Enhanced cell stress response and protein degradation capacity underlie artemisinin resistance in Plasmodium falciparum.

IF 3.7 2区 生物学 Q2 MICROBIOLOGY
mSphere Pub Date : 2024-11-21 Epub Date: 2024-10-22 DOI:10.1128/msphere.00371-24
Melissa R Rosenthal, Sukhithasri Vijayrajratnam, Tessa M Firestone, Caroline L Ng
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Abstract

Malaria remains a global health burden, killing over half a million people each year. Decreased therapeutic efficacy to artemisinin, the most efficacious antimalarial, has been detected in sub-Saharan Africa, a worrying fact given that over 90% of deaths occur on this continent. Mutations in Kelch13 are the most well-established molecular marker for artemisinin resistance, but these do not explain all artemisinin-resistant isolates. Understanding the biological underpinnings of drug resistance is key to curbing the emergence and spread of artemisinin resistance. Artemisinin-mediated non-specific alkylation leads to the accumulation of misfolded and damaged proteins and activation of the parasite unfolded protein response (UPR). In addition, the parasite proteasome is vital to artemisinin resistance, as we have previously shown that chemical inhibition of the proteasome or mutations in the β2 proteasome subunit increase parasite susceptibility to dihydroartemisinin (DHA), the active metabolite of artemisinins. Here, we investigate parasites with mutations at the Kelch13 and/or 19S and 20S proteasome subunits with regard to UPR regulation and proteasome activity in the context of artemisinin resistance. Our data show that perturbing parasite proteostasis kills parasites, early parasite UPR signaling dictates DHA survival outcomes, and DHA susceptibility correlates with impairment of proteasome-mediated protein degradation. Importantly, we show that functional proteasomes are required for artemisinin resistance in a Kelch13-independent manner, and compound-selective proteasome inhibition demonstrates why artemisinin-resistant Kelch13 mutants remain susceptible to the related antimalarial peroxide OZ439. These data provide further evidence for targeting the parasite proteasome and UPR to overcome existing artemisinin resistance.IMPORTANCEDecreased therapeutic efficacy represents a major barrier to malaria treatment control strategies. The malaria proteasome and accompanying unfolded protein response are crucial to artemisinin resistance, revealing novel antimalarial therapeutic strategies.

增强细胞应激反应和蛋白质降解能力是恶性疟原虫产生青蒿素抗药性的原因。
疟疾仍然是全球健康的负担,每年造成 50 多万人死亡。在撒哈拉以南非洲地区发现,对青蒿素(最有效的抗疟药物)的疗效有所下降,这是一个令人担忧的事实,因为超过 90% 的死亡发生在该大陆。Kelch13 基因突变是青蒿素抗药性最成熟的分子标记,但这并不能解释所有青蒿素抗药性分离株。了解耐药性的生物学基础是遏制青蒿素耐药性出现和蔓延的关键。青蒿素介导的非特异性烷基化会导致错误折叠和受损蛋白质的积累,并激活寄生虫的未折叠蛋白反应(UPR)。此外,寄生虫蛋白酶体对青蒿素抗性也至关重要,因为我们之前已经证明,对蛋白酶体的化学抑制或蛋白酶体β2亚基的突变会增加寄生虫对青蒿素的活性代谢产物双氢青蒿素(DHA)的敏感性。在这里,我们研究了 Kelch13 和/或 19S 和 20S 蛋白酶体亚基发生突变的寄生虫在青蒿素抗性背景下的 UPR 调节和蛋白酶体活性。我们的数据表明,扰乱寄生虫蛋白稳态会杀死寄生虫,寄生虫的早期 UPR 信号决定了 DHA 的存活结果,而 DHA 易感性与蛋白酶体介导的蛋白质降解受损有关。重要的是,我们发现功能性蛋白酶体是青蒿素抗性所必需的,而青蒿素抗性不依赖于 Kelch13,化合物选择性蛋白酶体抑制证明了为什么青蒿素抗性 Kelch13 突变体仍然对相关的抗疟过氧化物 OZ439 敏感。这些数据为以寄生虫蛋白酶体和 UPR 为靶点克服现有的青蒿素抗药性提供了进一步的证据。重要意义疗效降低是疟疾治疗控制策略的主要障碍。疟疾蛋白酶体和伴随的未折叠蛋白反应对青蒿素抗药性至关重要,揭示了新型抗疟疾治疗策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
mSphere
mSphere Immunology and Microbiology-Microbiology
CiteScore
8.50
自引率
2.10%
发文量
192
审稿时长
11 weeks
期刊介绍: mSphere™ is a multi-disciplinary open-access journal that will focus on rapid publication of fundamental contributions to our understanding of microbiology. Its scope will reflect the immense range of fields within the microbial sciences, creating new opportunities for researchers to share findings that are transforming our understanding of human health and disease, ecosystems, neuroscience, agriculture, energy production, climate change, evolution, biogeochemical cycling, and food and drug production. Submissions will be encouraged of all high-quality work that makes fundamental contributions to our understanding of microbiology. mSphere™ will provide streamlined decisions, while carrying on ASM''s tradition for rigorous peer review.
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