Structural characterization of Saccharomyces cerevisiae prion-like protein Ure2

Structure of the prion Ure2p in protein fibrils assembled in vitro

The Ure2 protein from the yeast Saccharomyces cerevisiae has prion properties. In vitro and at neutral pH, soluble Ure2p spontaneously forms long, straight, insoluble protein fibrils. Two models have been proposed to account for the assembly of Ure2p into protein fibrils. The "amyloid backbone" model postulates that a segment ranging from 40 to 70 amino acids in the flexible N-terminal domain from different Ure2p molecules forms a parallel superpleated beta-structure running along the fibrils. The second model hypothesizes that assembly of full-length Ure2p is driven by limited conformational rearrangements and non-native inter- and/or intramolecular interactions between Ure2p monomers. Here, we performed a cysteine scan on residues located in the N- and C-terminal parts of Ure2p to determine whether these domains interact. Amino acid sequences centered around residue 6 in the N-terminal domain of Ure2p and residue 137 in the C-terminal moiety interacted at least transiently via intramolecular interactions. We documented the assembly properties of a Ure2p variant in which a disulfide bond was established between the N- and C-terminal domains and showed that it possesses assembly properties indistinguishable from those of wild-type Ure2p. We probed the structure of Ure2pC6C137 within the fibrils and demonstrate that the polypeptide is in a conformation similar to that of its soluble assembly-competent state. Our results constitute the first structural characterization of the N-terminal domain of Ure2p in both its soluble assembly-competent and fibrillar forms. Our data indicate that the flexibility of the N-terminal domain and conformational changes within this domain are essential for fibril formation and provide new insight into the conformational rearrangements that lead to the assembly of Ure2p into fibrils and the propagation of the [URE3] phenotype in yeast.

The [URE3] prion is not conserved among Saccharomyces species

The [URE3] prion of Saccharomyces cerevisiae is a self-propagating inactive form of the nitrogen catabolism regulator Ure2p. To determine whether the [URE3] prion is conserved in S. cerevisiae-related yeast species, we have developed genetic tools allowing the detection of [URE3] in Saccharomyces paradoxus and Saccharomyces uvarum. We found that [URE3] is conserved in S. uvarum. In contrast, [URE3] was not detected in S. paradoxus. The inability of S. paradoxus Ure2p to switch to a prion isoform results from the primary sequence of the protein and not from the lack of cellular cofactors as heterologous Ure2p can propagate [URE3] in this species. Our data therefore demonstrate that [URE3] is conserved only in a subset of Saccharomyces species. Implications of our finding on the physiological and evolutionary meaning of the yeast [URE3] prion are discussed.

Filaments of the Ure2p prion protein have a cross-β core structure

Formation of filaments by the Ure2 protein constitutes the molecular mechanism of the [URE3] prion in yeast. According to the "amyloid backbone" model, the N-terminal asparagine-rich domains of Ure2p polymerize to form an amyloid core fibril that is surrounded by C-terminal domains in their native conformation. Protease resistance and Congo Red binding as well as beta-sheet content detected by spectroscopy-all markers for amyloid-have supported this model, as has the close resemblance between 40 A N-domain fibrils and the fibrillar core of intact Ure2p filaments visualized by cryo-electron microscopy and scanning transmission electron microscopy. Here, we present electron diffraction and X-ray diffraction data from filaments of Ure2p, of N-domains alone, of fragments thereof, and of an N-domain-containing fusion protein that demonstrate in each case the 4.7A reflection that is typical for cross-beta structure and highly indicative of amyloid. This reflection was observed for specimens prepared by air-drying with and without sucrose embedding. To confirm that the corresponding structure is not an artifact of air-drying, the reflection was also demonstrated for specimens preserved in vitreous ice. Local area electron diffraction and X-ray diffraction from partially aligned specimens showed that the 4.7A reflection is meridional and therefore the underlying structure is cross-beta.

Characterization of oligomeric species in the fibrillization pathway of the yeast prion Ure2p

The [URE3] prion of Saccharomyces cerevisiae shares many features with mammalian prions and poly-glutamine related disorders and has become a model for studying amyloid diseases. The development of the [URE3] phenotype is thought to be caused by a structural switch in the Ure2p protein. In [URE3] cells, Ure2p is found predominantly in an aggregated state, while it is a soluble dimer in wild-type cells. In vitro, Ure2p forms fibrils with amyloid-like properties. Several studies suggest that the N-terminal domain of Ure2p is essential for prion formation. In this work, we investigated the fibril formation of Ure2p by isolating soluble oligomeric species, which are generated during fibrillization, and characterized them with respect to size and structure. Our data support the critical role of the N-terminal domain for fibril formation, as we observed fibrils in the presence of 5 M guanidinium chloride, conditions at which the C-terminal domain is completely unfolded. Based on fluorescence measurements, we conclude that the structure of the C-terminal domain is very similar in dimeric and fibrillar Ure2p. When studying the time course of fibrillization, we detected the formation of small, soluble oligomeric species during the early stages of the process. Their remarkable resistance against denaturants, their increased content of beta-structure, and their ability to 'seed' Ure2p fibrillization suggest that conversion to the amyloid-like conformation has already occurred. Thus, they likely represent critical intermediates in the fibrillization pathway of Ure2p.

