Abstract
The propensity of proteins to form beta-sheet-rich amyloid fibrils is related to a variety of biological phenomena, including a number of human neurodegenerative diseases and prions. A subset of amyloidogenic proteins forms amyloid fibrils through glutamine/asparagine (Q/N)-rich domains, such as pathogenic polyglutamine (poly(Q)) proteins involved in neurodegenerative disease, as well as yeast prions. In the former, the propensity of an expanded poly(Q) tract to abnormally fold confers toxicity on the respective protein, leading to neuronal dysfunction. In the latter, Q/N-rich prion domains mediate protein aggregation important for epigenetic regulation. Here, we investigated the relationship between the pathogenic ataxin-3 protein of the human disease spinocerebellar ataxia type 3 (SCA3) and the yeast prion Sup35, using Drosophila as a model system. We found that the capacity of the Sup35 prion domain to mediate protein aggregation is conserved in Drosophila. Although select yeast prions enhance poly(Q) toxicity in yeast, the Sup35N prion domain suppressed poly(Q) toxicity in the fly. Suppression required the oligopeptide repeat of the Sup35N prion domain, which is critical for prion properties in yeast. These results suggest a trans effect of prion domains on pathogenic poly(Q) disease proteins in a multicellular environment and raise the possibility that Drosophila may allow studies of prion mechanisms.
Highlights
Ation with yeast, the Q/N-rich domains are critical for prion states, which are characterized by the capacity of the prion protein to pass on dominant, epigenetic effects through changes in protein conformation (4 – 6)
Our findings suggest that Sup35 prion aggregation is conserved in the cellular environment of Drosophila and implicate a trans effect of the Sup35 prion conformation on the toxicity of pathogenic poly(Q) protein
Sup35N showed characteristics reminiscent of prion states, we investigated potential interactions between Sup35N and poly(Q) protein
Summary
Ation with yeast, the Q/N-rich domains are critical for prion states, which are characterized by the capacity of the prion protein to pass on dominant, epigenetic effects through changes in protein conformation (4 – 6). The Sup35N Prion Domain Forms Aggregates and Is Recruited into Poly(Q) Inclusions in Drosophila S2 Cells—The yeast protein Sup35 has three distinctive domains [24].
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