We have shown previously that rats subjected to tourniquet shock develop an acute form of remote organ injury of the liver that is both Kupffer cell (KC) and polymorphonuclear (PMN) leukocyte dependent. Circulating plasma xanthine oxidase (XO) has been shown to be responsible for the development of endothelial dysfunction and for remote organ injury of the lung and intestine after ischemia-reperfusion protocols. We now hypothesize that XO is released from rat hind limbs upon reperfusion and that it is responsible for KC and PMN leukocyte activation in this shock model. Our results show that about 30% of rat gastrocnemius muscle xanthine dehydrogenase (XD) is converted to XO during the 5-h tourniquet period and that it is released into the femoral vein within 10 min of reperfusion. Total muscle xanthine oxidoreductase activity (XO + XD) decreases within 30 min of reperfusion and is paralleled by a corresponding increase in femoral vein lactic dehydrogenase. In addition, liver tissue XO increases significantly within 30 min of reperfusion without a corresponding conversion of endogenous XD. Conversion of hepatic XD becomes evident 60 min after reperfusion is initiated, as does XO, and alanine aminotransferase (ALT) release into the hepatic vein, presumably from damaged hepatocytes as a consequence of oxidative stress. Tissue myeloperoxidase activity also increases significantly after the 60-min reperfusion period. That XO mediates KC and PMN activation is supported by the following observations: a) the close relationships between plasma XO and the time courses of tumor necrosis factor-alpha TNFalpha release into the hepatic vein and colloidal carbon clearance by KCs; b) that colloidal carbon clearance, TNFalpha and ALT release, loss of tissue free thiols, lipid peroxidation (TBARS), and liver infiltration by PMN neutrophils can also be induced by the administration of exogenous XO to normal rats; and c) pretreatment of rats with allopurinol inhibits KC activation and liver leukocyte infiltration. These results suggest that XO, released from the ischemic limb on reperfusion, is taken up by the liver were it mediates KC and PMN neutrophil activation and thus contributes to the development of multiple system organ failure after hind limb reperfusion.

译文

我们先前已经表明,遭受止血带休克的大鼠会发生急性形式的肝脏远程器官损伤,该损伤既是Kupffer细胞 (KC) 又是多形核 (PMN) 白细胞依赖性。循环血浆黄嘌呤氧化酶 (XO) 已被证明是导致内皮功能障碍的发生以及缺血再灌注方案后肺和肠的远程器官损伤的原因。现在,我们假设XO在再灌注后从大鼠后肢释放,并且在该休克模型中,XO负责KC和PMN白细胞的激活。我们的结果表明,在5小时止血带期间,约30% 的大鼠腓肠肌黄嘌呤脱氢酶 (XD) 转化为XO,并在再灌注后10分钟内释放到股静脉。总肌肉黄嘌呤氧化还原酶活性 (XO XD) 在再灌注后30分钟内降低,并与股静脉乳酸脱氢酶的相应增加平行。此外,肝组织XO在再灌注后30分钟内显着增加,而内源性XD没有相应的转化。再灌注开始后60分钟肝XD的转化变得明显,XO也是如此,丙氨酸氨基转移酶 (ALT) 释放到肝静脉中,可能是由于氧化应激而受损的肝细胞。再灌注60分钟后,组织髓过氧化物酶活性也显着增加。以下观察结果支持XO介导KC和PMN激活: a) 血浆XO与肿瘤坏死因子-α TNFalpha释放到肝静脉和KCs的胶体碳清除的时间过程之间的密切关系; b) 胶体碳清除,TNFalpha和ALT释放,向正常大鼠施用外源性XO也可以诱导组织游离硫醇的丢失,脂质过氧化 (TBARS) 和PMN中性粒细胞的肝脏浸润; c) 用别嘌醇预处理大鼠可抑制KC活化和肝白细胞浸润。这些结果表明,XO在再灌注时从缺血肢体释放,通过介导KC和PMN中性粒细胞激活而被肝脏吸收,从而有助于后肢再灌注后多系统器官衰竭的发展。

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