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.     

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.     

Regulation of ADH-stimulated water flow at a post-luminal barrier in toad bladder

Recent studies show that ADH-stimulated water flow across toad bladder may be regulated at a site other than the luminal membrane. In these studies luminal membrane particle aggregate frequency has been used as a measure of luminal membrane water permeability. In fully stretched bladders the relationship between total tissue permeability and aggregate frequency is curvilinear, rather than linear. This implies a resistance in series with the luminal membrane that can become rate-limiting for water flow during ADH stimulation. The possibility that transtissue water movement is actually regulated at such a post-luminal membrane resistance is suggested by the finding that within 30 min following exposure to hormone, water flow becomes attenuated without any change in aggregate frequency. Supporting this possibility, recent data from follow-up studies suggest that the apparent water permeability per luminal membrane aggregate is not reduced with time. Finally, for bladders in which prostaglandin synthesis is inhibited (by naproxen), increases in both base-line water flow and water flow consequent to treatment with a submaximal dose of ADH (0.125 mU/ml), are much less than expected from simultaneously observed changes in luminal membrane aggregate frequency. In parallel experiments to these, moreover, direct measurements of luminal membrane water permeability from the rate of change of cell volume consequent to a transluminal membrane osmotic challenge, confirm that luminal membrane water permeability increases to the extent expected from changes in aggregate frequency. All of the data taken together argue for a post-luminal membrane barrier in toad bladder which regulates tissue permeability during ADH stimulation.     

Stabilization of vasopressin-induced membrane events by bifunctional imidoesters

Vasopressin increases the water permeability of the luminal membrane of the toad bladder epithelial cell. This change in permeability correlates with the occurrence in luminal membranes of intramembrane particle aggregates, which may be the sites for transmembrane water flow. Withdrawal of vasopressin is ordinarily associated with a rapid reduction of water flow to baseline values and a simultaneous disappearance of the particle aggregates. The bifunctional imidoesters dithiobispropionimidate (DTBP) and dimethylsuberimidate (DMS), which cross-link amino groups in membrane proteins and lipids, slow the return of water flow to baseline after vasopressin withdrawal. Cross- linking is maximal at pH 10, and is reduced as pH is lowered. Freeze- fracture studies show persistence of luminal membrane particle aggregates in cross-linked bladders and a reduction in their frequency as water flow diminishes. Fusion of aggregate-containing cytoplasmic tubular membrane structures with the luminal membrane is also maintained by the imidoesters. Reductive cleavage of the central S-S bond of DTBP by beta-mercaptoethanol reverses cross-linking, permitting resumption of the rapid disappearance of the vasopressin effect. Bladders that have undergone DTBP cross-linking and beta- mercaptoethanol reduction respond to a second stimulation by vasopressin. Thus, the imidoesters provide a physiologic and reversible means of stabilizing normally rapid membrane events.     

The water permeability of toad urinary bladder. I. Permeability of barriers in series with the luminal membrane

Antidiuretic hormone (ADH) induces a large increase in the water permeability of the luminal membrane of toad urinary bladder. Measured values of the diffusional water permeability coefficient, Pd(w), are spuriously low, however, because of barriers within the tissue, in series with the luminal membrane, that impede diffusion. We have now determined the water permeability coefficient of these series barriers in fully stretched bladders and find it to be approximately 6.3 X 10(- 4) cm/s. This is equivalent to an unstirred aqueous layer of approximately 400 microns. On the other hand, the permeability coefficient of the bladder to a lipophilic molecule, hexanol, is approximately 9.0 X 10(-4) cm/s. This is equivalent to an unstirred aqueous layer of only 100 microns. The much smaller hindrance to hexanol diffusion than to water diffusion by the series barriers implies a lipophilic component to the barriers. We suggest that membrane-enclosed organelles may be so tightly packed within the cytoplasm of granular epithelial cells that they offer a substantial impediment to diffusion of water through the cell. Alternatively, the lipophilic component of the barrier could be the plasma membranes of the basal cells, which cover most of the basement membrane and thereby may restrict water transport to the narrow spaces between basal and granular cells.     

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.     

