The State of Water in the Isolated Toad Bladder in the Presence and Absence of Vasopressin

An attempt has been made to assess the validity of applying the frictional and viscous coefficients of bulk water to the movement of water and solutes through the urinary bladder of the toad. The temperature dependence of diffusion of THO, C¹⁴-urea, C¹⁴-thiourea, and net water transfer across the bladder was determined in the presence and absence of vasopressin. The activation energy for diffusion of THO was 9.8 kcal per mole in the absence of vasopressin and 4.1 kcal per mole with the hormone present. Activation energies simultaneously determined following vasopressin for diffusion and net transfers of water were similar, and in the same range as known activation energies for diffusion and viscous flow in water. Urea had activation energies for diffusion of 4.1 and 3.9 kcal per mole in the absence and presence of vasopressin, respectively. Thiourea had a high activation energy for diffusion of 6.3 kcal per mole, which was unchanged, 6.6 kcal per mole, following hormone. These findings suggest that in its rate-limiting permeability barrier, water is present in a structured state, offering a high resistance to penetration by water. Vasopressin enlarges the aqueous channels so that the core of water they contain possesses the physical properties of ordinary bulk water. Urea penetrates the tissue via these aqueous channels while thiourea is limited by some other permeability barrier.     

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 membrane action of antidiuretic hormone (ADH) on toad urinary bladder.

Radioactive tracer and electrical techniques were used to study the transport of nonelectrolytes and sodium, respectively, across toad urinary bladders in the presence and absence of ADH. The permeability of lipophilic molecules was roughly proportional to bulk phase oil/water partition coefficients both in the presence and absence of hormone; i.e., ADH elicited a general nonselective increase in the permeation of all nine solutes tested. The branched nonelectrolyte, isobutyramide, was less permeable than its straight-chain isomer, n-butyramide, in control tissues. ADH reduced the discrimination between these structural isomers. Hydrophilic solutes permeated more rapidly than expected. In the presence of hormone, there was no change in the permeation of large hydrophilic solutes considered to move via an extracellular pathway, but there was a marked increase in the permeability of water and other small hydrophilic solutes. Collectively, these results suggest that ADH acts to increase the motional freedom or fluidity of lipids in the cell membrane which is considered to be the preferred pathway for the permeation of lipophilic and small hydrophilic molecules. At concentrations of cAMP and ADH which elicit equivalent increments in the shortcircuit current, the effects of these agents on nonelectrolyte transport and membrane electrical conductance are divergent. Such observations suggest that some membrane effects of ADH may not be directly dependent upon cAMP. ADH in the mucosal solution increased the permeability of the toad bladder when the surface charge on the outer surface of the apical membrane was screened with the polyvalent cation, La-3+. These experiments emphasize that interaction of ADH with membranes of toad urinary bladder may account for at least some effects of this hormone.     

Effects of sulfhydryl and other reagents on the diffusional permeability of dog erythrocytes to small solutes

The effects of p-chloromercuriphenylsulfonic acid (PCMBS), 5,5'-dithiobis (2-nitrobenzoic acid) (DTNB), phloretin and thiourea on the diffusional permeability of dog erythrocytes to tritiated water and to small 14C-labeled lipophilic and hydrophilic solutes were measured at 37 degrees C by means of the linear diffusion technique. Permeability to 3HHO was significantly decreased by PCMBS but was not affected by the other reagents. The permeability to the small hydrophilic solutes acetamide and urea was decreased by phloretin and thiourea but only the permeability to acetamide was reduced to a statistically significant extent by PCMBS. The permeability to the lipophilic solutes methanol, ethanol and antipyrine was not affected by any of these agents. We interpret these results as an indication that the small lipophilic solutes probably move through lipid areas, that the small hydrophilic solutes probably move through protein associated areas in the erythrocyte membrane and that pathways for the small hydrophilic solutes are distinct from those for water. While the pathways for water may be associated with membrane protein they do not appear to be associated specifically with band 3 protein as has been suggested for human erythrocytes. Diffusional water movement through the dog erythrocyte occurs by two distinct pathways.     

