KGF prevents hyperoxia-induced reduction of active ion transport in alveolar epithelial cells

We evaluated theeffects of acute hyperoxic exposure on alveolar epithelial cell (AEC)active ion transport and on expression ofNa⁺ pump(Na⁺-K⁺-ATPase)and rat epithelial Na⁺ channelsubunits. Rat AEC were cultivated in minimal defined serum-free medium(MDSF) on polycarbonate filters. Beginning on day5, confluent monolayers were exposedto either 95% air-5% CO₂(normoxia) or 95% O₂-5%CO₂ (hyperoxia) for 48 h.Transepithelial resistance(R_t) andshort-circuit current(I_sc) weredetermined before and after exposure.Na⁺ channel -, -, and-subunit andNa⁺-K⁺-ATPase₁- and₁-subunit mRNA levels werequantified by Northern analysis.Na⁺ pump₁- and₁-subunit protein abundance wasquantified by Western blotting. After hyperoxic exposure,I_sc across AECmonolayers decreased by ~60% at 48 h relative to monolayersmaintained under normoxic conditions.Na⁺ channel -subunit mRNAexpression was reduced by hyperoxia, whereas - and -subunit mRNAexpression was unchanged. Na⁺ pump₁-subunit mRNA was unchanged,whereas ₁-subunit mRNA was decreased ~80% by hyperoxia in parallel with a reduction in₁-subunit protein. Becausekeratinocyte growth factor (KGF) has recently been shown to upregulateAEC active ion transport and expression ofNa⁺-K⁺-ATPaseunder normoxic conditions, we assessed the ability of KGF to preventhyperoxia-induced changes in active ion transport by supplementingmedium with KGF (10 ng/ml) from day2. The presence of KGF prevented theeffects of hyperoxia on ion transport (as measured byI_sc) relativeto normoxic controls. Levels of₁ mRNA and protein wererelatively preserved in monolayers maintained in MDSF and KGF comparedwith those cultivated in MDSF alone. These results indicate that AECnet active ion transport is decreased after 48 h of hyperoxia, likelyas a result of a decrease in the number of functionalNa⁺ pumps per cell. KGF largelyprevents this decrease in active ion transport, at least in part, bypreserving Na⁺ pump expression.

     

Effects of amphotericin B on ion transport proteins in airway epithelial cells

Topical intranasal application of the antifungal Amphotericin B (AmphoB) has been shown as an effective medical treatment of chronic rhinosinusitis. Because this antibiotic forms channels in lipid membranes, we considered the possibility that it affects the properties and/or cell surface expression of ion channels/pumps, and consequently transepithelial ion transport. Human nasal epithelial cells were exposed apically to AmphoB (50 microM) for 4 h, 5 days (4 h daily), and 4 weeks (4 h daily, 5 days weekly) and allowed to recover for 18-48 h. AmphoB significantly reduced transepithelial potential difference, short-circuit current, and the amiloride-sensitive current. This was not due to generalized cellular toxicity as judged from normal transepithelial resistance and mitochondrial activity, but was related to inhibitory effects of AmphoB on ion transport proteins. Thus, cells exposed to AmphoB for 4 h showed decreased apical epithelial sodium channels (ENaC) activity with no change in basolateral Na(+)K(+)-ATPase activity and K(+) conductance, and reduced amount of alphaENaC, alpha1-Na(+)K(+)-ATPase, and NKCC1 proteins at the cell membrane, but no change in mRNA levels. After a 5-day treatment, there was a significant decrease in Na(+)K(+)-ATPase activity. After a 4-week treatment, a decrease in basolateral K(+) conductance and in alphaENaC and alpha1-Na(+)K(+)-ATPase mRNA levels was also observed. These findings may reflect a feedback mechanism aimed to limit cellular Na(+) overload and K(+) depletion subsequently to formation of AmphoB pores in the cell membrane. Thus, the decreased Na(+) absorption induced by AmphoB resulted from reduced cell surface expression of the ENaC, Na(+)K(+)-ATPase pump and NKCC1 and not from direct inhibition of their activities.     

