Effects of a small serosal hydrostatic pressure on sodium and water transport and morphology in rabbit gall-bladder

Trans-epithelial fluid flow and mechanics of epithelial morphogenesis

Active fluid transport across epithelial monolayers is emerging as a major driving force of tissue morphogenesis in a variety of healthy and diseased systems, as well as during embryonic development. Cells use directional transport of ions and osmotic gradients to drive fluid flow across the cell surface, in the process also building up fluid pressure. The basic physics of this process is described by the osmotic engine model, which also underlies actin-independent cell migration. Recently, the trans-epithelial fluid flux and the hydraulic pressure gradient have been explicitly measured for a variety of cellular and tissue model systems across various species. For the kidney, it was shown that tubular epithelial cells behave as active mechanical fluid pumps: the trans-epithelial fluid flux depends on the hydraulic pressure difference across the epithelial layer. When a stall pressure is reached, the fluid flux vanishes. Hydraulic forces generated from active fluid pumping are important in tissue morphogenesis and homeostasis, and could also underlie multiple morphogenic events seen in other developmental contexts. In this review, we highlight findings that examined the role of trans-epithelial fluid flux and hydraulic pressure gradient in driving tissue-scale morphogenesis. We also review organ pathophysiology due to impaired fluid pumping and the loss of hydraulic pressure sensing at the cellular scale. Finally, we draw an analogy between cellular fluidic pumps and a connected network of water pumps in a city. The dynamics of fluid transport in an active and adaptive network is determined globally at the systemic level, and transport in such a network is best when each pump is operating at its optimal efficiency.

cAMP triggers Na+ absorption by distal airway surface epithelium in cystic fibrosis swine

A controversial hypothesis pertaining to cystic fibrosis (CF) lung disease is that the CF transmembrane conductance regulator (CFTR) channel fails to inhibit the epithelial Na⁺ channel (ENaC), yielding increased Na⁺ reabsorption and airway dehydration. We use a non-invasive self-referencing Na⁺-selective microelectrode technique to measure Na⁺ transport across individual folds of distal airway surface epithelium preparations from CFTR^-/- (CF) and wild-type (WT) swine. We show that, under unstimulated control conditions, WT and CF epithelia exhibit similar, low rates of Na⁺ transport that are unaffected by the ENaC blocker amiloride. However, in the presence of the cyclic AMP (cAMP)-elevating agents forskolin+IBMX (isobutylmethylxanthine), folds of WT tissues secrete large amounts of Na⁺, while CFTR^-/- tissues absorb small, but potentially important, amounts of Na⁺. In cAMP-stimulated conditions, amiloride inhibits Na⁺ absorption in CFTR^-/- tissues but does not affect secretion in WT tissues. Our results are consistent with the hypothesis that ENaC-mediated Na⁺ absorption may contribute to dehydration of CF distal airways.

Regulation of Epithelial Cell Functions by the Osmolality and Hydrostatic Pressure Gradients: A Possible Role of the Tight Junction as a Sensor

Epithelia act as a barrier to the external environment. The extracellular environment constantly changes, and the epithelia are required to regulate their function in accordance with the changes in the environment. It has been reported that a difference of the environment between the apical and basal sides of epithelia such as osmolality and hydrostatic pressure affects various epithelial functions including transepithelial transport, cytoskeleton, and cell proliferation. In this paper, we review the regulation of epithelial functions by the gradients of osmolality and hydrostatic pressure. We also examine the significance of this regulation in pathological conditions especially focusing on the role of the hydrostatic pressure gradient in the pathogenesis of carcinomas. Furthermore, we discuss the mechanism by which epithelia sense the osmotic and hydrostatic pressure gradients and the possible role of the tight junction as a sensor of the extracellular environment to regulate epithelial functions.

