Regulation of luminal membrane water permeability by water flow in toad urinary bladder

Intramembranous particle aggregates (presumed sites for water flow) which appear in the luminal membrane consequent to ADH treatment are derived from cytoplasmic membrane structures (now termed "aggrephores") which fuse with the luminal membrane. We have previously shown that bladders stimulated in the absence of an osmotic gradient have about twice as many aggregates and about three times as many sites of aggrephore fusion as bladders stimulated with ADH in the presence of a 175 milliosmolal gradient. The present studies show that the frequency of fused aggrephores and luminal membrane aggregates can be modified as a consequence of alterations in transmembrane water flow initiated by changing the transbladder osmotic gradient during hormone stimulation. Bladders treated with ADH for 1 hr without a gradient and then for 1 hr with a gradient had approximately 1/3 as many aggregates and fusion sites as paired bladders treated for 2 hr without a gradient. Conversely, bladders treated with ADH for 1 hr with a gradient and then for 1 hr without a gradient had approximately 2x as many aggregates and fusion sites as bladders treated for 2 hr with a gradient. In other experiments we demonstrate that the time course of hormone washout is greatly accelerated if carried out in the presence of an osmotic gradient. In paired bladders that were first stimulated with ADH for 30 min in the absence of a gradient, aggregates and fusion sites as well as osmotic water permeability determined in fixed bladders, persisted at near maximum levels for 15 min of washout in the absence of a gradient.(ABSTRACT TRUNCATED AT 250 WORDS)     

Barriers to water flow in vasopressin-treated toad urinary bladder

Summary Unstirred layers of water complicate the measurement of water permeability across epithelia. In the toad urinary bladder, the hormone vasopressin increases the osmotic water permeability of the granular epithelial cell's luminal membrane, and also leads to the appearance of aggregates of particles within this membrane. The aggregates appear to be markers for luminal membrane osmotic water permeability. This report analyzes the relationship between transbladder osmotic water flow and aggregate frequency, and demonstrates that flow across the bladder is significantly attenuated by unstirred layers of water or by structural barriers other than the luminal membrane when the luminal membrane is made permeable by vasopressin. This analysis in addition yields unique values for the permeabilities of both the luminal membrane and the barriers to water flow which lie in series with it.     

Localization of barriers to water flow in toad urinary bladder

Although it is well accepted that vasopressin (ADH) increases the permeability to water of the toad bladder granular cell's luminal membrane, recent studies have suggested that regulation also takes place at an additional "postluminal" site within the epithelial granular cell. These studies are based upon the observation that a number of experimental maneuvers can alter tissue permeability to water, but do not change the number of particle aggregates observed on the protoplasmic face of the granular cell's luminal membrane with freeze-fracture electron microscopy. These aggregates are believed by many investigators to mediate the transport of water across the luminal membrane. The dissociation between permeability and aggregate frequency described above has been variously interpreted as the consequence of changes in the permeability of the aggregates themselves, or of changes in the permeability of a "postluminal" barrier that is functionally in series with the luminal membrane. We attempted to distinguish between these 2 possibilities by studying paired toad bladders during 3 protocols that alter vasopressin-stimulated water flow across the intact tissue without altering aggregate frequency. Estimates of the permeability of postluminal barriers were obtained by exposing the luminal surface to amphotericin B, an antibiotic that forms water-permeant channels in the luminal membrane. Of the 3 protocols, only diminishing bladder filling volume decreased the water flow elicited by luminal amphotericin B, suggesting that only that protocol indeed decreased the permeability of some postluminal barrier. The other 2 protocols, increasing PCO2 and repeatedly stimulating the bladder with vasopressin, did not alter amphotericin B-elicited flow, suggesting that postluminal barriers were not altered by these 2 protocols.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of distension on ADH-induced osmotic water flow in toad urinary bladder

