The ART of Resistance.

Autophagy reports Pub Date : 2022-10-26 eCollection Date: 2022-01-01 DOI:10.1080/27694127.2022.2134254

Ananya Ray, Namita Surolia

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Abstract

Recent emergence and spread of artemisinin (ART) resistance in South-east Asia caused by mutations in P. falciparum Kelch13 in the background of other mutations including mutations in the macroautophagy/autophagy-related protein PfATG18, has intensified studies towards understanding the molecular mechanisms of resistance. The autophagy pathway of the parasite has been hypothesized to engage in resistance-associated proteostasis involving enhanced phosphatidylinositol-3-phosphate vesiculation, oxidative stress, unfolded protein response and also reduced hemoglobin endocytosis resulting from nutrient-limiting conditions, albeit without any experimental evidence. We demonstrate that ART-induced ER stress leads to upregulation of parasite autophagy through the unfolded protein response pathway. In addition, we show elevated basal expression of autophagy proteins in the ART resistant Kelch13^C58°^Y isolate as compared to its isogenic counterpart WT Kelch13. When autophagy is induced through starvation, the expression levels of autophagy proteins increase further in the resistant parasites. The decreased IC50 of the autophagy-specific inhibitor MRT68921 in resistant parasites relative to its isogenic counterpart establishes that autophagy is the key parasite survival mechanism in ART resistance. Additionally, upon analyses of PfKelch13 mutations from various field isolates, we observe a clear association between PfKelch13 (C580Y, R539T and Y493H) and PfATG18 (T38I) mutations. The copresence of PfATG18 with PfKelch13 on parasite cytostome-like and hemoglobin-containing vesicles provides further evidence that autophagy underpins various mechanisms of ART resistance. Abbreviations: ART, artemisinin; DHA, dihydroartemisinin; eIF2A, eukaryotic translation initiation factor subunit eIF2A; ER, endoplasmic reticulum; PtdIns3P, phosphatidylinositol-3-phosphate; PfATG18, P. falciparum autophagy-related protein 18; PfATG8, P. falciparum autophagy-related protein 8; PfSEC62, P. falciparum translocation protein SEC62; PK4, Plasmodium eIF2A kinase; WT, wild type.

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在包括巨噬/自噬相关蛋白PfATG18突变在内的其他突变背景下，由恶性疟原虫Kelch13突变引起的青蒿素（ART）耐药性最近在东南亚的出现和传播，加强了对耐药性分子机制的研究。尽管没有任何实验证据，但寄生虫的自噬途径被假设参与抗性相关的蛋白质停滞，包括增强磷脂酰肌醇-3-磷酸的囊泡，氧化应激，未折叠的蛋白质反应以及由于营养限制条件导致的血红蛋白内吞作用减少。我们证明了art诱导的内质网应激通过未折叠的蛋白反应途径导致寄生虫自噬的上调。此外，我们发现，与同基因的WT Kelch13相比，耐ART的Kelch13C58°Y分离物中自噬蛋白的基础表达有所升高。当通过饥饿诱导自噬时，自噬蛋白的表达水平在抗性寄生虫中进一步增加。耐药寄生虫中自噬特异性抑制剂MRT68921的IC50值相对于其等基因对应物降低，这表明自噬是抗抗逆转录病毒药物耐药性中寄生虫生存的关键机制。此外，通过对不同田间分离株PfKelch13突变的分析，我们观察到PfKelch13 （C580Y， R539T和Y493H）与PfATG18 （T38I）突变之间存在明显的关联。PfATG18和PfKelch13在寄生虫细胞样囊泡和含血红蛋白囊泡上的存在进一步证明了自噬是抗逆转录病毒药物耐药的多种机制的基础。缩写词：ART，青蒿素；双氢青蒿素含量测定DHA,;eIF2A，真核翻译起始因子亚基eIF2A；内质网；PtdIns3P phosphatidylinositol-3-phosphate;PfATG18，恶性疟原虫自噬相关蛋白18；PfATG8，恶性疟原虫自噬相关蛋白8；PfSEC62，恶性疟原虫易位蛋白SEC62；PK4，疟原虫eIF2A激酶；野生型。

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Autophagy reports

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