Cystic fibrosis affects chloride and sodium channels in human airway epithelia

CFTR stabilizes ENaC at the plasma membrane

CFTR was reported to regulate ENaC channel opening, decreasing ENaC activity in airways and increasing it in sweat ducts. We generated MDCK-I cell lines stably expressing tagged alphabetagammaENaC+CFTR or ENaC alone, and developed an assay to quantify cell-surface half-life of ENaC. Surprisingly, we found that co-expressed CFTR stabilizes ENaC at the plasma membrane, suggesting that CFTR regulates ENaC stability, not just opening.

The cytosolic termini of the beta- and gamma-ENaC subunits are involved in the functional interactions between cystic fibrosis transmembrane conductance regulator and epithelial sodium channel

Epithelial sodium channel (ENaC) and cystic fibrosis transmembrane conductance regulator (CFTR) are co-localized in the apical membrane of many epithelia. These channels are essential for electrolyte and water secretion and/or reabsorption. In cystic fibrosis airway epithelia, a hyperactivated epithelial Na(+) conductance operates in parallel with defective Cl(-) secretion. Several groups have shown that CFTR down-regulates ENaC activity, but the mechanisms and the regulation of CFTR by ENaC are unknown. To test the hypothesis that ENaC and CFTR regulate each other, and to identify the region(s) of ENaC involved in the interaction between CFTR and ENaC, rENaC and its mutants were co-expressed with CFTR in Xenopus oocytes. Whole cell macroscopic sodium currents revealed that wild type (wt) alphabetagamma-rENaC-induced Na(+) current was inhibited by co-expression of CFTR, and further inhibited when CFTR was activated with a cAMP-raising mixture (CKT). Conversely, alphabetagamma-rENaC stimulated CFTR-mediated Cl(-) currents up to approximately 6-fold. Deletion mutations in the intracellular tails of the three rENaC subunits suggested that the carboxyl terminus of the beta subunit was required both for the down-regulation of ENaC by activated CFTR and the up-regulation of CFTR by ENaC. However, both the carboxyl terminus of the beta subunit and the amino terminus of the gamma subunit were essential for the down-regulation of rENaC by unstimulated CFTR. Interestingly, down-regulation of rENaC by activated CFTR was Cl(-)-dependent, while stimulation of CFTR by rENaC was not dependent on either cytoplasmic Na(+) or a depolarized membrane potential. In summary, there appear to be at least two different sites in ENaC involved in the intermolecular interaction between CFTR and ENaC.

Na+/K+ ATPase in lower airway epithelium from cystic fibrosis and non-cystic-fibrosis lung

The basolateral Na+/K+ ATPase plays a critical role in sodium reabsorption across airway epithelium. Nasal epithelium shows increased Na+/K+ ATPase activity in cystic fibrosis (CF) but Na+/K+ ATPase has not been characterized in human lung epithelium or compared in CF and normal lung. We measured 3[H] ouabain binding and Na+/K+ ATPase activity in human tracheal epithelium and compared Na/K ATPase activity in bronchial epithelium in CF and control subjects. In tracheal epithelium Na+/K+ ATPase pumps were abundant and of high 3[H] ouabain affinity (Kd 4.7 nM, Bmax 38 pmol/mg) and Na+/K+ ATPase activity was 55 +/- 8 nmol/mg protein/min. Bronchial epithelial Na+/K+ ATPase activity was twofold higher in CF patients than in controls. The increased Na+/K+ ATPase activity may contribute to the increased sodium reabsorption seen in cystic fibrosis.

