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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 

Some proteins, including yeast translation termination factor Sup35 (eRF3) are capable of both stress-induced liquid-liquid phase separation (LLPS) and formation of solid fibrous aggregates (amyloids). Fragmentation and propagation of amyloid fibrils generates transmissible (in yeast, heritable) self-perpetuating protein agents, termed prions. Relationships between these processes are still poorly understood. Previous literature data suggested that the ability of Sup35 orthologs to form a prion is sporadically distributed in fungal evolution, and depends on amino acid composition of Sup35 prion domain (PrD), rather than on a evolutionarily variable specific sequence. We have studied two groups of proteins: 1) fungal Sup35 PrDs of various evolutionary origins, and 2) artificially synthesized “scrambled” variants of Saccharomyces cerevisiae Sup35 PrD, that possess identical amino acid composition but different sequences. These proteins 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. Our data indicates that propagation of prion state strongly depends on the evolutionary distance from the host. In contrast, majority of proteins studied are capable of both LLPS and ability to form amyloid fibrils. These capabilities are associated with specific patterns of PrD amino acid distribution, that are broadly conserved among fungi. Notably, PrDs of different sequences differ from each other by their ability to convert from liquid condensates to amyloids, and relationship between these processes is apparently optimized in evolution. Moreover, heterotypic PrDs are can colocalize with each other within liquid condensates and influence amyloid conversion by each other. To conclude, 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. This work was supported by NSF grant 2345660. 

The Special Issue “Protein-Based Infection, Inheritance, and Memory” includes a set of experimental and review papers covering different aspects of protein memory, infection, and inheritance [...] 

Prions are transmissible self-perpetuating protein isoforms associated with diseases and heritable traits. Yeast prions and non-transmissible protein aggregates (mnemons) are frequently based on cross-β ordered fibrous aggregates (amyloids). The formation and propagation of yeast prions are controlled by chaperone machinery. Ribosome-associated chaperone Hsp70-Ssb is known (and confirmed here) to modulate formation and propagation of the prion form of the Sup35 protein [PSI+]. Our new data show that both formation and mitotic transmission of the stress-inducible prion form of the Lsb2 protein ([LSB+]) are also significantly increased in the absence of Ssb. Notably, heat stress leads to a massive accumulation of [LSB+] cells in the absence of Ssb, implicating Ssb as a major downregulator of the [LSB+]-dependent memory of stress. Moreover, the aggregated form of Gγ subunit Ste18, [STE+], behaving as a non-heritable mnemon in the wild-type strain, is generated more efficiently and becomes heritable in the absence of Ssb. Lack of Ssb also facilitates mitotic transmission, while lack of the Ssb cochaperone Hsp40-Zuo1 facilitates both spontaneous formation and mitotic transmission of the Ure2 prion, [URE3]. These results demonstrate that Ssb is a general modulator of cytosolic amyloid aggregation, whose effect is not restricted only to [PSI+]. 

Amyloids are self-perpetuating protein aggregates causing neurodegenerative diseases in mammals. Prions are transmissible protein isoforms (usually of amyloid nature). Prion features were recently reported for various proteins involved in amyloid and neural inclusion disorders. Heritable yeast prions share molecular properties (and in the case of polyglutamines, amino acid composition) with human disease-related amyloids. Fundamental protein quality control pathways, including chaperones, the ubiquitin proteasome system and autophagy are highly conserved between yeast and human cells. Crucial cellular proteins and conditions influencing amyloids and prions were uncovered in the yeast model. The treatments available for neurodegenerative amyloid-associated diseases are few and their efficiency is limited. Yeast models of amyloid-related neurodegenerative diseases have become powerful tools for high-throughput screening for chemical compounds and FDA-approved drugs that reduce aggregation and toxicity of amyloids. Although some environmental agents have been linked to certain amyloid diseases, the molecular basis of their action remains unclear. Environmental stresses trigger amyloid formation and loss, acting either via influencing intracellular concentrations of the amyloidogenic proteins or via heterologous inducers of prions. Studies of environmental and physiological regulation of yeast prions open new possibilities for pharmacological intervention and/or prophylactic procedures aiming on common cellular systems rather than the properties of specific amyloids. 

Yeast prions and mnemons are respectively transmissible and non-transmissible self-perpetuating protein assemblies, frequently based on cross-β ordered detergent-resistant aggregates (amyloids). Prions cause devastating diseases in mammals and control heritable traits in yeast. It was shown that the de novo formation of the prion form [PSI+] of yeast release factor Sup35 is facilitated by aggregates of other proteins. Here we explore the mechanism of the promotion of [PSI+] formation by Ste18, an evolutionarily conserved gamma subunit of a G-protein coupled receptor, a key player in responses to extracellular stimuli. Ste18 forms detergent-resistant aggregates, some of which are colocalized with de novo generated Sup35 aggregates. Membrane association of Ste18 is required for both Ste18 aggregation and [PSI+] induction, while functional interactions involved in signal transduction are not essential for these processes. This emphasizes the significance of a specific location for the nucleation of protein aggregation. In contrast to typical prions, Ste18 aggregates do not show a pattern of heritability. Our finding that Ste18 levels are regulated by the ubiquitin-proteasome system, in conjunction with the previously reported increase in Ste18 levels upon the exposure to mating pheromone, suggests that the concentration-dependent Ste18 aggregation may mediate a mnemon-like response to physiological stimuli.