TGF-alpha reduces bradykinin-stimulated ion transport and prostaglandin release in human colonic epithelial cells

The effect of chronic exposure to transforming growth factor-(TGF-) on bradykinin-stimulated acute prostanoid production and ionsecretion in monolayers of HCA-7 colony 29 colonic epithelial cells hasbeen studied. Monolayers synthesized prostaglandinE₂ (PGE₂) at a basal rate of 2.10 ± 0.31 pg · monolayer¹ · min¹over 24 h. Bradykinin(10⁸-10⁵M) dose dependently increased acutePGE₂ release by three orders ofmagnitude. This was associated with a rise in cAMP from 1.60 ± 0.14 to 2.90 ± 0.1 pmol/monolayer (P < 0.02) and a dose-dependent increase in short-circuit current (SCC).When monolayers were primed by a 24-h exposure to TGF-, basalPGE₂ release rose to 6.31 ± 0.38 pg · monolayer¹ · min¹(TGF- concn 10 ng/ml; P = 0.001).However, the stimulation of acute prostaglandin release, intracellularcAMP, and increased SCC by bradykinin was significantly reduced bypreincubation with TGF-. Priming withPGE₂(10⁸-10⁶M) over 24 h mimicked the effect of TGF- on bradykinin-induced changes in cAMP and SCC. These data suggest that enhanced chronic release of prostaglandins in response to stimulation with TGF- maydownregulate acute responses to bradykinin. In vivo, TGF- could havean important modulatory function in regulating secretion underinflammatory conditions.     

Modification of transepithelial ion transport in human cultured bronchial epithelial cells by interferon-gamma

Human bronchial epithelial cells were treated in vitro with interferon-gamma or tumor necrosis factor-alpha to assess their effect on transepithelial ion transport. Short-circuit current measurements revealed that Na(+) absorption was markedly inhibited by interferon-gamma (10-1,000 U/ml). The cystic fibrosis transmembrane conductance regulator was also downregulated by interferon-gamma as evident at the protein level and by the decrease in the cAMP-dependent current. On the other hand, interferon-gamma caused an increase of the current elicited by apical UTP application, which is due to the activity of Ca(2+)-dependent Cl(-) channels. Tumor necrosis factor-alpha caused few changes in ion transport. Transepithelial fluid transport was measured in normal and cystic fibrosis cells. At rest, both types of cells showed an amiloride-sensitive fluid absorption that was inhibited by interferon-gamma but not by tumor necrosis factor-alpha. Our results show that interferon-gamma alters the transepithelial ion transport of cultured bronchial cells. This effect may change the ion composition and/or volume of periciliary fluid.     

Protease-activated receptor-2-mediated inhibition of ion transport in human bronchial epithelial cells

A cytoprotective role for protease-activated receptor-2 (PAR2) has been suggested in a number of systems including the airway, and to this end, we have studied the role that PARs play in the regulation of airway ion transport, using cultures of normal human bronchial epithelial cells. PAR2 activators, added to the basolateral membrane, caused a transient, Ca2+-dependent increase in short-circuit current (I(sc)), followed by a sustained inhibition of amiloride-sensitive I(sc). These phases corresponded with a transient increase in intracellular Ca2+ concentration and then a transient increase, followed by decrease, in basolateral K+ permeability. After PAR2 activation and the addition of amiloride, the forskolin-stimulated increase in I(sc) was also attenuated. By contrast, PAR2 activators added to the apical surface of the epithelia or PAR1 activators added to both the apical and basolateral surfaces were without effect. PAR2 may, therefore, play a role in the airway, regulating Na+ absorption and anion secretion, processes that are central to the control of airway surface liquid volume and composition.     

Sodium-dependent nucleoside transport in mouse intestinal epithelial cells. Two transport systems with differing substrate specificities