Pathways for movement of ions and water across toad urinary bladder

Summary Mucosal hypertonicity, produced by the addition of NaCl, KCl, mannitol, urea, sucrose or raffinose, reduced the electrical resistance of toad urinary bladder and induced bullous deformations (blisters) of the most apical junctions of the mucosal epithelium: the smaller solutes were most effective in eliciting both phenomena. Study of the effect of addition and subsequent removal of mannitol from the mucosal medium indicated that both the electrical and morphologic changes are reversible and follow the same time course. Mucosal hypertonicity induced comparable changes in the tissue in the presence or absence of inhibition of active sodium transport by replacement of sodium by choline, or by addition of ouabain or amiloride. Dilution of the tonicity of the serosal medium similarly reduced the tissue resistance and induced blisters within the epithelium, demonstrating that the osmotic gradient, rather than the mucosal hypertonicity itself is the cause of the osmotically-induced resistance change. The data indicate, therefore, that the osmotic gradient reduces the electrical resistance of the tissue primarily by deforming the apical junctions.The simplest interpretation of the data is that the apical tight junctions are considerably more permeable to water and small solutes than had previously been thought. Addition of solute to the mucosal medium leads to the diffusion of solute into the junctions: the subsequent transfer of water from the lateral intercellular spaces and/or the adjacent cellular cytoplasm, deforms these structures and reduces the resistance to the passage of ions across the tissue. The results suggest that the apical junctions constitute the rate-limiting permeability barrier of the putative parallel shunt pathway across toad bladder.     

Studies on the Movement of Water through the Isolated Toad Bladder and Its Modification by Vasopressin

Measurements of diffusion permeability and of net transfer of water have been made across the isolated urinary bladder of the toad, Bufo marinus, and the effects thereon of mammalian neurohypophyseal hormone have been examined. In the absence of a transmembrane osmotic gradient, vasopressin increases the unidirectional flux of water from a mean of 340 to a mean of 570 µl per cm² per hour but the net water movement remains essentially zero. In the presence of an osmotic gradient but without hormone net transfer of water remains very small. On addition of hormone large net fluxes of water occur; the magnitude of which is linearly proportional to the osmotic gradient. The action of the hormone on movement of water is not dependent on the presence of sodium or on active transport of sodium. Comparison of the net transport of water and of unidirectional diffusion permeability of the membrane to water indicates that non-diffusional transport must predominate as the means by which net movement occurs in the presence of an osmotic gradient. An action of the hormone on the mucosal surface of the bladder wall is demonstrated. The effects of the hormone on water movement are most simply explained as an action to increase the permeability and porosity of the mucosal surface of the membrane.     

Effect of metabolic inhibitors on vasopressin-stimulated transport systems in the toad bladder

Vasopressin increases the permeability of receptor cells to water and, in tissues such as toad bladder, to solutes such as urea. While cyclic AMP appears to play a major role in mediating the effects of vasopressin, there is evidence that activation of the water permeability system and the urea permeability system involves separate pathways. In the present study, we have shown that inhibitors of oxidative metabolism (rotenone, dinitrophenol, and methylene blue) selectively inhibit either vasopressin-stimulated water flow or vasopressin-stimulated urea transport. There was no inhibition, however, when exogenous cyclic AMP was substituted for vasopressin, and little to no inhibition when the potent analogue 8-bromoadenosine 3′,5′-cyclic monophosphate (8-Br-cAMP) was employed. Rotenone had no effect on adenylate cyclase activity or cyclic AMP levels within the cell; dinitrophenol decreased adenylate cyclase activity minimally. Additional studies with vinblastine and nocodazole, inhibitors of microtubule assembly, demonstrated an inhibition of vasopressin and cyclic AMP-stimulated water flow but showed no effect on urea transport. We would conclude that water and urea transport, as examples of hormone-stimulated processes, have different links to cell metabolism, and that in addition to cyclic AMP, a non-nucleotide pathway may be involved in the action of vasopressin.     

