Zhao Xiao, Lorent Kristin, Wilkins Benjamin J, Marchione Dylan M, Gillespie Kevin, Waisbourd-Zinman Orith, So Juhoon, Koo Kyung Ah, Shin Donghun, Porter John R, Wells Rebecca G, Blair Ian, Pack Michael
Division of Gastroenterology, Department of Medicine, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA.
Department of Pathology and Laboratory Medicine, Children's Hospital of Philadelphia, Philadelphia, PA.
Hepatology. 2016 Sep;64(3):894-907. doi: 10.1002/hep.28603. Epub 2016 Jun 11.
Biliatresone is an electrophilic isoflavone isolated from Dysphania species plants that has been causatively linked to naturally occurring outbreaks of a biliary atresia (BA)-like disease in livestock. Biliatresone has selective toxicity for extrahepatic cholangiocytes (EHCs) in zebrafish larvae. To better understand its mechanism of toxicity, we performed transcriptional profiling of liver cells isolated from zebrafish larvae at the earliest stage of biliatresone-mediated biliary injury, with subsequent comparison of biliary and hepatocyte gene expression profiles. Transcripts encoded by genes involved in redox stress response, particularly those involved in glutathione (GSH) metabolism, were among the most prominently up-regulated in both cholangiocytes and hepatocytes of biliatresone-treated larvae. Consistent with these findings, hepatic GSH was depleted at the onset of biliary injury, and in situ mapping of the hepatic GSH redox potential using a redox-sensitive green fluorescent protein biosensor showed that it was significantly more oxidized in EHCs both before and after treatment with biliatresone. Pharmacological and genetic manipulation of GSH redox homeostasis confirmed the importance of GSH in modulating biliatresone-induced injury given that GSH depletion sensitized both EHCs and the otherwise resistant intrahepatic cholangiocytes to the toxin, whereas replenishing GSH level by N-acetylcysteine administration or activation of nuclear factor erythroid 2-like 2 (Nrf2), a transcriptional regulator of GSH synthesis, inhibited EHC injury.
These findings strongly support redox stress as a critical contributing factor in biliatresone-induced cholangiocyte injury, and suggest that variations in intrinsic stress responses underlie the susceptibility profile. Insufficient antioxidant capacity of EHCs may be critical to early pathogenesis of human BA. (Hepatology 2016;64:894-907).
双氢异黄酮是一种从藜属植物中分离出的亲电异黄酮,它与家畜自然发生的类似胆道闭锁(BA)疾病的爆发有因果关系。双氢异黄酮对斑马鱼幼虫的肝外胆管细胞(EHC)具有选择性毒性。为了更好地理解其毒性机制,我们在双氢异黄酮介导的胆道损伤的最早阶段对从斑马鱼幼虫分离的肝细胞进行了转录谱分析,随后比较了胆管细胞和肝细胞的基因表达谱。参与氧化还原应激反应的基因所编码的转录本,特别是那些参与谷胱甘肽(GSH)代谢的转录本,在双氢异黄酮处理的幼虫的胆管细胞和肝细胞中都是上调最显著的。与这些发现一致,在胆道损伤开始时肝脏GSH被消耗,并且使用氧化还原敏感的绿色荧光蛋白生物传感器对肝脏GSH氧化还原电位进行原位映射显示,在双氢异黄酮处理前后,EHC中的氧化程度明显更高。GSH氧化还原稳态的药理学和基因操作证实了GSH在调节双氢异黄酮诱导的损伤中的重要性,因为GSH耗竭使EHC和原本具有抗性的肝内胆管细胞对毒素敏感,而通过给予N-乙酰半胱氨酸或激活GSH合成的转录调节因子核因子红细胞2样2(Nrf2)来补充GSH水平可抑制EHC损伤。
这些发现有力地支持氧化还原应激是双氢异黄酮诱导的胆管细胞损伤的关键促成因素,并表明内在应激反应的差异是易感性特征的基础。EHC的抗氧化能力不足可能对人类BA的早期发病机制至关重要。(《肝脏病学》2016年;64:894 - 907)