Effects of cardiogenic edema fluid on ion and fluid transport in the adult lung

We have previously shown that cardiogenic pulmonary edema fluid (EF) increases Na(+) and fluid transport by fetal distal lung epithelia (FDLE) (Rafii B, Gillie DJ, Sulowski C, Hannam V, Cheung T, Otulakowski G, Barker PM and O'Brodovich H. J Physiol 544: 537-548, 2002). We now report the effect of EF on Na(+) and fluid transport by the adult lung. We first studied primary cultures of adult type II (ATII) epithelium and found that overnight exposure to EF increased Na(+) transport, and this effect was mainly due to factors other than catecholamines. Plasma did not stimulate Na(+) transport in ATII. Purification of EF demonstrated that at least some agent(s) responsible for the amiloride-insensitive component resided within the globulin fraction. ATII exposed to globulins demonstrated a conversion of amiloride-sensitive short-circuit current (I(sc)) to amiloride-insensitive I(sc) with no increase in total I(sc). Patch-clamp studies showed that ATII exposed to EF for 18 h had increased the number of highly selective Na(+) channels in their apical membrane. In situ acute exposure to EF increased the open probability of Na(+)-permeant ion channels in ATII within rat lung slices. EF did increase, by amiloride-sensitive pathways, the alveolar fluid clearance from the lungs of adult rats. We conclude that cardiogenic EF increases Na(+) transport by adult lung epithelia in primary cell culture, in situ and in vivo.     

The identity of the current carriers in canine lingual epithelium in vitro

Ion transport across the lingual epithelium has been implicated as an early event in gustatory transduction. The fluxes of isotopically labelled Na+ and Cl- were measured across isolated canine dorsal lingual epithelium under short-circuit conditions. The epithelium actively absorbs Na+ and to a lesser extent actively secretes Cl-. Under symmetrical conditions with Krebs-Henseleit buffer on both sides, (1) Na+ absorption accounts for 46% of the short-circuit current (Isc); (2) there are two transcellular Na+ pathways, one amiloride-sensitive and one amiloride-insensitive; (3) ouabain, added to the serosal solution, inhibits both Isc and active Na+ absorption. When hyperosmotic (0.25 M) NaCl is placed in the mucosal bath, both Isc and Na+ absorption increase; net Na+ absorption is at least as much as Isc. Ion substitution studies indicate that the tissue may transport a variety of larger ions, though not as effectively as Na+ and Cl-. Thus we have shown that the lingual epithelium, like other epithelia of the gastrointestinal tract, actively transports ions. However, it is unusual both in its response to hyperosmotic solutions and in the variety of ions that support a transepithelial short-circuit current. Since sodium ion transport under hyperosmotic conditions has been shown to correlate well with the gustatory neural response, the variety of ions transported may likewise indicate a wider role for transport in taste transduction.     

Lack of amiloride-sensitive transport across alveolar and respiratory epithelium of iNOS(-/-) mice in vivo

The extent to which endogenously generated nitric oxide alters Na(+) transport across the mammalian alveolar epithelium in vivo has not been documented. Herein we measured alveolar fluid clearance and nasal potential differences in mice lacking the inducible form of nitric oxide synthase [iNOS; iNOS(-/-)] and their corresponding wild-type controls [iNOS(+/+)]. Alveolar fluid clearance values in iNOS(+/+) and iNOS(-/-) anesthetized mice with normal oxygenation and acid-base balance were ~30% of instilled fluid/30 min. In both groups of mice, fluid absorption was dependent on vectorial Na(+) movement. Amiloride (1.5 mM) decreased alveolar fluid clearance in iNOS(+/+) mice by 61%, whereas forskolin (50 microM) increased alveolar fluid clearance by 55% by stimulating amiloride-insensitive pathways. Neither agent altered alveolar fluid clearance in iNOS(-/-) mice. Hyperoxia upregulated iNOS expression in iNOS(+/+) mice and decreased their amiloride-sensitive component of alveolar fluid clearance but had no effect on the corresponding values in iNOS(-/-) mice. Nasal potential difference measurements were consistent with alveolar fluid clearance in that both groups of mice had similar baseline values, which were amiloride sensitive in the iNOS(+/+) but not in the iNOS(-/-) mice. These data suggest that nitric oxide produced by iNOS under basal conditions plays an important role in regulating amiloride-sensitive Na(+) channels in alveolar and airway epithelia.     

