Morphologic response of the rabbit cortical collecting tubule to peritubular hypotonicity: Quantitative examination with differential interferene contrast microscopy

Summary The isolated and perfused cortical collecting tubule of the rabbit was examined by differential interference contrast microscopy in order to characterize the morphologic response of this nephron segment to peritubular hypotonicity. Computer-assisted, morphometric procedures were developed to obtain measurements of cell volume and lateral intercellular space geometry from interference contrast images of perfused nephron segments. Following dilution of the bath from 290 to 190 mOsm in the absence of antidiuretic hormone (T=25°C), the cells swelled rapidly to a new steady-state volume which was maintained for at least 20 to 30 min and which was about 90% of that predicted for ideal osmometric behavior. The increase in cell volume was accomplished entirely by bulging of the cells into the lumen; lateral space width and outside tubule diameter were unaffected by peritubular hypotonicity. In addition, the swelling of the cells was associated with an apparent swelling of intracellular organelles, e.g., nuclei and mitochondria. Our results indicate that cells of the mammalian collecting tubule swell without the capacity for significant volume regulation at 25°C and without the cytoplasmic vacuolation and dilation of the lateral intercellular spaces observed following the onset of antidiuretic hormone-dependent volume reabsorption (E. Ganote, J. Grantham, H. Moses, M. Burg and J. Orloff,J. Cell Biol. 36:355, 1968).     

Apical membrane endocytosis via coated pits is stimulated by removal of antidiuretic hormone from isolated,perfused rabbit cortical collecting tubule

Summary Antidiuretic hormone increases the water permeability of the cortical collecting tubule and causes the appearance of intramembrane particle aggregates in the apical plasma membrane of principal cells. Particle aggregates are located in apical membrane coated pits during stimulation of collecting ducts with ADHin situ. Removal of ADH causes a rapid decline in water permeability. We evaluated apical membrane retrieval associated with removal of ADH by studying the endocytosis of horseradish peroxidase (HRP) from an isotonic solution in the lumen. HRP uptake was quantified enzymatically and its intracellular distribution examined by electron microscopy. When tubules were perfused with HRP for 20 min in the absence of ADH, HRP uptake was 0.5±0.3 pg/min/m tubule length (n=6). The uptake of HRP in tubules exposed continuously to ADH during the 20-min HRP perfusion period was 1.3±0.8 pg/min/m (n=8). HPR uptake increased markedly to 3.2±1.1 pg/min/m (n=14), when the 20-min period of perfusion with HRP began immediately after removal of ADH from the peritubular bath. Endocytosis of HRP occurred in both principal and intercalated cells via apical membrane coated pits. We suggest that the rapid decline in cortical collecting duct water permeability which occurs following removal of ADH is mediated by retrieval of water permeable membrane via coated pits.     

Ouabain-induced cell swelling in rabbit cortical collecting tubule: NaCl transport by principal cells

Summary Ouabain had no effect on the volume of intercalated cells of DOCA-stimulated rabbit cortical collecting tubules, but caused principal cells to swell rapidly at an initial rate of 67% min., Principal cells swelled 133% then activated regulatory volume decrease mechanisms and shrank at an initial rate of –3%/min to a new volume 13% above control. The initial rate of ouabain swelling was completely inhibited by perfusate Na⁺ removal or reduced 95% by luminal addition of 10^–5 m amiloride. Luminal peritubular, or bilateral Cl^– removal each caused cell shrinkages of 10% and reduced the rate of ouabain swelling by 70, 85, and 99%, respectively. The presence of an apical Cl^– transport step in principal cells was confirmed by increasing luminal K⁺ from 5 to 53mm, which caused cell swelling of 22%. This volume increase was completely blocked by luminal Cl^– removal, but was unaffected by peritubular Cl^– substitution. Perfusion of CCT with 0.1mm acetazolomide, 0.1mm DPC or 0.5mm SITS caused principal cell shrinkages of 7–9% and reduced the rate of ouabain swelling by 60, 70, and 40%, respectively. The initial rate of ouabain swelling was inhibited 70% by bilateral CO₂/HCO₃ removal and 50% by whole animal acid loading. Taken together these results demounstrate that ouabain swelling is due to cellular NaCl accumulation and that Na⁺ enters the cell primarily through apical Na⁺ channels. Cellular Cl^– entry occurs at least partially through the apical membrane and may be mediated by a Cl^–/HCO ₃ ^– exchanger. Brief (45–90 sec) exposure of principal cells to ouabain is associated with a rapid inhibition of Na⁺ and/or Cl^– entry steps, whereas long-term (>5min) ouabvain exposure completely blocks one or both of these transport pathways.