cGMP stimulates sodium and chloride currents in rat tracheal airway epithelia

To test the hypothesis that guanosine 3',5'-cyclic monophosphate (cGMP) regulates ion transport in airway epithelial cells, we measured short-circuit current (I(sc)) and (22)Na+ fluxes in primary cultured rat tracheal epithelial cells. In Cl- -containing Ringer solution, I(sc) was increased by approximately 17 microA/cm2 after application of 1 mM 8-bromoguanosine 3',5'-cyclic monophosphate (8-BrcGMP), whereas, in Cl- -free solutions, the Na+ -mediated component was approximately 5 microA/cm2, suggesting a cGMP stimulation of Cl-secretory current and a smaller Na+ absorptive current. Inward and net mucosal-to-serosal (22)Na+ flux was doubled in the presence of 2 mM 8-BrcGMP. To determine whether nucleotide-gated channels play a role in this transepithelial Na+ absorption, blockers of nucleotide-gated cation channels were used to inhibit I(sc). The cGMP-stimulated Na+-mediated I(sc) was blocked by as little as 500 nM dichlorobenzamil or 50 microM L-cis-diltiazem, which are known blockers for cyclic nucleotide-gated cation channels. These agents also blocked the basal (non-cGMP-stimulated) current when measured in the presence of 10 microM amiloride, which blocks current through 5-pS amiloride-sensitive Na+ channels. To document whether the distribution of nucleotide-gated nonselective cation channels was consistent with a role in airway epithelial transport, in situ hybridization was performed. In situ hybridization of mRNA encoding for nucleotide-gated cation channels was found in epithelial cell layers of rat trachea, bronchi, bronchioles, and alveolar cells but not in smooth muscle layers or tracheal cartilage. Reverse transcriptase-polymerase chain reaction, restriction enzyme analysis, and sequencing of the cDNA transcribed from mRNA of whole lung and tracheal epithelial cells indicate that a channel highly homologous to the retinal nucleotide-gated nonselective cation channel (CNG1) is present. Thus these data, along with evidence supporting the existence of signal transduction pathways elevating intracellular levels of cGMP, indicate that cGMP regulates transepithelial ion transport in lung epithelial tissues.

Expression of the cystic fibrosis phenotype in a renal amphibian epithelial cell line

Mutations in a Cl- channel (cystic fibrosis transmembrane conductance regulator or CFTR) are responsible for the cystic fibrosis (CF) phenotype. Increased Na+ transport rates are observed in CF airway epithelium, and recent studies suggest that this is due to an increase in Na+ channel open probability (Po). The Xenopus renal epithelial cell line, A6, expresses both cAMP-activated 8-picosiemen (pS) Cl- channels and amiloride-sensitive 4-pS Na+ channels, and provides a model system for examining the interactions of CFTR and epithelial Na+ channels. A6 cells express CFTR mRNA, as demonstrated by reverse transcriptase-polymerase chain reaction and partial sequence analysis. A phosphorothioate antisense oligonucleotide, complementary to the 5' end of the open reading frame of Xenopus CFTR, was used to inhibit functional expression of CFTR in A6 cells. Parallel studies utilized the corresponding sense oligonucleotide as a control. CFTR protein expression was markedly reduced in cells incubated with the antisense oligonucleotide. Incubation of A6 cells with the antisense oligonucleotide led to inhibition of forskolin-activated amiloride-insensitive short circuit current (Isc). After a 30-min exposure to 10 microM forskolin, 8-pS Cl- channel activity was detected in only 1 of 31 (3%) cell-attached patches on cells treated with antisense oligonucleotide, compared to 5 of 19 (26%) patches from control cells. A shift in the single-channel current-voltage relationship derived from antisense-treated cells was also consistent with a reduction in Cl- reabsorption. Both amiloride-sensitive Isc and Na+ channel Po were significantly increased in antisense-treated, forskolin-stimulated A6 cells, when compared with forskolin-stimulated controls. These data suggest that the regulation of Na+ channels by CFTR is not limited to respiratory epithelia and to epithelial cells in culture overexpressing CFTR and epithelial Na+ channels.

