Use of ORO resulted in a more consistent estimation of liver steatosis compared with H&E, but human interpretations failed to correlate with computer measurements. Such differences in fat content estimations might result in the rejection of a potentially transplantable organ or the acceptance of a marginal one. Ideally, our protocol can rapidly be applied to clinical practice for accurate and consistent measurement of fat in liver sections for the ultimate purpose of increasing the number of successful transplantable organs.
Cerulenin has been shown to reduce body weight and hepatic steatosis in murine models of obesity by inhibiting fatty acid synthase (FAS). We have shown that attenuating intrahepatocyte lipid content diminished the sensitivity of ob/ob mice to ischemia/reperfusion injury and improved survival after liver transplantation. The mechanism of action is by inhibition of fatty acid metabolism by downregulating PPARa , as well as mitochondrial uncoupling protein 2 (UCP2), with a concomitant increase in ATP. A short treatment course of cerulenin prior to I/R injury is ideal for protection of steatotic livers. Cerulenin opens the potential for expanding the use of steatotic livers in transplantation.
Steatotic mice are particularly susceptible to hepatic ischemia/reperfusion injury compared with their lean littermates. We have previously demonstrated that livers of mice having a spontaneous mutation in the leptin gene (ob/ob), resulting in global obesity and liver steatosis, are ATP depleted, are endotoxin sensitive, and do not survive (I/R) injury. We hypothesize that administration of an anti-LPS monoclonal antibody (mAb) prior to initiation of I/R would be protective from that insult. Steatotic mice (ob/ob) were subjected to 15 min of ischemia via complete porta-hepatis occlusion and varying lengths of reperfusion with or without pre-treatment with an anti-LPS mAb. There was 14-31% survival of isotype matched control mAb treated ob/ob mice after 15 min of ischemia and 24 h of reperfusion. In contrast, 75-83% of ob/ob mice pre-treated with an anti-LPS mAb prior to initiation of I/R survived both ischemia and 24 h of reperfusion. Furthermore, there was a decrease in ALT and circulating endotoxin levels when treated with an anti-LPS mAb compared with control antibodies. Attenuation of the endotoxin load with anti-LPS mAb, prior to initiation of I/R, was cytoprotective and improved survival. Consequently, these studies might offer a solution to the problems associated with using steatotic livers in clinical transplantation.
We have previously shown that treatment of steatotic livers with vitamin E succinate decreases liver injury and increases survival after ischemia/reperfusion (I/R). It is now understood that compromised energy status is associated with increased injury following liver ischemia in the setting of hepatic steatosis at least partially as a result of increased reactive oxygen species (ROS) and induction of mitochondrial uncoupling protein-2 (UCP2). Given the association between ROS, mitochondrial function, and UCP2, it was our goal to determine whether the protective effects of vitamin E succinate were associated with decreased ROS injury, down-regulation of UCP2, or improvement of ATP levels following I/R. To test this, leptin deficient (ob/ob) mice with steatotic livers that had received other 50 IU of vitamin E succinate supplement per day or control chow for 7 days were subjected to total hepatic ischemia (15 minutes) followed by reperfusion. We measured liver expressions of ATP, glutathione (GSH), and UCP2 as well as mitochondrial DNA damage. Vitamin E treatment decreased hepatic UCP2 expression and increased ATP and GSH levels prior to I/R. These levels were maintained at 1 hour after I/R. At 24 hours, while hepatic UCP2 expression, ATP, and GSH levels were similar to those of mice not receiving vitamin E, mitochondrial DNA damage was blocked. These results revealed that vitamin E succinate decreased hepatic UCP2 expression, reduced oxidative stress, and improved mitochondrial function in mice with steatotic livers before and after I/R, identifying mechanisms of protection in this setting.Mitochondrial adaptations to excess metabolic substrate are now believed to increase the sensitivity of steatotic livers to damage following ischemia/reperfusion (I/R). Specifically, mitochondria in steatotic hepatocytes contain high levels of uncoupling protein-2 (UCP2), whereas hepatocytes from lean livers express little or protein. [1][2][3] UCP2 is a member of a family of mitochondrial proteins that are known to uncouple electron transport from oxidative phosphorylation. 4,5 The functional significance of UCP2 up-regulation in the liver is not entirely clear; however, through mitochondrial uncoupling it may be involved in homeostasis of cellular energy in the settings of excess substrate and of protection against reactive oxygen species (ROS) production. [6][7][8][9] We have shown that UCP2 expression contributes to the ATP depletion and injury observed in steatotic livers following I/R. 1,10 The availability of excess metabolic substrate to the cells of a steatotic liver results in a sustained shift in the electrochemical potential of mitochondria, resulting in greater amounts of superoxide (O 2 − ) and H 2 O 2 than are present in lean livers. 11 UCP2 expression is a protective adaptation to this imbalance. Blockade or deficiency of UCP2 expression has been correlated with observations of increased oxidative stress, including superoxide production in endothelial
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