Isolation and separation of toad bladder epithelial cells

Arginine vasotocin promotes urea permeability through urea transporter expressed in the toad urinary bladder cells

We previously isolated a cDNA of a urea transporter (Bufo UT) from the kidney of the marine toad, Bufo marinus, and demonstrated that the Bufo UT was specifically localized on the epithelial membrane of the early distal tubules in the kidney and urinary bladder. In the present study, the function of Bufo UT was investigated using a Xenopus oocytes expression system. Further, we examined the effects of arginine vasotocin (AVT) on urea transport in isolated cells from the toad urinary bladder. When expressed in Xenopus oocytes Bufo UT induced more than a 10-fold increase in [(14)C]urea uptake compared with water-injected control oocytes. Phloretin, a urea transport inhibitor, fully blocked the increase of urea uptake. In epithelial cells isolated from the toad urinary bladder, addition of AVT to the medium increased the urea uptake in a concentration-dependent manner (10(-12)-10(-8)M). To examine the relationship between the Bufo UT protein expression and an increase of urea transportability, we analyzed the time course of the Bufo UT expression levels and urea uptake in the cells treated with 10(-8)M AVT. Treatment of 10(-8)M AVT increased the urea uptake in the cells after 24 and 48h incubation, but not after 12h. According to the immunoblot analysis, UT protein expression was coincident with the results of urea uptake in the AVT-treated cells. These results suggest that Bufo UT isolated from the kidney, functions as an AVT-mediated urea transporter in the urinary bladder of the toad.

Apical and basolateral membrane conductances in the TBM cell line

Cultured cell lines present several advantages over whole organ or ex vivo isolated epithelium for the physiological and biochemical study of epithelial transport. We have developed a new technique allowing for simultaneous intracellular and transepithelial electrophysiological measurements in the epithelium formed by a cultured cell line grown on thin collagen membranes. This technique was applied to the TBM 18/23 (toad bladder origin) cell line. The transepithelial and basolateral membrane potentials were -30 +/- 11 and -72 +/- 8 (SD) mV (n = 36), respectively. With the use of the effect of amiloride, which partially blocked the apical membrane conductance, and circuit analysis, the apical and basolateral membrane conductances were estimated to 0.7 +/- 0.1 and 2.8 +/- 0.4 mS/cm2, respectively. A sodium-selective conductive pathway was demonstrated in the apical membrane, and a barium-sensitive K(+)-selective conductance was shown to be present in the basolateral membrane. The basolateral membrane conductance was not modified by sudden inhibition of sodium transport by amiloride, but it was significantly reduced after a long-term decrease of Na+ transport. The cultured TBM cell line appears to be a convenient model to investigate the regulation of membrane ionic conductances in tight epithelia.

Morphometric analysis of epithelial cells of frog urinary bladder, II. Effect of ADH, calcium ionophore (A23187) and verapamil on isolated dissociated cells

Isolated frog urinary bladder epithelial cells, upon dissociation lose their polarity and develop microridges and occasional microvilli in a global fashion. These cells, when exposed only to isotonic Ringer's solution manifest a membrane conformation with smooth discontinuous microridges, a cytoplasm with numerous free ribosomes, rough ER, thin Golgi cisternae, mitochondria, small vacuoles, electron-dense granules, few microtubules, and numerous microfilaments and intermediate filaments with an apparent random distribution, the dissociated cells, when treated with ADH or calcium ionophore (A23187), have the appearance of numerous elongated microvilli over the entire cell surface. The cytoplasm, under these conditions, is occupied by large vacuoles with a distribution of long profiles of aggrephores and associated vesicles. The peripheral cytoplasm as well as the cavities of the elongated microvilli of these cells contain large concentrations of microfilaments often showing a strong axial orientation to the long axis of the microvilli. Many of these filamentous elements appear in contact with the apical membrane of these microvilli with an alignment with the external glycocalyx. There is an indication that these morphocytological changes as revealed by SEM and TEM studies, correlated with a redistribution and realignment of microfilaments and possibly microtubules as detected by fluorescent microscopy using immunofluorescent antibody labeling for actin and tubulin. Cells treated with verapamil, a calcium antagonist, presented dwarf and stout microvilli with little detectable alterations in the cytoplasmic compositions from that of non-hormonal treated cells. Verapamil prevented ADH induction of microvilli, with the membrane, under these conditions, appearing as compact microridges. The results indicate that calcium ionophore, like ADH, produces intense formation of microvilli in dissociated cells, mobilization and realignment of microfilaments, microtubules, increase in the density of vesicles, aggrephores and possibly secretory granules, whereas the calcium antagonist, verapamil, opposes these actions. The results suggests a prominent role of calcium in the morphological changes induced by ADH.

