatible with Cl- currents estimated by relating density of MR cells to transepithelial ICl or by measurements with the self-referencing ('vibrating') probe technique. In the discussion, Ussing's work on epithelial shunt pathways is considered. His thinking and experiments leading to his theory of isotonic transport in leaky epithelia is emphasized. It is our thesis that the understanding of the physiology of epithelia owes as much to Ussing's studies of shunt pathways as to his studies of the active sodium pathway.

Chloride channels in the plasma membrane of a foetal Drosophila cell line, S2.

We evaluated the suitability of the S2 foetal Drosophila cell line as an expression system for vertebrate anion channel proteins (e.g. cystic fibrosis transmembrane conductance regulator, CFTR) in patch-clamp studies of the endogenous ion channels. In the inside-out configuration (symmetric 150 mM Cl-) we found most frequently an inwardly rectifying Cl- channel with single-channel conductances (gamma) of 57, 45 and 17 pS at -80, 0 and 80 mV, respectively. Reduction of bath [Cl-] to 40 mM caused a shift in reversal potential (Vrev) to -22.5 mV indicating pronounced Cl- selectivity. In the outside-out configuration ([Cl-]pipette = 40 mM, [Cl-]bath = 150 mM) we observed a Cl- channel with a linear unitary current/voltage (i/V) relation for which gamma was 30 pS. The kinetics were quite slow in both configurations. Cl-selectivity was also observed in whole-cell experiments ([Cl-]pipette = 40 mM) in which a Vrev of -43.8 mV, i.e. close to the Cl- equilibrium potential, demonstrated that the membrane current was dominated by Cl-. We conclude that the important features making S2 cells suitable as an expression system for heterologous expressed anion channel proteins are: small total whole-cell currents (less than 100 pA), single-channel and whole-cell currents that, unlike those of CFTR, cannot be described by the Goldman-Hodgkin-Katz regime, and slow kinetics distinctly different from those of CFTR.

Comparative aspects of actions of a short-chain phospholipid on epithelial Na+ channels and tight junction conductance.

Ion transport in both the frog skin (a high-resistance epithelium) and the rabbit nasal airway epithelium (a low-resistance epithelium) are dominated by electrogenic Na+ absorption via apical membrane amiloride-sensitive Na+ channels, and short-circuit current (ISC) is essentially a measure of Na+ absorption in both epithelia. In both epithelia, mucosal application of the short-chain phospholipid didecanoyl-L-alpha-phosphatidylcholine (DDPC) dose-dependently inhibited the amiloride-sensitive ISC and caused an initial decrease in epithelial conductance (Gt) followed by an increase in Gt to steady-state values above control level. The effects were reversible. It is concluded that DDPC (a) inhibits epithelial amiloride-sensitive Na+ channels and (b) induces an increase in paracellular tight junction conductance. These effects may involve changes in non-specific lipid-protein interactions at the cell membrane level.

Interference of a short-chain phospholipid with ion transport pathways in frog skin.

The effects of mucosal application of the short-chain phospholipid didecanoyl-L-alpha-phosphatidylcholine (DDPC; with two saturated 10-carbon acyl chains) on active Na+ transport and transepithelial conductance (G) in the frog skin (Rana temporaria) were investigated. Active Na+ transport was measured as the amiloride-sensitive short-circuit current (ISC) and G was determined from transepithelial voltage-clamp pulses under short-circuit conditions. DDPC dose-dependently inhibited ISC with an ID50 of about 0.05% (w/v) and a maximal effect ( approximately 55%) at >/= 1% DDPC. G increased to steady-state values above control level. Simultaneously, equal increases in unidirectional sucrose permeabilities (PSu; measured from [14C]sucrose fluxes) were observed, and a positive correlation was demonstrated between DDPC-induced changes in PSu and G. Since amiloride did not prevent the increase in G by DDPC, these results suggest that the DDPC-induced increase in G represents an increase in the paracellular shunt conductance. The effects of mucosal DDPC were almost fully reversible within 8 h. The results indicate that DDPC inhibits amiloride-sensitive Na+ channels in the apical membrane of the frog skin epithelium and opens a paracellular tight junction pathway. Both effects may be caused by incorporation of DDPC in the apical cell membrane.

