Yeast prion‐protein, sup35, fibril formation proceeds by addition and substraction of oligomers

S Narayanan, S Walter, B Reif - Chembiochem, 2006 - Wiley Online Library
S Narayanan, S Walter, B Reif
Chembiochem, 2006Wiley Online Library
In analogy to human prions, a domain of the translation‐termination protein in
Saccharomyces cerevisiae, Sup35, can switch its conformation from a soluble functional
state,[psi−], to a conformation,[PSI+], that facilitates aggregation and impairs its native
function. Overexpression of the molecular chaperone Hsp104 abolishes the [PSI+]
phenotype and restores the normal function of Sup35. We have recently shown that Hsp104
interacts preferably with low oligomeric species of a Sup35 derived peptide, Sup35 [5–26]; …
Abstract
In analogy to human prions, a domain of the translation‐termination protein in Saccharomyces cerevisiae, Sup35, can switch its conformation from a soluble functional state, [psi], to a conformation, [PSI+], that facilitates aggregation and impairs its native function. Overexpression of the molecular chaperone Hsp104 abolishes the [PSI+] phenotype and restores the normal function of Sup35. We have recently shown that Hsp104 interacts preferably with low oligomeric species of a Sup35 derived peptide, Sup35[5–26]; however, due to possible exchange between different oligomeric states, it was not possible to obtain information on the distribution and stability of the oligomeric state. We show here, that low‐molecular‐weight oligomers (Sup35[5–26])n (n≈4–6) are indeed important for the fibril formation and disassembly process. We find that Hsp104 is able to disaggregate Sup35[5–26] fibrils by substraction of hexameric to decameric Sup35[5–26] oligomers. This disaggregation effect does not require assistance from other chaperones and is independent of ATP at high Hsp104 concentrations. Furthermore, we demonstrate that critical oligomers have a preference for α‐helical conformations. The conformational reorganization into β‐sheet structures seems to occur only upon incorporation of these oligomers into fibrillar structures. The results are demonstrated by using an equilibrium dialysis experiment that employed different molecular‐weight cut‐off membranes. A combination of thioflavin‐T (ThT) fluorescence and UV measurements allowed the quantification of fibril formation and the amount of peptide diffusing out of the dialysis bag. CD and NMR spectroscopy data were combined to obtain structural information.
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