We studied the mechanisms by which prostaglandin E2 (PGE2) regulates amiloride-blockable 4-pS Na+ channels in A6 distal nephron cells. With each apical cell-attached patch acting as its own control, acute (3-6 min) basolateral, but not apical, exposure to 1 microM PGE2 inhibited Na+ channel activity by decreasing the open probability (Po). This PGE2-induced inhibition was attenuated by 30 min pretreatment with the protein kinase C (PKC) antagonists 1 microM staurosporine or 100 microM D-sphingosine but was insensitive to pertussis toxin (PTX). Furthermore, the time course for channel inhibition by acute PGE2 correlated with a transient increase in intracellular inositol 1,4,5-trisphosphate (IP3) levels. In contrast, after chronic (10-50 min) exposure of A6 cells to 1 microM basolateral PGE2, channel activity was stimulated compared with controls. This stimulation was due to an increase in the number of apical Na+ channels, similar to the effect of maneuvers that increase intracellular adenosine 3',5'-cyclic monophosphate (cAMP) levels in A6 cells (22). Indeed, chronic exposure to basolateral PGE2 correlated with a sustained increase in cAMP levels. In conclusion, 1) the regulation of apical 4-pS highly selective Na+ channel activity by basolateral PGE2 is a complicated biphasic process, which includes inhibition by acute PGE2 and stimulation by chronic PGE2 exposure; 2) acute PGE2 promotes a transient generation of IP3 which activates Ca(2+)-dependent PKC and promotes a decrease in Po; 3) chronic PGE2 promotes a sustained generation of cAMP that leads to an increase in channel density; and 4) both the acute and chronic effects of PGE2 on Na+ channels are PTX-insensitive processes.
Insulin increases epithelial Na+ reabsorption, and many of its actions involve tyrosine kinase. We used tyrosine kinase inhibitors to examine the role of tyrosine kinase in the action of insulin. Pretreatment of Na+ transporting cells with tyrosine kinase inhibitors attenuates the subsequent action of insulin, suggesting that the action of insulin on epithelial Na+ transport involves tyrosine kinase activity. In addition to their effect on insulin-induced Na+ transport, the tyrosine kinase inhibitors also significantly reduce Na+ transport in Na(+)-transporting epithelial cells, suggesting that there is a significant tonic tyrosine kinase activity that modulates epithelial Na+ transport. Using patch-clamp methods, we found that one inhibitor, genistein, reduces the number of active Na+ channels in cell-attached patches without significantly affecting the open probability of any remaining channels. The effects of the tyrosine kinase inhibitors are not due to inhibition of protein kinase A (PKA), since H89, a PKA inhibitor, does not affect Na+ transport of control cells (as the tyrosine kinase inhibitors do), and the tyrosine kinase inhibitor, genistein or tyrphostin 23, does not alter the stimulation of ion transport by 8-(4-chlorophenylthio)adenosine 3',5'-cyclic monophosphate, a membrane-permeable adenosine 3',5'-cyclic monophosphate analogue (as H89 does).
Fluid transport across cultures of bovine tracheal epithelium was measured with a capacitance probe technique. Baseline fluid absorption ( J v) across bovine cells of 3.2 μl ⋅ cm−2 ⋅ h−1was inhibited by ∼78% after 1 h of exposure to suspensions of Pseudomonas aeruginosa, with a concomitant decrease in transepithelial potential (TEP) and increase in transepithelial resistance ( R t). Effects of P. aeruginosa were blocked by amiloride, which decreased J v by 112% from baseline of 2.35 ± 1.25 μl ⋅ cm−2 ⋅ h−1, increased R t by 101% from baseline of 610 ± 257 Ω ⋅ cm2, and decreased TEP by 91% from baseline of −55 ± 18.5 mV. Microelectrode studies suggested that effects of P. aeruginosa on amiloride-sensitive Na absorption were due in part to a block of basolateral membrane K channels. In the presence of Cl transport inhibitors [5-nitro-2-(3-phenylpropylamino)-benzoic acid, H2-DIDS, and bumetanide], P. aeruginosa induced a fluid secretion of ∼2.5 ± 0.4 μl ⋅ cm−2 ⋅ h−1and decreased R twithout changing TEP. However, these changes were abolished when the transport inhibitors were used in a medium in which Cl was replaced by an impermeant organic anion. Filtrates of P. aeruginosa suspensions had no effect on J v, TEP, or R t. Mutants lacking exotoxin A or rhamnolipids or with defective lipopolysaccharide still inhibited fluid absorption and altered bioelectrical properties. By contrast, mutations in the rpoN gene encoding a ς factor of RNA polymerase abolished actions of P. aeruginosa. In vivo, changes in transepithelial salt and water transport induced by P. aeruginosa may alter viscosity and ionic composition of airway secretions so as to foster further bacterial colonization.
Previous work from this laboratory has shown that apical membrane sodium channel activity is stimulated by serosal hyposmotic solutions (Wills, Millinoff & Crowe, 1991). In the present study, we determined whether this stimulation of sodium transport is additive with the actions of prostaglandin E2 (PGE2) or cyclic AMP (cAMP). Addition of exogenous PGE2 (100 nM; serosal bath) to isosmotic solutions led to large increases in the amiloride-sensitive short-circuit current (Isc) and transepithelial conductance (Gt), whereas no significant effects of PGE2 were observed in hyposmotic serosal solutions. Subsequent addition of mucosal amiloride reduced Isc by approximately 95% and Gt by approximately 60%. Inhibition of endogenous PGE2 production by blockers of phospholipase A2 activity (quinacrine or 3[4-octadecyl]-benzoylacrylic acid; OBBA), or inhibition of cyclooxygenase activity by indomethacin reduced the stimulation of Isc and Gt by hyposmotic solutions. Addition of forskolin (FSK) or 3-Isobutyl-1-methylxanthine (IBMX) also resulted in approximately twofold increases in the amiloride-sensitive Isc and Gt and abolished the effects of subsequent hyposmotic challenge. The effects of forskolin, PGE2, and hyposmotic challenge were diminished by pretreatment with H89, a protein kinase A (PKA) inhibitor. We conclude that osmotic regulation of sodium channel activity interacts with multiple intracellular signaling pathways, specifically the arachidonic acid metabolic pathway and the cAMP/PKA intracellular messenger cascade.
The presence of blood proteins and excess liquid in the airway lumen during airway inflammation may be secondary to extravasation and elevation of subepithelial hydrostatic pressure. This study examines how hydrostatic pressures of 5-20 cm H2O affect hydraulic conductivity and macromolecular permeability of primary cultures of bovine tracheal epithelium. Hydraulic conductivity was not altered by transepithelial pressure gradients of up to 20 cm H2O directed from the mucosal to serosal side of the tissue (m-s). By contrast, a 20-cm H2O s-m pressure resulted in a marked increase in hydraulic conductivity with the critical pressure lying between 10 and 20 cm H2O. Electrical conductance (i.e., permeability to ions) was not altered by m-s pressure gradients, or by a 5-cm H2O s-m gradient, but was increased by s-m pressures > or = 10 cm. Fluxes (s-m and m-s) of fluorescein and fluorescent dextrans (70 and 2000 kDa) were not altered by pressures of up to 20 cm H2O m-s. By contrast s-m pressure gradients of 20 cm H2O dramatically increased the s-m fluxes of these probes. The increases in flux were completely reversible. The results indicate that s-m pressure gradients greatly increase the hydraulic conductivity of airway epithelium by creating pores with an effective diameter greater than 54 nm.
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