To study the relationship between the dynamic actin web and bile secretion, we developed an acute model of cholestasis, using phalloidin, and examined sequential morphologic and biochemical events in rat liver. Biliary function (bite flow, bile, and canalicular membrane components) and cellular integrity (release of hepatic enzymes in serum and bile, canalicular structure, and microfilaments distribution) in rats given a single iv dose of phalloidin (0.8 mg/kg body weight) were assessed at 15, 45, and 90 min, 24 hr, and 5 days postinjection. Bile flow decreased significantly at 45 and 90 min, but cholestasis was transient since bile secretion returned to control levels at 24 hr. The biliary bile acid secretion rate was not modified during the same time period, indicating that cholestasis may have been due to impairment of the bile acid independent component of bile flow. Serum alanine aminotransferase and lactate dehydrogenase as well as biliary alkaline phosphatase and alkaline phosphodiesterase-1 activities were not altered by phalloidin treatment. These data, coupled with morphologic studies, provide no evidence of cell damage. Electron microscopy revealed that the pericanalicular actin web in both centrilobular and periportal hepatocytes was increased at 90 min and further enlarged at 24 hr and 5 days after phalloidin injection. At all time periods, the canalicular structure was well preserved. Na+K+ -ATPase and Mg2+ -ATPase activities in membrane fractions enriched in bile canalicular complexes decreased significantly at 15 min and remained low up to Day 5. Mg2+ -ATPase activity returned to control levels by Day 5. The lipid constituents of liver cell membranes enriched in canalicular complexes showed no significant variations 90 min after toxin treatment but, at 24 hr, phospholipid content rose and membrane fluidity increased. These results clearly indicate that the bile flow variation after a single low dose of phalloidin can be dissociated from specific pericanalicular microfilament distribution, lending further support to the view that normal biliary function is not strictly dependent on the integrity of the actin filament network.