Abstract
Prion strains (or variants) are structurally distinct amyloid conformations arising from a single polypeptide sequence. The existence of prion strains has been well documented in mammalian prion diseases. In many cases, prion strains manifest as variation in disease progression and pathology, and in some cases, these prion strains also show distinct biochemical properties. Yet, the underlying basis of prion propagation and the extent of conformational possibilities available to amyloidogenic proteins remain largely undefined. Prion proteins in yeast that are also capable of maintaining multiple self-propagating structures have provided much insight into prion biology. Here, we explore the vast structural diversity of the yeast prion [RNQ+] in Saccharomyces cerevisiae. We screened for the formation of [RNQ+] in vivo, allowing us to calculate the rate of spontaneous formation as ~2.96x10-6, and successfully isolate several different [RNQ+] variants. Through a comprehensive set of biochemical and biological analyses, we show that these prion variants are indeed novel. No individual property or set of properties, including aggregate stability and size, was sufficient to explain the physical basis and range of prion variants and their resulting cellular phenotypes. Furthermore, all of the [RNQ+] variants that we isolated were able to facilitate the de novo formation of the yeast prion [PSI+], an epigenetic determinant of translation termination. This supports the hypothesis that [RNQ+] acts as a functional amyloid in regulating the formation of [PSI+] to produce phenotypic diversity within a yeast population and promote adaptation. Collectively, this work shows the broad spectrum of available amyloid conformations, and thereby expands the foundation for studying the complex factors that interact to regulate the propagation of distinct aggregate structures.
Highlights
Protein misfolding disorders refer broadly to a class of human diseases associated with the failure of a protein or peptide to adopt its native, functional conformation [1]
These highly ordered arrangements of β sheets are formed from non-covalent interactions of neighboring polypeptides in which the β strands run perpendicular to the fibril axis [1,3]
Such amyloid polymorphism has been most studied in the context of prion strains, but recent data suggest that it is a common feature of many amyloidogenic proteins [6,7,8]
Summary
Protein misfolding disorders refer broadly to a class of human diseases associated with the failure of a protein or peptide to adopt its native, functional conformation [1]. Amyloid fibers typically form as a β sheet-rich structure in a self-replicating process [2] These highly ordered arrangements of β sheets are formed from non-covalent interactions of neighboring polypeptides in which the β strands run perpendicular to the fibril axis [1,3]. This fundamental architecture is shared among a variety of proteins associated with unrelated protein conformational disorders, including Alzheimer’s disease and Type II diabetes [4]. Such amyloid polymorphism has been most studied in the context of prion strains, but recent data suggest that it is a common feature of many amyloidogenic proteins [6,7,8]
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