Identification of anion-selective channels in the basolateral membrane of mitochondria-rich epithelial cells.

Epithelial cells of toad (Bufo bufo) skin were isolated by treatments of the epidermis with collagenase and trypsin. Cl- channels in the basolateral membrane from soma or neck of mitochondria-rich cells were studied in cell-attached and excised inside-out configurations. Of a total of 87 sealed patches only 28 (32%) were electrically active, and in these we identified four different types of Cl- channels. The two major populations constituted Ohmic Cl- channels with limiting conductance (gamma125/125) of 10 pS and 30 pS, respectively. A much rarer 150 pS Ohmic Cl- channel was also characterized. From i/V relationships of individual channels the following Goldman-Hodgkin-Katz permeabilities were calculated, 2.2 (+/-0.1) x 10(-14), 5.7 (+/-0.7) x 10(-14), and 32 (+/-2) x 10(-14) cm3/sec, for the 10, 30 and 150 pS Cl- channels, respectively. The 30 pS channel was activated by hyperpolarization. The gating kinetics of the 150 pS channel was complex with burstlike closures within openings of long duration. The fourth type of Cl- channel was studied in patches generating 'noisy currents' with no discrete single-channel events, but with vanishing fluctuations at pipette potentials near ECl. Noise analysis revealed a power spectrum with cutoff frequencies of 1.2 and 13 Hz, indicating that resolution of kinetic steps was limited by small channel currents rather than fast channel gating. From the background noise level we estimated the channel conductance to be less than 1.7 pS. Despite the fact that the majority of patches did not contain electrically active Cl- channels, patches being active, generally, contained more than a single active channel. Thus, for the above three types of resolvable channels, the mean number of active channels per patch amounted to 2.1, 1.4, and 2.0, respectively. This observation, like the finding of few patches with several unresolvable channels, indicates that electrically active Cl- channels are organized in clusters.

Proton pump activity of mitochondria-rich cells. The interpretation of external proton-concentration gradients.

We have hypothesized that a major role of the apical H(+)-pump in mitochondria-rich (MR) cells of amphibian skin is to energize active uptake of Cl- via an apical Cl-/HCO3(-)-exchanger. The activity of the H+ pump was studied by monitoring mucosal [H+]-profiles with a pH-sensitive microelectrode. With gluconate as mucosal anion, pH adjacent to the cornified cell layer was 0.98 +/- 0.07 (mean +/- SEM) pH-units below that of the lightly buffered bulk solution (pH = 7.40). The average distance at which the pH-gradient is dissipated was 382 +/- 18 microns, corresponding to an estimated "unstirred layer" thickness of 329 +/- 29 microns. Mucosal acidification was dependent on serosal pCO2, and abolished after depression of cellular energy metabolism, confirming that mucosal acidification results from active transport of H+. The [H+] was practically similar adjacent to all cells and independent of whether the microelectrode tip was positioned near an MR-cell or a principal cell. To evaluate [H+]-profiles created by a multitude of MR-cells, a mathematical model is proposed which assumes that the H+ distribution is governed by steady diffusion from a number of point sources defining a set of particular solutions to Laplace's equation. Model calculations predicted that with a physiological density of MR cells, the [H+] profile would be governed by so many sources that their individual contributions could not be experimentally resolved. The flux equation was integrated to provide a general mathematical expression for an external standing [H+]-gradient in the unstirred layer. This case was treated as free diffusion of protons and proton-loaded buffer molecules carrying away the protons extruded by the pump into the unstirred layer; the expression derived was used for estimating stationary proton-fluxes. The external [H+]-gradient depended on the mucosal anion such as to indicate that base (HCO3-) is excreted in exchange not only for Cl-, but also for Br- and I-, indicating that the active fluxes of these anions can be attributed to mitochondria-rich cells.