Evidence for NHE3-mediated Na transport in sheep and bovine forestomach

Na absorption across the cornified, multilayered, and squamous rumen epithelium is mediated by electrogenic amiloride-insensitive transport and by electroneutral Na transport. High concentrations of amiloride (>100 μM) inhibit Na transport, indicating Na(+)/H(+) exchange (NHE) activity. The underlying NHE isoform for transepithelial Na absorption was characterized by mucosal application of the specific inhibitor HOE642 for NHE1 and S3226 for NHE3 in Ussing chamber studies with isolated epithelia from bovine and sheep forestomach. S3226 (1 μM; NHE3 inhibitor) abolished electroneutral Na transport under control conditions and also the short-chain fatty acid-induced increase of Na transport via NHE. However, HOE642 (30 μM; NHE1 inhibitor) did not change Na transport rates. NHE3 was immunohistochemically localized in membranes of the upper layers toward the lumen. Expression of NHE1 and NHE3 has been previously demonstrated by RT-PCR, and earlier experiments with isolated rumen epithelial cells have shown the activity of both NHE1 and NHE3. Obviously, both isoforms are involved in the regulation of intracellular pH, pH(i). However, transepithelial Na transport is only mediated by apical uptake via NHE3 in connection with extrusion of Na by the basolaterally located Na-K-ATPase. The missing involvement of NHE1 in transepithelial Na transport suggests that the proposed "job sharing" in epithelia between these two isoforms probably also applies to forestomach epithelia: NHE3 for transepithelial transport and NHE1 for, among others, pH(i) and volume regulation.     

Volume flow across the alveolar epithelium of adult rat lung

We separated the solute and water flow across the alveolar epithelium from flow across airway epithelia of the adult rat. Small volumes (0.5-1.0 ml) of Krebs-Ringer bicarbonate (KRB) were trapped in the distal air space of the isolated vascular-perfused left lung lobes while the airways were blocked by immiscible O2-carrying fluorocarbon. Lobe weight was lost or gained in response to colloid gradients and was raised by metabolic inhibitors but did not change with only fluorocarbon in the air space or in response to modifiers of epithelial ion transport. When serum was added to the KRB-colloid perfusion, weight loss occurred in the absence of a colloid gradient (3.4 ml/min) and was Na+ dependent (inhibited by luminal Na(+)-free KRB). The change in the concentration of blue dextran in liquid sampled by micropuncture from subpleural alveoli was smaller than expected from lobe weight under basal conditions or with a colloid gradient, even though the volume marker accurately detected edema formation (weight gain) induced by metabolic inhibitors. We conclude that 1) weight changes represent volume absorption from the air spaces, 2) serum stimulates a Na+ absorptive process, and 3) by exclusion, small airways and/or other subpopulations of alveoli are the site of this absorption.     

Transforming growth factor-beta1 decreases expression of the epithelial sodium channel alphaENaC and alveolar epithelial vectorial sodium and fluid transport via an ERK1/2-dependent mechanism