Morphometric analysis of epithelial cells of frog urinary bladder. I. Effect of antidiuretic hormone, calcium ionophore (A23187) and PGE2

Changes in epithelial cell morphology, especially at the apical plasma membrane, are frequently cited as initial evidence for antidiuretic hormone (ADH)-induced increase in membrane permeability. The effects of ADH and agents that alter and modify calcium and prostaglandin concentrations on the morphology and cytology of the epithelial cells of frog (Rana pipiens) urinary bladder are presented using the techniques of transmission and scanning electron microscopy. It was found that, like ADH, calcium ionophore, A23187, produce intense microvilli formation, microfilament mobilization and an increase in the density of granules and membrane associated vesicles, suggesting a prominent role of calcium in these processes. Moreover, our results suggest that these membrane and cytosolic transformations may be mediated in part through prostaglandin formation, as exogenous PGE2 mimicked these effects, and indomethacin, a prostaglandin synthesis inhibitor, attenuated ionophore's effect on luminal cytomorphology. However, unlike ADH, prostaglandins and ionophore inhibit hormonal-induced increase in transepithelial water flow. These results suggest that other components more distal to the luminal membrane, perhaps the basolateral membrane, may be rate-limiting for transepithelial water flow and possibly are regulated by either changes in calcium concentrations or prostaglandins.

Calcium/phospholipid-dependent protein kinase and its relationship to antidiuretic hormone in toad urinary bladder epithelium

The hydro-osmotic response of the toad urinary bladder to antidiuretic hormone (ADH) and cyclic AMP was inhibited by phorbol myristate acetate (PMA) and 4 beta- phorbol dideconate (4 beta-PDD), activators of protein kinase C (PKC). The inactive epimer of 4 beta-PDD, had no effect on the ADH response. The osmotic transfer of water in the absence of ADH was unaffected by PMA. PKC activity, localized in the soluble fraction of isolated toad bladder cells, was activated by PMA. ADH initially inhibited and subsequently stimulated 32Pi incorporation into phosphatidic acid (PA) and phosphatidylinositol (PI). Carbachol, which inhibits ADH-induced water flow, also stimulated 32P incorporation into PA and PI. It is suggested that phosphoinositide breakdown to diacylglycerol may activate PKC which functions to attenuate the hormone-mediated permeability response.

Carbon-dioxide-induced exocytotic insertion of H+ pumps in turtle-bladder luminal membrane: role of cell pH and calcium

The contents of endocytic vesicles and other intracellular organelles (such as Golgi and microsomes) are acidified by an electrogenic proton-translocating ATPase that is remarkably similar to that found in urinary epithelia. We recently found that the number of H+ ATPases in the apical plasma membrane of these epithelia is regulated by exocytotic insertion of endocytic vesicles whose membranes contain this H+ pump. Carbon dioxide, a major stimulus for urinary acidification, causes rapid fusion of these vesicles with the luminal membrane, thereby inserting these pumps there and increasing the rate of net transepithelial H+ secretion; CO2 also inhibits endocytic retrieval of the pumps from the luminal membrane. Such reciprocal regulation of endocytosis and exocytosis by a physiological modulator makes this system particularly attractive for studying the cellular events regulating membrane fusion. Here we present evidence that CO2 induces exocytosis by a cascade of events, the first step of which is cytoplasmic acidification. Cell acidification then increases calcium activity, which causes the fusion event.

Inhibition of the hydro-osmotic response to vasopressin and hypertonicity by phenothiazines and W7, calmodulin antagonists

Phenothiazines and W7, calmodulin antagonists, inhibit the water flow response produced by ADH, exogenous cyclic AMP, phosphodiesterase inhibition and serosal hypertonicity. Calmodulin antagonists had no effect on osmotic water movement in the absence of hormone. Calmodulin was isolated and localized by immunofluorescence in bladder epithelial cells. Phenothiazines inhibited toad bladder calmodulin activation of phosphodiesterase and prevented fluorescent antibody recognition. The results suggest that the calcium-calmodulin process plays a role in the hydro-osmotic response to ADH and that produced by serosal hypertonicity. The calmodulin common site occurs subsequent to cyclic AMP formation, perhaps on the microtubule-microfilament system.

