Consequences of larval competition and exposure to permethrin for the development of the rodent malaria Plasmodium berghei in the mosquito Anopheles gambiae

Hauser, Gaël; Thiévent, Kevin; Koella, Jacob C.

doi:10.1186/s13071-020-3983-9

Cited by 12 publications

(11 citation statements)

References 52 publications

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“…While most insects are declining 2 , many mosquito species are thriving 3 , 4 . Recent laboratory and mesocosm studies provided important clues suggesting that anthropogenic disturbances can promote population growth of several pathogen-transmitting mosquito species, or disease vectors 5 - 8 , and potentially mediate interactions between mosquito species 9 , their hosts 10 , their pathogens 11 , 12 , and their predators 13 . This hints that, if these patterns hold true for natural systems, the way humans influence their local environment presents a critical driver of disease risk 14 .…”

Section: Introductionmentioning

confidence: 99%

Human practices promote presence and abundance of disease-transmitting mosquito species

Schrama

Hunting

Beechler

et al. 2020

Sci Rep

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Humans alter the environment at unprecedented rates through habitat destruction, nutrient pollution and the application of agrochemicals. this has recently been proposed to act as a potentially significant driver of pathogen-carrying mosquito species (disease vectors) that pose a health risk to humans and livestock. Here, we use a unique set of locations along a large geographical gradient to show that landscapes disturbed by a variety of anthropogenic stressors are consistently associated with vector-dominated mosquito communities for a wide range of human and livestock infections. this strongly suggests that human alterations to the environment promote the presence and abundance of disease vectors across large spatial extents. As such, it warrants further studies aimed at unravelling mechanisms underlying vector prevalence in mosquito communities, and opens up new opportunities for preventative action and predictive modelling of vector borne disease risks in relation to degradation of natural ecosystems. Habitat destruction, chemical pollution, and climate change are ongoing human disturbances 1 that have resulted in worldwide shifts in insect communities 2. While most insects are declining 2 , many mosquito species are thriving 3,4. Recent laboratory and mesocosm studies provided important clues suggesting that anthropogenic disturbances can promote population growth of several pathogen-transmitting mosquito species, or disease vectors 5-8 , and potentially mediate interactions between mosquito species 9 , their hosts 10 , their pathogens 11,12 , and their predators 13. This hints that, if these patterns hold true for natural systems, the way humans influence their local environment presents a critical driver of disease risk 14. Field data in natural systems has largely focused on the influence of climate-temperature and precipitationin driving the abundance of single species or vector groups 15-19. These studies constitute an important foundation for mechanistic models and risk maps to anticipate disease outbreaks such as malaria, chikungunya and Zika 20,21. Mosquito abundance and composition can also vary across locations and land use types 22-27. However, many comparisons rely on opportunistic sampling across different time periods or targeted sampling at locations to maximize collections 28 , but not always 29,30. Here, we use a paired sampling design to show that human activities beyond climate are strongly associated with high abundances of known vectors across large spatial extents. Kruger National Park (KNP) is the largest natural reserve in South Africa and is fringed with rural and urbanizing areas. The mosaic of waterbodies along its 400 km north-south gradient provides a unique opportunity to assess the effect of human disturbances on mosquito population dynamics and community composition. We simultaneously sampled representative waterbodies within paired sites inside and outside the national park in four regions (Fig. 1); the paired sites have similar geomorphology and climatic conditions (Table S...

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Section: Introductionmentioning

confidence: 99%

Human practices promote presence and abundance of disease-transmitting mosquito species

Schrama

Hunting

Beechler

et al. 2020

Sci Rep

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“…Additionally, it has been shown that the adaptation of anopheline vectors to polluted water can influence adult emergence times 28 – 30 . Similarly, exposure to sub-lethal doses of insecticides has been reported to increase the life span of infected mosquitoes 31 . In the current study, we found that presence of the sesquiterpene lactone parthenin released from the root exudate of P. hysterophorus to the oviposition site environment influenced mosquito bionomics.…”

Section: Discussionmentioning

confidence: 97%

Root exudate chemical cues of an invasive plant modulate oviposition behavior and survivorship of a malaria mosquito vector