Amyloidogenic domains, prions and structural inheritance: rudiments of early life or recent acquisition?

Amyloids are self-assembled fibre-like beta-rich protein aggregates. Amyloidogenic prion proteins propagate amyloid state in vivo and transmit it via infection or in cell divisions. While amyloid aggregation may occur in the absence of any other proteins, in vivo propagation of the amyloid state requires chaperone helpers. Yeast prion proteins contain prion domains which include distinct aggregation and propagation elements, responsible for these functions. Known aggregation and propagation elements are short in length and composed of relatively simple sequences, indicating possible ancient origin. Prion-like self-assembled structures could be involved in the initial steps of biological compartmentalization in early life.

The Yeast Prion Protein Ure2 Shows Glutathione Peroxidase Activity in Both Native and Fibrillar Forms

Ure2p is the precursor protein of the Saccharomyces cerevisiae prion [URE3]. Ure2p shows homology to glutathione transferases but lacks typical glutathione transferase activity. A recent study found that deletion of the Ure2 gene causes increased sensitivity to heavy metal ions and oxidants, whereas prion strains show normal sensitivity. To demonstrate that protection against oxidant toxicity is an inherent property of native and prion Ure2p requires biochemical characterization of the purified protein. Here we use steady-state kinetic methods to characterize the multisubstrate peroxidase activity of Ure2p using GSH with cumene hydroperoxide, hydrogen peroxide, or tert-butyl hydroperoxide as substrates. Glutathione-dependent peroxidase activity was proportional to the Ure2p concentration and showed optima at pH 8 and 40 degrees C. Michaelis-Menten behavior with convergent straight lines in double reciprocal plots was observed. This excludes a ping-pong mechanism and implies either a rapid-equilibrium random or a steady-state ordered sequential mechanism for Ure2p, consistent with its classification as a glutathione transferase. The mutant 90Ure2, which lacks the unstructured N-terminal prion domain, showed kinetic parameters identical to wild type. Fibrillar aggregates showed the same level of activity as native protein. Demonstration of peroxidase activity for Ure2 represents important progress in elucidation of its role in vivo. Further, establishment of an in vitro activity assay provides a valuable tool for the study of structure-function relationships of the Ure2 protein as both a prion and an enzyme.

The [URE3] yeast prion results from protein aggregates that differ from amyloid filaments formed in vitro

The [URE3] yeast prion is a self-propagating inactive form of the Ure2 protein. Ure2p is composed of two domains, residues 1-93, the prion-forming domain, and the remaining C-terminal part of the protein, which forms the functional domain involved in nitrogen catabolite repression. In vitro, Ure2p forms amyloid filaments that have been proposed to be the aggregated prion form found in vivo. Here we showed that the biochemical characteristics of these two species differ. Protease digestions of Ure2p filaments and soluble Ure2p are comparable when analyzed by Coomassie staining as by Western blot. However, this finding does not explain the pattern specifically observed in [URE3] strains. Antibodies raised against the C-terminal part of Ure2p revealed the existence of proteolysis sites efficiently cleaved when [URE3], but not wild-type crude extracts, were submitted to limited proteolysis. The same antibodies lead to an equivalent digestion pattern when recombinant Ure2p (either soluble or amyloid) was analyzed in the same way. These results strongly suggest that aggregated Ure2p in [URE3] yeast cells is different from the amyloid filaments generated in vitro.

Conformational constraints for amyloid fibrillation: the importance of being unfolded

Recent reports give strong support to the idea that amyloid fibril formation and the subsequent development of protein deposition diseases originate from conformational changes in corresponding amyloidogenic proteins. In this review, recent findings are surveyed to illustrate that protein fibrillogenesis requires a partially folded conformation. This amyloidogenic conformation is relatively unfolded, and shares many structural properties with the pre-molten globule state, a partially folded intermediate frequently observed in the early stages of protein folding and under some equilibrium conditions. The inherent flexibility of such an intermediate is essential in allowing the conformational rearrangements necessary to form the core cross-beta structure of the amyloid fibril.