Summary We recently described a method by which the resistance to water flow of the luminal membrane of ADH-stimulated toad bladder can be quantitatively distinguished from that of barriers lying in series with it. This method requires estimates of both total bladder water permeability (assessed by transbladder osmotic water flow at constant gradient) and luminal membrane water permeability (assessed by quantitation of the frequency of ADH-induced luminal membrane particle aggregates). In the present study we examined the effect of bladder distension on transepithelial osmotic water flow before and during maximal ADH stimulation. Base-line water flow was unaffected by bladder distension, but hormonally stimulated flow increased systematically as bladders became more distended. Distension had no effect on the frequency of ADH-induced intramembranous particle aggregates. By comparing the relationships between aggregate frequency and hormonally induced water permeability in distended and undistended bladders, we found that distension appeared to enhance ADH-stimulated water flow by decreasing the resistance of the series permeability barrier while the apparent water permeability associated with each single luminal membrane aggregate was unaffected. In that bladder distension causes tissue thinning, the series resistance limiting ADH-stimulated water flow appears to be accounted for by deformable barriers within the bladder tissue itself, probably unstirred layers of water.     

The effect of acid-base changes on vasopressin-stimulated water flow in toad urinary bladder

Water flow was measured gravimetrically in the presence and absence of vasopressin across the toad urinary bladder. Four groups of toads in different states of acid-base balance were used; a normal group, a group in NH₄Cl induced metabolic acidosis, respiratory acidosis, and a group in NaHCO₃ induced metabolic alkalosis. Vasopressin induced water flow was significantly reduced during metabolic acidosis and respiratory acidosis. Metabolic alkalosis had no effect on the hydro-osmotic response to vasopressin. Dibutyryl cyclic-AMP-stimulated water flow on the other hand was not affected by either a metabolic or respiratory acidosis. Treatment with indomethacin was able to reverse the observed reduction in the vasopressin-stimulated water flow response in the toad bladder during metabolic and respiratory acidosis. We conclude that the vasopressin stimulated water flow is altered during acidosis and evidence suggests that prostaglandins may be involved in the observed reduction in vasopressin-stimulated water flow.     

Evidence that ADH-stimulated intramembrane particle aggregates are transferred from cytoplasmic to luminal membranes in toad bladder epithelial cells

In freeze-fracture (FF) preparations of ADH-stimulated toad urinary bladder, characteristic intramembrane particle (IMP) aggregates are seen on the protoplasmic (P) face of the luminal membrane of granular cells while complementary parallel grooves are found on the exoplasmic (E) face. These IMP aggregates specifically correlate with ADH-induced changes in water permeability. Tubular cytoplasmic structures whose membranes contain IMP aggregates which look identical to the IMP aggregates in the luminal membrane have also been described in granular cells from unstimulated and ADH-stimulated bladders. The diameter of these cytoplasmic structures (0.11 +/- 0.004 micrometers) corresponds to that of tubular invaginations of the luminal membrane seen in thin sections of ADH-treated bladders (0.13 +/- 0.005 micrometers). Continuity between the membranes of these cytoplasmic structures (which are not granules) and the luminal membrane has been directly observed in favorable cross-fractures. In FF preparations of the luminal membrane, these apparent fusion events are seen as round, ice-filled invaginations (0.13 +/- 0.01 micrometer Diam), of which about half have the characteristic ADH-associated aggregates near the point of membrane fusion. They are less numerous than, but linearly related to, the number of aggregates counted in the same preparations (n = 78, r = 0.71, P less than 0.01). These observations suggest that the IMP aggregates seen in luminal membrane after ADH stimulation are transferred preformed by fusion of cytoplasmic with luminal membrane.     

