DIFFUSION RESISTANCES BETWEEN ADH-INDUCED VACUOLES AND THE EXTRACELLULAR-SPACE IN RABBIT COLLECTING DUCT - EVIDENCE THAT MOST VACUOLES ARE INTRACELLULAR, ENDOCYTIC COMPARTMENTS

Large vacuoles form in the renal collecting duct following the onset of antidiuretic hormone (ADH)-stimulated water reabsorption. The aim of the present study was to test two alternative hypotheses regarding the origins of these structures: (1) the vacuoles constitute basilar, extracellular spaces that dilate as water flows through these spaces from cells into the peritubular compartment; or (2) the vacuoles represent intracellular, endocytic compartments that dilate during water reabsorption due to enhanced fluid phase endocytosis. Fluorescence-digital imaging microscopy was used to visualize the uptake into vacuoles of a hydrophilic fluorochrome (6 methoxy-N-[3 sulfopropyl] quinolinium) whose fluorescence is markedly quenched by halides. During their formation, most vacuoles (67%) accumulated the fluorochrome from the peritubular bath and trapped the dye well after ( > 60 min) washing it from the bath. The spatial pattern of fluorescence within individual vacuoles indicated that the dye was trapped within these structures as a fluid-phase marker and was not bound to the vacuole margins. The fluorescence of dye trapped within vacuoles was virtually unaltered by changes in peritubular Cl- or Br- concentration that elicit dramatic quenching of dye-fluorescence in bulk solution, as expected if there exists a high diffusion resistance between the interiors of these structures and the peritubular space. These results indicate that most ADH-induced vacuoles represent endocytic compartments that are not directly connected to the extracellular space.