Timing malaria transmission with mosquito fluctuations

Pigeault, Romain; Caudron, Quentin; Nicot, Antoine; Rivero, Ana; Gandon, Sylvain

doi:10.1002/evl3.61

Cited by 45 publications

(52 citation statements)

References 49 publications

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“…We reveal that: (i) gametocytes are less numerous in the host's blood at night but night time gametocytes are more likely to develop to oocysts; (ii) the greater infectivity of night time gametocytes does not increase the probability that mosquitoes become infected or result in more intense infection at the oocyst stage; (iii) independently of parasite time of day, mosquitoes fed at night are less likely to be infected with oocysts; and (iv) the greater infectivity of night time gametocytes does not alter the probability of mosquitoes harbouring sporozoites but does increase sporozoite burden in mosquitoes fed in their daytime. Our findings are broadly consistent with a recent study on the avian malaria Plasmodium relictum [ 16 ], which also reveals that transmission (to oocyst stage) is more efficient in the late afternoon and night (when vectors are active) than at noon or early morning. However, in this study, enhanced transmission is associated with elevated parasite density in the avian host's blood in the late afternoon.…”

Section: Discussionsupporting

confidence: 93%

Adaptive periodicity in the infectivity of malaria gametocytes to mosquitoes

et al. 2018

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Daily rhythms in behaviour, physiology and molecular processes are expected to enable organisms to appropriately schedule activities according to consequences of the daily rotation of the Earth. For parasites, this includes capitalizing on periodicity in transmission opportunities and for hosts/vectors, this may select for rhythms in immune defence. We examine rhythms in the density and infectivity of transmission forms (gametocytes) of rodent malaria parasites in the host's blood, parasite development inside mosquito vectors and potential for onwards transmission. Furthermore, we simultaneously test whether mosquitoes exhibit rhythms in susceptibility. We reveal that at night, gametocytes are twice as infective, despite being less numerous in the blood. Enhanced infectiousness at night interacts with mosquito rhythms to increase sporozoite burdens fourfold when mosquitoes feed during their rest phase. Thus, changes in mosquito biting time (owing to bed nets) may render gametocytes less infective, but this is compensated for by the greater mosquito susceptibility.

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Section: Discussionsupporting

confidence: 93%

Adaptive periodicity in the infectivity of malaria gametocytes to mosquitoes

et al. 2018

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“…mosquito biting rate, host immunity, mosquito susceptibility) are equal [61]. Although time-of-day may affect transmission efficacy [81,82], host, parasite and mosquito time-of-day have been controlled for in our experiment thus allowing for comparison of transmission probability between groups. The proportional change in transmission probability resulting from changing vs. not changing conversion, is estimated as transmission probabilities of drug treated groups relative to that of the untreated groups.…”

Section: Discussionmentioning

confidence: 99%

“…From [61], and assuming all else equal with respect to other factors that could influence transmission (e.g. vector biting rates, host immunity, vector susceptibility, time-of-day of transmissions [61,81,82]), the probability of transmission for a given gametocyte density, G(t) is given by exp ½À 12:69 þ 3:6 log 10 GðtÞ� 1 þ exp½À 12:69 þ 3:6 log 10 GðtÞ� ð4Þ…”

