The hydrosmotic effect of vasopressin: a scanning electrom-microscope study.

Scanning electron-microscopy (SEM) was used to investigate the hydrosmotic effect of vasopressin on the apical surface of urinary bladders of toads Bufo marinus. Bladders were mounted on glass chambers and water fluxes were monitored with an optical method. Tissues were fixed in 2% glutaraldehyde and processed for SEM. Three types of cells were seen on the surface of control bladders:large polygonal (granular) cells, with blunt microvilli; smaller (mitochondria-rich) cells, with longer microvilli; goblet cells. Neither exposure of the bladders to a large osmotic gradient nor exposure to vasopressin in the absence of a gradient altered appreciably the epithelial surface. In contrast, the combination of vasopressin and an osmotic gradient resulted ina conspicuous diminution of the blunt microvilli. However, the small cells with longer microvilli remained unchanged. Identical results were seen with cAMP or theophylline in the presence of an osmotic gradient. These findings suggest that the hydrosmotic effect of vasopressin is mainly exerted on the granular cells of toad bladder and confirm observations made by others with the electron-microscope.     

Reversible histochemical modifications of endoplasmic reticulum following arginine vasopressin stimulation of granular cells of toad bladder

The endoplasmic reticulum is generally absent from schematic representations of transport phenomena, although it shows a well-organized network in most transport epithelial cells. In order to examine the correlation between this organelle and cellular activity, bladders of Bufo marinus were studied under different experimental conditions and fixed by immersion in glutaraldehyde, followed by OsO₄ impregnation for 3 days. Normal granular and mitochondria-rich cells showed a rich cytoplasmic network of canaliculi, well-impregnated by osmium deposits. Following a 2 to 15-min stimulation (serosal bath) with arginine vasopressin, the V₂ receptor agonist dD-arginine-vasopressin or cyclic AMP (cAMP), the staining of endoplasmic reticulum in granular cells disappeared. After washing out of the hormone or the agonist, impregnation of the endoplasmic reticulum could be observed once again. Arginine vasopressin did not modify the impregnation of endoplasmic reticulum of either mitochondria-rich or basal cells. Our data indicate a correlation between the reactivity of endoplasmic reticulum to osmium, and a cAMP-dependent effect of arginine vasopressin through its V₂ receptors. Incubation of toad bladders carried out with agents interfering with cellular calcium (calcium ionophores, high or low bath calcium) or with calcium release from the endoplasmic reticulum (TMB-8, thapsigargin) suggested that an early step in the cAMP-dependent effect of arginine vasopressin must involve the release of intracellular calcium from the endoplasmic reticulum. However, calcium ATPases in this organelle do not seem to participate in the hormonal effect. The reversible loss of osmium impregnation induced by arginine vasopressin may represent protein changes in the endoplasmic reticulum accompanying a cAMP-dependent calcium release, from the organelle.     

Biochemical characterization of isolated branchial mitochondria-rich cells of Oreochromis mossambicus acclimated to fresh water or hyperhaline sea water

Mitochondria-rich cells have been separated from other epithelial cells of tilapia (Oreochromis mossambicus) gills by density gradient centrifugation on Percoll. During centrifugation two main bands of cells formed. The viability of the cells in both bands was high (>90%). In one band, 45–47% of the total cell number was mitochondria-rich cells. The other band contained at least 80% pavement cells, representing the majority of other gill epithelial cell types. A comparison of the activities of four enzymes involved in major metabolic and ion regulatory functions was made between these two different fractions of cells. Furthermore, the separation of gill epithelial cells and determination of enzymatic activity was carried out in tilapia after the fish were acclimated to fresh water or hyperhaline sea water (60 mg·ml^-1 S) to gain an indication of the relative contribution of mitochondria-rich cells and pavement cells to both NaCl excretion and absorption. Regardless of acclimation salinity, the activities of Na⁺/K⁺-ATPase, glutamate dehydrogenase and glucose-6-phosphate dehydrogenase were significantly higher in mitochondria-rich cells than in pavement cells. However, tilapia acclimated to hyperhaline sea water possessed significantly lower carbonic anhydrase activity in mitochondria-rich cells than in pavement cells. In contrast, no significant difference of carbonic anhydrase activity was observed between the two cell fractions in tilapia acclimated to fresh water.Abbreviations ATPase adenosine triphosphatase - CA carbonic anhydrase - DASPMI dimethylaminostyrylmethylpyridinium iodine - FW fresh-water - GIDH glutamate dehydrogenase - G6PDH glucose-6-phosphate dehydrogenase - HSW hyperhaline sea water (60 mg·ml^-1) - MR cells, mitochondria-rich cells - S salinity     

