在人源化小鼠模型中,5,6-北喹啉可直接溶解老年 G6PD 缺乏的红细胞。

IF 3.1 3区 医学 Q2 PHARMACOLOGY & PHARMACY
Karolina H Dziewulska-Cronk, Julie A Reisz, Ariel M Hay, Travis Nemkov, Francesca I Cendali, Aaron Issaian, Derek R Lamb, Mitasha S Palha, Eric A Legenzov, Joseph P Y Kao, Larry A Walker, Babu L Tekwani, Paul W Buehler, Angelo D'Alessandro, James C Zimring
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引用次数: 0

摘要

普利马喹和他喹是目前唯一获准用于根治间日疟原虫疟疾的药物,但由于药物代谢产物的氧化还原循环产生的活性氧(ROS)可能导致严重溶血,因此缺乏葡萄糖-6-磷酸脱氢酶(G6PDd)的患者禁用。5-hydroxyprimaquine 及其醌-亚胺会在红细胞(RBCs)中引起强烈的氧化还原循环,但却很不稳定,无法在血液或尿液中检测到。相反,5,8-醌亚胺会迅速转化为伯氨喹-5,6-正醌(5,6-POQ),然后随尿液排出体外。5,6-POQ对溶血的影响程度尚不清楚,但有人认为它是一种次要毒素,应主要用作推断5-羟基伯氨喹水平的替代物。在本报告中,我们描述了一种新型人源化 G6PD 地中海变异体小鼠模型(hG6PDMed-),该模型再现了红细胞年龄依赖性酶衰减的人类生物学特性,同时还描述了与人源非缺失 G6PD hG6PDND 的同源匹配对照小鼠。输注经处理的红细胞表明,5,6-POQ 可选择性地导致体内清除较老的 hG6PDMed- 红细胞。这些发现支持了 5,6-POQ 直接诱导溶血的假设,并对 5,6-POQ 是一种非活性代谢废物的观点提出了质疑。事实上,鉴于 5-hydroxyprimaquine 的极度不稳定性和 5,6-POQ 的相对稳定性,这些数据提出了 5,6-POQ 是体内主要溶血伯氨喹代谢产物的可能性。意义声明 这些研究结果表明,5,6-POQ 被认为是活性伯氨喹代谢产物的惰性废物,它能直接诱导 ROS,从而导致较老的 G6PDd 红细胞从血液循环中被清除。由于 5,6-POQ 与其他活性伯氨喹代谢物相比相对稳定,这些数据支持了 5,6-POQ 是伯氨喹诱导溶血的主要毒素这一假设。此外,一种新的 G6PDd 模型显示,年轻的 G6PDd 红细胞对伯氨喹诱导的溶血具有抵抗力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Primaquine-5,6-Orthoquinone Is Directly Hemolytic to Older G6PD Deficient RBCs in a Humanized Mouse Model.

Primaquine and Tafenoquine are the only approved drugs that can achieve a radical cure for Plasmodium vivax malaria but are contraindicated in patients who are deficient in glucose 6-phosphate dehydrogenase (G6PDd) due to risk of severe hemolysis from reactive oxygen species generated by redox cycling of drug metabolites. 5-hydroxyprimaquine and its quinoneimine cause robust redox cycling in red blood cells (RBCs) but are so labile as to not be detected in blood or urine. Rather, the quinoneimine is rapidly converted into primaquine-5,6-orthoquinone (5,6-POQ) that is then excreted in the urine. The extent to which 5,6-POQ contributes to hemolysis remains unclear, although some have suggested that it is a minor toxin that should be used predominantly as a surrogate to infer levels of 5-hydroxyprimaquine. In this report, we describe a novel humanized mouse model of the G6PD Mediterranean variant (hG6PDMed-) that recapitulates the human biology of RBC age-dependent enzyme decay, as well as an isogenic matched control mouse with human nondeficient G6PD hG6PDND In vitro challenge of RBCs with 5,6-POQ causes increased generation of superoxide and methemoglobin. Infusion of treated RBCs shows that 5,6-POQ selectively causes in vivo clearance of older hG6PDMed- RBCs. These findings support the hypothesis that 5,6-POQ directly induces hemolysis and challenges the notion that 5,6-POQ is an inactive metabolic waste product. Indeed, given the extreme lability of 5-hydroxyprimaquine and the relative stability of 5,6-POQ, these data raise the possibility that 5,6-POQ is a major hemolytic primaquine metabolite in vivo. SIGNIFICANCE STATEMENT: These findings demonstrate that 5,6-POQ, which has been considered an inert waste product of primaquine metabolism, directly induces ROS that cause clearance of older G6PDd RBCs. As 5,6-POQ is relatively stable compared with other active primaquine metabolites, these data support the hypothesis that 5,6-POQ is a major toxin in primaquine induced hemolysis. The findings herein also establish a new model of G6PDd and provide the first direct evidence, to our knowledge, that young G6PDd RBCs are resistant to primaquine-induced hemolysis.

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来源期刊
CiteScore
6.90
自引率
0.00%
发文量
115
审稿时长
1 months
期刊介绍: A leading research journal in the field of pharmacology published since 1909, JPET provides broad coverage of all aspects of the interactions of chemicals with biological systems, including autonomic, behavioral, cardiovascular, cellular, clinical, developmental, gastrointestinal, immuno-, neuro-, pulmonary, and renal pharmacology, as well as analgesics, drug abuse, metabolism and disposition, chemotherapy, and toxicology.
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