Mosquito microevolution drives Plasmodium falciparum dynamics.
Markus GildenhardEvans K RonoAssetou DiarraAnne BoissièrePriscila BascunanPaola Carrillo-BustamanteDjeneba CamaraHanne KrügerModibo MarikoRamata MarikoPaul MirejiSandrine E NsangoJulien PomponYara ReisMartin K RonoPamela B SedaJanis ThailayilAlou TraorèCynthia V YaptoParfait Awono-AmbeneRoch K DabiréAbdulaye DiabatéDaniel K MasigaFlaminia CatterucciaIsabelle MorlaisMouctar DialloDjibril SangareElena A LevashinaPublished in: Nature microbiology (2019)
Malaria, a major cause of child mortality in Africa, is engendered by Plasmodium parasites that are transmitted by anopheline mosquitoes. Fitness of Plasmodium parasites is closely linked to the ecology and evolution of its anopheline vector. However, whether the genetic structure of vector populations impacts malaria transmission remains unknown. Here, we describe a partitioning of the African malaria vectors into generalists and specialists that evolve along ecological boundaries. We next identify the contribution of mosquito species to Plasmodium abundance using Granger causality tests for time-series data collected over two rainy seasons in Mali. We find that mosquito microevolution, defined by changes in the genetic structure of a population over short ecological timescales, drives Plasmodium dynamics in nature, whereas vector abundance, infection prevalence, temperature and rain have low predictive values. Our study demonstrates the power of time-series approaches in vector biology and highlights the importance of focusing local vector control strategies on mosquito species that drive malaria dynamics.