Nucleoside transport was examined in freshly isolated mouse intestinal epithelial cells. The uptake of formycin B, the C nucleoside analog of inosine, was concentrative and required extracellular sodium. The initial rate of sodium-dependent formycin B transport was saturable with a Km of 45 +/- 3 microM. The purine nucleosides adenosine, inosine, guanosine, and deoxyadenosine were all good inhibitors of sodium-dependent formycin B transport with 50% inhibition (IC50) observed at concentrations less than 30 microM. Of the pyrimidine nucleosides examined, only uridine (IC50, 41 +/- 9 microM) was a good inhibitor. Thymidine and cytidine were poor inhibitors with IC50 values greater than 300 microM. Direct measurements of [3H]thymidine transport revealed, however, that the uptake of this nucleoside was also mediated by a sodium-dependent mechanism. Thymidine transport was inhibited by low concentrations of cytidine, uridine, adenosine, and deoxyadenosine (IC50 values less than 25 microM), but not by formycin B, inosine, or guanosine (IC50 values greater than 600 microM). These data indicate that there are two sodium-dependent mechanisms for nucleoside transport in mouse intestinal epithelial cells, and that formycin B and thymidine may serve as model substrates to distinguish between these transporters. Neither of these sodium-dependent transport mechanisms was inhibited by nitrobenzylmercaptopurine riboside (10 microM), a potent inhibitor of one of the equilibrative (facilitated diffusion) nucleoside transporters found in many cells.     

Kinins and epithelial ion transport in the alimentary tract

Kinin effects on epithelial electrogenic ion transport are reviewed, with reference to the alimentary tract. The transported ion is usually chloride, but some epithelia also transport bicarbonate. The key components of the transport system are the sodium-potassium-chloride cotransporter, Na+-K+ ATPase (both located basolaterally) and the CFTR chloride channel (located apically). Activation of K+-channels in both membranes may secondarily affect the anion transport mechanism. The types of kinin receptors that cause chloride secretion, the second messengers involved and the possible functional responsibilities of the kinin-activated secretory mechanism are discussed.     

The role of volume-sensitive ion transport systems in regulation of epithelial transport

This review focuses on using the knowledge on volume-sensitive transport systems in Ehrlich ascites tumour cells and NIH-3T3 cells to elucidate osmotic regulation of salt transport in epithelia. Using the intestine of the European eel (Anguilla anguilla) (an absorptive epithelium of the type described in the renal cortex thick ascending limb (cTAL)) we have focused on the role of swelling-activated K+- and anion-conductive pathways in response to hypotonicity, and on the role of the apical (luminal) Na+-K+-2Cl- cotransporter (NKCC2) in the response to hypertonicity. The shrinkage-induced activation of NKCC2 involves an interaction between the cytoskeleton and protein phosphorylation events via PKC and myosin light chain kinase (MLCK). Killifish (Fundulus heteroclitus) opercular epithelium is a Cl(-)-secreting epithelium of the type described in exocrine glands, having a CFTR channel on the apical side and the Na+/K+ ATPase, NKCC1 and a K+ channel on the basolateral side. Osmotic control of Cl- secretion across the operculum epithelium includes: (i) hyperosmotic shrinkage activation of NKCC1 via PKC, MLCK, p38, OSR1 and SPAK; (ii) deactivation of NKCC by hypotonic cell swelling and a protein phosphatase, and (iii) a protein tyrosine kinase acting on the focal adhesion kinase (FAK) to set levels of NKCC activity.     

The role of bestrophin in airway epithelial ion transport

The purpose of this study was to identify Cl- channels in the basolateral membrane of airway epithelial cells at the molecular level. We have focused on a new family of Cl- channels, bestrophins, which have previously been identified in retinal pigment epithelium. RT-PCR, Western blot and confocal microscopy studies revealed the presence of bestrophin in airway epithelial cells. Decreasing bestrophin expression using siRNA resulted in diminished 36Cl- flux. These studies also showed that bestrophin regulation is similar to that of native basolateral Cl- channels. The data indicate that the presence of a functional bestrophin may contribute to the basolateral cell conductance in airway epithelial cells.     

Sodium ion transport in isolated intestinal epithelial cells. The effect of actively transported sugars on sodium ion efflux

A technique to measure Na⁺ efflux from isolated intestinal epithelial cells has permitted us to examine the mechanisms responsible for Na⁺ transport in absorptive cells without contamination by other cell types. We examined the effect of actively transported sugars on Na⁺ efflux from isolated rat jejunal epithelial cells to evaluate the mechanism by which actively transported non-electrolytes stimulate Na⁺ absorption. Glucose, galactose and 3-O-methylglucose, sugars known to be actively transported by the small intestine, stimulate total Na⁺ efflux from isolated epithelial cells. This stimulation results from an increase of active Na⁺ transport, since it is inhibited by ouabain. Glucose stimulation is significantly greater than that produced by galactose or 3-O-methylglucose, 2-Deoxyglucose, a sugar that is not actively transported, has no effect on total Na⁺ efflux from isolated cells. Phloridzin, which has no effect on Na⁺ efflux in a sugar-free medium, completely abolishes the effect of galactose. These findings (a) support the hypothesis that the increase in intestinal absorption of Na⁺ in the presence of actively transported non-electrolytes occurs by a transcellular route; and (b) are consistent with the ion-gradient model. The results are not compatible with the direct energy-coupling model.     