Acute lung injury (ALI) is characterized by the flooding of the alveolar airspaces with protein-rich edema fluid and diffuse alveolar damage. We have previously reported that transforming growth factor-beta1 (TGF-beta1) is a critical mediator of ALI after intratracheal administration of bleomycin or Escherichia coli endotoxin, at least in part due to effects on lung endothelial and alveolar epithelial permeability. In the present study, we hypothesized that TGF-beta1 would also decrease vectorial ion and water transport across the distal lung epithelium. Therefore, we studied the effect of active TGF-beta1 on 22Na+ uptake across monolayers of primary rat and human alveolar type II (ATII) cells. TGF-beta1 significantly reduced the amiloride-sensitive fraction of 22Na+ uptake and fluid transport across monolayers of both rat and human ATII cells. TGF-beta1 also significantly decreased alphaENaC mRNA and protein expression and inhibited expression of a luciferase reporter downstream of the alphaENaC promoter in lung epithelial cells. The inhibitory effect of TGF-beta1 on sodium uptake and alphaENaC expression in ATII cells was mediated by activation of the MAPK, ERK1/2. Consistent with the in vitro results, TGF-beta1 inhibited the amiloride-sensitive fraction of the distal airway epithelial fluid transport in an in vivo rat model at a dose that was not associated with any change in epithelial protein permeability. These data indicate that increased TGF-beta1 activity in the distal airspaces during ALI promotes alveolar edema by reducing distal airway epithelial sodium and fluid clearance. This reduction in sodium and fluid transport is attributable in large part to a reduction in apical membrane alphaENaC expression mediated through an ERK1/2-dependent inhibition of the alphaENaC promoter activity.     

In vitro and in vivo regulation of transepithelial lung alveolar sodium transport by serine proteases

The amiloride-sensitive epithelial sodium channel (ENaC) constitutes a rate-limiting step for sodium (Na+) and water absorption across lung alveolar epithelium. Recent reports suggested that ENaC is regulated by membrane-bound extracellular serine proteases, such as channel-activating proteases (CAPs). The objectives of this study were to examine the role of serine proteases in the regulation of transepithelial alveolar Na+ and water transport in vitro and in vivo and the expression of CAPs in rodent distal lung. In vitro experiments showed that inhibition of endogenous serine proteases by apical aprotinin 1) decreased ENaC-mediated currents in primary cultures of rat and mouse alveolar epithelial cells without affecting the abundance nor the electrophoretic migration pattern of biotinylated alpha- and beta-ENaC expressed at the cell surface and 2) suppressed the increase in amiloride-sensitive short-circuit current induced by the beta2-agonist terbutaline. RT-PCR experiments indicated that CAP1, CAP2, and CAP3 mRNAs were expressed in mouse alveolar epithelial cells, whereas CAP1 was also expressed in alveolar macrophages recovered by bronchoalveolar lavage. CAP1 protein was detected by Western blotting in rat and mouse alveolar epithelial cells, alveolar macrophages and bronchoalveolar lavage fluid. Finally, in vivo experiments revealed that intra-alveolar treatment with aprotinin abolished the increase in Na+-driven alveolar fluid clearance (AFC) induced by terbutaline in an in situ mouse lung model, whereas trypsin potentiated it. These results show that endogenous membrane-bound and/or secreted serine proteases such as CAPs regulate alveolar Na+ and fluid transport in vitro and in vivo in rodent lung.     

Effect of aldosterone on 86Rb fluxes in cultured kidney cells (A6)

This study was designed to evaluate the relative contributions of hormone induced changes in active and passive K+ transport in an epithelial cell line in continuous culture derived from toad kidney (A6) using 86Rb as a tracer for measuring unidirectional K+ fluxes. The effects of 24 h exposure to aldosterone (A) and aldosterone plus insulin (A+I) on unidirectional K+ fluxes were evaluated under short-circuited conditions and under open circuit conditions. In epithelia exposed to A, a small but significant amount of active K+ secretion was found, although it was not significantly greater than in control epithelia. The bidirectional fluxes in both A and A+I treated epithelia, under short-circuited conditions, increased by a similar amount over control values indicating an increase in apparent permeability of passive transepithelial K+ transport. Under open circuit conditions, A stimulated net K+ transport by about 5-fold over controls. The increase in K+ secretion produced by A under open circuit conditions could be explained by the combined effects of an increase in transepithelial K+ permeability and an increase in the transepithelial electrical potential difference (PD). The presence of I produced no additional effects to that of A on K+ transport under the conditions used in this study. It is concluded that the substantial increase in K+ secretion induced in A6 cells by 24 h exposure to A is primarily passive in nature. It is possible that the changes in both PD and transepithelial K+ permeability, which can account for the observed increase in K+ secretion, are secondary to the stimulation of active Na+ transport.     