Electron microscopic cytochemical localization of adenylate cyclase in amphibian urinary bladder epithelium: effects of antidiuretic hormone

A cytochemical technique for electron microscopic localization of adenylate cyclase was used to identify this enzyme in quiescent and hormone-stimulated toad urinary bladder epithelium. In the absence of vasopressin (antidiuretic hormone), adenylate cyclase was detected along the outer surface of the basolateral plasma membranes of granular cells, mitochondria-rich cells, and basal cells, the major cell types comprising the hormone-sensitive urinary epithelium. In the presence of antidiuretic hormone, the basolateral precipitates were markedly increased. The latter was true for both tissues incubated in the presence of an osmotic gradient and those stimulated in the absence of such a gradient. A significant mucosal reaction was never seen. Such data indicate that the hormone receptors for vasopressin are located along the basolateral membranes of all epithelial cells comprising the mucosal hormone-sensitive epithelium. All cells of the epithelium also demonstrate a vasopressin-sensitive adenylate cyclase. We discuss possible mechanisms that attempt to integrate the cytochemical data into an overall scheme for the physiological action of this hormone on amphibian urinary bladder.     

The cellular specificity of the effect of vasopressin on toad urinary bladder

Summary Phase and electron micrographs of toad bladders were obtained following dilution of bathing media in the presence and absence of vasopressin. Dilution of the mucosal medium alone resulted in no morphologic changes. Subsequent addition of vasopressin produced an increase in the cell volume of the granular cells, manifested by some or all of the following changes: increased area of granular cell profiles as observed in sections, rounding of the cell nucleus, displacement of the two components of the nuclear envelope, loss of nuclear heterochromatin, sacculation of the endoplasmic reticulum and the Golgi apparatus, and reduction in the electron density of the cell cytoplasm. No such morphologic changes were noted in the other cell types comprising the mucosal epithelium — the mitochondria-rich, the goblet, and the basal cells. On the other hand, dilution of the serosal bathing medium in the absence of vasopressin caused a marked increase in the cell volume of all these cell types. The results demonstrate that the action of vasopressin to enhance bulk water flow across toad bladder is exerted specifically on the apical surface of the granular cells. It is suggested that the hormonal effect on sodium transport may also be limited to the granular cells. The route of osmotic water flow and the possible role of the other mucosal epithelial cells is discussed.     

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.     

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.     

The effects of vasopressin and catecholamines on cyclic AMP in homogenates of rat brain

Vasopressin is known to mediate its action on the kidney through increasing the concentrations of cyclic AMP. As vasopressin is widely distributed in many extra hypothalamic areas of the brain and can be shown to act centrally, we have investigated the effect of vasopressin on cyclic AMP levels in homogenates of the striatal and locus coeruleus areas. In contrast with the effect obtained on the kidney, vasopressin did not stimulate adenyl cyclase activity in rat brain homogenates in a dose-related manner. The stimulation of cyclic AMP observed with dopamine or noradrenaline in these brain areas and the hippocampus was not affected by the presence of vasopressin. These observations suggest that the action of vasopressin on the brain is not mediated through cyclic AMP.     

