Abstract
Prions are a singular subset of proteins able to switch between a soluble conformation and a self-perpetuating amyloid state. Traditionally associated with neurodegenerative diseases, increasing evidence indicates that organisms exploit prion-like mechanisms for beneficial purposes. The ability to transit between conformations is encoded in the so-called prion domains, long disordered regions usually enriched in glutamine/asparagine residues. Interestingly, Plasmodium falciparum, the parasite that causes the most virulent form of malaria, is exceptionally rich in proteins bearing long Q/N-rich sequence stretches, accounting for roughly 30% of the proteome. This biased composition suggests that these protein regions might correspond to prion-like domains (PrLDs) and potentially form amyloid assemblies. To investigate this possibility, we performed a stringent computational survey for Q/N-rich PrLDs on P. falciparum. Our data indicate that ∼10% of P. falciparum protein sequences have prionic signatures, and that this subproteome is enriched in regulatory proteins, such as transcription factors and RNA-binding proteins. Furthermore, we experimentally demonstrate for several of the identified PrLDs that, despite their disordered nature, they contain inner short sequences able to spontaneously self-assemble into amyloid-like structures. Although the ability of these sequences to nucleate the conformational conversion of the respective full-length proteins should still be demonstrated, our analysis suggests that, as previously described for other organisms, prion-like proteins might also play a functional role in P. falciparum.
Highlights
Malaria caused approximately 445,000 deaths in 2016 and in the latest World Malaria Report (November 2017) the number of cases was estimated to be as many as 216 million
Any predicted prion-like domains (PrLDs) in our subproteome would fulfill the following requirements: being Q/N-rich, disordered (PAPA includes the disorder predictor FoldIndex; Prilusky et al, 2005), compositionally similar to yeast prion domains (PrDs) and contain a short sequence stretch able to facilitate its conversion into an amyloidlike state; we have generically named these stretches “soft amyloid cores,” because their amyloid propensity is significantly lower than the classical amyloid regions of pathogenic proteins, but still enough to promote protein self-assembly (Batlle et al, 2017)
This value is lower than previously estimated applying other computational approaches based only in Q/N richness (Singh et al, 2004) or than the one estimated using only compositional similitude to yeast PrDs with PAPA, which predicts 22.5% of the parasite proteins as prion-like
Summary
Malaria caused approximately 445,000 deaths in 2016 and in the latest World Malaria Report (November 2017) the number of cases was estimated to be as many as 216 million. The global response to malaria is considered one of the world’s great public health achievements, the spread of resistance against anti-malarial drugs and insecticides, has stalled the incidence and mortality decline since 2014. Plasmodium falciparum is the species responsible for 85% of the malaria cases, causing the most severe form of the disease. The complete sequencing of P. falciparum genome has revealed some specific features that may shed light onto the biology and biochemistry of this deadly parasite (Gardner et al, 2002). A striking biased composition of its DNA was observed, with an overall AT content of 80.6%, a comparable AT enrichment only being observed in the social amoeba Dictyostelium discoideum (Eichinger et al, 2005). In P. falciparum, AT-rich codons present a significant preference toward encoding asparagines (N) over lysines, explaining why ∼30% of its proteome is rich in long low complexity regions displaying an exceptional abundance of asparagine residues (Aravind et al, 2003; Singh et al, 2004)
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