Computational studies of ion-water flux coupling in the airway epithelium. II. Role of specific transport mechanisms

Ion and water balance by the in vivo airway epithelium was investigated utilizing dynamic computer modeling. Parameters of the osmotically significant transport processes were varied to assess the sensitivity of water transport and fluid composition to transport perturbations. Establishment and regulation of water secretion represent a coordinated function of at least seven different ion transport processes: basolateral passive potassium transport, basolateral active sodium-potassium transport, basolateral sodium-potassium-chloride cotransport, apical passive sodium and chloride transport, and diffusion of sodium and chloride across the paracellular path. We found that apical chloride permeability at a level reported for cystic fibrosis is sufficient to cause the airway dehydration characteristic of cystic fibrosis. Given the reduction in apical chloride permeability in cystic fibrosis, a reduction in apical sodium permeability can potentially compensate completely for the airway dehydration associated with the cystic fibrosis genetic defect. Other simulations presented here address the importance of various membrane transport processes in airway epithelium water balance and the sensitivity of epithelium water balance to ion transport perturbations.

Regulation of epithelial sodium channels by the cystic fibrosis transmembrane conductance regulator

Cystic fibrosis airway epithelia exhibit enhanced Na+ reabsorption in parallel with diminished Cl- secretion. We tested the hypothesis that the cystic fibrosis transmembrane conductance regulator (CFTR) directly affects epithelial Na+ channel activity by co-incorporating into planar lipid bilayers immunopurified bovine tracheal CFTR and either heterologously expressed rat epithelial Na+ channel ( alpha,b eta,gamma-rENaC) or an immunopurified bovine renal Na+ channel protein complex. The single channel open probability (Po) of rENaC was decreased by 24% in the presence of CFTR. Protein kinase A (PKA) plus ATP activated CFTR, but did not have any effect on rENaC. CFTR also decreased the extent of elevation of the renal Na+ channel Po following PKA-mediated phosphorylation. Moreover, the presence of CFTR prohibited the inward rectification of the gating of this renal Na+ channel normally induced by PKA-mediated phosphorylation, thus down-regulating inward Na+ current. This interaction between CFTR and Na+ channels occurs independently of whether or not wild-type CFTR is conducting anions. However, the nonconductive CFTR mutant, G551D CFTR, cannot substitute for the wild-type molecule. Our results indicate that CFTR can directly down-regulate single Na+ channel activity, thus accounting, at least in part, for the observed differences in Na+ transport between normal and cystic fibrosis-affected airway epithelia.

Culture-dependent expression of Na+ conductances in airway epithelial cells

According to previous studies, amiloride-sensitive (Amil+) Na+ channels are present in apical membranes of airway epithelial cells. When isolated from intact tissue and grown in primary culture or as immortalized cell lines, these cells tend to lose these Amil+ Na+ channels. The present study examines this issue in immortalized human bronchial epithelial cells (16HBE14o- cell line). The mRNA of one subunit of the Na+ channel alphahENaC) was semi-quantified by polymerase chain reaction of reverse transcribed RNA. Transcripts were significantly increased when cells were exposed to aldosterone and dexamethasone irrespective of whether grown on permeable supports or plastic. When grown on plastic dishes 16HBE14o-cells showed cAMP-dependent Cl- currents in whole-cell (WC) patch-clamp experiments, corresponding to expression of the cystic fibrosis transmembrane conductance regulator (CFTR). Na+ currents could not be detected although cells expressed significant amounts of alphahENaC as demonstrated by Northern blot analysis. In contrast, when cells were grown on permeable supports or cultured in the presence of butyrate (5 mmol/l, plastic or permeable support) or aldosterone and dexamethasone (both 1 micromol/l, plastic or permeable support), amiloride (10 micromol/l) hyperpolarized the membrane voltage (deltaVm) by 2-9 mV, paralleled by small reductions of WC conductances (deltaGm) of 0.4-4.0 nS. The effects of amiloride on deltaVm were gnerally more pronounced (up to 12 mV) when cells were grown on permeable supports. The amiloride effect (deltaVm) was concentration dependent with an inhibitory constant, Ki, of about 0.1 micromol/l. We further examined whether the induction of an Amil+ Na+ conductance was paralleled by additional changes in membrane conductance. In fact, the cAMP-activated Cl- conductance was significantly attenuated by approximately 80% (n=35) in cells responding to amiloride, whilst the ATP-activated K+ conductance remained unaffected. The present data suggest that cellular mechanisms determining differentiation control the function expression of Na+ and Cl- conductances in human airway epithelial cells.