Membrane structural and functional responses to vasopressin in toad bladder

Summary Freeze-fracture electronmicroscopy demonstrates that vasopressin stimulation of isolated toad bladder results in a striking morphologic alteration of epithelial membrane structure. This alteration is characterized by the aggregation of intramembranous particles in orderly linear arrays at multiple sites in the luminal membranes of granular cells specifically. The size of these aggregates varies considerably, in terms of area, over a range from 0.5 to 70×10^–3 m². The median aggregate size is about 10.5×10^–3 m². Since the extent of vasopressin-associated particle aggregation, in terms of frequency of sites per area of membrane or cumulative area of membrane occupied by them, closely correlates with induced changes in transport function, as measured by osmotic water flow, the aggregates themselves appear to be of physiologic significance in the mechanism of action of vasopressin. This hypothesis is supported by the observations that sites of aggregation occur (a) in response to serosal exposure to hormone specifically, (b) independently of an osmotic gradient, and (c) following stimulation with cyclic adenosine monophosphate.     

Cell determinants of vasopressin-stimulated water flow

I present a technique that permits evaluation of the permeability to water of the luminal membrane of the toad urinary bladder, independently of constraints to water flow imposed by the remainder of the tissue. This technique essentially depends on fixation of the luminal membrane with 1% glutaraldehyde for 5 min, and subsequent elimination of cytosolic constraints by decreasing the tonicity of the serosal bath to 1/2 normal strength. The increased hydraulic conductivity found with serosal hypotonicity is readily reversible, as the bladder returns to an isotonic serosal bath. By evaluating water flow in luminally fixed bladders during bathing in normal and hypotonic bath, one may identify the relative contribution of the luminal membrane and the "cytosol" on water flow. Using this technique, I found that the effect of the prostaglandin inhibitor Naproxen to increase vasopressin-stimulated water flow is due to increased luminal membrane permeability. The effect of histidine to increase vasopressin-stimulated water flow, however, depends on increased permeability of both the luminal membrane as well as the underlying structures. The action of serosal hypertonicity to induce water flow is due to an increased luminal permeability. However, serosal hypertonicity decreases "cytosolic" permeability, so that its overall function is a composite effect of its action at the luminal membrane and the "cytosolic" level.     

Visualization of endocytosed markers in freeze-fracture studies of toad urinary bladder

Antidiuretic hormone (ADH) stimulation increases the apical membrane water permeability of granular cells in toad urinary bladder. This response correlates closely with the fusion of tubular cytoplasmic vesicles with the membrane and delivery of intramembrane particle (IMP) aggregates from the tubules (aggrephores) to the apical membrane. These aggregates are believed to be associated with the channels responsible for the water permeability increase. Removal of ADH triggers apical membrane endocytosis and disappearance of aggregates from the apical membrane. However, it has been unclear whether aggregate disappearance is due to disassembly of aggregates within the apical membrane or to their endocytic retrieval as intact structures. Using colloidal gold and horseradish peroxidase to follow endocytosis from the apical surface after ADH removal, we have directly observed in cross-fractured bladder cells the intramembrane structure of intracellular vesicles that contain these fluid-phase markers. Under these conditions, intact aggregates can be identified in the membrane of tubular endocytosed vesicles. This directly demonstrates that conditions which lower apical membrane water permeability cause the tubular aggrephores to "shuttle" intact aggregates from the apical membrane back into the cytoplasm. An additional population of vesicles with tracer are found which are spherical and display structural features of the apical membrane, as well as occasional aggregates. These vesicles may be responsible for retrieval of aggregates from the surface apical membrane.     

Permeability of the Isolated Toad Bladder to Solutes and Its Modification by Vasopressin

Measurements have been made of the permeability of the isolated urinary bladder of the toad to a number of small solute molecules, in the presence and absence of vasopressin. Vasopressin has a strikingly specific effect on increasing permeability of the bladder to a group of small, uncharged amides and alcohols while penetration by other small molecules and ions is unaffected. The movement of urea is passive, as indicated by equal flux rates in the two directions. The reflection coefficients for chloride and thiourea indicate a high degree of impermeability of the bladder to these solutes even in the presence of large net movements of water. The low concentration of thiourea in the tissue water when this compound is added to the mucosal bathing medium indicates that the major permeability barrier to thiourea is at the mucosal surface of the bladder. The findings can be accounted for by a double permeability barrier consisting of a fine selective diffusion barrier and a porous barrier in series. The former would constitute the permeability barrier to most small solutes while the latter would be the rate-limiting barrier for water and the amides. It would be the porous barrier which is affected by vasopressin. Reasons are presented which require both barriers to be contained in or near the plasma membrane at the mucosal surface of the bladder.     

