治疗镰状细胞病肺动脉高压的新策略:精氨酸治疗的基本原理。

Claudia R Morris
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引用次数: 21

摘要

镰状细胞病(SCD)中一氧化氮(NO)失活,而合成NO的底物精氨酸的生物利用度降低。一氧化氮生物利用度受损是内皮功能障碍的主要特征,也是SCD病理生理的关键因素。NO的失活与溶血率相关,并与溶血过程中红细胞释放游离血红蛋白和精氨酸酶有关。SCD中存在的氧化应激炎症环境进一步增强了NO的加速消耗。基于一氧化氮在调节血管舒张和细胞生长中的关键作用,一氧化氮生物利用度降低也与肺动脉高压(PHT)的发病机制有关。继发性PHT是SCD常见的危及生命的并发症,也发生在大多数遗传性和慢性溶血性疾病中。异常的精氨酸代谢有助于SCD的内皮功能障碍和PHT,并与预期患者死亡率密切相关。这种代谢紊乱的主要机制是精氨酸转换增强,继发于血浆精氨酸酶活性增强。这与越来越多的人认识到精氨酸酶活性过高在人类疾病(包括哮喘和PHT)中的作用是一致的。血红蛋白进入血浆的解体消耗内皮NO,从而驱动对精氨酸的代谢需求,精氨酸的生物利用度进一步受到精氨酸酶活性的限制。旨在通过抑制精氨酸酶、抑制溶血率或口服补充精氨酸来最大化精氨酸和一氧化氮生物利用度的新治疗方法可能是新的治疗策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New strategies for the treatment of pulmonary hypertension in sickle cell disease : the rationale for arginine therapy.

Nitric oxide (NO) is inactivated in sickle cell disease (SCD), while bioavailability of arginine, the substrate for NO synthesis, is diminished. Impaired NO bioavailability represents the central feature of endothelial dysfunction, and is a key factor in the pathophysiology of SCD. Inactivation of NO correlates with the hemolytic rate and is associated with erythrocyte release of cell-free hemoglobin and arginase during hemolysis. Accelerated consumption of NO is enhanced further by the inflammatory environment of oxidative stress that exists in SCD. Based upon its critical role in mediating vasodilation and cell growth, decreased NO bioavailability has also been implicated in the pathogenesis of pulmonary arterial hypertension (PHT). Secondary PHT is a common life-threatening complication of SCD that also occurs in most hereditary and chronic hemolytic disorders. Aberrant arginine metabolism contributes to endothelial dysfunction and PHT in SCD, and is strongly associated with prospective patient mortality. The central mechanism responsible for this metabolic disorder is enhanced arginine turnover, occurring secondary to enhanced plasma arginase activity. This is consistent with a growing appreciation of the role of excessive arginase activity in human diseases, including asthma and PHT. Decompartmentalization of hemoglobin into plasma consumes endothelial NO and thus drives a metabolic requirement for arginine, whose bioavailability is further limited by arginase activity. New treatments aimed at maximizing both arginine and NO bioavailability through arginase inhibition, suppression of hemolytic rate, or oral arginine supplementation may represent novel therapeutic strategies.

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