Evidence that channels below 1 pS cause the volume-sensitive chloride conductance in T84 cells

The volume-activated chloride current of T84 human colonic cells was studied using the whole-cell patch clamp. The current appeared reliably with a mild osmotic gradient and in the absence of intracellular ATP. It reversed at the chloride equilibrium potential and was blocked by the chloride channel blocker DIDS. Development of the current was accompanied by an increase in the current noise variance, typical of increasing ion channel open probability. Noise variance was always well-fitted by a double Lorentzian relationship with corner frequencies at approximately 1.7 Hz and approximately 60 Hz. The increase in variance during development of the volume-sensitive current was mostly due to an increase in the high frequency component. The relationship between noise variance and membrane current was well-fitted by a relationship with a single channel conductance of approximately 0.2 pS.

Amiloride-sensitive sodium uptake into human placental brush border membrane vesicles

Sodium transport into human placental brush border membrane vesicles was examined in the presence of an outwardly directed sodium gradient leading to the formation of an intravesicular negative charge. 22Na entered the vesicles in a time dependent fashion. The activation energy of the uptake process was calculated and was found to be 11.2 kcal/mol, similar to the value of ionic diffusion in free solution. Amiloride inhibited Na uptake in a concentration dependent fashion with an IC50 value of 3.08 microM. Neither ouabain nor bumetanide had an effect on Na uptake at concentrations up to 100 or 1000 microM, respectively. The system presented here indicates Na transport via channels without involvement of the Na-K-ATPase or the Na-K-Cl cotransporter. The system may be useful in investigating Na transport defects in cystic fibrosis.

Expression of the epithelial Na+ channel in the developing rat lung

The adult mature fetal, but not immature fetal, lung is capable of actively transporting Na+ from the alveolar space. The reason for the impaired Na+ transport in the immature lung is not known; however, the apical membrane Na+ channel is the rate-limiting step for epithelial Na+ transport. This study determined whether transcripts coding for the adult rat colonic epithelial Na+ channel (alpha rENaC) were present in the fetal and adult lung and whether they were developmentally regulated. Similarly sized alpha rENaC transcripts were identified in RNA isolated from fetal and adult whole rat lung, primary cultures of fetal and adult alveolar epithelium, and adult rat whole kidneys, suggesting that the lung alpha rENaC is a similar transcript to that found in the salt-deprived rat colonic epithelium. There were low mRNA levels in 17- to 18-day gestational age (GA) fetal lungs and epithelium (term GA = 22 days), but these levels increased markedly during the saccular stage of lung development (20 days GA) and remained high in adult lungs. The combined administration of thyroid-releasing hormone and dexamethasone to pregnant rats between 16 and 18 days GA induced the expression of lung alpha rENaC in their fetuses. We conclude that alpha rENaC is expressed in mature fetal and adult alveolar epithelium and that it is influenced by hormones known to alter maturation of the fetal lung.

Diphenylamine-2-carboxylate analogues block Cl- conductances in A7r5 cells by affecting cellular Ca2+ homeostasis