Differences in c-AMP levels in epithelial cells from pelvic and pectoral regions of the toad skin

Arginine vasopressin (AVP) stimulated active Na+ transport (JNa+) and osmotic water flow (JH2O) across the pelvic skin but only JNa+ across the pectoral skin of the toad, Bufo woodhouseii. Isolated epithelial cells from the pelvic skin had a maximal c-AMP level of 11.16 pmoles/mg protein after 5 min of AVP treatment while that of pectoral skin was 3.64 pmoles/mg protein. The c-AMP level of both skin areas fell to unstimulated values after 20 min of AVP treatment; however, JH2O (pelvic skin) and JNa+ (pelvic and pectoral skin) remained elevated during 3 hr of treatment. Dibutyryl c-AMP and theophylline stimulated JH2O across the pelvic but not the pectoral skin. Maintaining toads in water for 12-24 hr resulted in a substantial lowering of JH2O across the pectoral skin which was not reversible by treatment with c-AMP and theophylline.

Cytoplasmic involvement in ADH-mediated osmosis across toad urinary bladder

Several lines of investigation have suggested that antidiuretic hormone (ADH) may have direct effects on the cytoskeletal organization of granular epithelial cells in the toad urinary bladder. To some extent, these effects are in concert with the well-established action of ADH on the hydraulic permeability of the mucosal plasma membrane, but it appears that other conformational adjustments (largely cytoplasmic) may be of comparable importance. The thrust of this review is that the hormone brings about a general restructuring of the granular cells so that the epithelium as a whole may function efficiently as an osmotic pathway. Details of cytoskeletal changes are far from clear as yet, but interference with or modulation of these particular effects infer that cytoplasmic organization is the seat of feedback control of osmotic flow rate, the basis for viability in the presence of dramatic cytosolic dilution and a major factor in the observed disparity in osmotic and diffusional permeability coefficients. In the interest of stimulating new thoughts and experiments in this area, a number of preliminary findings have been freely cited.

Actin filaments and vasopressin-stimulated water flow in toad urinary bladder

Vasopressin increases the water permeability of the apical membrane of the granular epithelial cells of the toad urinary bladder. Cytochalasin B inhibits this action of the hormone, indicating that microfilaments may play a role in the water permeability response. We have extended previous functional studies with cytochalasin B and have demonstrated that dihydrocytochalasin B, a more specific inhibitor of actin filament elongation, similarly diminishes the hydrosmotic response to vasopressin. Biochemical studies of isolated epithelial cells indicate that an actin-like protein accounts for about 10% of the soluble protein of the epithelium. Morphological studies of whole toad bladders incubated with heavy meromyosin conclusively demonstrate that actin is a component of the epithelial cells and that actin-containing filaments are associated with both plasma membranes and cytoplasmic organelle membranes. Taken together, these findings provide strong, albeit indirect, evidence that actin microfilaments play a functional role in the hormone-induced increase in water permeability in the toad urinary bladder.

Binding of peanut lectin to specific epithelial cell types in kidney

The binding of peanut agglutinin (PNA) to epithelial membranes of the rabbit kidney was evaluated at the light- and electron-microscope level using PNA conjugated to horseradish peroxidase. In the renal cortex and outer stripe of the medulla PNA appears to bind exclusively to the luminal membrane of intercalated cells in connecting tubules and collecting ducts. PNA also binds to the thin descending limb of the loop of Henle in the inner stripe and inner zone of the medulla. This very specific affinity of PNA should be useful in the isolation and characterization of specific cell types in cytologically heterogeneous epithelia.