Effect of colchicine on the osmotic water flow across the toad urinary bladder

Osmotic water movement across the toad urinary bladder in response to both vasopressin and cyclic AMP was inhibited by 10^?5 to 10^?4 M colchicine on the serosal but not on the mucosal side. This inhibitory effect was found to be time- and dose-dependent. Colchicine alone did not change basal osmotic flow and a baseline of the short-circuit current (I_sc) and also did not affect a vasopressin-induced rise of the I_sc. The inhibitory effect was not prevented by the addition of pyruvate. The osmotic water movement produced by 360 mM Urea (mucosal), 360 mM mannitol (serosal) or 2 μg/ml amphotericin B (mucosal), was not affected by 10^?4 M colchicine. These results suggest that colchicine inhibits some biological process subsequent to the formation of cyclic AMP except a directional cytoplasmic streaming process where microtubules may be involved.     

Regulation of the formation and water permeability of endosomes from toad bladder granular cells

Osmotic water permeability (Pf) in toad bladder is regulated by the vasopressin (VP)-dependent movement of vesicles containing water channels between the cytoplasm and apical membrane of granular cells. Apical endosomes formed in the presence of serosal VP have the highest Pf of any biological or artificial membrane (Shi and Verkman. 1989. J. Gen. Physiol. 94:1101-1115). We examine here: (a) the influence of protein kinase A and C effectors on transepithelial Pf (Pfte) in intact bladders and on the number and Pf of labeled endosomes, and (b) whether endosome Pf can be modified physically or biochemically. In paired hemibladder studies, Pfte induced by maximal serosal VP (50 mU/ml, 0.03 cm/s) was not different than that induced by 8-Br-cAMP (1 mM), forskolin (50 microM), VP + 8-Br-cAMP, or VP + forskolin. Pf was measured in endosomes labeled in intact bladders with carboxyfluorescein by a stopped-flow, fluorescence-quenching assay using an isolated microsomal suspension; the number and Pf (0.08-0.11 cm/s, 18 degrees C) of labeled endosomes was not different in bladders treated with VP, forskolin, and 8-Br-cAMP. Protein kinase C activation by 1 microM mucosal phorbol myristate acetate (PMA) induced submaximal bladder Pfte (0.015 cm/s) and endosome Pf (0.022 cm/s) in the absence of VP, but had little effect on maximal Pfte and endosome Pf induced by VP. However, PMA increased by threefold the number of apical endosomes with high Pf formed in response to serosal VP. Pf of endosomes containing the VP-sensitive water channel decreased fourfold by increasing membrane fluidity with hexanol or chloroform (0-75 mM); Pf of phosphatidylcholine liposomes (0.002 cm/s) increased 2.5-fold under the same conditions. Endosome Pf was mildly pH dependent, strongly inhibited by HgCl2, but not significantly altered by GTP gamma S, Ca, ATP + protein kinase A, and phosphatase action. We conclude that: (a) water channels cycled in endocytic vesicles are functional and not subject to physiological regulation, (b) VP and forskolin do not have cAMP-independent cellular actions, (c) activation of protein kinase C stimulates trafficking of water channels, but does not increase the number of apical membrane water channels induced by maximal VP, and (d) water channel function is sensitive to membrane fluidity. By using VP and PMA together, large quantities of endosomes containing the VP-sensitive water channel are labeled with fluid-phase endocytic markers.     

