Plasmodium falciparum genetic diversity in coincident human and mosquito hosts

Abstract

AbstractPopulation genetic diversity of P. falciparum antigenic loci is high despite large bottlenecks in population size during the parasite life cycle. The extent of this diversity in human blood-stage infections, following expansion from a small number of liver-stage schizonts, has been well described. However, little is known about parasite genetic diversity in the vector, where a similar bottleneck and expansion occurs following parasite mating and where parasite genotypes from several different human infections may accumulate. We assessed parasite genetic diversity within human and mosquito P. falciparum infections collected from the same households during a 14-month longitudinal cohort study using amplicon deep sequencing of two antigenic gene fragments (ama1 and csp). To a prior set of infected humans (n=1175/2813; 86.2% sequencing success) and mosquito abdomens (n=199/1448; 95.5% sequencing success), we added sequences from infected mosquito heads (n=134/1448; 98.5% sequencing success). Across all sample types we observed 456 ama1 and 289 csp unique haplotypes. While both hosts contained many rare haplotypes, population genetic metrics indicated that the overall and sample-level parasite populations were more diverse in mosquitoes than in humans, and infections were more likely to harbor a dominant haplotype in humans than in mosquitoes (based on relative read abundance). Finally, within a given mosquito there was little overlap in genetic composition of abdomen and head infections, suggesting that infections may be cleared from the abdomen during a mosquito’s lifespan. Taken together, our observations provide evidence for the role of the mosquito vector in maintaining sequence diversity of malaria parasite populations.Significance statementConcurrent infections with multiple strains of Plasmodium falciparum, the leading causative agent of death due to malaria, are common in highly endemic regions. During transitions within and between the parasite’s mosquito and human hosts, population bottlenecks occur, and distinct parasite strains may have differential fitness in the various environments encountered. These bottlenecks and fitness differences may lead to differences in strain prevalence and diversity between hosts. We investigated differences in genetic diversity between P. falciparum parasites in human and mosquito hosts and found that, compared to human parasite populations and infections, mosquito populations and infections were more diverse. This suggests that the mosquito vector may play a role in in maintaining sequence diversity in malaria parasite populations.