Role of mitochondria-rich cells in epithelial chloride uptake.

Uptake of NaCl by amphibian tight epithelia, such as skin, urinary bladder and collecting duct, requires considerable thermodynamic work. By calculation it is demonstrated that NaCl absorption from dilute external solutions ([NaCl] approximately 1 mM) demands more energy than can be provided by the Na(+)-K(+)-ATPase alone. Thus, in addition to the Na+ pump, another transport ATPase must be involved. Previously, we have suggested that the other transport ATPase is an apical proton pump in mitochondria-rich (MR) cells. By driving an apical Cl(-)-HCO3- exchange, a rheogenic H+ pump would energize entrance of Cl- across the apical membrane. Since Cl- channels are present in the basolateral membrane, the net result would be a transcellular active rheogenic uptake of Cl-, and secretion of H+ and HCO3-. At higher external concentrations, the Cl- uptake by MR cells is driven by the Na+ pump-generated transepithelial electrical potential difference, which also requires the presence of apical Cl- channels. Electrophysiological methods have been developed by which we have been able to study the polarity of single MR cells and identify apical and basolateral transport systems. We have verified the existence of rheogenic H+ pumps in the apical membrane and Cl- channels in both membranes.

Tissue kinetics, ion transport, and recruitment of mitochondria-rich cells in the skin of the toad (Bufo bufo) in response to exposure to distilled water.

Mitochondria-rich cells (MRC) of the amphibian epidermis are responsible for active chloride uptake at low external salinity, and new MRCs are recruited in response to exposure to distilled (deionized) water. The time-course of this recruitment, the tissue kinetics and ion transport have been studied in toads (Bufo bufo) immediately before, and after 2,7, and 14 days exposure to distilled water. General epidermal structure was not affected. However, the numbers of MRCs per mm2 (DMRC) increased throughout the experiment as revealed by staining of epidermal sheets with AgNO3 (Ag) or methylene blue (MB). Part of the increased DMRC was accounted for by an increase in MRC subpopulation(s) that stained neither with Ag nor MB. The cell birth rate (Kb) decreased and cell loss by moulting (Kd) increased without any significant change in epidermal cell pool size, indicating a reduced apoptotic rate. The increase in DMRC was accompanied by a 3-fold increase in Cl- current (ICl). At day-2 there was a transient reduction in the ICl per MRC. H+ secretion was progressively reduced during prolonged exposure to distilled water. Thus, at day-2 MRCs appeared incompletely differentiated as indicated by decreased ICl and H+ flux per MRC, and by the increased proportion of MRCs unstained by Ag or MB. Full Cl- (but not H+) transport capacity, was restored at day-7. We conclude that increased DMRC following exposure to low external Cl-, rather than being due to an increased Kb, is the combined effect of a decreased apoptotic rate and an increased rate of differentiation, where 'morphological differentiation' precedes 'functional differentiation'.

Selective response of human airway epithelia to luminal but not serosal solution hypertonicity. Possible role for proximal airway epithelia as an osmolality transducer.

The response of cultured human nasal epithelia to hypertonic bathing solutions was tested using ion-selective microelectrode and quantitative microscopy. Raised luminal, but not serosal, osmolality (+/- 150 mM mannitol) decreased Na+ absorption but did not induce Cl- secretion. Raised luminal osmolality increased cell Cl- activity, Na+ activity, and transepithelial resistance and decreased both apical and basolateral membrane potentials and the fractional resistance of the apical membrane; equivalent circuit analysis revealed increases in apical, basolateral, and shunt resistances. Prolonged exposure (10 min) to 430 mosM luminal solution elicited no regulation of any parameter. Optical measurements revealed a reduction in the thickness of preparations only in response to luminal hypertonic solutions. We conclude that (a) airway epithelial cells exhibit asymmetric water transport properties, with the apical membrane water permeability exceeding that of the basolateral membrane; (b) the cellular response to volume loss is a deactivation of the basolateral membrane K+ conductance and the apical membrane Cl- conductance; (c) luminal hypertonicity slows the rate of Na+ absorption but does not induce Cl- secretion; and (d) cell volume loss increases the resistance of the paracellular path. We speculate that these properties configure human nasal epithelium to behave as an osmotic sensor, transducing information about luminal solutions to the airway wall.