Mucosal surface morphology of the toad urinary bladder. Scanning electron microscope study of the natriferic and hydro-osmotic response to vasopressin

The mucosal cell surface of the toad urinary bladder was examined by scanning electron microscopy, and changes in the structure of the surface of the granular cell were correlated with specific physiological responses to vasopressin. Survey views of the mucosal surface demonstrated that there was no consistent repeating anatomical relationship between the granular cell and the mitochondria-rich cell that would support the concept of cooperativeness in the response to vasopressin. During base-line states of Na+-transport and water flux, the microvilli on the mucosal surface of the granular cell are arranged in a ridge-like network with occasional individual projections. When water flux is increased by exposing the tissue to vasopressin, in the presence of an osmotic gradient across the tissue the microvilli on the granular cell lose the ridge structure and appear, predominantly, as individual projection. Variability-of this appearance points out the necessity of examining large areas and many samples before the significance of any morphological change can be assessed. Blocking the simultaneously occurring natriferic response of the toad urinary bladder with 10(-2)M ouabain does not prevent these changes in the microvilli. When the hydro-osmotic response is blocked by eliminating the osmotic gradient, the granular cell shows no consistent change in mucosal surface morphology even when fixed at the height of the natriferic response. The mitochondria-rich and mucous cells did not show any change in morphology throughout these studies. We conclude that the changes in the mucosal surface morphology of the toad bladder seen after exposure to vasopressin are a result of the increased water flux that occurs when an osmotic gradient exists across the tissue, and are not related to the natriferic response or any specific alteration in the membrane properties.     

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.     

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.     

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)     

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.     

Permeability properties of the Bufo bufo bladder as affected by isoprenaline and vasopressin

Isoprenaline, a beta adrenergic agonist, strongly increases both transepithelial fluxes across the urinary bladder of Bufo bufo; this effect is dose dependent, 10(-6)M being necessary for the maximal action. This effect is less selective than that of vasopressin: the ratio J urea/J thiourea is 3.8 under isoprenaline and 30.4 under vasopressin treatment. Both hormones differently affect the permeability of a mainly liposoluble molecule, i.e. antipyrine: vasopressin increases antipyrine permeability, while isoprenaline decreases it. Moreover diethylpyrocarbonate treatment of the luminal membrane strongly inhibits vasopressin effect on urea permeability leaving unmodified that of isoprenaline. However, the actions of both hormones are not additive. These results allows to assume that the tissue has a feedback mechanism which inhibits other hormonal action while the bladder is stimulated by a particular hormone.     

Peroxisomal membrane permeability and solute transfer

The review is dedicated to recent progress in the study of peroxisomal membrane permeability to solutes which has been a matter of debate for more than 40 years. Apparently, the mammalian peroxisomal membrane is freely permeable to small solute molecules owing to the presence of pore-forming channels. However, the membrane forms a permeability barrier for 'bulky' solutes including cofactors (NAD/H, NADP/H, CoA, and acetyl/acyl-CoA esters) and ATP. Therefore, peroxisomes need specific protein transporters to transfer these compounds across the membrane. Recent electrophysiological studies have revealed channel-forming activities in the mammalian peroxisomal membrane. The possible involvement of the channels in the transfer of small metabolites and in the formation of peroxisomal shuttle systems is described.     

Hyaluronate-hydrolases system and hydroosmotic effect of vasopressin]

Involvement of enzymes catabolizing hyaluronic acid (hyaluronidase, beta-glucuronidase, N-acetyl-beta-D-hexosaminidase) in the hydroosmotic action of vasopressin on the amphibian urinary bladder Rana Ridibunda was studied. It was found that vasopressin (50 nM), agonist of V2 receptors dDAVP (1.5 mcM) and forscolin (30 mcM) induce an activation of enzymes and its release into the Ringer solution at the mucosal surface simultaneously with the increase in the osmotic water flow. Maximal effect was observed 10 min later than hydroosmotic response. Release of enzymes under vasopressin effect was found in the absence of osmotic gradient and water flow through the epithelium. The repeated substitution of the outer Ringer solution for the fresh one resulted in the increase in the both the water permeability and the release of enzymes through the mucosal surface. We suggested that involvement of hyaluronate-hydrolases in the vasopressin effect is mediated by the cAMP-dependent mechanism. It is supposed that this effect creates conditions for the increase in the permeability of glycosaminoglycan structures covering adjacent to the apical cell surface.     

Water and sodium transport: effects of calcium channel blocker and calmodulin antagonists on the apical and basolateral membranes of amphibian epithelia

Ca2+ channel blocker (sensit) and calmodulin antagonists (thioridazine, perphenazine, oxyprothepine) applied to the mucosal side of frog urinary bladder, weakened the response of epithelial cells to vasopressin. Thioridazine (2.7 X 10(-5) mol X l-1) and sensit (1.7 X 10(-4) mol X l-1) applied to the serosal side rapidly increased the permeability of the epithelia for sodium and potassium ions along the concentration gradient (from serosa to mucosa). The same concentrations of these blockers when applied to the mucosal side of frog urinary bladder selectively decreased vasopressin stimulated water permeability and did not influence ionic permeability. Both thioridazine and sensit decreased the short-circuit current across frog skin. The results show that the Ca2+ channel blocker and the calmodulin antagonists tested influenced water and ionic transport across the epithelial cell membranes, and had different effects upon the apical and the basolateral cell membranes.     

