ISRN oxidative medicine最新文献

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Vasculotoxic and Proinflammatory Effects of Plasma Heme: Cell Signaling and Cytoprotective Responses. 血浆血红素的血管毒性和促炎作用:细胞信号传导和细胞保护反应。

ISRN oxidative medicine

Pub Date : 2013-01-01 DOI: 10.1155/2013/831596

John D Belcher, Karl A Nath, Gregory M Vercellotti

The proinfammatory vasculotoxic effects of intravascular hemolysis are modulated by plasma hemoglobin and heme clearance via the haptoglobin/CD163 system and the hemopexin/CD91 system, respectively, and detoxification through the heme oxygenase/ferritin system. However, sudden or excessive hemolysis can overwhelm these protective systems leading to heme interacting with cells of the vasculature. Heme presents a damage-associated molecular pattern to the innate immune system. Heme is an extracellular inflammatory signaling molecule with strict binding specificity for TLR4 on monocyte/macrophages, endothelial, and other cells. The resulting TLR4 signaling cascade rapidly leads to intracellular oxidative stress and an inflammatory response. Heme also induces a cytoprotective response that includes Nrf2 responsive genes such as heme oxygenase-1, ferritin, haptoglobin, hemopexin, and other antioxidant response genes. It is the balance between the pro-inflammatory/vasculotoxic effects of plasma hemoglobin/heme and the cytoprotective responses that ultimately determines the pathophysiologic outcome in patients.

血管内溶血的促炎血管毒性作用分别通过触珠蛋白/CD163系统和血凝素/CD91系统通过血浆血红蛋白和血红素清除以及血红素加氧酶/铁蛋白系统解毒来调节。然而，突然或过度的溶血会压倒这些保护系统，导致血红素与血管细胞相互作用。血红素在先天免疫系统中表现出一种与损伤相关的分子模式。血红素是一种细胞外炎症信号分子，对TLR4在单核/巨噬细胞、内皮细胞和其他细胞上具有严格的结合特异性。由此产生的TLR4信号级联迅速导致细胞内氧化应激和炎症反应。血红素还诱导细胞保护反应，包括Nrf2应答基因，如血红素加氧酶-1、铁蛋白、触珠蛋白、血红素和其他抗氧化应答基因。血浆血红蛋白/血红素的促炎/血管毒性作用与细胞保护反应之间的平衡最终决定了患者的病理生理结果。

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