Abstract
Drug resistance has been reported against all antimalarial drugs, and while parasites can evolve classical resistance mechanisms (e.g., efflux pumps), it is also possible that changes in life history traits could help parasites evade the effects of treatment. The life history of malaria parasites is governed by an intrinsic resource allocation problem: specialized stages are required for transmission, but producing these stages comes at the cost of producing fewer of the forms required for within‐host survival. Drug treatment, by design, alters the probability of within‐host survival, and so should alter the costs and benefits of investing in transmission. Here, we use a within‐host model of malaria infection to predict optimal patterns of investment in transmission in the face of different drug treatment regimes and determine the extent to which alternative patterns of investment can buffer the fitness loss due to drugs. We show that over a range of drug doses, parasites are predicted to adopt “reproductive restraint” (investing more in asexual replication and less in transmission) to maximize fitness. By doing so, parasites recoup some of the fitness loss imposed by drugs, though as may be expected, increasing dose reduces the extent to which altered patterns of transmission investment can benefit parasites. We show that adaptation to drug‐treated infections could result in more virulent infections in untreated hosts. This work emphasizes that in addition to classical resistance mechanisms, drug treatment generates selection for altered parasite life history. Understanding how any shifts in life history will alter the efficacy of drugs, as well as any limitations on such shifts, is important for evaluating and predicting the consequences of drug treatment.
Highlights
Malaria parasites (Plasmodium spp.) remain one of the most severe and common causes of human disease (White, Pukrittayakamee, et al, 2014)
In addition to classical resistance mechanisms, we have shown that drug treatment can select for altered life history of malaria parasites and, (a)
Our work predicts that reproductive restraint is adaptive in drug-treated infections, allowing parasites to partially compensate for the reductions in asexual densities caused by the drug
Summary
Malaria parasites (Plasmodium spp.) remain one of the most severe and common causes of human disease (White, Pukrittayakamee, et al, 2014). While conversion rate can change plastically in response to changing environmental conditions, data suggest that there is parasite genetic variation for patterns of conversion (Pollitt et al, 2011; Birget, Repton, O’Donnel, Schneider, & Reece, 2017) and that this variation can be selected upon (reviewed in Bousema & Drakeley, 2011) It is well known, for example, that serial passage and culture experiments, which by their nature select for faster within- host replication, result in reduced transmission investment (Dearsly, Sinden, & Self, 1990; Sinha et al, 2014; reviewed in Carter et al, 2013). We quantify the extent to which altering life history according to these optimal patterns can buffer against the effects of drugs and we evaluate the consequences for host health and onward transmission
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