Milugo

Tchouassi

Kavishe

et al. 2021

Sci Rep

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Gravid female Anopheles gambiae mosquitoes identify suitable oviposition sites through a repertoire of cues, but the influence of allelochemicals, especially root phytochemicals in modulating this behavior and impacting subsequent progeny bionomics remains unexplored. We addressed these questions in the malaria vector Anopheles gambiae and its invasive host plant Parthenium hysterophorus. Using chemical analysis combined with laboratory behavioral assays, we demonstrate that a blend of terpenes, namely α-pinene, α-phellandrene, β-phellandrene, 3-carene and (E)-caryophyllene emitted from P. hysterophorus root exudate treated-water attracted gravid females. However, fewer eggs (55%) hatched in this treatment than in control water (66%). The sesquiterpene lactone parthenin, identified in both the natural aquatic habitat harboring P. hysterophorus and root exudate-treated water was found to be responsible for the ovicidal effect. Moreover, larvae exposed to parthenin developed 2 to 3 days earlier but survived 4 to 5 days longer as adults (median larval survival time = 9 days (all replicates);11 to 12 days as adults) than the non-exposed control (median larval survival time = 11 days (reps 1 & 2), 12 days (rep 3); 6 to 7 days as adults). These results improve our understanding of the risk and benefits of oviposition site selection by gravid An. gambiae females and the role root exudate allelochemicals could play on anopheline bionomics, with potential implications in malaria transmission.

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“…The sublethal exposure to permethrin at larvae or adults of An. gambiae reduced the infection prevalence by Plasmodium berghei [94]. These studies with laboratory-consolidated models pointed that the level of interference of the exposure of the larvae to insecticides in the process of infection of mosquitoes depends on the species of both vector and pathogen and the mode of action of the compounds.…”

Section: Sublethal Exposure Of Larvae To Insecticidesmentioning

confidence: 96%

“…Studies have been carried out considering the interaction between adult mosquitoes derived from exposed larvae and malaria-causing parasites [86,87,94]. For instance, the exposure of Culex pipiens to the neonicotinoid imidacloprid did not affect the life history traits of individuals nor the susceptibility of adults to infection by avian malaria parasite (Plasmodium gallinaceum) [86].…”

Section: Sublethal Exposure Of Larvae To Insecticidesmentioning

confidence: 99%

Implications of Sublethal Insecticide Exposure and the Development of Resistance on Mosquito Physiology, Behavior, and Pathogen Transmission

Andreazza

Oliveira

Martins

2021

Insects

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For many decades, insecticides have been used to control mosquito populations in their larval and adult stages. Although changes in the population genetics, physiology, and behavior of mosquitoes exposed to lethal and sublethal doses of insecticides are expected, the relationships between these changes and their abilities to transmit pathogens remain unclear. Thus, we conducted a comprehensive review on the sublethal effects of insecticides and their contributions to insecticide resistance in mosquitoes, with the main focus on pyrethroids. We discuss the direct and acute effects of sublethal concentrations on individuals and populations, the changes in population genetics caused by the selection for resistance after insecticide exposure, and the major mechanisms underlying such resistance. Sublethal exposures negatively impact the individual’s performance by affecting their physiology and behavior and leaving them at a disadvantage when compared to unexposed organisms. How these sublethal effects could change mosquito population sizes and diversity so that pathogen transmission risks can be affected is less clear. Furthermore, despite the beneficial and acute aspects of lethality, exposure to higher insecticide concentrations clearly impacts the population genetics by selecting resistant individuals, which may bring further and complex interactions for mosquitoes, vertebrate hosts, and pathogens. Finally, we raise several hypotheses concerning how the here revised impacts of insecticides on mosquitoes could interplay with vector-mediated pathogens’ transmission.

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Consequences of larval competition and exposure to permethrin for the development of the rodent malaria Plasmodium berghei in the mosquito Anopheles gambiae

Cited by 12 publications

References 52 publications

Human practices promote presence and abundance of disease-transmitting mosquito species

Human practices promote presence and abundance of disease-transmitting mosquito species

Root exudate chemical cues of an invasive plant modulate oviposition behavior and survivorship of a malaria mosquito vector

Implications of Sublethal Insecticide Exposure and the Development of Resistance on Mosquito Physiology, Behavior, and Pathogen Transmission

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