Genetic Study of Interactions Between the Cytoskeletal Assembly Protein Sla1 and Prion-Forming Domain of the Release Factor Sup35 (eRF3) in Saccharomyces cerevisiae

Genetic Study of Interactions Between the Cytoskeletal Assembly Protein Sla1 and Prion-Forming Domain of the Release Factor Sup35 (eRF3) in Saccharomyces cerevisiae

Peggy A. Bailleul^a, Gary P. Newnam^a, Judith N. Steenbergen^a, and Yury O. Chernoff^a
^a School of Biology, Georgia Institute of Technology, Atlanta, Georgia 30332-0230

Corresponding author: Yury O. Chernoff, School of Biology, Georgia Institute of Technology, 310 Ferst Dr., Rm. 303, Atlanta, GA 30332-0230., yc22{at}prism.gatech.edu (E-mail)

Communicating editor: A. G. HINNEBUSCH

Striking similarities between cytoskeletal assembly and the"nucleated polymerization" model of prion propagation suggestthat similar or overlapping sets of proteins may assist in bothprocesses. We show that the C-terminal domain of the yeast cytoskeletalassembly protein Sla1 (Sla1C) specifically interacts with theN-terminal prion-forming domain (Sup35N) of the yeast releasefactor Sup35 (eRF3) in the two-hybrid system. Sla1C and severalother Sup35N-interacting proteins also exhibit two-hybrid interactionswith the poly-Gln-expanded N-proximal fragment of human huntingtin,which promotes Huntington disease-associated aggregation. TheSup35N-Sla1C interaction is inhibited by Sup35N alterationsthat make Sup35 unable to propagate the [PSI⁺] state and bythe absence of the chaperone protein Hsp104, which is essentialfor [PSI] propagation. In a Sla1^- background, [PSI] curing bydimethylsulfoxide or excess Hsp104 is increased, while translationalreadthrough and de novo [PSI] formation induced by excess Sup35or Sup35N are decreased. These data show that, in agreementwith the proposed function of Sla1 during cytoskeletal formation,Sla1 assists in [PSI] formation and propagation, but is notrequired for these processes. Sla1^- strains are sensitive tosome translational inhibitors, and some sup35 mutants, obtainedin a Sla1^- background, are sensitive to Sla1, suggesting thatthe interaction between Sla1 and Sup35 proteins may play a rolein the normal function of the translational apparatus. We hypothesizethat Sup35N is involved in regulatory interactions with intracellularstructural networks, and [PSI] prion may be formed as a by-productof this process.

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