We have investigated the cellular signalling pathway by which vasopressin stimulates a Ca2(+)-dependent Cl- conductance and the effects of two known Cl- channel blockers in cultured rat A7r5 aortic smooth muscle cells using anion efflux and fluorescent Ca2+ imaging studies. Addition of vasopressin (100 nM) to A7r5 cells enhanced 125I (Cl- substitute) efflux from the cells through a V1 receptor-mediated pathway. Maximal increases in the rate of efflux were observed 1 min following addition of vasopressin (4-fold above basal levels). Activation of the V1 pathway was demonstrated by an increase in inositol trisphosphate (IP3) formation and lack of cAMP accumulation by the cells following the addition of vasopressin. Fluorescent ratio imaging with fura-2 revealed that addition of vasopressin to the cells results in an increase of [Ca2+]i which peaks within 20 s and does not return to resting levels during the 100 s observation period. The addition of a Ca2+ ionophore mimicked the vasopressin-induced efflux from the cells. 5-Nitro-2-(3-phenylpropylamino)-benzoic acid (NPPB) and a chloro-substituted compound (cpd 149) inhibited the vasopressin-stimulated 125I efflux from the cells. The concentrations of NPPB and cpd 149 required to inhibit 125I efflux from the cells were similar to those which also attenuated vasopressin-induced Ca2+ transients in the cells. NPPB and cpd 149 had no effects on the ionomycin stimulated efflux. The mechanism(s) by which cpd 149 exerts its effect on stimulated efflux was examined by measuring its action on vasopressin-induced changes in IP3. Compound 149 inhibited IP3 generation in response to vasopressin.(ABSTRACT TRUNCATED AT 250 WORDS)

Halide permeation through three types of epithelial anion channels after reconstitution into giant liposomes

Anion-selective channels from apical membranes of cultured CFPAC-1 cells were isolated and incorporated into giant liposomes for patch clamp recording. Liposomes were formed from L-alpha-lecithin by a dehydration-hydration method. Ion channels were characterized using the excised inside-out patch clamp configuration. The most commonly observed anion channels were similar to those observed in native epithelial tissues. The linear 20 pS Cl- channel had the halide permeability sequence Cl- > I- > or = Br- > F-, and showed anomalous mole-fraction behavior in solutions containing different proportions of Cl- and F- ions. The autwardly rectifying Cl- channel had the halide permeability sequence I- > Br- > Cl- > F-, and also showed anomalous mole-fraction behavior, indicating that both these channels probably contain multi-ion pores. The third, voltage-dependent anion channel showed at least five different substrates, had a conductance of 390 pS in the main state, and showed two types of kinetics, fast (openings and closings < 1 ms), and slow (openings and closings > 1 s). The channel was seen more frequently after reconstitution into giant liposomes than in intact cells. It was not selective amongst the halides, and there was no deviation from a linear dependence of relative current on molar fractions, indicating relatively simple permeation through the pore. Differences in halide permeabilities suggest that different anion channels may be related to different membrane proteins. Comparison with the chloride channel proteins isolated biochemically from epithelial cell membranes is discussed.

GTP-binding proteins inhibit cAMP activation of chloride channels in cystic fibrosis airway epithelial cells

Cystic fibrosis (CF) is a genetic disease characterized, in part, by defective regulation of Cl- secretion by airway epithelial cells. In CF, cAMP does not activate Cl- channels in the apical membrane of airway epithelial cells. We report here whole-cell patch-clamp studies demonstrating that pertussis toxin, which uncouples heterotrimeric GTP-binding proteins (G proteins) from their receptors, and guanosine 5'-[beta-thio]diphosphate, which prevents G proteins from interacting with their effectors, increase Cl- currents and restore cAMP-activated Cl- currents in airway epithelial cells isolated from CF patients. In contrast, the G protein activators guanosine 5'-[gamma-thio]triphosphate and AlF4- reduce Cl- currents and inhibit cAMP from activating Cl- currents in normal airway epithelial cells. In CF cells treated with pertussis toxin or guanosine 5'-[beta-thio]diphosphate and in normal cells, cAMP activates a Cl- conductance that has properties similar to CF transmembrane-conductance regulator Cl- channels. We conclude that heterotrimeric G proteins inhibit cAMP-activated Cl- currents in airway epithelial cells and that modulation of the inhibitory G protein signaling pathway may have the therapeutic potential for improving cAMP-activated Cl- secretion in CF.

CFTR!