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.     

Very high water permeability in vasopressin-induced endocytic vesicles from toad urinary bladder

The regulation of transepithelial water permeability in toad urinary bladder is believed to involve a cycling of endocytic vesicles containing water transporters between an intracellular compartment and the cell luminal membrane. Endocytic vesicles arising from luminal membrane were labeled selectively in the intact toad bladder with the impermeant fluid-phase markers 6-carboxyfluorescein (6CF) or fluorescein-dextran. A microsomal preparation containing labeled endocytic vesicles was prepared by cell scraping, homogenization, and differential centrifugation. Osmotic water permeability was measured by a stopped-flow fluorescence technique in which microsomes containing 50 mM mannitol, 5 mM K phosphate, pH 8.5 were subject to a 60-mM inwardly directed gradient of sucrose; the time course of endosome volume, representing osmotic water transport, was inferred from the time course of fluorescence self-quenching. Endocytic vesicles were prepared from toad bladders with hypoosmotic lumen solution treated with (group A) or without (group B) serosal vasopressin at 23 degrees C, and bladders in which endocytosis was inhibited by treatment with vasopressin at 0-2 degrees C (group C), or with vasopressin plus sodium azide at 23 degrees C (group D). Stopped-flow results in all four groups showed a slow rate of 6CF fluorescence decrease (time constants 1.0-1.7 s for exponential fit) indicating a component of nonendocytic 6CF entrapment into sealed vesicles. However, in vesicles from group A only, there was a very rapid 6CF fluorescence decrease (time constant 9.6 +/- 0.2 ms, SEM, 18 separate preparations) with an osmotic water permeability coefficient (Pf) of greater than 0.1 cm/s (18 degrees C) and activation energy of 3.9 +/- 0.8 kcal/mol (16 kJ/mol). Pf was inhibited reversibly by greater than 60% by 1 mM HgCl2. The rapid fluorescence decrease was absent in vesicles in groups B, C, and D. These results demonstrate the presence of functional water transporters in vasopressin-induced endocytic vesicles from toad bladder, supporting the hypothesis that water channels are cycled to and from the luminal membrane and providing a functional marker for the vasopressin-sensitive water channel. The calculated Pf in the vasopressin-induced endocytic vesicles is the highest Pf reported for any biological or artificial membrane.     

Antidiuretic response in the urinary bladder of Xenopus laevis: Presence of typical aggrephores and apical aggregates

The urinary bladder of the aquatic toad Xenopus laevis is known to exhibit a low permeability to water and a poor sensitivity to antidiuretic hormone. In order to precise the characteristics and the specific cellular mechanisms of this reduced hydroosmotic response we used a sensitive volumetric technique to monitor net water flow and studied the correlation between the anti-diuretic hormone (ADH)-induced net water flow and the fine ultrastructural appearence of the urinary bladder epithelium. Transmural net water flow was entirely dependent on the osmotic gradient across the preparation and not on the hydrostatic pressure difference. We observed the existence of a low but significant hydro-osmotic response to arginine vasopressin. Freeze-fracture electron microscopy demonstrated the presence of typical aggrephores in the subapical cytoplasm. The response to the hormone was accompanied by the appearance of typical intramembrane aggregates into the apical plasma membrane. Water permeability increase and apical aggregate insertion were both slowly but fully reversible. Except for the multilayered structure of the epithelium and the particularly low response to antidiuretic hormone, all the studied permeability and ultrastructural characteristics of the bladder were thus very similar to those observed in other sensitive epithelia such as the amphibian bladder and skin and the mammalian collecting duct which exhibit a high hydro-osmotic response to the hormone.     

Membrane structural studies of the action of vasopressin

Freeze-fracture electron microscopy of the toad urinary bladder indicates that distinctive intramembrane particle aggregates are responsible for the increase in apical membrane water permeability that occurs with vasopressin (VP) stimulation. In unstimulated bladders the aggregates occur in the cytoplasm of the cells in tubular membrane structures now called aggrephores. After stimulation by VP, aggrephores are shuttled to the surface and fuse with the apical membrane. It is suggested by structural observations and by measurements of membrane capacitance that the area of aggregates inserted into the apical membrane is much greater than previously suspected because many aggregates remain in the wall of the fused aggrephores. The area of the aggregates in a stimulated bladder is sufficiently large for these structures to represent an organized array of water channels that mediates the change in apical membrane permeability. Work with antibodies supports the concept that these channels are not always resident in the apical membrane but become inserted only after stimulation by the hormone VP.     

