卤酸脱卤酶蛋白:恶性疟原虫代谢可塑性的新介体。

Microbiology insights Pub Date : 2019-05-15 eCollection Date: 2019-01-01 DOI:10.1177/1178636119848435
Philip M Frasse, Audrey R Odom John
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引用次数: 5

摘要

抗疟药物耐药性的广泛存在促使人们需要新的治疗方法,并进一步了解疟原虫生物学。为此,类异戊二烯生物合成抑制剂膦霉素已被用于探索疟原虫恶性疟原虫的代谢调节。卤代酸脱卤酶(HAD)超家族成员HAD2的遗传变化以适应度降低为代价,赋予了对膦霉素的抗性。在没有磷霉素的情况下,寄生虫获得了磷酸果糖激酶的突变,从而恢复了生长和磷霉素敏感性,从而揭示了核心糖酵解过程中可塑性的一个有趣例子。此外,这项研究标志着HAD超家族蛋白调节恶性疟原虫代谢稳态的第二份报告。卤酸脱卤酶分布在生活的各个领域,并越来越多地被发现影响恶性疟原虫的中心碳代谢和药物敏感性。研究HAD超家族成员调节代谢的机制,可能会阐明顶复门寄生虫和其他生物体中代谢网络的连接方式,并可能指导未来的治疗工作。
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Haloacid Dehalogenase Proteins: Novel Mediators of Metabolic Plasticity in Plasmodium falciparum.

Widespread antimalarial drug resistance has prompted the need for new therapeutics and greater understanding of malaria parasite biology. To this end, the isoprenoid biosynthesis inhibitor fosmidomycin has been used to probe the metabolic regulation in the malaria parasite, Plasmodium falciparum. Genetic changes in the haloacid dehalogenase (HAD) superfamily member HAD2 conferred resistance to fosmidomycin, at the cost of decreased fitness. In the absence of fosmidomycin, parasites gained mutations to phosphofructokinase that restored growth and fosmidomycin sensitivity, thus revealing an intriguing example of plasticity in a core glycolytic process. Moreover, this study marks a second report of a HAD superfamily protein-modulating metabolic homeostasis in P falciparum parasites. Haloacid dehalogenase enzymes are distributed across all domains of life and have increasingly been found to influence central carbon metabolism and drug sensitivity in P falciparum. Investigating the mechanisms by which HAD superfamily members modulate metabolism may shed light on how metabolic networks are connected in apicomplexan parasites and other organisms and may guide future therapeutic endeavors.

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