The role of microtubules and microfilaments in the hydrosmotic response to antidiuretic hormone

• Published in: Biochimica et biophysica acta Vol. 817; no. 2; pp. 333 - 342
• Main Authors: Parisi, M, Pisam, M, Mérot, J, Chevalier, J, Bourguet, J
• Format: Journal Article
• Language: English
• Published: Netherlands 25.07.1985
• Subjects: Animals; Body Water - metabolism; Colchicine - pharmacology; Cytochalasin B - pharmacology; Cytoskeleton - physiology; Ion Channels - drug effects; Mathematics; Microscopy, Electron; Microtubules - physiology; Osmosis - drug effects; Oxytocin - pharmacology; Permeability; Rana esculenta; Urinary Bladder - metabolism; Urinary Bladder - ultrastructure; Vasopressins - pharmacology
• ISSN: 0006-3002
• DOI: 10.1016/0005-2736(85)90036-7

To test the effects of colchicine and cytochalasin B on the ADH-induced response, unidirectional and net water fluxes were measured at one or two minutes intervals in frog urinary bladder. The action of these agents on the appearance of intramembrane particles aggregates in the luminal membrane of target cells under oxytocin stimulation and the changes in the tissue ultrastructure induced by cytochalasin B were also studied. It was observed that: the time-course of the response to oxytocin was strongly slowed by colchicine while the washout was not affected; the time-course of the 'on and off' of the response to oxytocin was not modified by cytochalasin B; cytochalasin B pretreatment proportionally reduced unidirectional and net water fluxes measured after glutaraldehyde fixation; the combined action of colchicine and cytochalasin B proportionally reduced the net water flux and the number of intramembrane particles aggregates, observed in freeze-fracture studies; after cytochalasin B action the dilation of intercellular spaces classically observed under oxytocin stimulation is strongly reduced. It is concluded that: microtubules probably play an important role in the water channels plug-in, but not in their removal; microfilaments integrity is necessary for the mechanisms inducing intercellular space dilation and the observed results confirm that water permeability is controlled by the number of permeation units present in the luminal border of granular cells and probably represented by the intramembrane particle aggregates.