Abstract
Currently, prion phenomena have been detected in various organisms, in addition to mammals affected by transmissible spongiform encephalopathies. In the budding yeast Saccharomyces cerevisiae, various proteins have prion properties and adopt atypical phenotypes as genetic elements, such as the Sup35 and Ure2 proteins, corresponding to the [PSI+] and [URE3] phenotypes, respectively. Each yeast prion protein has a prion-forming region rich in glutamines and/or asparagines, and can form amyloid fibrils in its prion conformation. Studies on yeast prions have revealed that the amyloid fibrils play critical roles in the life cycle of the yeast prion. First, the amyloid fibril binds the normal prion protein and catalyzes a structural conversion into the abnormal form, the key event of the prion phenomenon. Second, the amyloid fibril is related to the strain differences of the prion phenotypes, by its substructural differences. Third, the number of prion elements multiplies by the fragmentation of amyloid fibrils, which is mediated by a chaperone system in which Hsp104 plays a central role, and the prion elements are distributed to the daughter cells during cell division. Moreover, heterologous prion-prion communications may occur, probably by cross-seeding of amyloid fibrils among different prion proteins in the same yeast cell. Findings achieved by yeast prion studies are making great contributions toward understanding the characteristics of amyloid fibrils and prions.
Keywords: Prion, prion protein, yeast prion, amyloid
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