The influence of ambient salinity and temperature on lipid metabolism in toad (Bufo bufo) skin. Is phosphatidylethanolamine an endogenous regulator of ion channels?

Incorporation of (32P) phosphate and (14C) acetate into frog (Rana temporaria) skin phospholipids in vitro was positively correlated to skin MR cell density. Transport across toad (Bufo bufo) skin and incorporation into skin phospholipids of the radioactive tracers were independent of transepithelial electrical potential in vitro. While all the incorporations in vitro showed (32P) and (14C) frog and toad skin phospholipid patterns dominated by phosphatidylcholine-independent of adaptational temperature and salinity--corresponding phospholipid patterns dominated by phosphatidylethanolamine (PE) were found in vivo, when toads adapted to Ringer solution were transferred to tap water containing tracer amounts of (32P) phosphate and (14C) acetate. PE could play a role in the formation of a "hydrophilic" environment and thereby, e.g. stabilise the integral membrane proteins that regulate the function of ion channels.

Intracellular pH and its relationship to regulation of ion transport in normal and cystic fibrosis human nasal epithelia.

1. Intracellular pH (pHi) of cultured human airway epithelial cells from normal and cystic fibrosis (CF) subjects were measured with double-barrelled pH-sensitive liquid exchanger microelectrodes. The cells, which were grown to confluence on a permeable collagen matrix support, were mounted in a modified miniature Ussing chamber. All studies were conducted under open circuit conditions. Values are given as means +/- S.E.M. and n refers to the number of preparations. 2. Normal preparations (n = 15) were characterized by a transepithelial potential difference (Vt) of -18 +/- 2 mV, an apical membrane potential (Va) of -19 +/- 2 mV, a basolateral membrane potential (Vb) of -37 +/- 2 mV, a transepithelial resistance (Rt) of 253 +/- 15 omega cm2, a fractional apical membrane resistance (fRa) of 0.40 +/- 0.04 and an equivalent short circuit current (Ieq) of -73 +/- 7 microA cm-2. 3. CF preparations (n = 13) were characterized by a Vt of -46 +/- 7 mV, a Va of 3 +/- 5 mV, a Vb of -43 +/- 3 mV, Rt of 373 +/- 47 omega cm2, fRa of 0.44 +/- 0.04 and an Ieq of -130 +/- 16 microA cm-2. All parameters except Vb and fRa were significantly different (P < 0.025) from those of normal preparations. 4. Despite large differences in electrochemical driving force for proton flow across the apical cell membranes between normal and CF preparations (-4 +/- 3 mV and 20 +/- 7 mV, respectively), pHi was similar (7.15 +/- 0.02 and 7.11 +/- 0.05, respectively). The driving force across the basolateral membrane was similar in normal and CF preparations (22 +/- 3 and 26 +/- 3 mV, respectively). 5. Intracellular alkalinization achieved by removal of CO2 from the luminal Ringer solution or by luminal ammonium prepulse led to stimulation of Ieq in both normal (from -58 to -70 microA cm-2, n = 4; P < 0.05) and CF (from -144 to -163 microA cm-2, n = 4; P < 0.005) preparations. The increase in Ieq was associated with a reduction of Rt, increase in fRa, and hyperpolarization of Vb. All changes in bioelectric properties in response to intracellular alkalinization were fully reversible. 6. Intracellular acidification achieved by serosal ammonium prepulse led to marked reductions of Ieq in both normal (from -95 to -31 microA cm-2, n = 6; P < 0.05) and CF (from -111 to -67 microA cm-2, n = 7; P < 0.005) preparations.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of proton pump of mitochondria-rich cells for active transport of chloride ions in toad skin epithelium.