Section: Mathematical Modelmentioning

confidence: 99%

Adaptive plasticity in the gametocyte conversion rate of malaria parasites

et al. 2018

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Sexually reproducing parasites, such as malaria parasites, experience a trade-off between the allocation of resources to asexual replication and the production of sexual forms. Allocation by malaria parasites to sexual forms (the conversion rate) is variable but the evolutionary drivers of this plasticity are poorly understood. We use evolutionary theory for life histories to combine a mathematical model and experiments to reveal that parasites adjust conversion rate according to the dynamics of asexual densities in the blood of the host. Our model predicts the direction of change in conversion rates that returns the greatest fitness after perturbation of asexual densities by different doses of antimalarial drugs. The loss of a high proportion of asexuals is predicted to elicit increased conversion (terminal investment), while smaller losses are managed by reducing conversion (reproductive restraint) to facilitate within-host survival and future transmission. This non-linear pattern of allocation is consistent with adaptive reproductive strategies observed in multicellular organisms. We then empirically estimate conversion rates of the rodent malaria parasite Plasmodium chabaudi in response to the killing of asexual stages by different doses of antimalarial drugs and forecast the short-term fitness consequences of these responses. Our data reveal the predicted non-linear pattern, and this is further supported by analyses of previous experiments that perturb asexual stage densities using drugs or within-host competition, across multiple parasite genotypes. Whilst conversion rates, across all datasets, are most strongly influenced by changes in asexual density, parasites also modulate conversion according to the availability of red blood cell resources. In summary, increasing conversion maximises short-term transmission and reducing conversion facilitates in-host survival and thus, future transmission. Understanding patterns of parasite allocation to reproduction matters because within-host replication is responsible for disease symptoms and between-host transmission determines disease spread.

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“…Given that rhythms of parasites and mosquitoes each affect malaria transmission in lab experiments 54,55 , what are the likely epidemiological consequences? Recent work suggests that mosquitoes are more susceptible to infection when they feed in the daytime and parasites are more infectious at night 54 .…”

Section: Rhythms In Parasite Offencementioning

confidence: 99%

The evolutionary ecology of circadian rhythms in infection

et al. 2019

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Biological rhythms coordinate organisms' activities with daily rhythms in the environment. For parasites, this includes rhythms in both the external abiotic environment and the within-host biotic environment. Hosts exhibit rhythms in behaviours and physiologies, including immune responses, and parasites exhibit rhythms in traits underpinning virulence and transmission. Yet, the evolutionary and ecological drivers of rhythms in traits underpinning host defence and parasite offence are largely unknown. Here, we explore how hosts use rhythms to defend against infection, why parasites have rhythms, and whether parasites can manipulate host clocks to their own ends. Harnessing host rhythms or disrupting parasite rhythms could be exploited for clinical benefit; we propose an interdisciplinary effort to drive this emerging field forward. Circadian rhythms have long been taken for granted by science. Indeed, the first observation of a clock-controlled behaviour (leaf opening and closing in Mimosa pudica) was not recorded until the 18 th century 1. Following the fundamental observation that organisms can adaptively anticipate daily rhythms in their environment, the field of "chronobiology" took off in the mid-20 th century with a focus on evolutionary and ecological questions. However, the advent of genetic tools a few decades later shifted the remit to determining the molecular and genetic workings of circadian clocks. Yet, despite their assumed major impact on fitness, circadian rhythms remain overlooked in evolutionary ecology 2-4. Here, we propose that the integration of chronobiology and evolutionary ecology return 2 to its roots to tackle a topic of growing and applied interest; the role of rhythms in host-parasite interactions. Note that we use the term "parasite" to collectively refer to all agents of infection (e.g. single-celled and multicellular eukaryotes, bacteria, viruses). One of the most fundamental ecological interactions is that between hosts and parasites. Research from diverse taxa (plants, mammals, and insects) reveals that host clocks drive daily rhythms in immune defences, disease severity and spread 5,6. Parasites display daily rhythms in traits underpinning within-host survival and between-host transmission 7,8. Rhythms in parasite activities and in host responses to infection could provide an advantage to parasites, hosts, both, or neither. To what extent parasites and hosts are in control of their own and/or each other's rhythms is also poorly understood. Understanding the evolution (and possibly, coevolution) of rhythms may enable vaccines and drugs to take advantage of rhythmic vulnerabilities in parasites or harness host rhythms to improve efficacy and reduce drug toxicity. For such interventions to be robust to parasite evolution, understanding how host-parasite interactions shape rhythms in hosts and parasites is necessary 7. Key questions include how rhythms in diverse host traits contribute to defence, how parasites cope with exposure to their host's rhythms, and whether hosts and parasit...

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Timing malaria transmission with mosquito fluctuations

Cited by 45 publications

References 49 publications

Adaptive periodicity in the infectivity of malaria gametocytes to mosquitoes

Adaptive periodicity in the infectivity of malaria gametocytes to mosquitoes

Adaptive plasticity in the gametocyte conversion rate of malaria parasites

The evolutionary ecology of circadian rhythms in infection

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