Iron transport pathways in the human malaria parasite Plasmodium falciparum revealed by RNA-sequencing.

IF 4.6 2区 医学 Q2 IMMUNOLOGY Frontiers in Cellular and Infection Microbiology Pub Date : 2024-11-07 eCollection Date: 2024-01-01 DOI:10.3389/fcimb.2024.1480076
Juliane Wunderlich, Vadim Kotov, Lasse Votborg-Novél, Christina Ntalla, Maria Geffken, Sven Peine, Silvia Portugal, Jan Strauss
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Abstract

Host iron deficiency is protective against severe malaria as the human malaria parasite Plasmodium falciparum depends on bioavailable iron from its host to proliferate. The essential pathways of iron acquisition, storage, export, and detoxification in the parasite differ from those in humans, as orthologs of the mammalian transferrin receptor, ferritin, or ferroportin, and a functional heme oxygenase are absent in P. falciparum. Thus, the proteins involved in these processes may be excellent targets for therapeutic development, yet remain largely unknown. Here, we show that parasites cultured in erythrocytes from an iron-deficient donor displayed significantly reduced growth rates compared to those grown in red blood cells from healthy controls. Sequencing of parasite RNA revealed diminished expression of genes involved in overall metabolism, hemoglobin digestion, and metabolite transport under low-iron versus control conditions. Supplementation with hepcidin, a specific ferroportin inhibitor, resulted in increased labile iron levels in erythrocytes, enhanced parasite replication, and transcriptional upregulation of genes responsible for merozoite motility and host cell invasion. Through endogenous GFP tagging of differentially expressed putative transporter genes followed by confocal live-cell imaging, proliferation assays with knockout and knockdown lines, and protein structure predictions, we identified six proteins that are likely required for ferrous iron transport in P. falciparum. Of these, we localized PfVIT and PfZIPCO to cytoplasmic vesicles, PfMRS3 to the mitochondrion, and the novel putative iron transporter PfE140 to the plasma membrane for the first time in P. falciparum. PfNRAMP/PfDMT1 and PfCRT were previously reported to efflux Fe2+ from the digestive vacuole. Our data support a new model for parasite iron homeostasis, in which PfE140 is involved in iron uptake across the plasma membrane, PfMRS3 ensures non-redundant Fe2+ supply to the mitochondrion as the main site of iron utilization, PfVIT transports excess iron into cytoplasmic vesicles, and PfZIPCO exports Fe2+ from these organelles in case of iron scarcity. These results provide new insights into the parasite's response to differential iron availability in its environment and into the mechanisms of iron transport in P. falciparum as promising candidate targets for future antimalarial drugs.

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通过 RNA 测序揭示恶性疟原虫的铁运输途径。
宿主缺铁对严重疟疾有保护作用,因为人类疟原虫恶性疟原虫依赖宿主提供的生物可用铁来增殖。寄生虫体内铁的获取、储存、输出和解毒的基本途径与人类不同,因为恶性疟原虫体内没有哺乳动物转铁蛋白受体、铁蛋白或铁蛋白的直向同源物,也没有功能性血红素加氧酶。因此,参与这些过程的蛋白质可能是治疗开发的绝佳靶点,但大部分情况下仍不为人所知。在这里,我们发现与在健康对照组红细胞中培养的寄生虫相比,在缺铁供体红细胞中培养的寄生虫的生长速度明显降低。寄生虫 RNA 测序显示,与对照组相比,低铁条件下参与整体代谢、血红蛋白消化和代谢物运输的基因表达量减少。补充铁皮质素(一种特异性铁皮质素抑制剂)后,红细胞中的可溶性铁含量增加,寄生虫复制能力增强,负责裂殖子运动和宿主细胞侵袭的基因转录上调。通过对不同表达的假定转运体基因进行内源性 GFP 标记,然后进行共聚焦活细胞成像、基因敲除和基因敲除株的增殖试验以及蛋白质结构预测,我们确定了恶性疟原虫亚铁转运可能需要的六种蛋白质。其中,我们首次在恶性疟原虫中将 PfVIT 和 PfZIPCO 定位于细胞质囊泡,将 PfMRS3 定位于线粒体,并将新型推定铁转运体 PfE140 定位于质膜。以前曾报道过 PfNRAMP/PfDMT1 和 PfCRT 从消化液泡中外流 Fe2+。我们的数据支持一种新的寄生虫铁平衡模型,其中 PfE140 参与质膜的铁吸收,PfMRS3 确保线粒体作为铁利用的主要场所的非冗余 Fe2+ 供应,PfVIT 将多余的铁转运到细胞质液泡中,而 PfZIPCO 则在铁缺乏时将 Fe2+ 从这些细胞器中排出。这些结果为我们提供了新的视角,让我们了解寄生虫对其环境中不同铁可用性的反应,以及恶性疟原虫的铁转运机制,这些机制有望成为未来抗疟药物的候选靶标。
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来源期刊
CiteScore
7.90
自引率
7.00%
发文量
1817
审稿时长
14 weeks
期刊介绍: Frontiers in Cellular and Infection Microbiology is a leading specialty journal, publishing rigorously peer-reviewed research across all pathogenic microorganisms and their interaction with their hosts. Chief Editor Yousef Abu Kwaik, University of Louisville is supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide. Frontiers in Cellular and Infection Microbiology includes research on bacteria, fungi, parasites, viruses, endosymbionts, prions and all microbial pathogens as well as the microbiota and its effect on health and disease in various hosts. The research approaches include molecular microbiology, cellular microbiology, gene regulation, proteomics, signal transduction, pathogenic evolution, genomics, structural biology, and virulence factors as well as model hosts. Areas of research to counteract infectious agents by the host include the host innate and adaptive immune responses as well as metabolic restrictions to various pathogenic microorganisms, vaccine design and development against various pathogenic microorganisms, and the mechanisms of antibiotic resistance and its countermeasures.
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