Molecular Mechanisms of Hydrogen Sulfide Toxicity

Abstract

Rationale. The toxicity of H2S has been attributed to its ability to inhibit cytochrome c oxidase in a similar manner to HCN. However, the successful use of methemoglobin for the treatment of HCN poisoning was not successful for H2S poisonings even though the ferric heme group of methemoglobin scavenges H2S. Thus, we speculated that other mechanisms contribute to H2S induced cytotoxicity. Experimental procedure. Hepatocyte isolation and viability and enzyme activities were measured as described by , and . Results. Incubation of isolated hepatocytes with NaHS solutions (a H₂S source) resulted in glutathione (GSH) depletion. Moreover, GSH depletion was also observed in TRIS-HCl buffer (pH 6.0) treated with NaHS. Several ferric chelators (desferoxamime and DETAPAC) and antioxidant enzymes (superoxide dismutase [SOD] and catalase) prevented cell-free and hepatocyte GSH depletion. GSH-depleted hepatocytes were very susceptible to NaHS cytotoxicity, indicating that GSH detoxified NaHS or H₂S in cells. Cytotoxicity was also partly prevented by desferoxamine and DETAPC, but it was increased by ferric EDTA or EDTA. Cell-free oxygen consumption experiments in TRIS-HCl buffer showed that NaHS autoxidation formed hydrogen peroxide and was prevented by DETAPC but increased by EDTA. We hypothesize that H₂S can reduce intracellular bound ferric iron to form unbound ferrous iron, which activates iron. Additionally, H₂S can increase the hepatocyte formation of reactive oxygen species (ROS) (known to occur with electron transport chain). H₂S cytotoxicity therefore also involves a reactive sulfur species, which depletes GSH and activates oxygen to form ROS.

Key Words :

• Hydrogen sulfide
• Cytotoxicity
• GSH
• Hepatocyte
• Fenton reaction
• P450
• autoxidation

Notes

*Presented at the Seventh International Symposium on Biological Reactive Intermediates, Tucson, Arizona, January 4–7, 2006.