Calcium dependence of BAY K 8644 effects on the rabbit gall-bladder

In the present study, we characterized the effects of the calcium (Ca2+) channel activator BAY K 8644 on sodium (Na+) absorption and transepithelial potential difference (Pd) in the rabbit gall-bladder. In gall-bladders mounted in an Ussing chamber it was observed that serosal BAY K 8644 (10(-5) M) inhibited Na+ absorption in the presence, but not in the absence of serosal Ca2+. Serosal nifedipine (a Ca2+ channel antagonist) at 10(-5) M did not reverse the Na+ transport inhibition caused by BAY K 8644. Another effect of serosal BAY K 8644 (10(-5) M) was to induce oscillations in Pd. These Pd-oscillations had a frequency of about one per minute and an amplitude of 20-40 microV. The appearance of Pd-oscillations was dependent on the presence of Ca2+ in the serosal medium. The oscillations were abolished by 1-3 x 10(-5) M serosal nifedipine and by bilateral application of 3 mM barium (Ba2+) (a K+ channel blocker). In a sac preparation of the rabbit gall-bladder, spontaneous cyclic contractions of smooth muscle cells in the gall-bladder wall were observed as oscillations in the transmural pressure. These spontaneous contractions were not accompanied by oscillations in Pd. Serosal BAY K 8644 (10(-5) M) evoked oscillations in Pd in half of the sac preparations, but in each gall-bladder the frequencies of Pd-oscillations and pressure oscillations were different. Serosal nifedipine (2 x 10(-5) M) abolished both types of oscillation.(ABSTRACT TRUNCATED AT 250 WORDS)

Transcellular sodium fluxes and pump activity in Necturus gall-bladder epithelial cells

1. Transepithelial Na transport in Necturus was determined by measuring the rate of isotonic fluid flow. The rate at 20 degrees C was equivalent to 175 pmol cm-2 s-1. 2. Ouabain was effective in Necturus, binding to the Na pump in gall-bladder cells with a mean rate constant of 5.4 X 10(3) M-1 s-1. Measurement of the diffusive time constant of the free space for [3H]ouabain shows that the pump must be fully inhibited within 20 s when ouabain is applied to the serosa at 10(-3) M. 3. The serosal Na efflux from loaded cells was inhibited 36% by ouabain equal to a flux of 73 pmol cm-2 s-1. The remaining flux could not be attributed to either exchange diffusion or electrodiffusion induced by ouabain. 4. The transepithelial potential was 0.3 mV serosa positive. The short-circuit current measured was 6.33 +/- 1.9 microA cm-2, equal to a positive univalent ion flux of 65.6 pmol cm-2 s-1 or 38% of the net Na transfer. The current was inhibited within 1-5 min by 5 X 10(-5) M-amiloride. 5. Fluid secretion was immediately inhibited 34% by ouabain, equivalent to an isotonic transport of Na of 59.7 pmol cm-2 s-1. Thereafter it continued for at least an hour, sometimes declining slowly. Amiloride had little effect (13%). 6. The Na pump rate was measured by titrating the cell content with tracer Na at different times after ouabain treatment. The initial slope was equal to a rate of 61.6 pmol cm-2 s-1 or 35% of the net flux at time zero. 7. The Na pump rate has also been measured by recording the rise in cell Na activity with ion-specific micro-electrodes, and correcting for swelling effects. The Na pump rate was very similar to that estimated from the rise in tracer Na content, equal to 59.3 pmol cm-2 s-1 or 31.4% of the transepithelial rate. Examination of the same experiment in the literature shows a closely similar value, about one-third of that expected from fluid secretion or net flux measurements. 8. A scheme is proposed to explain the results, which requires a flow of NaCl through a parallel pathway of small Na content involving exchange en route with the cytoplasmic Na.

Current-induced volume flow across bovine tracheal epithelium: evidence for sodium-water coupling

The passage of a constant current from lumen to serosa (Il-s), in the range 0.5-2.0 mA, across ouabain-treated bovine tracheal epithelium, induced a stable volume flow (Jv) toward the serosa, proportional to the current. No consistent Jv occurred when current was applied from serosa to lumen. When the standard K+ (6 mM) in the bathing solution was omitted or replaced by choline, Jv was in the same direction as, and proportional to, the current, both with Is-l and with Il-s. The electro-osmotic permeability beta was in the range of 10-15 microl h-1 cm-2 mA-1, i.e. 3-4 X 10(-6) cm s-1 mA-1. The fluxes of Na+, Cl- and mannitol were measured in current-clamp (1 mA, passed from serosa to lumen or lumen to serosa) or voltage-clamp (-20, 0 and +20 mV) conditions, with and without K+. Net transepithelial Na+ fluxes toward the cathode were either smaller than (with Is-l) or equal to (with Il-s) the net fluxes of Cl- toward the anode. The total transepithelial conductance (Gt) increased with the applied electrical gradient, both with Is-l and with Il-s, the change in Gt being larger with Il-s than with Is-l. This increase of Gt was less pronounced when K+ was omitted. The analyses of partial ionic conductances (GNa and GCl) and of the flux ratios indicate the existence of non-conductive diffusion for Cl- and also for Na+. The direction of the electrical gradient influenced the permeability ratio PNa/PCl. With Is-l, PNa/PCl was consistently lower than 0.7, i.e. the mobility ratio of Na+ and Cl- in solution. With Il-s, PNa/PCl was closer to 0.7. The highest Cl- selectivity of the epithelium was observed with Is-l in the presence of K+, i.e. under conditions which failed to induce any conspicuous Jv. The passage of current at 1 mA induced a net flux of mannitol toward the cathode, i.e. in the same direction as Na+ net flux and Jv. However, this mannitol flux was significant only in the absence of K+. These results indicate that Jv was predominantly coupled to the migration of Na+ along the electrical gradient, through a paracellular pathway.

