对青蒿素及其类似物具有耐受性的恶性疟原虫的环期休眠——一种基因调控的“睡美人”

Saranya Auparakkitanon , Prapon Wilairat
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引用次数: 0

摘要

2008年在柬埔寨西部出现了对青蒿素耐受的恶性疟原虫,其定义是给药后寄生虫清除时间更长,并且在体外用700nM青蒿素(或类似物,统称为ART)治疗3小时后环期存活率略高,引起了人们对这种一线抗疟药物[以青蒿素联合疗法(ACT)的形式使用]可能损失的担忧,因为它对环期的IC50值较低,并且具有多效性的前药/毒特性。ART耐受表型的关键遗传标记是Pfkelch13螺旋桨结构域中的许多非同义突变。这导致位于寄生虫膜细胞质侧的细胞口结构在环期的组装有缺陷,这是携带宿主胞质溶胶血红蛋白的双膜内体内陷到消化液泡所必需的。氨基酸的相应剥夺使携带PfK13(或其他关键细胞口组分)因果突变的环期寄生虫进入休眠状态(“睡美人”),在比短暂ART更长的持续时间后,发育以维持48小时的红细胞内生命周期。我们假设,当抗逆转录病毒疗法耐受的恶性疟原虫在抗逆转录病毒治疗应激下获得致病的PfK13突变(如果突变发生在其他关键的细胞口成分中,则不是强制性的),以及其他必要的突变,以适应新的常态并提供生存竞争力时,抗逆转录病毒药物耐受的寄生虫现在已经进化成一种基因编程的“睡美人”。预防抗逆转录病毒疗法耐药性恶性疟原虫传播的责任在于ACT合作药物的疗效,因此建议使用三重ACT(TACT)。然而,还应关注了解休眠的机制,如诱导、维持和恢复,以发现和开发针对这一独特寄生虫阶段的新型抗疟药物。
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Ring stage dormancy of Plasmodium falciparum tolerant to artemisinin and its analogues – A genetically regulated “Sleeping Beauty”

The appearance in 2008 in western Cambodia of Plasmodium falciparum tolerant to artemisinin, defined by longer parasite clearance time following drug administration and in vitro by a slightly higher survival rate of the ring stage after a 3-h treatment with 700 nM artemisinin (or analogues, collectively termed ART), has raised concerns of the possible loss of this frontline antimalarial [used in the form of an artemisinin combination therapy (ACT)], with its low IC50 value against the ring stage and pleiotropic pro-drug/poison property. The key genetic marker of ART tolerance phenotype is a number of non-synonymous mutations in Pfkelch13 propeller domain. This results in defective assembly at the ring stage of a cytostome structure located at cytoplasmic side of the parasite membrane required for invagination of a double-membrane endosome carrying host cytosol haemoglobin to the digestive vacuole. The consequential deprivation of amino acids initiates ring stage parasites bearing the causal mutations in PfK13 (or other key cytostome components) entry into a dormant state (“Sleeping Beauty”), which, after a duration longer than that the short-lived ART, “Sleeping Beauty” ring parasite resumes its normal, but accelerated, development to maintain the 48-h intra-erythrocytic life-cycle. We posit that when ART-tolerant P. falciparum has acquired under ART stress the causative PfK13 mutation (not obligatory if mutations occur in other critical cytostome components), together with other necessary mutations to adjust to the new normalcy and to provide survival competitiveness, ART-tolerant parasite has now evolved into a genetically programmed “Sleeping Beauty”. The onus of preventing the spread of ART-tolerant P. falciparum lies with the efficacy of ACT partner drug, hence the recommendation of a triple ACT (TACT). Nevertheless, attention should also be focussed on understanding the mechanisms of dormancy, such as induction, maintenance and recovery, to enable discovery and development of novel antimalarials targeting this unique parasite stage.

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来源期刊
CiteScore
7.90
自引率
7.50%
发文量
31
审稿时长
48 days
期刊介绍: The International Journal for Parasitology – Drugs and Drug Resistance is one of a series of specialist, open access journals launched by the International Journal for Parasitology. It publishes the results of original research in the area of anti-parasite drug identification, development and evaluation, and parasite drug resistance. The journal also covers research into natural products as anti-parasitic agents, and bioactive parasite products. Studies can be aimed at unicellular or multicellular parasites of human or veterinary importance.
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