Propagating Prions in Fungi and Mammals

Prions constitute a rare class of protein, which can switch to a robust amyloid form and then propagate that form in the absence of a nucleic acid determinant, thereby creating a unique, protein-only infectious agent. Details of the mechanism that drives conversion to the prion form and then subsequent propagation of that form are beginning to emerge using a range of in vivo and in vitro approaches. Recent studies on both mammalian and fungal prions are providing a greater understanding of the structural features that distinguish prions from non-transmissible amyloids.

The N-terminal Prion Domain of Ure2p Converts from an Unfolded to a Thermally Resistant Conformation upon Filament Formation

According to the "amyloid backbone" model of Ure2p prionogenesis, the N-terminal domain of Ure2p polymerizes to form an amyloid filament backbone surrounded by the C-terminal domains. The latter domains retain their native glutathione-S-transferase (GST)-like fold but are sterically inactivated from their regulatory role in nitrogen catabolism. We have tested this model by differential scanning calorimetry of soluble and filamentous Ure2p and of soluble C-terminal domains, combined with electron microscopy. As predicted, the C-terminal domains respond to thermal perturbation identically in all three states, exhibiting a single endotherm at 76 degrees C. In contrast, no thermal signal was associated with the N-terminal domains: in the soluble state of Ure2p, because they are unfolded; in the filamentous state, because their robust amyloid conformation resists heating to 100 degrees C.

Structural Characterization of the Fibrillar Form of the Yeast Saccharomyces cerevisiae Prion Ure2p

The protein Ure2 from the yeast Saccharomyces cerevisiae has prion properties. It assembles in vitro into long, straight, insoluble fibrils that are similar to amyloids in that they bind Congo Red and show green-yellow birefringence and have an increased resistance to proteolysis. We recently showed that Ure2p fibrils assembled under physiologically relevant conditions are devoid of a cross-beta-core. A model for fibril formation, where assembly is driven by non-native inter- and/or intramolecular interaction between Ure2p monomers following subtle conformational changes was proposed [Bousset et al. (2002) EMBO J. 21, 2903-2911]. An alternative model for the assembly of Ure2p into fibrils where assembly is driven by the stacking of 40-70 N-terminal amino acid residues of Ure2p into a central beta-core running along the fibrils from which the C-terminal domains protrude was proposed [Baxa et al. (2003) J. Biol. Chem. 278, 43717-43727]. We show here that Ure2p fibril congophilia and the associated yellow-green birefringence in polarized light are not indicative that the fibrils are of amyloid nature. We map the structures of the fibrillar and soluble forms of Ure2p using limited proteolysis and identify the reaction products by microsequencing and mass spectrometry. Finally, we demonstrate that the C-terminal domain of Ure2p is tightly involved in the fibrillar scaffold using a sedimentation assay and a variant Ure2p where a highly specific cleavage site between the N- and C-terminal domains of the protein was engineered. Our results are inconsistent with the cross-beta-core model and support the model for Ure2p assembly driven by subtle conformational changes and underline the influence of the natural context of the N-terminal domain on the assembly of Ure2p.

Aggregation of the Acylphosphatase from Sulfolobus solfataricus: the folded and partially unfolded states can both be precursors for amyloid formation

Protein aggregation is associated with a number of human pathologies including Alzheimer's and Creutzfeldt-Jakob diseases and the systemic amyloidoses. In this study, we used the acylphosphatase from the hyperthermophilic Archaea Sulfolobus solfataricus (Sso AcP) to investigate the mechanism of aggregation under conditions in which the protein maintains a folded structure. In the presence of 15-25% (v/v) trifluoroethanol, Sso AcP was found to form aggregates able to bind specific dyes such as thioflavine T, Congo red, and 1-anilino-8-naphthalenesulfonic acid. The presence of aggregates was confirmed by circular dichroism and dynamic light scattering. Electron microscopy revealed the presence of small aggregates generally referred to as amyloid protofibrils. The monomeric form adopted by Sso AcP prior to aggregation under these conditions retained enzymatic activity; in addition, folding was remarkably faster than unfolding. These observations indicate that Sso AcP adopts a folded, although possibly distorted, conformation prior to aggregation. Most important, aggregation appeared to be 100-fold faster than unfolding under these conditions. Although aggregation of Sso AcP was faster at higher trifluoroethanol concentrations, in which the protein adopted a partially unfolded conformation, these findings suggest that the early events of amyloid fibril formation may involve an aggregation process consisting of the assembly of protein molecules in their folded state. This conclusion has a biological relevance as globular proteins normally spend most of their lifetime in folded structures.

beta-Helix is a likely core structure of yeast prion Sup35 amyloid fibers

We have studied the core structure of amyloid fibers of yeast prion protein Sup35. We developed procedures to prepare straight fibers of relatively uniform diameters from three kinds of fragments; N (1-123), NMp (1-189), and NM (1-253). X-ray fiber diffraction patterns from dried oriented fibers gave common reflections in all three cases; a sharp meridional reflection at 4.7A, and a diffuse equatorial peak at around 9A, apparently supporting the typical "cross-beta" structure with stacked beta-sheets proposed for many different amyloid fibers. However, X-ray fiber diffraction from hydrated fibers showed the meridional reflection at 4.7A but no equatorial reflections at 9A in all three cases, indicating that the stack of beta-sheets in dried fibers is an artifact produced by drying process. Thus, the core structure of these amyloid fibers made of the N domain is likely to be beta-helix nanotube as proposed by Perutz et al.

