We initiated a new field of yeast genetics with our discovery that two non-chromosomal genetic elements, [URE3] and [PSI], were prions (infectious proteins), analogous to the agent causing the transmissible spongiform encephalopathies of mammals. The first, [URE3], is an altered form of Ure2p, the protein product of the chromosomal URE2 gene important in regulation of nitrogen catabolism. The second, [PSI], is an altered form of Sup35p, a subunit of the translation release factor and product of the chromosomal SUP35 gene. We found that Ure2p is more resistant to protease digestion in [URE3] strains than in wild-type strains, and is aggregated specifically in cells carrying the prion, supporting the prion model and suggesting amyloid formation as its molecular basis. The N-terminal 65 aminoacid residues of Ure2p is sufficient to propagate [URE3], or to induce the de novo appearance of [URE3]. We showed that the Ure2p prion domain forms amyloid filaments in vitro. Moreover, just as the prion domain induces prion formation in vivo, it induces the otherwise stably soluble native Ure2p to form amyloid in vitro. The properties of Ure2p amyloid formation in vitro reflect and explain the prion properties of [URE3] in vivo. We thus proposed that the [URE3] prion is an infectious amyloidosis. We showed that fragments of Ure2p or fusions with other proteins cure the prion efficiently. This phenomenon may be due to interruption of the growth of the amyloid 'crystals' due to the fragments or fusion proteins, and suggests a new approach to the treatment of amyloid diseases. We find that the Mks1 protein is essential for the de novo formation of the [URE3] prion. Mks1 activity is negatively regulated by the Ras - cAMP pathway, and we find that activation of Ras2p prevents de novo [URE3] prion formation by inactivating Mks1. We showed that the Hsp104 chaperone is necessary for [URE3] prion propagation, and that overexpression of the Hsp40-family chaperone Ydj1p can cure the [URE3] prion. We recently showed that the Hsp70-family chaperone Ssa2p is also necessary for the propagation of [URE3]. In collaboration with Drs. Vladislav Speransky and Alasdair Steven (NIAMS), we further showed that cells with the [URE3] prion contain networks of filaments consisting of the Ure2 protein. Further, most of the Ure2p in extracts of [URE3] strains is in a form insoluble even after boiling in 3M urea and 2% SDS, confirming that it is in an amyloid state. Our collaborators, Drs. Tim Umland and David Davies (LMB, NIDDK), have determined the structure of the nitrogen regulation domain of Ure2p and find that it is closely similar to glutathione-S-transferases (GST). Ure2p is inactivated by prion (amyloid) formation in vivo. We find that Ure2p is not inactivated by a conformational change in the functional part of the molecule, but by a steric effect or diffusion limitation on the interaction of Ure2p with Gln3p. The Ure2-GFP fusion protein forms amyloid filaments with a helical form. The length of the helical repeat is constant within each filament, but this length varies by more than 2 fold from one filament to another. This may be the basis of prion strains, that have different infectious properties and different effects on the host. We have isolated homologs of the URE2 gene from other strains of S. cerevisiae, from various pathogenic Candida species and from a filamentous fungus. While the C-terminal domain is highly conserved and the homologs can substitute for the cerevisiae Ure2p, the N-terminal domain (up to residue 99) is highly variable. Nonetheless, there is a conserved part of the prion domain from residues 10 to 39. This region apparently interacts with the Ure2p C-terminus as judged by inactivation of Ure2p when the fragment is overexpressed. This region also is responsible for the curing of the [URE3] prion by fusions with GFP mentioned above. We find that the prion domain forms the centralll core of the amyloid filaments, with residues 1 to 65 comprising the highly protease resistant part. Ure2p residues 71-95 serve as a linker between the amyloid core and the peripherally arrayed functional domains (residues 95-354). Monomers of Ure2p are bound to eachother by interactions between the prion domains. We have recently described an entirely new class of prions, based not on amyloid formation, but on the requirement for autoactivation in trans of the vacuolar protease B (PrB) of yeast. Cells that lack active PrB remain in that state, except for the rare (10^-5) spontaneous activation of the enzyme. Cells with active PrB give rise to progeny nearly all of whom have active enzyme. These cells can also infect cells without active enzyme by the transfer of active PrB. Thus PrB, in its active form is an infectious protein (a prion). There are many proteins that are necessary for their own activation, which could thus potentially act as prions. The N-terminal prion domain of Ure2p (residues 1-90) is rich in N and Q residues and we showed that these are important for prion formation and propagation. However, we find that there are no essential amino acid sequence elements in the prion domain: five random shuffles of these amino acids leave a protein that can form prions in vivo and amyloid in vitro. This surprising result implies that amino acid composition, rather than sequence, is the critical driving force for prion formation in the case of Ure2p. We are now testing other prion-forming proteins to extend this result. Amyloid of Ure2p has an amyloid core that is high in beta sheet structure with beta strands perpendicular to the filament axis as judged by X-ray diffraction and electron diffraction (with U. Baxa, D. R. Davies, A. C. Steven). This result confirms the amyloid nature of the filaments formed by Ure2p. Our studies of the mechanism of the Mks1p requirement for [URE3] prion generation show that this requirement is independent of its role in regulating glutamate biosynthesis, and that altered expression of the cAMP-dependent protein kinases alters [URE3] generation as predicted from our earlier studies. Using expression chip analysis, we find that the [URE3] prion does not induce any transcriptional changes other than those attributable to the role of Ure2p in regulation of nitrogen catabolism. Using the yeast two hybrid method, we have detected a set of proteins that interact with the Ure2p prion domain in vivo. Possible effects of these proteins on prion generation or propagation are now being examined. In another study, we have used the yeast deletion bank to look for genes involved in prion generation. A number of candidates are now being further studied to determine the mechanisms of their involvement.
Shewmaker, Frank; Wickner, Reed B (2006) Ageing in yeast does not enhance prion generation. Yeast 23:1123-8 |
Edskes, Herman K; Naglieri, Benedetta M; Wickner, Reed B (2006) Nitrogen source and the retrograde signalling pathway affect detection, not generation, of the [URE3] prion. Yeast 23:833-40 |
Wickner, Reed B; Edskes, Herman K; Shewmaker, Frank (2006) How to find a prion: [URE3], [PSI+] and [beta]. Methods 39:3-8 |
Baxa, Ulrich; Cheng, Naiqian; Winkler, Dennis C et al. (2005) Filaments of the Ure2p prion protein have a cross-beta core structure. J Struct Biol 150:170-9 |
Brachmann, Andreas; Baxa, Ulrich; Wickner, Reed Brendon (2005) Prion generation in vitro: amyloid of Ure2p is infectious. EMBO J 24:3082-92 |
Ross, Eric D; Edskes, Herman K; Terry, Michael J et al. (2005) Primary sequence independence for prion formation. Proc Natl Acad Sci U S A 102:12825-30 |
Pierce, Michael M; Baxa, Ulrich; Steven, Alasdair C et al. (2005) Is the prion domain of soluble Ure2p unstructured? Biochemistry 44:321-8 |
Nakayashiki, Toru; Kurtzman, Cletus P; Edskes, Herman K et al. (2005) Yeast prions [URE3] and [PSI+] are diseases. Proc Natl Acad Sci U S A 102:10575-80 |
Ross, Eric D; Minton, Allen; Wickner, Reed B (2005) Prion domains: sequences, structures and interactions. Nat Cell Biol 7:1039-44 |
Wickner, Reed B (2005) Scrapie in ancient China? Science 309:874 |
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