22Na+ fluxes in thymic lymphocytes. I. Na+/Na+ and Na+/H+ exchange through an amiloride-insensitive pathway

The Na+ transport pathways of normal rat thymocytes were investigated. Na+ conductance was found to be lower than K+ conductance, which is consistent with reported values of membrane potential. In contrast, the isotopically measured Na+ permeability was greater than 10-fold higher than that of K+, which indicates that most of the flux is electroneutral. Cotransport with Cl- (or K+ and Cl-) and countertransport with Ca2+ were ruled out by ion substitution experiments and use of inhibitors. Countertransport for Na+ or H+ through the amiloride-sensitive antiport accounts for only 15-20% of the resting influx. In the presence of amiloride, 22Na+ uptake was increased in Na+-loaded cells, which suggests the existence of Na+/Na+ countertransport. Cytoplasmic pH determinations using fluorescent probes indicated that under certain conditions this amiloride-resistant system will also exchange Na+ for H+, as evidenced by an internal Na+- dependent acidification is proportional to internal [Na+] but inversely related to extracellular [Na+]. Moreover, 22Na+ uptake is inhibited by increasing external [H+]. The results support the existence of a substantial amiloride-insensitive, electroneutral cation exchange system capable of transporting Na+ and H+.     

Mechanisms of pulmonary edema clearance

The mechanisms of pulmonary edema resolution are different from those regulating edema formation. Absorption of excess alveolar fluid is an active process that involves vectorial transport of Na+ out of alveolar air spaces with water following the Na+ osmotic gradient. Active Na+ transport across the alveolar epithelium is regulated via apical Na+ and chloride channels and basolateral Na-K-ATPase in normal and injured lungs. During lung injury, mechanisms regulating alveolar fluid reabsorption are inhibited by yet unclear pathways and can be upregulated by pharmacological means. Better understanding of the mechanisms that regulate edema clearance may lead to therapeutic interventions to improve the ability of lungs to clear fluid, which is of clinical significance.     

Congenital diaphragmatic hernia prevents absorption of distal air space fluid in late-gestation rat fetuses

We hypothesized that congenital diaphragmatic hernia (CDH) may decrease distal air space fluid absorption due to immaturity of alveolar epithelial cells from a loss of the normal epithelial Na+ transport, as assessed by amiloride and epithelial Na+ channel (ENaC) and Na-K-ATPase expression, as well as failure to respond to endogenous epinephrine as assessed by propranolol. Timed-pregnant dams were gavage fed 100 mg of nitrofen at 9.5-day gestation to induce CDH in the fetuses, and distal air space fluid absorption experiments were carried out on 22-day gestation (term) fetuses. Controls were nitrofen-exposed fetuses without CDH. Absorption of distal air space fluid was measured from the increase in 131I-albumin concentration in an isosmolar, physiological solution instilled into the developing lungs. In controls, distal air space fluid absorption was rapid and mediated by beta-adrenoceptors as demonstrated by reversal to fluid secretion after propranolol. Normal lung fluid absorption was also partially inhibited by amiloride. In contrast, CDH fetuses continued to show lung fluid secretion, and this secretion was not affected by either propranolol or amiloride. CDH lungs showed a 67% reduction in alpha-ENaC and beta-ENaC expression, but no change in alpha1-Na-K-ATPase expression. These studies demonstrate: 1) CDH delays lung maturation with impaired distal air space fluid absorption secondary to inadequate Na+ uptake by the distal lung epithelium that results in fluid-filled lungs at birth with reduced capacity to establish postnatal breathing, and 2) the main stimulus to lung fluid absorption in near-term control fetuses, elevated endogenous epinephrine levels, is not functional in CDH fetuses.     