Gramicidin and ion transport in isolated liver mitochondria

1. Eight distinct acid-hydrolase activities present in cytoplasmic extracts from bone tissue occur in latent form to the extent of 50-70% of their total activity, depending on the enzyme. 2. This latency can be decreased or suppressed by exposure to Triton X-100 or to media of low osmotic pressure, by treatment in the Waring Blendor, and by freezing and thawing, but not by increasing the substrate concentration in the assay medium up to 10-fold the Michaelis constant of the enzymes. 3. Latency is the property of the particle-bound enzymes, and treatments that suppress latency simultaneously cause solubilization of the enzymes. Most enzymes show an excess of free over soluble activity; the magnitude of this excess seems to depend largely on the nature of the enzyme, and sometimes also on the kind of treatment suffered by the preparations; it is attributed mainly to adsorption artifacts. 4. In preparations subjected to graded activating treatments, seven of the eight acid hydrolases studied are released in closely parallel fashion, suggesting that they are associated with particles possessing similar properties. Acid phenylphosphatase is released less readily than the other enzymes by Triton X-100 and by exposure to media of low osmotic pressure. 5. It is concluded from these and previous published fractionation experiments that, with the possible exception of part of the acid-phenylphosphatase activity, the eight acid hydrolases studied belong to lysosome-like particles. Bone lysosomes exhibit a relatively high degree of biochemical and physical heterogeneity. Their possible functions are discussed. Part of the acid-phenylphosphatase activity could be linked to another group of particles. 6. Catalase is also partly (30%) latent in cytoplasmic extracts of bone. Latent catalase can be released by some of the treatments that suppress the latency of the lysosomal enzymes, but differs from the latter by a greater resistance to Triton X-100, and, especially, by a complete insensitivity to exposure to media of low osmotic pressure. It is concluded from these results that the catalase-containing particles are probably different from lysosomes, as they are in liver. 7. Cytochrome oxidase, which is presumably associated with the mitochondria, and alkaline phenylphosphatase, an enzyme occurring predominantly in the microsomal fraction, exhibited no latency under the conditions of the present experiments.     

Relative suppression of the sodium-dependent Vitamin C transport in mouse versus human lens epithelial cells

Vitamin C is a major antioxidant and UV absorbent in the human lens. In the rodent lens, the levels are very low for unknown reasons. Searching for clues to explain this suppression, we investigated the comparative uptake of Vitamin C in cultured human and mouse lens epithelial cells. When compared to human HLE-B3 lens epithelial cells, ¹⁴C-ASA uptake was 4- to 10-fold impaired in confluent mouse lens 17EM15 (p < 0.0001) and 21EM15 (p < 0.001) cells, respectively. High glucose concentrations reduced the uptake by 30–50% in all cells (p < 0.005). Incubation of cells with 6-deoxy-6-fluoro-ascorbic (F-ASA), i.e. a probe specific for the sodium-dependent Vitamin C uptake (SVCT2), revealed a 10-fold uptake suppression into mouse 17EM15 relative to human HLE-B3 and JAR choriocarcinoma cells (a control), that could be overcome by overexpressing hSVCT2 using two different promoter constructs. The relative Vitamin C uptake differences suggest either low expression of SVCT2, molecular differences between the transporters themselves or their biological regulation, since a recent study has shown that exogenous feeding of ascorbic acid to rats increased only modestly lenticular uptake (Mody et al., Acta Ophthalmol Scand 83: 228–223, 2005). Elucidation of the mechanism by which SCVT2 activity is suppressed in mouse lens may help unravel a major question of evolutionary significance for night vision in nocturnal animals.     

