From sequence to prion: comparison and evolutionary analysis of patterns controlling liquid-liquid phase separation and prion formation

Introduction: Some proteins, including yeast prion protein Sup35 (eRF3) are capable of both stress-induced liquid-liquid phase separation (LLPS) and formation of prion state, propagated via solid fibrous aggregates (amyloids). Relationships between these processes are still poorly understood. Previous literature data suggested that prion formation by Sup35 is sporadically distributed in fungal evolution and depends on amino acid composition of its prion domain (PrD), rather than on a specific sequence which is highly variable.

Objectives: Identify sequence patterns that control LLPS and amyloid formation by Sup35 PrD, and trace their conservation in fungal evolution.

Methods: Fungal Sup35 PrDs of various evolutionary origins, as well as artificially synthesized “scrambled” variants of Saccharomyces cerevisiae Sup35 PrD, having identical amino acid composition but different sequences, were fused to fluorophores and expressed in S. cerevisiae cells. LLPS and amyloid/prion formation were assessed by fluorescence microscopy and biochemical approaches. Amino acid sequences were analyzed by various computational algorithms.

Results/Discussion: While propagation of prion state depends on evolutionary distance from the host, both LLPS and ability to form an amyloid are associated with specific patterns of PrD amino acid distribution, that are broadly conserved among fungi. PrDs of different origins are capable of colocalizing within liquid condensates and influencing amyloid conversion by each other.

Conclusion: LLPS and amyloid properties depend on specific evolutionarily conserved sequence patterns, indicating possible important biological roles for these processes. These patterns could potentially be used to predict LLPS and prion potential in other sequence contexts.

Funding: NSF grant 2345660