Role and regulation of lung Na,K-ATPase.

The recognition that pulmonary edema is cleared from the alveolar airspace by active Na+ transport has led to studies of the role and regulation of alveolar epithelial Na,K-ATPases. In the lung these heterodimers are predominantly composed of alpha1 and beta1-subunits and are located on the basolateral aspect of alveolar type 2 epithelial cells (AT2). Working with apically positioned epithelial Na+ channels they generate a transepithelial osmotic gradient which causes the movement of fluid out of the alveolar airspace. Accumulating data indicates that in some forms of pulmonary edema alveolar Na,K-ATPases function is reduced suggesting that pulmonary edema may be due, in part, to impairment of edema clearance mechanisms. Other studies suggest that Na,K-ATPase dysfunction or inhibition may contribute to airway reactivity. It is now recognized that lung Na,K-ATPases are positively regulated by glucocorticoids, aldosterone, catecholamines and growth hormones. These findings have led to investigations that show that enhancement of Na,K-ATPase function can accelerate pulmonary edema clearance in vitro, in normal and injured animal lungs in vivo, and in human lung explants. This review focuses on Na,K-ATPase data from lung and lung cell experiments that highlight the importance of Na,K-ATPases in airway reactivity and in maintaining a dry alveolar airspace. Review of data that suggests that there may be a role for therapeutic modulation of alveolar Na,K-ATPases for the purpose of treating patients with respiratory failure are also included.     

Dopamine increases lung liquid clearance during mechanical ventilation

Short-term mechanical ventilation with high tidal volume (HVT) causes mild to moderate lung injury and impairs active Na+ transport and lung liquid clearance in rats. Dopamine (DA) enhances active Na+ transport in normal rat lungs by increasing Na+-K+-ATPase activity in the alveolar epithelium. We examined whether DA would increase alveolar fluid reabsorption in rats ventilated with HVT for 40 min compared with those ventilated with low tidal volume (LVT) and with nonventilated rats. Similar to previous reports, HVT ventilation decreased alveolar fluid reabsorption by ~50% (P < 0.001). DA increased alveolar fluid reabsorption in nonventilated control rats (by ~60%), LVT ventilated rats (by approximately 55%), and HVT ventilated rats (by ~200%). In parallel studies, DA increased Na+-K+-ATPase activity in cultured rat alveolar epithelial type II cells (ATII). Depolymerization of cellular microtubules by colchicine inhibited the effect of DA on HVT ventilated rats as well as on Na+-K+-ATPase activity in ATII cells. Neither DA nor colchicine affected the short-term Na+-K+-ATPase alpha1- and beta1-subunit mRNA steady-state levels or total alpha1- and beta1-subunit protein abundance in ATII cells. Thus we reason that DA improved alveolar fluid reabsorption in rats ventilated with HVT by upregulating the Na+-K+-ATPase function in alveolar epithelial cells.     

营养不良性肺水肿大鼠肺泡液体清除机制的研究

目的探讨营养不良性肺水肿大鼠肺泡液体清除功能的变化及其机制。方法制备营养不良性肺水肿大鼠动物模型,分别于48h和120h测定大鼠肺泡液体清除率（AFC）、总肺水量（TLW）和肺血管外水量（EVLW）。将钠通道阻断剂氨氯毗眯、Na-K-ATP酶阻断剂畦巴因及β2受体激动剂特布他林分别灌注到正常及禁食120h大鼠的肺泡腔内,测定AFC的变化。结果大鼠禁食48hAFC（19．7±3．22％）与正常大鼠AFC（18．5±2．21％）比较没有明显变化;120h时AFC（9．50±2．19％）明显降低。氨氯吡咪、哇巴因明显降低营养不良性肺水肿大鼠AFC（P＜0．05）,特布他林对营养不良性肺水肿大鼠AFC的作用与对照组大鼠比较差异无显著性（P＞0．05）。结论营养不良性肺水肿与钠通道及Na-K-ATP酶及的活性被抑制,导致肺泡液体清除能力降低有关。     

Effects of PKA inhibitors, H-compounds, on epithelial Na+ channels via PKA-independent mechanisms.