Chloride transport in rabbit esophageal epithelial cells

We investigated Cl(-) transport pathways in the apical and basolateral membranes of rabbit esophageal epithelial cells (EEC) using conventional and ion-selective microelectrodes. Intact sections of esophageal epithelium were mounted serosal or luminal side up in a modified Ussing chamber, where transepithelial potential difference and transepithelial resistance could be determined. Microelectrodes were used to measure intracellular Cl(-) activity (a), basolateral or apical membrane potentials (V(mBL) or V(mC)), and the voltage divider ratio. When a basal cell was impaled, V(mBL) was -73 +/- 4.3 mV and a(i)(Cl) was 16.4 +/- 2.1 mM, which were similar in presence or absence of bicarbonate. Removal of serosal Cl(-) caused a transient depolarization of V(mBL) and a decrease in a(i)(Cl) of 6.5 +/- 0.9 mM. The depolarization and the rate of decrease of a(i)(Cl) were inhibited by approximately 60% in the presence of the Cl(-)-channel blocker flufenamate. Serosal bumetanide significantly decreased the rate of change of a(i)(Cl) on removal and readdition of serosal Cl(-). When a luminal cell was impaled, V(mC) was -65 +/- 3.6 mV and a was 16.3 +/- 2.2 mM. Removal of luminal Cl(-) depolarized V(mC) and decreased a by only 2.5 +/- 0.9 mM. Subsequent removal of Cl(-) from the serosal bath decreased a(i)(Cl) in the luminal cell by an additional 6.4 +/- 1.0 mM. A plot of V(mBL) measurements vs. log a(i)(Cl)/log a(o)(Cl) (a(o)(Cl) is the activity of Cl(-) in a luminal or serosal bath) yielded a straight line [slope (S) = 67.8 mV/decade of change in a(i)(Cl)/a(o)(Cl)]. In contrast, V(mC) correlated very poorly with log a/a (S = 18.9 mV/decade of change in a/a). These results indicate that 1) in rabbit EEC, a(i)(Cl) is higher than equilibrium across apical and basolateral membranes, and this process is independent of bicarbonate; 2) the basolateral cell membrane possesses a conductive Cl(-) pathway sensitive to flufenamate; and 3) the apical membrane has limited permeability to Cl(-), which is consistent with the limited capacity for transepithelial Cl(-) transport. Transport of Cl(-) at the basolateral membrane is likely the dominant pathway for regulation of intracellular Cl(-).     

Solute transport process in intestinal epithelial cells

In rat small intestine, the active transport of organic solutes results in significant depolarization of the membrane potential measured in an epithelial cell with respect to a grounded mucosal solution and in an increase in the transepithelial potential difference. According to the analysis with an equivalent circuit model for the epithelium, the changes in emf's of mucosal and serosal membranes induced by active solute transport were calculated using the measured conductive parameters. The result indicates that the mucosal cell membrane depolarizes while the serosal cell membrane remarkably hyperpolarizes on the active solute transport. Corresponding results are derived from the calculations of emf's in a variety of intestines, using the data that have hitherto been reported. The hyperpolarization of serosal membrane induced by the active solute transport might be ascribed to activation of the serosal electrogenic sodium pump. In an attempt to determine the causative factors in mucosal membrane depolarization during active solute transport, cell water contents and ion concentrations were measured. The cell water content remarkably increased and, at the same time, intracellular monovalent ion concentrations significantly decreased with glucose transport. Net gain of glucose within the cell was estimated from the restraint of osmotic balance between intracellular and extracellular fluids. In contrast to the apparent decreases in intracellular Na+ and K+ concentrations, significant gains of Na+ and K+ occurred with glucose transport. The quantitative relationships among net gains of Na+, K+ and glucose during active glucose transport suggest that the coupling ratio between glucose and Na+ entry by the carrier mechanism on the mucosal membrane is approximately 1:1 and the coupling ratio between Na+-efflux and K+-influx of the serosal electrogenic sodium pump is approximately 4:3 in rat small intestine. In addition to the electrogenic ternary complex inflow across the mucosal cell membrane, the decreases in intracellular monovalent ion concentrations, the temporary formation of an osmotic pressure gradient across the cell membrane and the streaming potential induced by water inflow through negatively charged pores of the cell membrane in the course of an active solute transport in intestinal epithelial cells are apparently all possible causes of mucosal membrane depolarization.