Endogenous hydroperoxide formation, cell volume and cellular K+ balance in perfused rat liver.

Addition of benzylamine (0.5 mM) to isolated perfused rat liver led to a net release of K+ of 10.5 +/- 0.3 mumol/g, which was accompanied by a decrease in liver mass by 9.3 +/- 0.4% and a decrease of the intracellular water space by 13.7 +/- 0.6%, suggestive of hepatocellular shrinkage. Benzylamine had no effect on the perfusion pressure, and there was a close relationship between benzylamine-induced net K+ release and the accompanying decrease in liver mass. Benzylamine-induced net K+ release was sensitive to inhibition of monoamine oxidase by pargyline and increased with benzylamine flux through monoamine oxidase, suggesting its dependence on intracellular H2O2 formation. In line with this, infusion of H2O2 (but not of benzaldehyde, the other product of benzylamine metabolism) stimulated net K+ release from the liver. However, at a given H2O2 load K+ release was about 2-3-fold higher when H2O2 was generated intracellularly during the oxidation of benzylamine, as compared with exogenously delivered H2O2. Inhibition of catalase by 3-amino-1,2,4-triazole (0.2 mM) significantly increased the benzylamine-induced net K+ release as well as the benzylamine-induced release of GSSG into bile, but had no effect on benzylamine oxidation at monoamine oxidase. In the presence of Ba2+ (1 mM) or in Ca(2+)-free perfusions, the benzylamine-induced net K+ efflux was diminished by 60-70% or about 30%, respectively. This was not explained by the 20-30% decrease in flux through monoamine oxidase observed under these conditions. The results suggest that metabolic generation of H2O2 inside the liver leads to a net K+ efflux and subsequent hepatocellular shrinkage. Net K+ efflux under these conditions is enhanced when catalase is inhibited, suggesting that the rate of both intracellular H2O2 generation and degradation can modulate cellular K+ balance and cellular volume. The data support the idea that oxidative stress may affect hepatocellular functions also by lowering the hepatocellular hydration state.