Abstract
Malaria control efforts have been continuously stymied by drug-resistant strains of Plasmodium falciparum, which typically originate in Southeast Asia prior to spreading into high-transmission settings in Africa. One earlier proposed explanation for Southeast Asia being a hotbed of resistance has been the hypermutability or “Accelerated Resistance to Multiple Drugs” (ARMD) phenotype, whereby multidrug-resistant Southeast Asian parasites were reported to exhibit 1,000-fold higher rates of resistance to unrelated antimalarial agents when compared to drug-sensitive parasites. However, three recent studies do not recapitulate this hypermutability phenotype. Intriguingly, genome sequencing of recently derived multidrug-resistant Cambodian isolates has identified a high proportion of DNA repair gene mutations in multidrug-resistant parasites, suggesting their potential role in shaping local parasite evolution. By adapting fluctuation assays for use in P. falciparum, we have examined the in vitro mutation rates of five recent Cambodian isolates and three reference laboratory strains. For these studies we also generated a knockout parasite line lacking the DNA repair factor Exonuclease I. In these assays, parasites were typed for their ability to acquire resistance to KAE609, currently in advanced clinical trials, yielding 13 novel mutations in the Na+/H+-ATPase PfATP4, the primary resistance determinant. We observed no evidence of hypermutability. Instead, we found evidence of a mild mutator (up to a 3.4-fold increase in mutation rate) phenotype in two artemisinin-resistant Cambodian isolates, which carry DNA repair gene mutations. We observed that one such mutation in the Mismatch Repair protein Mlh1 contributes to the mild mutator phenotype when modeled in yeast (scmlh1-P157S). Compared to basal rates of mutation, a mild mutator phenotype may provide a greater overall benefit for parasites in Southeast Asia in terms of generating drug resistance without incurring detrimental fitness costs.
Highlights
Malaria infections caused by the eukaryotic pathogen Plasmodium falciparum place an immense burden on many under-resourced nations around the world, in subSaharan Africa
Fluctuation assays estimate mutation rates based on the distribution of mutant clones that arise in parallel cultures subjected to selective pressure
We chose KAE609 for three major reasons: (1) Resistance to low-level (2.5 nM) KAE609 can be readily conferred by a number of unique single nucleotide polymorphisms (SNPs) in pfatp4 [19, 34,35,36]
Summary
Malaria infections caused by the eukaryotic pathogen Plasmodium falciparum place an immense burden on many under-resourced nations around the world, in subSaharan Africa. Over the past 15 years, considerable progress towards reducing the global burden of malaria has been achieved through the widespread adoption of highly effective artemisinin-based combination therapies (ACTs) and mosquito control [1]. These gains, are threatened by the emergence of ACT resistance in Western Cambodia [2], which has spread across Southeast Asia [3]. The emergence of artemisinin resistance in Southeast Asia recalls that of resistance to earlier first-line antimalarials, notably chloroquine (CQ) and sulfadoxine-pyrimethamine [4,5,6,7]. It was earlier hypothesized that CQ-resistant Southeast Asian strains exhibited a hypermutability phenotype compared to non-Southeast Asian counterparts [8, 9], enabling the former to acquire single nucleotide polymorphisms (SNPs) and new drug resistance traits at an accelerated rate
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