TY - JOUR
T1 - Prion protein remodelling confers an immediate phenotypic switch
AU - Satpute-Krishnan, Prasanna
AU - Serio, Tricia R.
N1 - Funding Information:
Acknowledgements This work is dedicated to the memory of A. Serio, Jr. We thank S. Lindquist, M. Hochstrasser, J. Laney, B. Glick and S. Hanes for reagents and discussions, J. Laney, K. Mowry, A. Jacobson, J. Sedivy, A. Landy, M. McKeown, A. DeLong, M. Strbuncelj, S. Langseth and Z. Zinn for comments on the manuscript, and R. Lesiak and J. Nathanson for graphics assistance. This research was supported by the National Cancer Institute and the Pew Scholars Program in the Biomedical Sciences.
PY - 2005/9/8
Y1 - 2005/9/8
N2 - In a variety of systems, proteins have been linked to processes historically limited to nucleic acids, such as infectivity and inheritance. These atypical proteins, termed prions, lack sequence homology but are collectively defined by their capacity to adopt multiple physical and therefore functional states in vivo. Newly synthesized prion protein generally adopts the form already present in the cell, and this in vivo folding bias directs the near faithful transmission of the corresponding phenotypic state. Switches between the prion and non-prion phenotypes can occur in vivo; however, the fate of existing protein during these transitions and its effects on the emergence of new traits remain major unanswered questions. Here, we determine the changes in protein-state that induce phenotypic switching for the yeast prion Sup35/[PSI+]. We show that the prion form does not need to be specified by an alternate misfolding pathway initiated during Sup35 synthesis but instead can be accessed by mature protein. This remodelling of protein from one stable form to another is accompanied by the loss of Sup35 activity, evoking a rapid change in cellular phenotype within a single cell cycle.
AB - In a variety of systems, proteins have been linked to processes historically limited to nucleic acids, such as infectivity and inheritance. These atypical proteins, termed prions, lack sequence homology but are collectively defined by their capacity to adopt multiple physical and therefore functional states in vivo. Newly synthesized prion protein generally adopts the form already present in the cell, and this in vivo folding bias directs the near faithful transmission of the corresponding phenotypic state. Switches between the prion and non-prion phenotypes can occur in vivo; however, the fate of existing protein during these transitions and its effects on the emergence of new traits remain major unanswered questions. Here, we determine the changes in protein-state that induce phenotypic switching for the yeast prion Sup35/[PSI+]. We show that the prion form does not need to be specified by an alternate misfolding pathway initiated during Sup35 synthesis but instead can be accessed by mature protein. This remodelling of protein from one stable form to another is accompanied by the loss of Sup35 activity, evoking a rapid change in cellular phenotype within a single cell cycle.
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U2 - 10.1038/nature03981
DO - 10.1038/nature03981
M3 - Article
C2 - 16148935
AN - SCOPUS:24644467295
SN - 0028-0836
VL - 437
SP - 262
EP - 265
JO - Nature
JF - Nature
IS - 7056
ER -