Surface hydrophobicity and water transport of the toad urinary bladder: Effects of vasopressin

Summary The present study investigated whether the hydrophobic properties (wettability) of the luminal surface of the toad urinary bladder might play a role in modulating water transport across this epithelium. In the absence of vasopressin (ADH), water transport across the tissue was low, while luminal surface hydrophobicity (water contact angle) was relatively high. Following stimulation by ADH, water transport increased and surface hydrophobicity decreased. The addition of indomethacin to inhibit ADH-induced prostaglandin synthesis did not reduce these actions of ADH. In an attempt to alter water transport in this tissue, a liposomal suspension of surface-active phospholipids was administered to the luminal surface. This addition had no detectable influence on the low basal rates of water transport, but blocked the ADH-induced stimulation of water transport. We suggest that surface-active phospholipids on the toad bladder luminal membrane may contribute to the hydrophobic characteristics of this tissue. ADH may act to decrease surface hydrophobicity, facilitating the movement of water molecules across an otherwise impermeable epithelium. This surface alteration may be associated with the appearance of water channels in the apical membrane.     

Inhibition of the permeability response to vasopressin and oxytocin in the toad bladder: Effects of bradykinin,kallidin, eledoisin,and physalaemin

Summary It has been shown by means of Bentley'sin vitro preparation of the isolated urinary bladder of the toad,Bufo marinus paracnemis Lutz, that bradykinin reversibly inhibited the increase brought about by vasopressin on the permeability to water of the toad bladder. The increased hydro-osmotic response of the bladder to oxytocin was also inhibited by the kinin. The effect on water permeability was observed when bradykinin was added either to the serosal Ringer's solution or to the mucosal solution. The addition of bradykinin alone did not alter the basal osmotic water transfer across the bladder. In this context, bradykinin acted as a competitive antagonist of vasopressin (and oxytocin). Although lacking intrinsic activity, bradykinin exhibited affinity for receptor sites that are also common to the neurohypophysial hormones, causing a parallel shift of the log-dose/response curve for vasopressin without changing the maximal responses. The effects of other kinins (namely kallidin, eledoisin and physalaemin) on the toad bladder were also tested. Each of these drugs alone did not change the basal water flux across the bladder wall. Like bradykinin, these peptides inhibited the increase in water permeability evoked by vasopressin and oxytocin in the bladder. In view of the importance of neurohypophysial hormones and their target tissues to the osmotic homeostasis of amphibians, and the observation of antagonism between the kinins and the pituitary hormones coupled to the abundance of kinins in the amphibian organism, particularly in the skin and urinary bladder, teleological reasoning predicts a physiological role for the kinins, possibly functioning to dampen excesses and oscillations in membrane permeability that could occur in face of a constant and variable secretion of neurohypophysial hormone, thus adding to the homeostatic response of the amphibian organism.     

The Site of the Stimulatory Action of Vasopressin on Sodium Transport in Toad Bladder

Vasopressin increases the net transport of sodium across the isolated urinary bladder of the toad by increasing the mobility of sodium ion within the tissue. This change is reflected in a decreased DC resistance of the bladder; identification of the permeability barrier which is affected localizes the site of action of vasopressin on sodium transport. Cells of the epithelial layer were impaled from the mucosal side with glass micropipettes while current pulses were passed through the bladder. The resulting voltage deflections across the bladder and between the micropipette and mucosal reference solution were proportional to the resistance across the entire bladder and across the mucosal or apical permeability barrier, respectively. The position of the exploring micropipette was not changed and vasopressin was added to the serosal medium. In 10 successful impalements, the apical permeability barrier contributed 54% of the initial total transbladder resistance, but 98% of the total resistance change following vasopressin occurred at this site. This finding provides direct evidence that vasopressin acts to increase ionic mobility selectively across the apical permeability barrier of the transporting cells of the toad bladder.     

The effects cytochalasin B on the surface morphology of the toad urinary bladder epithelium: a scanning electron microscopic study.