Amiloride sensitive and insensitive sodium pathways and the cellular sodium transport pool of colonic epithelium in rats

Methods for measurement of the epithelial Na transport pool (Nat) using epithelial scrapings and for analysing the transepithelial ionic fluxes of rat distal colon in vivo into transcellular and paracellular components have been used to study the amiloride sensitive (a.s.) and amiloride insensitive (a.i.) transcellular pathways in relation to variations of Nat. In the Na-replete normal rats, substitution of SO4 for Cl in the lumen approximately halved the Na transported by a.i. pathways and reduced Nat by about 60%, but in the Na-depleted rats, substitution of SO4 did not affect either the Na transported by a.s. pathways or Nat. The value of Nat for normal rats, with 150 mM-NaCl in the lumen, was 6-7 nmol Na mg-1 dry weight (corresponding to about 2-3 mmol kg-1 cell water) and fell by about 60% when lumen Na concentration was reduced to 50 mM. Its turnover half-time was 0.6 min. Nat was about threefold greater in the Na-depleted than in the normal rats but became undetectable when amiloride was in the lumen. Amiloride did not affect Nat in normal rats. We conclude that the increased Na absorption in Na depletion depended on substitution of a.s. for a.i. apical membrane pathways allowing increased Na entry into the epithelial cells so expanding Nat and stimulating the basolateral Na pumps.

Effect of amiloride on sodium and water reabsorption in the rabbit gall-bladder

The effects of the Na+-channel-blocking diuretic agent amiloride were assessed in the rabbit gall-bladder epithelium, a low-resistance epithelium with an isosmotic, coupled NaCl transport mechanism. Amiloride caused a rapid, reversible, and dose-dependent decrease in fluid absorption when applied from the mucosal side in concentrations between 8.8 X 10(-5) and 1.76 X 10(-3) M. These concentrations were without effect from the serosal side, suggesting an action of amiloride in the luminal cell membrane as in high-resistance epithelia. Amiloride did not affect the epithelial resistance or the passive serosa-to-mucosa Na+ flux, while net Na+ and water reabsorption were inhibited in parallel. Thus, amiloride did not affect the paracellular tight junction pathway, but inhibited a transcellular, coupled salt and water transport mechanism. The kinetics of the amiloride effect were of a Michaelis-Menten type. The dose of amiloride giving 50% inhibition of fluid absorption (ID50) was 4 X 10(-4) M, a value about three orders of magnitude higher than in high-resistance, Na+-retaining epithelia. The percentage inhibitory effect at each concentration of amiloride increased with increasing rate of spontaneous (control) fluid transport, reaching maximal responses fitting a Michaelis-Menten kinetic with an ID50 of 1.5 X 10(-4) M. No effects of changing the extracellular Na+ concentration between 51 and 145 mequiv/l on the maximal inhibitory effect of amiloride on Na+ and water reabsorption were observed. This suggests a non-competitive type of action of amiloride on a Na+-dependent isosmotic fluid transport mechanism. Removal of mucosal Ca2+ did not alter the effect of amiloride. The implications of these findings are discussed in relation to concepts concerning the mechanism of isosmotic salt and water transport. The data are compatible with the concept that amiloride interferes with a Na+-dependent formation and transcellular transport of isosmotic fluid volumes in a sequestered compartment in the epithelial cells.