Regulation of protein phosphorylation and sodium transport in toad bladder

It is well established that active sodium-ion transport and water flow across isolated toad bladder are increased by antidiuretic hormone (ADH) and by cAMP. These agents were also observed in previous studies to cause changes in the amount of radioactive phosphate in a specific protein in the toad bladder. This protein, found by SDS-polyacrylamide gel electrophoresis of toad bladder epithelial preparations, had an apparent molecular weight of 49,000 daltons. In the present study, a correlation was found between the ability of a variety of substances to affect the amount of radioactive phosphate in this 40,000-dalton protein and their ability to alter the rate of sodium transport. Thus several agents (ADH, cAMP, theophylline, adenine, prostaglandin E1, and Mn Cl-2) caused a decrease in the amount of radioactive phosphate in the 49,000-dalton protein and also stimulated active sodium transport across the bladder. Conversely, ZnCl-2 produced an increase in the amount of radioactive phosphate in this protein and an inhibition of sodium transport. With each of these agents, the time-course of change in phosphorylation of this protein was, in general, similar to that for sodium transport. A second phosphoprotein, with an apparent molecular weight of about 42,000 daltons, showed changes in parallel with, but less extensive than, those observed in the 49,000 dalton protein. There was no consistent relationship between changes in level of phosphorylation of either in the 49,000- or 42,000- dalton protein and changes in osmotic water permeability. The results are compatible with the possibility that regulation by ADH and by cAMP of sodium transport in the toad bladder epithelium may be mediated through regulation of the amount of phosphate in a specific protein.     

Effect of colchicine on the osmotic water flow across the toad urinary bladder.

Osmotic water movement across the toad urinary bladder in response to both vasopressin and cyclic AMP was inhibited by 10(-5) to 10(-4) M colchicine on the serosal but not on the mucosal side. This inhibitory effect was found to be time- and dose-dependent. Colchicine alone did not change basal osmotic flow and a baseline of the short-circuit current (Isc) and also did not affect a vasopressin-induced rise of the Isc. The inhibitory effect was not prevented by the addition of pyruvate. The osmotic water movement produced by 360 mM Urea (mucosal), 360 mM mannitol (serosal) or 2 mug/ml amphotericin B (mucosal), was not affected by 10(-4) M colchicine. These results suggest that colchicine inhibits some biological process subsequent to the formation of cyclic AMP except a directional cytoplasmic streaming process where microtubules may be involved.     

Fura-2 handling in a polarized epithelial barrier: the toad urinary bladder.

Toad bladders sacs were placed inside quartz cuvettes. When fura-2 AM was added to the mucosal compartment, low temperature (4 degrees C) almost completely blocked the transepithelial transfer of fluorescence observed at 20 degrees C (20 degrees C = 371 +/- 56, 4 degrees C = 29 +/- 29 fluorescence intensity in arbitrary units (FIAU), excitation at 340 nm, emission at 510 nm). Simultaneously, fluorescence accumulation inside the tissue was significantly higher (20 degrees C = 25 +/- 5, 4 degrees C = 91 +/- 24% increase on basal levels (%IBL)). When fura-2 AM was added to the serosal side, low temperature also reduced the serosal to mucosal transfer (20 degrees C = 149 +/- 36, 4 degrees C = 61 +/- 35 FIAU). Nevertheless, in this situation tissue accumulation, that was significantly higher that the one observed when fura-2 AM was added to the mucosal side, was reduced at low temperature (20 degrees C = 300 +/- 30, 4 degrees C = 48 +/- 7 %IBL). Spectral analysis of the mucosal and serosal compartments indicated that free fura-2 was transferred from the intracellular to the serosal compartment, but not to the mucosal one. These results indicate that fura-2 appears as a useful tool to evaluate the cellular distribution and traffic of polycyclic charged and non-charged molecules.     

Dopaminergic inhibition of vasopressin-stimulated water flow in the toad bladder: Evidence for local formation of dopamine