Cystic fibrosis (CF) is a fatal genetic disease primarily affecting Caucasians, although cases have been reported from other ethnic groups. CF has a complex etiology, but it is chiefly a disease of electrolyte transport and is characterized by defects in fluid secretion by several epithelia, including the sweat duct, exocrine pancreas, and the pulmonary airways. The link between CF and a defect in cAMP-mediated Cl- transport in secretory epithelia was established in the early 1980s. Since then, numerous electrophysiological studies have focused on the characterization and regulation of individual Cl- channels underlying the macroscopic Cl- currents of secretory epithelia in the airways, sweat ducts, and gut. In this review the results of these studies in the light of current knowledge of the function of the CF gene product, the CF transmembrane conductance regulator (CFTR) protein, will be analyzed. The CFTR protein is a member of a family of ATP-binding proteins that act as unidirectional solute pumps. These proteins are membrane spanning, are found in both prokaryotic and eukaryotic cells, and have two ATP-binding domains. The family includes the p-glycoproteins that are involved with the expression of multidrug resistance in certain tumor cells. The majority of CF chromosomes (70%) have a single codon deletion that translates to a missing phenylalanine residue at position 508 (delta F508) of the protein. Unique for this family of proteins, the CFTR protein possesses an additional highly charged domain (the R domain) containing several consensus polypeptide sequences for kinase phosphorylation. Although CFTR bears structural resemblance to this family of ATP-dependent pumps, overexpression of the protein in a variety of different cell types is associated with the appearence of a cAMP-sensitive Cl- channel. We critically examine current information concerning the structure-function relationships of the CFTR protein obtained from both electrophysiological and biochemical approaches. We also summarize recent evidence suggesting that the CFTR protein may act as a pump and a channel, a hypothesis in keeping with the multifaceted nature of the disease.

Halide permeation through 10 pS and 20 pS anion channels in human airway epithelial cells

Halide permeability sequences were obtained from reversal potential measurements of single-channel currents through 10 pS and 20 pS anion channels in human airway epithelial cells. The sequences obtained were Cl- greater than I- greater than Br- greater than or equal to F- for the 10 pS channel and Cl- greater than I- greater than or equal to Br- greater than or equal to F- for the 20 pS channel. However, the permeability differences were not large, the greatest being 0.66 for the ratio of fluoride to chloride permeability in the 20 pS channel. Single-channel currents were also measured with solutions of constant halide concentration but varying ratios of chloride to fluoride ions. An anomalous mole fraction effect was observed for the 20 pS channel but not for the 10 pS channel, suggesting that the former is a multi-ion channel. Comparison of the halide permeability sequences of these two channels with those of whole-cell currents in other epithelial cells does not support their involvement in any of the known whole-cell epithelial currents.

Noise analysis and single-channel observations of 4 pS chloride channels in human airway epithelia

Apical membranes of human airway epithelial cells have significant chloride permeability, which is reduced in cystic fibrosis (CF), causing abnormal electrochemistry and impaired mucociliary clearance. At least four types of chloride channels have been identified in these cells, but their relative roles in total permeability and CF are unclear. Noise analysis was used to measure the conductance of chloride channels in human nasal epithelial cells. The data indicate that channels with a mean conductance of 4.5 pS carry most of the chloride current, and that the mean number of such channels per cell is approximately 4,000. Chloride channels in this conductance range were also seen in single-channel recordings.

