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Role of Pfs47 in the dispersal of ancestral Plasmodium falciparum malaria through adaptation to different anopheline vectors.

Alvaro Molina-CruzGaspar E CanepaAnkit DwivediWeimin LiuNadia RaytselisChristophe Antonio-NkondjioBeatrice H HahnJoana C SilvaCarolina Barillas-Mury
Published in: Proceedings of the National Academy of Sciences of the United States of America (2023)
Plasmodium falciparum malaria originated when Plasmodium praefalciparum , a gorilla malaria parasite transmitted by African sylvan anopheline mosquitoes, adapted to humans. Pfs47, a protein on the parasite surface mediates P. falciparum evasion of the mosquito immune system by interacting with a midgut receptor and is critical for Plasmodium adaptation to different anopheline species. Genetic analysis of 4,971 Pfs47 gene sequences from different continents revealed that Asia and Papua New Guinea harbor Pfs47 haplotypes more similar to its ortholog in P. praefalciparum at sites that determine vector compatibility, suggesting that ancestral P. falciparum readily adapted to Asian vectors. Consistent with this observation, Pfs47-receptor gene sequences from African sylvan malaria vectors, such as Anopheles moucheti and An. marshallii , were found to share greater similarity with those of Asian vectors than those of vectors of the African An. gambiae complex. Furthermore, experimental infections provide direct evidence that transformed P. falciparum parasites carrying Pfs47 orthologs of P. praefalciparum or P. reichenowi were more effective at evading the immune system of the Asian malaria vector An. dirus than An. gambiae . We propose that high compatibility of ancestral P. falciparum Pfs47 with the receptors of Asian vectors facilitated the early dispersal of human malaria to the Asian continent, without having to first adapt to sub-Saharan vectors of the An. gambiae complex.
Keyphrases
  • plasmodium falciparum
  • gene therapy
  • aedes aegypti
  • genome wide
  • copy number
  • endothelial cells
  • gene expression
  • dengue virus
  • dna methylation
  • single cell
  • zika virus
  • induced pluripotent stem cells