The mechanism of patulin's cytotoxicity and the antioxidant activity of indole tetramic acids

Abstract In LLC-PK 1 cells exposed to patulin (50 μ m ), lipid peroxidation, abrupt calcium influx, extensive blebbing, and total LDH release appeared to be serially connected events with each representing a step in the loss of structural integrity of the plasma membrane. The aforementioned patulin-induced events were prevented by concurrent incubation with butylated hydroxytoluene, deferoxamine, and cyclopiazonic acid, a fungal metabolite. Patulin also caused depletion of nonprotein sulfhydryls, increased 86 Rb + efflux, dome collapse, and eventually the loss of cell viability. These events were not prevented by antioxidants, results consistent with the hypothesis that the were also serially connected but occurring parallel to those previously mentioned. The earliest events observed in patulin-treated cells were the decrease in nonprotein sulfhydryls and increase in 86 Rb + efflux (5 min) which occurred before statistically significant alterations in protein-bound sulfhydryls. The increased potassium efflux ( 86 Rb + efflux) occurred via a pathway distinct from BaCl 2 , quinine, or tetraethylammonium sensitive potassium channels. This is the first published report of the antioxidant activity of indole tetramic acids (cyclopiazonic acid and cyclopiazonic acid imine). The protective effect of tetramic acids in LLC-PK 1 cells was restricted to indole tetramic acids, and their prevention of lipid peroxidation did not involve iron chelation. The results of this study demonstrate that cyclopiazonic acid is a potent inhibitor of azide-insensitive, ATP-dependent, a23187-sensitive calcium uptake by the lysate of LLC-PK 1 cells. This result is consistent with the hypothesis that the endoplasmic reticulum calcium transport ATPase is a sensitive target for cyclopiazonic acid in LLC-PK 1 cells. These findings raise the interesting possibility that the antioxidant activity of indole tetramic acids may involve multiple novel mechanisms: surface charge alterations on the cytoplasmic surface of plasma membranes, alterations in calcium permeability in the plasma and endoplasmic reticulum membrane, and inhibition of the calcium-dependent ATPase of the endoplasmic reticulum.