Activation of cyclic AMP-dependent protein kinase A common step in vasopressin- and hypertonicity-induced water flow

Water flow across the amphibian urinary bladder can be induced by either vasopressin or serosal hypertonicity. In an effort to determine the common intracellular steps mediating both responses, we determined the in situ activation of cyclic AMP-dependent protein kinase in bladders stimulated by vasopressin or hypertonicity. Treatment of bladders with vasopressin (1 mU/ml) caused in situ activation of cytosolic cyclic AMP-dependent protein kinase of epithelial cells, with a rise in the kinase ratio and cyclic AMP content. Similarly, hyperonicity increased the kinase ratio, but this occured without a measurable increase in cyclic AMP content per mg protein. Because of the hypertonicity-induced cell shrinkage, epithelial cell water decreased by 20%, which may result in a proportionate increase in cyclic AMP concentration (per ml cell water). Furthermore, cell shrinkage also increases intracellular electrolyte concentration, which, in turn, should delay reassociation and consequent inactivation of the predominant Type II cyclic AMP-dependent protein kinase of the epithelial cells. Thus activation of cyclic AMP-dependent protein kinase during hypetonicity may be the result of cell shrinkage, with an associated increase in cyclic AMP and electrolyte concentrations. Studies with prostaglandin synthesis inhibitors and colchicine, a microtubule disrupting agent, also indicated common pathways for vasopressin and hypertonicity. Both naproxen and meclofenamate significantly enhanced the hypertonicity response. Colchicine pretreatment, on the other hand, caused a small (18%) but significant inhibition of the hypertnicity response, similar to its effect on the vasopressine response (25% inhibition). Thus, the increased water permeability of the toad bladder in response to both vasopressin and hypertonicity follows a similar pathway. Activation of cyclic AMP-dependent protein kinase represents the first common step yet identified.     

Adenylate cyclase activity in cultured epithelial cells.

The cyclic AMP metabolism of cultured epithelial cells was investigated. Epinephrine or 1-methyl,3-isobutylxanthine (MIX) alone had no effect on cyclic AMP levels in intact cells, whereas the combination of the two agents yielded a 6- to 10-fold increase in cyclic AMP levels. Both basal and stimulated cyclic AMP levels decreased with increasing cell density. Cell-free adenylate cyclase preparations were stimulated markedly by epinephrine or isoproterenol in the absence of MIX. Since the epithelial cells were found to have a relatively small amount of cyclic nucleotide phosphodiesterase (PDE) activity, the requirement for MIX to visualize intact cell responsiveness to epinephrine could be explained only partially by its PDE inhibitory properties.     

Adenylate cyclase activity in cultured epithelial cells

Summary The cyclic AMP metabolism of cultured epithelial cells was investigated. Epinephrine or 1-methyl, 3-isobutylxanthine (MIX) alone had no effect on cyclic AMP levels in intact cells, whereas the combination of the two agents yielded a 6- to 10-fold increase in cyclic AMP levels. Both basal and stimulated cyclic AMP levels decreased with increasing cell density. Cell-free adenylate cyclase preparations were stimulated markedly by epinephrine or isoproterenol in the absence of MIX. Since the epithelial cells were found to have a relatively small amount of cyclic nucleotide phosphodiesterase (PDE) activity, the requirement for MIX to visualize intact cell responsiveness to epinephrine could be explained only partially by its PDE inhibitory properties. This study was supported in part by Grant PDT-16B, American Cancer Society.     

Regulation of Cyclic AMP Accumulation by Peptide Hormone Receptors in Immunocytochemically: Defined Astroglial Cells

Primary cultures of neonatal murine brain have been reported to express multiple receptors that regulate adenylate cyclase activity. Since for the most part these results were obtained with mixed cell cultures, it has been difficult to define receptor profiles for specific cell types. With this concern in mind a series of studies has been initiated designed to identify specific receptors present on highly purified, immunocytochemically defined astroglia derived from the cerebral cortices of neonatal rats. In this study the capacity of a variety of peptide hormones to regulate cyclic AMP metabolism in these cells was examined. Fibroblasts derived from the meninges represent a predictable source of contamination in primary CNS culture. Thus, to assign more clearly specific receptors to the astroglial cell population, receptor-mediated regulation of cyclic AMP accumulation was also examined in fibroblasts. Cyclic AMP accumulation in astroglia was stimulated by catecholamines (acting at beta 1-adrenergic receptors), prostaglandin E1, vasoactive intestinal polypeptide, alpha-melanocyte-stimulating hormone, and adrenocorticotropin. Bombesin, luteinizing hormone-releasing hormone, neurotensin, thyrotropin-releasing hormone, somatostatin, secretin, and vasopressin did not significantly increase cyclic AMP levels in these cultures. Catecholamines, acting at alpha 2-adrenergic receptors, and somatostatin inhibited agonist-stimulated cyclic AMP accumulation. In meningeal cell cultures catecholamines (acting at beta 2- and alpha 2-adrenergic receptors) and prostaglandin E1 regulated cyclic AMP levels. However, vasoactive intestinal peptide did not stimulate and somatostatin did not inhibit cyclic AMP accumulation in these cells.     

