Malian children infected with Plasmodium ovale and Plasmodium falciparum display very similar gene expression profiles

Abstract

AbstractPlasmodium parasites caused 241 million cases of malaria and over 600,000 deaths in 2020. Both P. falciparum and P. ovale are endemic to Mali and cause malaria illness, with P. falciparum infections typically being more severe. Here, we sequenced RNA from nine pediatric blood samples collected during uncomplicated, symptomatic infections with either P. falciparum or P. ovale and characterized the host and parasite gene expression profiles. We found that human gene expression varies more between individuals than according to the parasite species causing the infection, while parasite gene expression profiles cluster by species. Additionally, we characterized DNA polymorphisms of the parasites directly from the RNA-seq reads and found comparable levels of genetic diversity in both species despite dramatic differences in prevalence. Our results provide unique insights into host-pathogen interactions during malaria infections and their variations according to the infecting Plasmodium species, which will be critical to develop better elimination strategies against all human Plasmodium parasites.Author SummaryMultiple species of Plasmodium parasites can cause human malaria. Most studies and elimination efforts target P. falciparum, the most common cause of malaria worldwide and the species responsible for the vast majority of the mortality. Other Plasmodium species, such as P. ovale, typically lead to less severe forms of the disease but little is known about the molecular mechanisms at play during malaria infections with different parasites. We analyzed host and parasite gene expression from children successively infected with P. ovale and P. falciparum and found that, while the parasite gene expression differed significantly, the transcriptional profiles of the host immune cells were similar in P. ovale or P. falciparum infections. This suggests that infected individuals respond to uncomplicated malaria infections similarly, regardless of the Plasmodium species causing the infection, and that alternative immune processes may become important during the progression to severe P. falciparum malaria (rather than being inherent features of P. falciparum infections). Additionally, we observed similar levels of genetic diversity among P. ovale and P. falciparum parasites, suggesting that the P. ovale population might be larger than currently thought, possibly due to extensive misdiagnosis or the existence of hidden reservoirs of parasites.