Cytochalasin B depresses the hydroosmotic response of the toad urinary bladder to vasopressin without affecting basal (bulk flow) permeability, diffusional permeability, or the hormone induced increase in short circuit current. Fine structural studies demonstrated that this macrolide fungal metabolite, in the presence of both an osmotic gradient and vasopressin, induces the formation of large intracellular vacuoles or 'lakes' in epitelial cells lining the bladder mucosa. Some surface changes (shortening and irregularity of microvilli, clumping of the glycocalyx, etc.) were reported by transmission electron microscopy. Scanning electron microscopy demonstrates that cytochalasin B drastically alters the mucosal surface morphology of the hormone stimulated bladder. Lesser changes were seen in the absence of vasopressin. In the presence of arginine vasopressin, excessive cellular swelling and possible rupturing, as well as surface membrane infolding and rippling, were seen in the cytochalasin treated tissues, The specific entity most affected by this treatment is the granular cell.     

Intramembrane particle structures in epithelial cells of the toad urinary bladder: a quantitative freeze-fracture study

Freeze-fracture electron microscopy reveals intramembrane particle arrays in basal membranes of granular epithelial cells as well as both upper and lower plasma membranes of the underlying basal cells in the toad urinary bladder. These particle arrays are morphologically indistinguishable from the luminal membrane aggregates which are known to be associated with antidiuretic hormone (ADH)-stimulated water transport. In both granular and basal cells particle arrays are frequently located in and/or around the openings of vesicular and/or tubular structures fused to the plasma membranes, suggesting that they may be transferred from the cytoplasm by membrane fusion. Quantification of cytoplasmic aggrephores in control granular cells shows that they can be numerous and as close to the basolateral membrane as they are with the luminal membrane, to which they are known to fuse and deliver aggregates upon ADH stimulation. Aggrephore-like tubules were also found in the basal cells. Particle array densities were quantified for 6 pairs of control and ADH-stimulated hemibladders. At least 1440 microns 2 area of plasma membrane for each membrane domain was examined. Results indicate that the presence of these particle arrays in granular and basal cell membranes is highly variable and that exposure to ADH does not cause a statistically significant increase in their frequency.     

Effect of hypertonicity and colchicine on intramembranous particle aggregation in toad urinary bladder

Summary Colchicine, an agent which disrupts microtubules, inhibits the vasopressin (VP)-induced increase in water permeability as well as intramembranous particle (IMP) aggregation in the luminal plasma membrane of granular cells of toad urinary bladder. However, the hydroosmotic response induced by serosal hypertonicity is not affected by colchicine. The present investigation was initiated to establish whether serosal hypertonicity is associated with IMP aggregation and whether the aggregation, if present, is altered by colchicine. The experimental half of paired hemibladders from the toad, Bufo marinus, treated with 0.1 mM colchicine for 4 h prior to exposure to serosal mannitol (240 mM) demonstrated no significant difference in osmotic water How (Jv) (1.03 × 0.18 vs. 1.13 ± 0.22l · min^–1 · cm^–2; p>0.20) when compared with control hemibladders. Similarly, comparison of control and colchicine-treated bladders revealed no difference in the number of IMP aggregation sites per area of membrane (17.8 ± 2.0 vs. 24.7 ± 3.5/100^m; p>0.10), the relative area of membrane occupied by these sites (0.30 ± 0.06 vs. 0.39 ± 0.07%; p>0.10) or the mean size of the aggregates (17.0 ± 1.4 vs. 15.8 ± 1.0 × 10³ m²; p > 0.20). These results indicate that in toad bladder the increase in J_v induced by serosal hypertonicity is associated with IMP aggregation. Secondly, an intact microtubule system is not required to induce the hydroosmotic or the aggregation responses. If, as has been proposed, the cellular actions of VP and serosal hypertonicity share a common pathway to bring about an increase in osmotic water permeability and cause IMP aggregation in the luminal membrane of the granular cell, the present results suggest that the pathway begins at a step subsequent not only to the generation of cAMP, but also beyond the involvement of the microtubule system.This work was supported in part by U.S. Public Health Service Grant AM 13845. Dr. Dratwa was supported through a U.S. Public Health Service International Research Fellowship F05TW2447. The authors gratefully acknowledge the technical assistance of Mrs. Helen Parks, Mr. Isaiah Taylor, Mrs. Betty Waller, and Mrs. Jessie Calder