Gene Delivery of Cu/Zn–Superoxide Dismutase Improves Graft Function After Transplantation of Fatty Livers in the Rat

Abstract

Oxygen–derived free radicals play a central role in reperfusion injury after organ transplantation, and fatty livers are particularly susceptible. Endogenous radical scavengers such as superoxide dismutase (SOD) degrade these radicals; however, SOD is destroyed rapidly when given exogenously. Therefore, an adenoviral vector encoding the Cu/Zn–SOD gene (Ad.SOD1) was used here to test the hypothesis that organ injury would be reduced and survival increased in a rat model of transplantation of fatty livers. Donors received chow diet (untreated), high–fat diet, or ethanol–containing high–fat diet. Some of the ethanol–fed donors were infected either with the gene lacZ encoding bacterial β–galactosidase (Ad. lacZ), or Ad.SOD1. After liver transplantation, SOD activity and protein expression in liver, survival, histopathology, release of transaminases, free radical adducts in bile, and activation of NF–κB, IκB kinase (IKK), Jun–N–terminal kinase (JNK), and TNFα were evaluated. Ad.SOD1 treatment increased survival dramatically, blunted transaminase release, and reduced necrosis and apoptosis significantly. Free radical adducts were increased two–fold in the ethanol group compared with untreated controls. Ad.SOD1 blunted this increase and reduced the activation of NF–κB. However, release of TNFα was not affected. Ad.SOD1 also blunted JNK activity after transplantation. This study shows that gene therapy with Ad.SOD1 protects marginal livers from failure after transplantation because of decreased oxygen radical production. Genetic modification of fatty livers using viral vectors represents a new approach to protect marginal grafts against primary nonfunction.