The Na+ transport in alveolar type II epithelial cells of rat fetal lung was stimulated by cAMP, which is generally thought to act through activation of protein kinase A (PKA). PKA inhibitors (H8, H89 and H7) stimulated amiloride-sensitive Na+ transport in the alveolar type II epithelial cells. H85, an inactive form of H89 as a PKA inhibitor, had also mimicked the stimulatory action of H89 on the Na+ transport. On the other hand, another type of PKA inhibitor, KT5720 or myristoylated PKA inhibitory peptide [14-22] amide, did not stimulate the Na+ transport, but inhibited the Na+ transport unlike H-compounds. These observations suggest that H-compounds act on the Na+ transport depending on the structure.     

An SH3 binding region in the epithelial Na+ channel (alpha rENaC) mediates its localization at the apical membrane.

The amiloride-sensitive Na+ channel constitutes the rate-limiting step for Na+ transport in epithelia. Immunolocalization and electrophysiological studies have demonstrated that this channel is localized at the apical membrane of polarized epithelial cells. This localization is essential for proper channel function in Na+ transporting epithelia. In addition, the channel has been shown to associate with the cytoskeletal proteins ankyrin and alpha-spectrin in renal epithelia. However, the molecular mechanisms underlying the cytoskeletal interactions and apical membrane localization of this channel are largely unknown. In this study we show that the putative pore forming subunit of the rat epithelial (amiloride-sensitive) Na+ channel (alpha ENaC) binds to alpha-spectrin in vivo, as determined by co-immunoprecipitation. This binding is mediated by the SH3 domain of alpha-spectrin which binds to a unique proline-rich sequence within the C-terminal region of alpha rENaC. Accordingly, the C-terminal region is sufficient to mediate binding to intact alpha-spectrin from alveolar epithelial cell lysate. When microinjected into the cytoplasm of polarized primary rat alveolar epithelial cells, a recombinant fusion protein containing the C-terminal proline-rich region of alpha rENaC localized exclusively to the apical area of the plasma membrane, as determined by confocal microscopy. This localization paralleled that of alpha-spectrin. In contrast, microinjected fusion protein containing the N-terminal (control) protein of alpha rENaC remained diffuse within the cytoplasm. These results suggest that an SH3 binding region in alpha rENaC mediates the apical localization of the Na+ channel. Thus, cytoskeletal interactions via SH3 domains may provide a novel mechanism for retaining proteins in specific membranes of polarized epithelial cells.     

CFTR is required for maximal transepithelial liquid transport in pig alveolar epithelia

A balance between alveolar liquid absorption and secretion is critical for maintaining optimal alveolar subphase liquid height and facilitating gas exchange in the alveolar space. However, the role of cystic fibrosis transmembrane regulator protein (CFTR) in this homeostatic process has remained elusive. Using a newly developed porcine model of cystic fibrosis, in which CFTR is absent, we investigated ion transport properties and alveolar liquid transport in isolated type II alveolar epithelial cells (T2AECs) cultured at the air-liquid interface. CFTR was distributed exclusively to the apical surface of cultured T2AECs. Alveolar epithelia from CFTR(-/-) pigs failed to increase liquid absorption in response to agents that increase cAMP, whereas cAMP-stimulated liquid absorption in CFTR(+/-) epithelia was similar to that in CFTR(+/+) epithelia. Expression of recombinant CFTR restored stimulated liquid absorption in CFTR(-/-) T2AECs but had no effect on CFTR(+/+) epithelia. In ex vivo studies of nonperfused lungs, stimulated liquid absorption was defective in CFTR(-/-) alveolar epithelia but similar between CFTR(+/+) and CFTR(+/-) epithelia. When epithelia were studied at the air-liquid interface, elevating cAMP levels increased subphase liquid height in CFTR(+/+) but not in CFTR(-/-) T2AECs. Our findings demonstrate that CFTR is required for maximal liquid absorption under cAMP stimulation, but it is not the rate-limiting factor. Furthermore, our data define a role for CFTR in liquid secretion by T2AECs. These insights may help to develop new treatment strategies for pulmonary edema and respiratory distress syndrome, diseases in which lung liquid transport is disrupted.     

