Effect of As2O3 on gluconeogenesis

Abstract

1) The effect of As₂O₃ and As₂O₅ on gluconeogenesis from various substrates in the liver and kidney of rats was investigated. 2) A concentration-dependent inhibition by As₂O₃ was found. The effect was not dependent on the amount of investigated material (hepatocytes or kidney tubules). For either hepatocytes or kidney tubules the extent of inhibition depended strongly on the substrate used. The highest degree of inhibition was observed in incubations with pyruvate. The inhibition of glucose formation was accompanied to a lesser extent by a diminution in O₂ consumption and ATP content. The effect was also dependent on the substrate used. Maximum effect was found in incubations with pyruvate. 3) Oleate, 0.5 mmol/l, increased gluconeogenesis from pyruvate. The effect was not abolished by As₂O₃. 4) A decrease in the content of acetyl-CoA, 3-hydroxybutyrate, and reduced glutathione was found in suspensions of isolated rat kidney tubules or hepatocytes incubated with As₂O₃. 5) About 10 times higher concentrations of As₂O₅ were necessary to induce a similar extent of inhibition of gluconeogenesis, decrease in O₂ consumption, and in ATP content as compared with As₂O₃. The extent of the As₂O₅ effect depended on the concentration of the toxicant and on the substrate used. Gluconeogenesis from pyruvate exhibited the highest sensitivity to As₂O₅. 6) All findings can be largely explained by inhibition of pyruvate dehydrogenase as the central target for arsenicals. The subsequent depletion of acetyl CoA results in impaired formation of reducing equivalents in the citric acid cycle, decrease in high energy phosphates and, acetyl CoA being a strong positive modulator of pyruvate carboxylase, in gluconeogenesis inhibition. Carbohydrate depletion, resulting mainly from gluconeogenesis inhibition, is proposed to be a major problem in poisoning with trivalent arsenicals. In accordance with this proposal, starved rats were shown to be much more sensitive to As₂O₃ than animals with free access to food.