The role of CYP enzymes in cocaine-induced liver damage.

Cocaine is hepatotoxic in several species, including man. A high dose of cocaine produces metabolism-dependent, mainly pericentral, liver damage. At 24 h after a single dose of cocaine, mouse hepatic P450 content decreases but CYP2A activities; coumarin 7-hydroxylase and testosterone 15 alpha-hydroxylase increase concomitant with prominent diffuse cell necrosis. Repeated administration of cocaine for up to 5 days decreases CYP1A1/2, 2A4/5, 2Cx, and 2E1 related enzymatic activities. However, after five doses of cocaine, CYP2B10 increases in conjunction with the healing process. In the acute phase, the increased CYP2A activities do not participate in cocaine bioactivation. CYP3A enzymes are principally responsible for the cocaine N-demethylation in human and mouse liver microsomes. The hepatic metabolic CYP enzyme profile will change during prolonged cocaine intake, this being accompanied by altered cell morphology. Possible connections to cocaine toxicity in man are discussed.