Cultured gill epithelia from freshwater tilapia (Oreochromis niloticus): effect of cortisol and homologous serum supplements from stressed and unstressed fish

Procedures for the preparation and culture of branchial epithelia from dispersed gill cells of freshwater tilapia (Oreochromis niloticus) are described. Epithelia were cultured on permeable supports (terephthalate membranes, "filters") and bathed on both the apical and basolateral side with isotonic media containing 6% fetal bovine serum (FBS). When the apical medium was replaced with freshwater (pseudo in vivo asymmetrical culture conditions), transepithelial resistance (TER) increased markedly, transepithelial potential became negative, and paracellular permeability decreased. The physiological effects of cortisol and 10% homologous (tilapia) serum were investigated. Tilapia serum (TS) was prepared from unstressed and stressed fish and therefore allowed comparison between the effects of homologous serum derived from fish in differing physiological states. Under both symmetrical and asymmetrical culture conditions, cortisol significantly elevated TER across cultured tilapia gill epithelia, indicative of a significant increase in epithelial "tightness." Cortisol reduced transepithelial Na + and Cl? movement and paracellular permeability. The glucocorticoid agonist dexamethasone elicited a similar response, which was inhibited by the glucocorticoid antagonist (receptor blocker) RU486. Cortisol did not stimulate active ion transport across epithelia under either symmetrical or asymmetrical culture conditions. In epithelia supplemented with TS from stressed fish, physiological changes in cultured preparations were consistent with those observed in FBS + cortisol-supplemented epithelia. Differences between the physiological status of epithelia supplemented with TS from unstressed and stressed fish could be abolished with RU486. Using TS as a medium supplement did not stimulate active ion transport under asymmetrical culture conditions, although Na +-K +-ATPase activity increased in TS-supplemented epithelia relative to FBS-supplemented preparations.     

Lung edema clearance: 20 years of progress: invited review: role of aquaporin water channels in fluid transport in lung and airways.

Water transport across epithelial and endothelial barriers in bronchopulmonary tissues occurs during airway hydration, alveolar fluid transport, and submucosal gland secretion. Many of the tissues involved in these processes are highly water permeable and express aquaporin (AQP) water channels. AQP1 is expressed in microvascular endothelia throughout the lung and airways, AQP3 in epithelia in large airways, AQP4 in epithelia throughout the airways, and AQP5 in type I alveolar epithelial cells and submucosal gland acinar cells. The expression of some of these AQPs increases near the time of birth and is regulated by growth factors, inflammation, and osmotic stress. Transgenic mouse models of AQP deletion have provided information about their physiological role. In lung, AQP1 and AQP5 provide the principal route for osmotically driven water transport; however, alveolar fluid clearance in the neonatal and adult lung is not affected by AQP deletion nor is lung CO(2) transport or fluid accumulation in experimental models of lung injury. In the airways, AQP3 and AQP4 facilitate water transport; however, airway hydration, regulation of the airway surface liquid layer, and isosmolar fluid absorption are not impaired by AQP deletion. In contrast to these negative findings, AQP5 deletion in submucosal glands in upper airways reduced fluid secretion and increased protein content by greater than twofold. Thus, although AQPs play a major physiological role outside of the airways and lung, AQPs appear to be important mainly in airway submucosal gland function. The substantially slower rates of fluid transport in airways, pleura, and lung compared with renal and some secretory epithelia may account for the apparent lack of functional significance of AQPs at these sites. However, the possibility remains that AQPs may play a role in lung physiology under conditions of stress and/or injury not yet tested or in functions unrelated to transepithelial fluid transport.