Activation of cyclic AMP-dependent protein kinase and stimulation of protein phosphorylation in response to adenosine in C-1300 murine neuroblastoma

DEAE-cellulose chromatography of the 20,000g supernatant fraction of homogenates of C-1300 murine neuroblastoma (clone N2a) yields one major and two minor peaks of cyclic AMP-dependent protein kinase activity. Assessment of the endogenous activation state of the enzyme(s) reveals that the enzyme is fully activated by the treatment of whole cells with adenosine (10 μM) in the presence of the phosphodiesterase inhibitor Ro 20 1724 (0.7 mM). This treatment produces a large elevation in the cyclic AMP content of the cells. The treatment of whole cells with adenosine alone (1–100 μM) or Ro 20 1724 alone (0.1–0.7 mM) produces minimal elevations in cyclic AMP but nevertheless causes significant activations of cyclic AMP-dependent protein kinase. The autophosphorylation of whole homogenates of treated and untreated cells was studied using [γ-³²P] ATP, sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Treatments which activate cyclic AMP-dependent protein kinase selectively stimulate the incorporation of ³²P into several proteins. This stimulation is most prominent in the 15,000-dalton protein band. The addition of cyclic AMP to phosphorylation reactions containing homogenate of untreated cells stimulates the phosphorylation of the same protein bands. These results indicate that adenosine may have regulatory functions through its effect on the cyclic AMP: cyclic AMP-dependent protein kinase system.     

The effect of aldosterone on cyclic nucleotide phosphodiesterase activity in toad urinary bladder

Cyclic AMP phosphodiesterase activity was assayed in the 700 xg supernatant solution of homogenates of epithelial cells scraped from toad urinary bladders. The activity of the enzyme was lower in cells obtained from bladders incubated with aldosterone for 24 hours than in cells from paired tissue incubated without aldosterone. This difference may well account for the permissive effect of aldosterone on the physiologic and biochemical responses of the toad bladder to vasopressin.     

Modulation of cyclic AMP-dependent protein kinase by vasopressin and calcitonin in cultured porcine renal LLC-PK1 cells

We have previously demonstrated that a cultured porcine kidney cell, LLC-PK(1), maintains the characteristics of a polar renal epithelial cell in culture, and responds to salmon calcitonin and [arginine]vasopressin by increasing cyclic AMP content. To demonstrate the usefulness of this cell line as a model for the study of the biochemical events distal to cyclic AMP production, the activation of cyclic AMP-dependent protein kinase was examined. Intact cells in monolayer demonstrated progressive increases in cyclic AMP content and activation of protein kinase in response to [arginine]vasopressin (2-200nm) and salmon calcitonin (0.03-30nm) with both hormones fully activating the enzyme at a cell cyclic AMP content of 35pmol/mg of protein. Of the total cyclic AMP-dependent protein kinase activity, 80% was found in the 27000g supernatant fraction of sonicated cell material, and this soluble protein kinase could be fully activated by hormone. Conversely, the 27000g pellet contained a significant proportion of cyclic AMP-independent protein kinase and only 20% of total cell cyclic AMP-dependent protein kinase; the latter showed little response to hormone. On the basis of DEAE-cellulose chromatography, type II protein kinase was the predominant isoenzyme in both soluble and particulate fractions of the LLC-PK(1) cells and the soluble fractions of rat and guinea-pig renal medulla. Thus, the LLC-PK(1) cell line can serve as a model for hormonal modulation of protein kinase and as a potential source for defining the endogenous substrates for these enzymes.     

