Abstract
The study of prions as infectious aggregates dates several decades. From its original formulation, the definition of a prion has progressively changed to the point that many aggregation-prone proteins are now considered bona fide prions. RNA molecules, not included in the original ‘protein-only hypothesis’, are also being recognized as important factors contributing to the ‘prion behaviour’, that implies the transmissibility of an aberrant fold. In particular, an association has recently emerged between aggregation and the assembly of prion-like proteins in RNA-rich complexes, associated with both physiological and pathological events. Here, we discuss the historical rising of the concept of prion-like domains, their relation to RNA and their role in protein aggregation. As a paradigmatic example, we present the case study of TDP-43, an RNA-binding prion-like protein associated with amyotrophic lateral sclerosis. Through this example, we demonstrate how the current definition of prions has incorporated quite different concepts making the meaning of the term richer and more stimulating. An important message that emerges from our analysis is the dual role of RNA in protein aggregation, making RNA, that has been considered for many years a ‘silent presence’ or the ‘stone guest’ of protein aggregation, an important component of the process.
Highlights
This review deals with the concept of prion-like proteins and/or domains
Several other human RNA-binding proteins with prion-like domains associated with disease were identified including, for instance, FUS, TDP-43 and TAF15 that are linked to amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) [86] (Figure 2B)
We have discussed how the concept of prions has evolved and covers almost all examples of amyloid-prone proteins, extending from TDP43 and FUS to cover other macromolecules involved in protein aggregation such as A, ␣-synuclein and polyglutamine containing proteins, which have not been covered in this review [16]
Summary
This review deals with the concept of prion-like proteins and/or domains. This concept dates the 90s when Wickner found proteins in yeast with a behaviour similar to that observed for vertebrate prions [1]. We explore the concept of prion-like proteins and their link to RNA-binding properties and liquid-liquid phase separation. The essentiality of the PrPC to PrPSc structural conversion is at the base of the original ‘protein-only’ hypothesis according to which the infectious component of the prion disease would consist solely of proteins without any nucleic acid element [36].
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