The isolation of the membrane of the toad bladder epithelial cell

Water and nonelectrolyte permeabilities of apical membranes of toad urinary bladder granular cells

Certain types of epithelial cells such as those lining the toad urinary bladder have been classified as "tight" because their apical membranes exhibit low permeabilities to water, ions, and small nonelectrolytes. However, the permeability properties and structural features of these specialized apical membranes remain unclear because these membranes have never been purified. To isolate toad bladder granular cell apical membranes, we derivatized the bladder apical surface with the membrane-impermeant bifunctional reagent N-hydroxysulfosuccinimydyl-S,S-biotin (NHS-SS-biotin). After cell disruption, these derivatized apical membranes were purified using streptavidin-coated magnetic beads in a magnetic field. With the use of lactoperoxidase-mediated radioiodination as a marker for apical membrane, this preparative procedure purified apical membrane 48- or 72-fold as compared with homogenate. Thin section electron microscopy revealed unilamellar vesicles with some nonvesiculated membranes, while fragments of organelles such as mitochondria were absent. Water and nonelectrolyte permeabilities of purified apical membrane vesicles were similar to those obtained in intact bladders in the absence of antidiuretic hormone stimulation. The results demonstrate that isolated apical vesicles do not contain water channels and confirm the applicability of Overton's rule to the apical membrane of the toad urinary bladder. The technique has general applicability to isolation of other plasma membranes, and the apical membranes obtained are suitable for structural analysis.

Retention of antidiuretic hormone-induced particle aggregates by luminal membranes separated from toad bladder epithelial cells

Aggregates of intramembrane particles appear in the luminal membranes of renal collecting duct and amphibian bladder cells after stimulation by antidiuretic hormone (ADH). We undertook this freeze-fracture study to determine whether particle aggregates, once in place, remain in the luminal membrane of the amphibian bladder after the membrane is physically separated from the rest of the cell. We found that the aggregates do remain in high yield in isolated membranes stabilized with a bifunctional imidoester (DTBP) followed by fixation with glutaraldehyde, or unfixed but stabilized with DTBP. These findings support the view that the particles are intrinsic membrane components and that their organization in the form of aggregates does not depend on the presence of the intact cell. In addition, the availability of isolated membranes containing particle aggregates provides a starting point for the isolation of the water-conducting proteins.

Isolation of radio-iodinated apical and basal-lateral plasma membranes of toad bladder epithelium

The apical and basal-lateral plasma membranes of toad bladder epithelium were radio-iodinated with the glucose-glucose oxidase-lactoperoxidase system. The covalently bound radio iodine was used as a marker during subcellular fractionation and membrane isolation. Homogenization conditions that ensured rupture of more than 80% of the cells without substantial nuclear damage were defined by Normarski optics. The nuclei were separated by differential centrifugation and the apical and basal-lateral components were resolved by differential and sucrose density gradient centrifugation. The apical components yielded two radioactive bands that were identified as glycocalyx and plasma membrane labeled with 125I. The basal-lateral components yielded a hetero-disperse pattern made up of at least 3 radioactive bands, but the bulk of the activity of ouabain-sensitive ATPase comigrated with only one of these bands. The mitochondia, identified by assays for cytochrome oxidase and NADH cytochrome c reductase activities, were separated from the radio-iodine labeled by centrifugation in sucrose density gradients under isokinetic conditions. The labeled glycocalyx and the slowly migrating components of basal-lateral labeling were separated from the radio-iodinated membranes by centrifugation at 100,000 x g x 1 hr after removal of the mitochrondria by the isokinetic method. The labeled membranes were then subjected to ultracentrifugation in sucrose density gradients under isopycnic conditions; the basal-lateral membranes containing ouabain-sensitive ATP-ase were well resolved from the apical membranes by this method. These results provide a relatively rapid method of attaining partial purification of the apical and basal-lateral plasma membranes of toad bladder epithelium.

Composition of cellular membranes in the pancreas of the guinea pig. 3. Enzymatic activities

A COMPARATIVE STUDY OF THE ENZYMIC ACTIVITIES OF MEMBRANE FRACTIONS DERIVED FROM GUINEA PIG PANCREATIC HOMOGENATES HAS YIELDED THE FOLLOWING RESULTS: Rough microsomal membranes (derived from the rough ER) have the reductase activities of the two microsomal electron transport systems but lack enzyme activities of Golgi-type (TPPase) and plasmalemmal-type (5'-nucleotidase, beta-leucyl naphthylamidase, Mg-ATPase). Smooth microsomal membranes (derived primarily from the Golgi complex), zymogen granule membranes, and plasmalemmal fractions possess overlapping enzyme activities of plasmalemmal type, in different relative concentrations for each fraction. In addition, the smooth microsomal membranes exhibit TPPase and ADPase activity and share with rough microsomes the reductase activities of the two electron transport chains. Taken together with recent data on the lipid composition of the same fractions (2), these results indicate that the membranes of the pancreatic exocrine cell are chemically and functionally distinct, and hence do not mix with one another during the transport of secretory products.

STRUCTURE AND REPRODUCTION OF THE ALGAL SYMBIONTS OF HYDRA VIRIDIS(1)

The algal symbionts of Hydra viridis are found within vacuoles of the gastrodermal digestive cells of the host. Electron microscopy reveals that the symbionts possess cell walls, and that their reproductive cycle follows the general pattern of free-living Chlorella. Nuclear and chloroplast divisions arc followed by formation of new cell walls, the Golgi apparatus being quite active during cell wall synthesis. Autospores are released when the parent wall ruptures. The autospores are then usually segregated into separate animal vacuoles. Remnants of the ruptured parent wall persist in the vacuoles for an indefinite period. The ruptured parent walls curl at the breakage clefts, forming double-layered scroll-like structures. The fate of these wall remnants has not been firmly established. Long-term starvation of the animals does not result in a detectable change in the structure of the symbionts, and they continue to divide and to store carbohydrate as starch grains.