Hormone-specific responses and biosynthesis of sulfolipids in cell lines derived from mammalian kidney

The established cell lines isolated from mammalian kidney were characterized by its receptor activities against hormones and the ability to synthesize sulfolipids localized in the renal tubule.The level of 3′: 5′-cyclic AMP in JTC-12.P3 (monkey kidney) cells increased in 2 min as much as 2.5–5-fold on activation with 1.0 unit/ml of bovine parathyroid hormone or 1.9 units/ml of synthetic parathyroid hormone (1–34) resulting in intracellular cyclic AMP concentration of more than 40 pmol/mg protein. Prostaglandin E₁ (14 μM) and isopropylnorepinephrine (10 μM) were also found to increase the concentration of cyclic AMP by more than 30- and 9-fold, respectively. Addition in medium of calcitonin, arginine vasopressin, adrenocorticotropic hormone and glucagon caused no significant changes of cyclic AMP level in the cell.In contrast, MDCK, a cell line isolated from canine kidney, reacted to arginine vasopressin, isopropylnorepinephrine and prostaglandin E₁ and only slightly to parathyroid hormone. MDBK cell line derived from bovine kidney or fibroblast cell lines from rat lung and guinea pig kidney did not react to any of the hormones specific to kidney, i.e. arginine vasopressin, calcitonin or parathyroid hormone in the presence of theophylline. However, in the presence of 2 mM isobutylmethylxanthine, small but significant elevation of cellular cyclic AMP levels in response to calcitonin, arginine vasopressin, isopropylnorepinephrine and prostaglandin E₁ was observed.The cell lines JTC-12, MDCK and MDBK, when incubated with H₂³⁵SO₄, incorporated the isotope into sulfolipids assigned as sulfatides and ceramide dihexoside sulfate or in MDCK also into cholesterol sulfate.The results suggested that JTC-12, MDCK and MDBK cell lines are epithelial origin and also JTC-12 and MDCK originated most probably from renal tubular cells of cortex and medulla, respectively.     

Metabolic and cyclic nucleotide enzyme activities in muscle and nonmuscle cells of rat heart during perinatal development

Enzyme activities related to aerobic metabolism and cyclic nucleotides were evaluated in muscle and nonmuscle cells of rat heart. The perinatal period from weaning to adult was studied. Malate dehydrogenase, citrate synthase, and 3-hydroxyacyl-CoA dehydrogenase activities of nonmuscle cells equal or exceed muscle cell activities in the weanling heart. Aerobic enzymes remain unchanged in nonmuscle cells during growth; however, muscle cell activities are enhanced. Adenylate cyclase and guanylate cyclase activities are higher in heart homogenates of weanling than adult rats. Despite elevated adenylate cyclase activity, cyclic AMP levels are identical in weanling and adult rats. Cyclic GMP levels are twofold higher in weanling than in adult rats. Muscle cell metabolism and cyclic nucleotide levels are associated with growth-related changes in heart function and cellularity, respectively.     

Hyperoxic-induced alterations in lung cell structure and function: Effects on cellular cyclic AMP content and comparison to alterations produced by exogenous cyclic AMP

Hyperoxic exposure in vitro of two lung-derived cell types (the epithelial-derived L2 cells and WI-38 fibroblasts) inhibits cellular replication, produces striking morphologic changes and may result in cell death; these effects have been observed consistently in other cell types. Hyperoxic exposure of L2 cells is associated with an increase in cellular cyclic AMP content (cellular cyclic AMP content 454 ± 115 fmol/μg DNA in cells exposed to p_O2 677 Torr for 96 h compared to 136 ± 17 fmol/μg DNA in air-grown cells). Hyperoxic exposure of WI-38 fibroblasts is not associated with increased cyclic AMP content. Although cultivation of L2 cells in the presence of exogenous dibutyryl cyclic AMP does inhibit replication and produce morphologic alterations, similar effects are produced by sodium butyrate alone. Hyperoxic exposure alters cyclic AMP metabolism in some cell types, but the structural and functional alterations observed in L2 cells and WI-38 fibroblasts following hyperoxic exposure are not produced by changes in cellular cyclic AMP content.     