1. Active Cl- currents were studied in short-circuited toad skin epithelium in which the passive voltage-activated Cl- current is zero. Under visual control double-barrelled microelectrodes were used for impaling principal cells from the serosal side, or for measuring the pH profile in the solution bathing the apical border. 2. The net inward (active) 36Cl- flux of 27 +/- 8 pmol s-1 cm-2 (16) (mean +/- S.E.M (number of observation)) was abolished by 2 mM-CN- (6.3 +/- 3.5 pmol s-1 cm-2 (8)). The active flux was maintained in the absence of active Na+ transport when the latter was eliminated by either 100 microM-mucosal amiloride, replacement of mucosal Na+ with K+, or by 3 mM-serosal ouabain. 3. In Ringer solution buffered by 24 mM-HCO3- -5% CO2 mucosal amiloride reversed the short circuit current (ISC). The outward ISC was maintained when gluconate replaced mucosal Cl-, and it was reversibly reduced in CO2-free 5 mM-Tris-buffered Ringer solution (pH = 7.40) or by the proton pump inhibitor oligomycin. These observations indicate that the source of the outward ISC is an apical proton pump. 4. Amiloride caused principal cells to hyperpolarize from a basolateral membrane potential, Vb, of -73 +/- 3 (22) to -93 +/- 1 mV (26), and superfusion with CO2-free Tris-buffered Ringer solution induced a further hyperpolarization (Vb = -101 +/- 1 mV (26)) which could be blocked by Ba2+. The CO2-sensitive current changes were null at Vb = EK (potassium reversal potential, -106 +/- 2 mV (55)) implying that they are carried by K+ channels in the basolateral membrane. Such a response cannot account for the inhibition of the outward ISC which by default seems to be located to mitochondria-rich (MR) cells. 5. In the absence of mucosal Cl- a pH gradient was built up above MR cells with pH = 7.02 +/- 0.04 (42) and pH increasing to 7.37 +/- 0.02 (10) above principal cells (pH = 7.40 in bulk solution buffered by 0.1 mM-Tris). This observation localizes a proton pump to the apical membrane of MR cells. Using the integrated diffusion equation it was shown that the measured external pH gradient would account within an order of magnitude for measured currents. 6. Standing gradients of protons were eliminated in the presence of mucosal Cl- suggesting that active uptake of Cl- is associated with the exit of base equivalents across the apical membrane of MR cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Cyclic AMP-and beta-agonist-activated chloride conductance of a toad skin epithelium.

1. The control by intracellular cyclic AMP and beta-adrenergic stimulation of chloride conductance was studied in toad skin epithelium mounted in a chamber on the stage of an upright microscope. Impalement of identified principal cells from the serosal side with single-barrelled conventional or double-barrelled Cl(-)-sensitive microelectrodes was performed at x500 magnification. For blocking the active sodium current 50 microM-amiloride was present in the mucosal bath. 2. When clamped at transepithelial potential difference V = 0 mV, the preparations generated clamping currents of 0.9 +/- 1 microA/cm2 (mean +/- S.E.M.; number of observations n = 55). The intracellular potential of principal cells (Vb) was -96 +/- 2 mV with a fractional resistance of the basolateral membrane (fRb) of 0.016 +/- 0.003 (n = 54), and an intracellular Cl- activity of 40 +/- 2 mM (n = 24). 3. At V = 0 mV, serosal application of a cyclic AMP analogue, dibutyryl cyclic AMP (500 microM) or a beta-adrenergic agonist, isoprenaline (5 microM) resulted in a sixfold increase in transepithelial Cl- conductance identified by standard 36Cl- tracer technique. 4. The clamping current at V = 0 mV was unaffected by cyclic AMP (short-circuit current Isc = 0.1 +/- 0.3 microA/cm2, n = 16) indicating that subepidermal Cl(-)-secreting glands are not functioning in our preparations obtained by collagenase treatment. 5. Cyclic AMP- or isoprenaline-induced chloride conductance (Gcl) activation (V = 0 mV) was not reflected in membrane potential and intracellular Cl- activity in principal cells. Intracellular chloride activity was constant at approximately 40 mM at membrane potentials between -90 and -100 mV. Therefore, it can be concluded that the principal cells are not contributing to activated Cl- currents. 6. At V = -100 mV where the voltage-dependent chloride conductance of mitochondria-rich (MR) cells was already fully activated, GCl was unaffected by cyclic AMP or isoprenaline. The major effect of these treatments was a rightward displacement of the MR cell-generated GCl-V relationship along the V axis. 7. Our results indicate that the beta-adrenergically controlled cyclic AMP-mediated chloride conductance is localized to the mitochondria-rich cells.