Immunochemical evidence for a transmembrane orientation of both the (Na+, K+)-ATPase subunits

Antibodies were raised against the large catalytic subunit (apparent Mr 96000) and the glycoprotein (apparent Mr 60000) of the sodium- and potassium-dependent adenosine triphosphatase [(Na+, K+)-ATPase] from Bufo marinus. The specificity of each antiserum was assessed by two-dimensional immunoelectrophoresis using toad kidney microsomes or the purified holoenzyme as a source of antigen and by indirect immunoprecipitation of detergent-solubilized (Na+, K+)-ATPase subunits from radioiodinated or biosynthetically labeled kidney holoenzyme, microsomes, or postnuclear supernatant. The anticatalytic subunit serum reacted exclusively with a 96000-dalton protein. The antiserum to the glycoprotein was rendered specific to this subunit by absorption with purified catalytic subunit. The two antisera were agglutinating and lytic in the presence of complement when toad erythrocytes were used as targets, indicating that antigenic determinants of both subunits were exposed on the cell surface. The specific reactivities with surface-exposed antigenic determinants of both subunits could be absorbed with toad red blood cells. Such absorbed antisera still reacted with detergent-treated or untreated kidney microsomes, revealing the presence of cytoplasmic and/or intramembranous antigenic sites. Our immunochemical data demonstrate that the glycoprotein subunit of (Na+, K+)-ATPase spans the lipid bilayer and confirm the transmembrane orientation of the catalytic subunit postulated from functional studies.

Surface characteristics of carbonic-anhydrase-rich cells in turtle urinary bladder

Addition of a disulfonic stilbene, 4-acetamido 4'-isothiocyano-2,2'-disulfonic stilbene (SITS), to the serosal side of the turtle bladder blocks the efflux of bicarbonate ions from the acidifying cells and thereby inhibits hydrogen ion secretion into the luminal solution. Because SITS has little effect on other transport systems, we used it to define the relationship between hydrogen ion secretion (JH) and the different cell types facing the luminal surface. Cells were identified by scanning and transmission electron microscopy (SEM and TEM) and by histochemical localization of carbonic anhydrase (CA). SEM revealed that SITS caused marked alterations in luminal surface characteristics of a cell population with prominent microplicae. Two hours after the serosal addition of SITS, cells with identifiable microplicae had decreased from 12.7 to 0.5% of total cells. TEM studies and CA histochemistry showed that the number of cells rich in CA (CA cells) remained the same, whereas the individual luminal surface areas of a subpopulation of CA cells had decreased markedly. A comparison of the distribution of individual surface areas of cells with microplicae and CA cells revealed that the CA cells with large surface areas corresponded to the cells with microplicae and that both were affected by the serosal addition of SITS. Acetazolamide, which also inhibits JH, caused similar changes. The luminal addition of SITS and an inactive analogue of acetazolamide, which have no effect on JH, did not alter surface morphology, These results indicate that the CA cell with microplicae represents the active state of the hydrogen ion secreting cell.

Microfilament-rich cells in the toad bladder epithelium

Basal cells of the bladder epithelium of Bufo marinus have been found heterogenous and consist of microfilament-rich cells (MFR-cell) and undifferentiated cells (Un-cell). The MFR-cell, which represents approximately 20% of the epithelial cell population, lies between the epithelial layer lining the urinary space and the basement membrane; it extends under several epithelial cells by processes of varying widths and lengths which contact, via desmosomes, other MFR-cells, as well as cells in the superficial layer, i.e., granular and mitochondria-rich cells. The cytoplasm of MFR-cell is filled with intermediate filaments arranged in bundles which run parallel to the plane of the epithelium and no dense granules, typical of granular cells, have been detected. Strong immunofluorescence for actin is associated with cells which occupy the same basal position as MFR-cells. Undifferentiated cells have no contact via desmosomes with adjacent cells and their cytoplasm is filled with free ribosomes; they lack bundles of intermediate filaments and possess no specialized organelles. After a 4-hr pulse of 3H-thymidine, 1.5% of epithelial cells incorporate thymidine into nuclear DNA, out of which 3/4 are basally and 1/4 are apically located. Identification of cell types by electron microscopy reveals that approximately 10% of undifferentiated basal cells are labeled, whereas less than 0.1% of granular cells and no MFR-cells incorporate 3H-thymidine into DNA. When dissociated from the epithelium and separated by isopycnic centrifugation, MFR-cells possess a mean buoyant density of approximately 1.025, cosediment with mitochondria-rich cells and exhibit a strong immunofluorescence for actin. The function of MFR-cells remains unknown; however, they may play a role in cell coupling and responses to hormonal and physical factors.