Regulation by a β-adrenergic receptor of a Ca2+-independent adenosine 3′,5′-(cyclic)monophosphate phosphodiesterase in C6 glioma cells

The hormonal control of cyclic nucleotide phosphodiesterase (EC 3.1.4.17) activity has been studied by using as a model the isoproterenol stimulation of cyclic AMP phosphodiesterase activity in C6 glioma cells. A 2-fold increase in cyclic AMP phosphodiesterase specific activity was observed in homogenates of isoproterenol-treated cells relative to control. This increase reached a maximum 3 h after addition of isoproterenol, was selective for cyclic AMP hydrolysis, was reproduced by incubation with 8-Br cyclic AMP but not with 8-Br cyclic GMP and was limited to the soluble enzyme activity. The presence of 0.1 mM EGTA did not alter the magnitude of the increase in phosphodiesterase activity. Moreover, the calmodulin content in the cell extracts was not changed after isoproterernol. DEASE-Sephacel chromatography of the 100 000×g supernatant resolved two peaks of phosphodiesterase activity. The first peak hydrolyzed both cyclic nucleotides and was activated by Ca²⁺ and purified calmodulin. The second peak was specific for cyclic AMP but it was Ca²⁺- and calmodulin-insensitive. Isoproterenol selectively increased the specific activity of the second peak. Kinetic analysis of the cyclic AMP hydrolysis by the induced enzyme reveled a non-linear Hofstee plot with apparent K_m values of 2–5 μM. Cyclic GMP was not hydrolyzed by this enzyme in the absence or presence of calmodulin and failed to affect the kinetics of the hydrolysis of cyclic AMP. Gel filtration chromatography of the induced DEASE-Sephacel peak resolved a single peak of enzyme activity with an apparent molecular weight of 54 000.     

The effect of turpentine-induced inflammation on rat liver glycosyltransferases and Golgi complex ultrastructure

The effect of vasopressin on the toad urinary bladder has been shown to be mediated by cyclic AMP. It has been assumed that, as demonstrated for other systems, this involves activation of cyclic AMP-dependent protein kinase. In order to test this hypothesis we investigated the effect of vasopressin on cyclic AMP-dependent protein kinases in epithelial cells of toad bladders. About 80% of protein kinase activity and cyclic AMP-binding capacity was found to be in the cytosol. DEAE-cellulose chromatography showed a pattern of 15--20% type I and 80--85% type II cyclic AMP-dependent protein kinase. Cytosolic kinase was activated 3--4-fold by cyclic AMP with half-maximal activation at 5 . 10(-8) M. Similarly, half-maximal binding of cyclic AMP occurred at 7 . 10(-8) M. Incubation of toad bladders in Ringer's solution containing 0.1 mM 3-isobutyl-1-methylxanthine, prior to homogenization and assay, showed stable cyclic AMP-binding capacity and protein kinase ratio --cyclic AMP/+cyclic AMP. Exposure of bladders to 10 mU/ml of vasopressin for 10 min caused intracellular activation of protein kinase and decrease in cyclic AMP-binding capacity that were maintained for at least 30 min. Incubation of bladders with increasing concentrations of vasopressin (0.5--100 mU/ml) resulted in a discrepancy between a progressive increase in cyclic AMP levels and a levelling off at 10 mU/ml of vasopressin for the changes in protein kinase ratio and cyclic AMP-binding capacity. The increase in kinase ratio was due to higher activity in the absence of exogenous cyclic AMP and was fully inhibitable by a specific protein kinase inhibitor. Using Sephadex G-25-CM50 column chromatography for separation of holoenzyme and free catalytic subunit we demonstrated that the activation of protein kinase in the vasopressin-treated bladders is due to intracellular dissociation of the kinase. These results show that the effect of vasopressin on the toad bladder involves activation of a cytosolic cyclic AMP-dependent protein kinase. The time course and the dose-response curve of the kinase activation closely parallel vasopressin's effect on osmotic water flow.