Transcriptome analysis reveals molecular targets of erythrocyte invasion phenotype diversity in natural Plasmodium falciparum isolates from Cameroon

Ines A. Ngoh, Karim Mane, Jarra Manneh, F. Bojang, A. Jawara, Theresia N. Akenji, D. Anong, Umberto D’Alessandro, A. Amambua-Ngwa
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Abstract

Further understanding of the molecular mediators of alternative RBC invasion phenotypes in endemic malaria parasites will support malaria blood-stage vaccine or drug development. This study investigated the prevalence of sialic acid (SA)-dependent and SA-independent RBC invasion pathways in endemic Plasmodium falciparum parasites from Cameroon and compared the schizont stage transcriptomes in these two groups to uncover the wider repertoire of transcriptional variation associated with the use of alternative RBC invasion pathway phenotypes. A two-color flow cytometry-based invasion-inhibition assay against RBCs treated with neuraminidase, trypsin, and chymotrypsin and deep RNA sequencing of schizont stages harvested in the first ex vivo replication cycle in culture were employed in this investigation. RBC invasion phenotypes were determined for 63 isolates from asymptomatic children with uncomplicated malaria. Approximately 80% of the isolates invaded neuraminidase-treated but not chymotrypsin-treated RBCs, representing SA-independent pathways of RBC invasion. The schizont transcriptome profiles of 16 isolates with invasion phenotypes revealed a total of 5,136 gene transcripts, with 85% of isolates predicted at schizont stages. Two distinct transcriptome profile clusters belonging to SA-dependent and SA-independent parasites were obtained by data reduction with principal component analysis. Differential analysis of gene expression between the two clusters implicated, in addition to the well-characterized adhesins, the upregulation of genes encoding proteins mediating merozoite organelle discharges as well as several conserved, virulent, merozoite-associated, and exported proteins. The latter majority have been shown to have structural and physiological relevance to RBC surface remodeling and immune evasion in malaria and thus have potential as anti-invasion targets.
转录组分析揭示喀麦隆恶性疟原虫天然分离株红细胞侵袭表型多样性的分子靶标
进一步了解地方性疟疾寄生虫中替代性 RBC 侵袭表型的分子介质将有助于疟疾血液阶段疫苗或药物的开发。本研究调查了喀麦隆地方性恶性疟原虫中依赖和不依赖硅铝酸(SA)的 RBC 侵袭途径的流行情况,并比较了这两类寄生虫的裂殖期转录组,以揭示与使用替代 RBC 侵袭途径表型相关的更广泛的转录变异。这项研究采用了一种基于双色流式细胞仪的入侵抑制检测方法,针对经神经氨酸酶、胰蛋白酶和糜蛋白酶处理的红细胞进行检测,并对培养物中第一个体外复制周期收获的裂殖期进行深度 RNA 测序。对来自无症状疟疾患儿的 63 个分离株的红细胞侵袭表型进行了测定。约 80% 的分离株侵入了神经氨酸酶处理过的红细胞,但没有侵入糜蛋白酶处理过的红细胞,这表明红细胞侵入的途径与 SA 无关。16 个具有入侵表型的分离株的裂殖转录组图谱共显示了 5,136 个基因转录本,其中 85% 的分离株被预测为处于裂殖阶段。通过主成分分析对数据进行还原,得到了两个不同的转录组图谱群,分别属于依赖 SA 和不依赖 SA 的寄生虫。对这两个群组之间基因表达的差异分析表明,除了特征明显的粘附蛋白外,编码介导子实体细胞器排出的蛋白质以及几种保守的、有毒性的、与子实体相关的和输出的蛋白质的基因也出现了上调。后一类蛋白质已被证明在结构上和生理上与 RBC 表面重塑和疟疾的免疫逃避有关,因此有可能成为抗入侵的目标。
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