Summary Dopamine administration increases renal excretion of water and Na. It remains uncertain whether these effects of dopamine are the result of a hemodynamic effect or the consequence of a direct cellular action. We investigated the effect of dopamine on water transport by the isolated toad bladderin vitro. Dopamine failed to alter baseline water flow but caused a significant inhibition of arginine vasopressin (AVP) or cyclic adenosine monophosphate (AMP) stimulated water flow. The effect of dopamine on stimulated water flow was not due to activation of adrenergic, adrenergic, or cholinergic receptors. The selective antagonists of dopamine, metoclopramide and apomorphine, prevented the effect of dopamine on AVP-stimulated water flow. These observations suggest the existence of a dopaminergic receptor in the toad bladder.l-Dopa also inhibited AVP-stimulated water flow. The effect ofl-Dopa could be prevented by metoclopramide, thus suggesting thatl-Dopa is converted to dopamine by an aromatic amino acid decarboxylase present in the toad bladder. To investigate this possibility we measured the effect of the decarboxylase inhibitor, carbidopa, on the¹⁴CO₂ production generated by decarboxylation of¹⁴Cl-Dopa in isolated toad bladder epithelial cells. Isolated toad bladder epithelial cells generated significant amounts of¹⁴CO₂ from¹⁴Cl-Dopa. This effect could be blocked by carbidopa, thus suggesting the existence of an aromatic amino acid decarboxylase system in the toad bladder. Carbidopa also prevented the inhibitory effect ofl-Dopa on AVP-stimulated water flow, suggesting thatl-Dopa needs to be converted to dopamine to inhibit water flow. These data suggest the existence of a dopaminergic receptor in the toad bladder. These data also suggest that dopamine can be formed locally in the toad bladder and can thus serve as a local modulator of water transport.     

Regulation of membrane permeability by vasopressin; activation of the water permeability pathway in toad urinary bladder by N-ethyl-maleimide

1. Vasopressin induces a rapid increase in water permeability and stimulates net sodium transport in responsive epithelia through the mediation of cAMP. 2. In amphibian urinary bladder, the increase in water permeability is dependent on an intact cytoskeleton and is associated with the exocytotic insertion of tubular vesicles containing particle aggregates (the putative water channels) into the apical membrane of the granular epithelial cells. 3. In the toad bladder, mucosal addition of NEM, 0.1 mM, elicits a slow and irreversible increase in transepithelial water flow, whilst decreasing net sodium transport. 4. The hydrosmotic response to mucosal NEM is inhibited by cellular acidification, by pretreatment with cytoskeleton-disruptive drugs, and by agents that increase cytosolic calcium. 5. Mucosal NEM potentiates the hydrosmotic response to a submaximal, but not a maximal, dose of vasopressin. 6. Mucosal NEM, like vasopressin, induces both vesicle fusion and the appearance of particle aggregates at the granular cell apical surface. 7. NEM, unlike vasopressin, does not increase cellular cAMP content. 8. Mucosal NEM appears to increase transcellular water flow by activating cellular processes normally triggered by vasopressin, at a step beyond cAMP.     

Dobutamine inhibits vasopressin-mediated water transport across toad bladder epithelium

This study aimed to investigate the effect of dobutamine on water transport across toad bladder epithelium. Water flow through the membrane was measured gravimetrically in bladder sac preparations. Dobutamine had no effect on basal water transport, but partially inhibited transport stimulated by vasopressin. Similarly, dobutamine exerted no influence on the hydrosmotic response to 8-chlorophenylthio-cAMP, but interfered with the response to phosphodiesterase inhibitor 1-methyl-3-isobutyl-xanthine. These results demonstrate that this catecholamine may inhibit vasopressin-stimulated water transport at a site prior to cAMP formation. The use of propranolol was ineffective in blocking the effect of dobutamine on transport stimulated by vasopressin, indicating that beta-adrenoceptors play no role in this effect. On the other hand, phentolamine significantly reduced the effect of dobutamine, indicating the involvement of alpha-adrenoceptors in such event. Rauwolscine also inhibited the effect of dobutamine, pointing to the specific contribution of the alpha(2)-adrenoceptors to this effect. Taken together, the results of this study demonstrate that dobutamine inhibits vasopressin-stimulated water transport in toad bladders through a mechanism mediated by the stimulation of alpha(2)-adrenoceptors, thus suggesting that such a drug may exert a direct cellular effect on membrane permeability to water in transporting epithelia. The current study may provide a better understanding of the effects of dobutamine on renal function by contributing towards the elucidation of its action mechanism.