Sodium transport and intracellular sodium activity in cultured human nasal epithelium.

Human airway epithelia are predominantly Na(+)-absorbing epithelia. To investigate the mechanisms for Na+ absorption across airway epithelia, the driving forces and paths for Na+ translocation across each membrane were examined with double-barreled Na(+)-selective microelectrodes in cultured human nasal epithelium (HNE). Under control conditions, intracellular Na+ activity (acNa) was 23 +/- 1 mM (n = 44 preparations, 393 impalements). Amiloride (10(-4) M) hyperpolarized the apical membrane and increased the fractional apical membrane resistance but did not affect acNa. Exposure to Na(+)-free luminal solution induced bioelectric responses similar to amiloride but also reduced acNa to 8 +/- 1 mM. Reduction of luminal Na+ concentration ([Na+]) in the presence of amiloride also reduced acNa without further changes in bioelectric parameters. Reduction of serosal [Na+] decreased aNac, a response blocked by bumetanide (10(-4) M). Ouabain (10(-4) M, serosal) led to a reduction in equivalent short-circuit current (Ieq) and increase in acNa. We conclude that 1) acNa is higher in HNE than in most mammalian epithelial cells, 2) the apical membrane expresses a conductive Na+ path, and 3) the basolateral membrane transports Na+ via the Na(+)-K(+)-adenosinetriphosphatase and a Na(+)-K(+)-2Cl- cotransport system.

Transcellular sodium transport in cultured cystic fibrosis human nasal epithelium.

Cystic fibrosis (CF) airway epithelia exhibit raised transepithelial Na+ transport rates, as determined by open-circuit isotope fluxes and estimates of the amiloride-sensitive equivalent short-circuit current (Ieq). To study the contribution of apical and basolateral membrane paths to raised Na+ transport in CF, CF nasal epithelial cultures were studied with double-barreled Na(+)-selective microelectrodes and the Ussing chamber technique. Intracellular Na+ activity (acNa) was 24.1 +/- 1.5 mM (n = 36), a value similar to acNa of normal nasal epithelial cells. Reduction of luminal [Na+] to 3 mM abolished Ieq and reduced acNa. Amiloride (10(-4) M) abolished Ieq but increased acNa from 20 +/- 2 to 36 +/- 7 mM (n = 10). Amiloride-induced increase in acNa was not affected by serosal [Na+] reduction but was blocked by preexposure to reduced luminal [Na+]. Amphotericin B increased Ieq during amiloride exposure, indicating that amiloride did not inhibit NA(+)-K(+)-ATPase. Ouabain abolished Ieq and slowly raised acNa. Reduction of serosal [Na+] led to a decrease in acNa that was blocked by bumetanide. It is concluded that 1) CF airway epithelia exhibit an increased apical membrane Na+ permeability, 2) acNa is regulated to a normal level in CF cells despite increased transcellular Na+ fluxes, 3) the abnormal increase in acNa in response to amiloride is dependent on luminal Na+, 4) Na+ is transported across the basolateral membrane by a bumetanide-sensitive cotransport mechanism, and 5) ouabain inhibits the basolateral Na(+)-K(+)-ATPase, causing slow dissipation of the chemical and electrical gradients across the cell membranes.