Abstract
Plasmodium parasites, along with their Piroplasm relatives, have caused malaria-like illnesses in terrestrial mammals for millions of years. Several Plasmodium-protective alleles have recently evolved in human populations, but little is known about host adaptation to blood parasites over deeper evolutionary timescales. In this work, we analyze mammalian adaptation in ~500 Plasmodium- or Piroplasm- interacting proteins (PPIPs) manually curated from the scientific literature. We show that (i) PPIPs are enriched for both immune functions and pleiotropy with other pathogens, and (ii) the rate of adaptation across mammals is significantly elevated in PPIPs, compared to carefully matched control proteins. PPIPs with high pathogen pleiotropy show the strongest signatures of adaptation, but this pattern is fully explained by their immune enrichment. Several pieces of evidence suggest that blood parasites specifically have imposed selection on PPIPs. First, even non-immune PPIPs that lack interactions with other pathogens have adapted at twice the rate of matched controls. Second, PPIP adaptation is linked to high expression in the liver, a critical organ in the parasite life cycle. Finally, our detailed investigation of alpha-spectrin, a major red blood cell membrane protein, shows that domains with particularly high rates of adaptation are those known to interact specifically with P. falciparum. Overall, we show that host proteins that interact with Plasmodium and Piroplasm parasites have experienced elevated rates of adaptation across mammals, and provide evidence that some of this adaptation has likely been driven by blood parasites.
Highlights
Malaria is one of the world’s most notorious infectious diseases, responsible for billions of illnesses and millions of deaths in the last fifty years alone [1]
Malaria caused by the parasite Plasmodium falciparum remains the third-most deadly infectious disease of humans
We queried the PubMed database for scientific papers whose abstracts mentioned the name of a host gene along with the terms malaria, Plasmodium, Babesia, Theileria, Rangelia, or Cytauxzoon, the latter four being the best-studied Piroplasmid genera (Methods, Piroplasm-interacting proteins (PPIPs) Identification)
Summary
Malaria is one of the world’s most notorious infectious diseases, responsible for billions of illnesses and millions of deaths in the last fifty years alone [1]. In the specific case of humans and Plasmodium, genetic variation in about 35 red blood cell or immune proteins has been associated with protection from severe complications of malaria, if not outright resistance (reviewed in [8,9,10]). Some of these protective genes, including HBB, DARC, and GYPA, have been supported by population genetic evidence of selection in African or Southeast Asian populations within the last 75,000 years Malaria has been labeled "one of the strongest selective forces on the human genome" [9, 10], though this statement has never been quantified
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