Second-messenger regulation of sodium transport in mammalian airway epithelia

1. Sodium absorption is the dominant ion transport process in conducting airways and is a major factor regulating the composition of airway surface liquid. However, little is known about the control of airway sodium transport by intracellular regulatory pathways. 2. In sheep tracheae and human bronchi mounted in Ussing chambers under short circuit conditions, the sodium current can be isolated by pretreating tissues with acetazolamide (100 microM) to inhibit bicarbonate secretion, bumetanide (100 microM) to inhibit chloride secretion and phloridzin (200 microM) to inhibit sodium-glucose cotransport. This sodium current consists of amiloride-sensitive (57%) and amiloride-insensitive (43%) components. 3. The regulation of the isolated sodium current by three second messenger pathways was studied using the calcium ionophore A23187 to elevate intracellular calcium, a combination of forskolin and the phosphodiesterase inhibitor zardaverine to elevate intracellular cyclic AMP, and the phorbol ester 12,13-phorbol dibutyrate (PDB) to stimulate protein kinase C. 4. In sheep trachea, A23187 produces a dose-related inhibition of the sodium current with maximal effect (38% of ISC) at 10 microM and IC50 1 microM. This response affects both the amiloride-sensitive and insensitive components of the sodium current and is not altered by prior stimulation of protein kinase C or elevation of intracellular cyclic AMP. In human bronchi, A23187 (10 microM) produced a significantly greater inhibition of ISC (68%), a response which was unaffected by prior treatment with PDB or forskolin-zardaverine. 5. In sheep trachea, stimulation of protein kinase C with PDB produced a dose-related inhibition of ISC maximal (56% of ISC) at 50 nM (IC50 7 nM). This response was abolished by amiloride (100 microM) pretreatment suggesting a selective effect on the amiloride-sensitive component of the sodium current. The response was not altered by prior elevation of intracellular calcium or cyclic AMP. PDB (10 nM) caused a similar inhibition of ISC in human bronchi (43%). The effect of PKC stimulation following pretreatment with A23187 was diminished in human bronchi. Elevating intracellular cyclic AMP did not alter this response. 6. Addition of forskolin (1 microM) together with the phosphodiesterase inhibitor zardaverine (100 microM) produced a mean 35-fold increase in intracellular cyclic AMP in sheep trachea. This was associated with a small, but significant, 6% transient increase in ISC followed by a significant 4% fall. Neither effect could be abolished by amiloride pretreatment. In human bronchi, a small decrease in ISC which could not be distinguished from that occurring in controls was observed.(ABSTRACT TRUNCATED AT 400 WORDS)

An inwardly rectifying chloride channel in ragweed-sensitized canine tracheal epithelial cells

The single channel inside-out patch clamp technique was used to characterize ion channels in the apical membranes of ragweed-sensitized and control canine tracheal epithelial cells maintained in primary culture. Patches were obtained from single isolated cells or from cells at the edges of confluent sheets. A new type of chloride channel was seen in sensitized cells but not in control cells. The channel showed inward rectification in symmetric chloride solutions with conductance varying from 95 pS to 52 pS over the range of -60 mV to 60 mV membrane potential. Channel gating was voltage dependent with maximal opening at about -30 mV. Kinetic analysis showed that distributions of closed and open times could both be well fitted by the sums of three exponential components. Rate constants for transitions between the states of a linear kinetic model were calculated, with only one rate being significantly voltage dependent. The possible significance of this channel is discussed.

Cystic fibrosis, the CFTR, and rectifying Cl- channels

The human genetic disease cystic fibrosis is caused by a single defective gene on chromosome 7 that codes for a 1480 amino acid protein called the cystic fibrosis transmembrane conductance regulator (CFTR). The defect causes a profound reduction of Cl- permeability in several tissues, which in turn impairs salt absorption and fluid secretion. A 25-80 pS, rectifying Cl- channel has been targeted as the exclusive or primary channel affected in CF. However, we have found no evidence for significant activation or spontaneous activity of this channel in cell-attached patches of normal lymphoblasts or dog tracheal cells. However, in dog tracheal cells, we find lower conductance, linear Cl- channels that are spontaneously active in unstimulated cells and may show increased activity in stimulated cells. Attempts to correlate the expression of mRNA for the CFTR protein in various types of cells with the presence of the rectifying Cl- channel show a lack of correlation: i.e., depolarization-activated rectifying Cl- channesl have been found in excised, inside-out patches from all cell types that we have examined to date, but the CFTR mRNA has so far only been detected in a subset of epithelial cells.