Vasopressin and water permeability of artificial lipid membranes

Vasopressin markedly stimulated the water permeability of bilayer lipid membranes: a two-fold increase was measured at 25° in presence of 1.7·10⁻⁹ M (50 μunits/ml) vasopressin. Oxytocin and a mixture of the amino acids comprising the vasopressin molecule could not substitute for vasopressin at comparable concentration. The experimental activation energy of water transport was reduced in the presence of vasopressin from 14 to 4 kcal/mole, in agreement with the effect of the hormone on water permeability of toad bladder.     

MIND the gap: an astroglial perspective on barrier regulation

The blood-brain barrier (BBB) is a specialized tissue interface that provides an important homeostatic and immunosurveillance role in the CNS. Unlike most microvascular tissues, which readily promote paracellular passage of solutes and macromolecules, the BBB is more analogous to polarized mucosal epithelia that restrict such permeability in order to prevent disease onset. Recent transgenic ablation studies have demonstrated that the BBB and mucosal tissues also share a requirement for astroglial-regulated barrier integrity. This review highlights the emerging concept that astroglia regulate barrier function at markedly different tissue interfaces. It also explores possible lessons that might be learnt by adopting epithelial model paradigms of the BBB. For example, novel glial-derived S-nitrosylation signals that regulate intestinal permeability in the digestive tract might provide new mechanistic insights into the function of the BBB. A better understanding of such universal mechanisms for barrier regulation will facilitate novel therapeutic strategies that target permeability disorders at CNS and mucosal tissue interfaces.     

The vertebrate urinary bladder: osmoregulatory and other uses

The bladder may serve more biological uses than simple storage. The importance of bladder functions can be inferred from its presence among vertebrates, its anatomy and histology. From an evolutionary perspective, bladders have evolved at least twice in the vertebrates. The variability of permeability of the urinary bladder to water and solutes among species is discussed. Finally, the urinary bladder may play an osmoregulatory role.     

Metabolic studies on rabbit bladder smooth muscle and mucosa

Recent studies indicate that the mucosa of the urinary bladder may play a major role in the maintenance of normal bladder function. The mucosal surface of the urinary bladder serves as a protective layer against the irritative solutes found in the urine. The integrity of this barrier can be broken by overdistension, anoxia, detergents, alcohols, bacterial infection and by contact with agents to which the mucosa has been sensitized.In view that both anoxia and ischemia can mediate a breakdown in the role of the mucosal layer as a permeability barrier, it is reasonable to assume that this function is dependent on cellular metabolism. As an initial investigation we have compared a variety of biochemical and metabolic parameters between the mucosal layer (consisting of the lamina propria, urothelium, and any connective tissue and vascular tissue within this layer); and the muscularis layer.The results of these studies demonstrated that the rate of glucose metabolism to lactic acid (LA) of the mucosa was more than three-fold greater than that of the smooth muscle. The rate of CO₂ production of the mucosa was 60% greater than that of the unstimulated smooth muscle. The maximal activity of the mitochondrial enzyme citrate synthase was significantly greater in the mucosa than in the smooth muscle, however, the activity of malate dehydrogenase was similar for both tissues. The maximal activity of the cytosolic enzyme creatine kinase was more than two-fold greater in the bladder smooth muscle than in the mucosa; although the affinities of the creatine kinase isoforms of the mucosa were sigificantly greater than those of the muscle.Although the concentrations of ATP and ADP were similar in both muscle and mucosa, the level of creatine phosphate (CP) was over four-fold greater in the bladder muscle while the level of AMP in the muscle was only 58% of that in the mucosal epithelium.In summary, the rate of glucose metabolism was greater in the mucosa than in the smooth muscle although the concentrations of high energy phosphates (ATP+CP) was significantly greater in the smooth muscle. Future studies will be directed at identifying the specific cellular processes within the mucosal layer that relate to the function of the urothelium as a permeability barrier.