The mechanisms of [URE3] prion elimination demonstrate that large aggregates of Ure2p are dead-end products

The yeast prion [URE3] is a self-propagating inactive form (the propagon) of the Ure2 protein. Ure2p is composed of two domains: residues 1-93--the prion-forming domain (PFD)--and the remaining C-terminal part of the protein, which forms the functional domain involved in nitrogen catabolite repression. Guanidine hydrochloride, and the overproduction of Ure2p 1-65 or Ure2-GFP have been shown to induce the elimination of [URE3]. We demonstrate here, two different curing mechanisms: the inhibition of [URE3] replication by guanidine hydrochloride and its destruction by Ure2p aggregation. Such aggregation is observed if PFD or Ure2-GFP are overproduced and in heterozygous URE2/URE2-GFP, [URE3] diploids. We found that the GFP foci associated with the presence of the prion were dead-end products, the propagons remaining soluble. Surprisingly, [URE3] propagated via the Ure2-GFP fusion protein alone is resistant to these two curing mechanisms and cannot promote the formation of foci. The relationship between aggregation, prion and Hsp104 gives rise to a model in which the propagon is in equilibrium with larger aggregates and functional protein.

Amyloid nucleation and hierarchical assembly of Ure2p fibrils. Role of asparagine/glutamine repeat and nonrepeat regions of the prion domains

The yeast prion protein Ure2 forms amyloid-like filaments in vivo and in vitro. This ability depends on the N-terminal prion domain, which contains Asn/Gln repeats, a motif thought to cause human disease by forming stable protein aggregates. The Asn/Gln region of the Ure2p prion domain extends to residue 89, but residues 15-42 represent an island of "normal" random sequence, which is highly conserved in related species and is relatively hydrophobic. We compare the time course of structural changes monitored by thioflavin T (ThT) binding fluorescence and atomic force microscopy for Ure2 and a series of prion domain mutants under a range of conditions. Atomic force microscopy height images at successive time points during a single growth experiment showed the sequential appearance of at least four fibril types that could be readily differentiated by height (5, 8, 12, or 9 nm), morphology (twisted or smooth), and/or time of appearance (early or late in the plateau phase of ThT binding). The Ure2 dimer (h = 2.6 +/- 0.5 nm) and granular particles corresponding to higher order oligomers (h = 4-12 nm) could also be detected. The mutants 15Ure2 and Delta 15-42Ure2 showed the same time-dependent variation in fibril types but with an increased lag time detected by ThT binding compared with wild-type Ure2. In addition, Delta 15-42Ure2 showed reduced binding to ThT. The results imply a role of the conserved region in both amyloid nucleation and formation of the binding surface recognized by ThT. Further, Ure2 amyloid formation is a multistep process via a series of fibrillar intermediates.

Small angle X-ray scattering study of the yeast prion Ure2p

The GdmCl-induced equilibrium unfolding and dissociation of the dimeric yeast prion protein Ure2, and its prion domain deletion mutants Delta 15-42Ure2 and 90Ure2, was studied by small angle X-ray scattering (SAXS) using synchrotron radiation and by chemical cross-linking with dithiobis(succinimidyl propionate) (DTSP). The native state is globular and predominantly dimeric prior to the onset of unfolding. R(g) values of 32 and 45A were obtained for the native and 5M GdmCl denatured states of Delta 15-42Ure2, respectively; the corresponding values for 90Ure2 were 2-3A lower. SAXS suggests residual structure in the 4M GdmCl denatured state and chemical cross-linking detects persistence of dimeric structure under these conditions. Hexamers consisting of globular subunits could be detected by SAXS at high protein concentration under partially denaturing conditions. The increased tendency of partially folded states to form small oligomers points to a mechanism for prion formation.

Architecture of Ure2p prion filaments: the N-terminal domains form a central core fiber

The [URE3] prion is an inactive, self-propagating, filamentous form of the Ure2 protein, a regulator of nitrogen catabolism in yeast. The N-terminal "prion" domain of Ure2p determines its in vivo prion properties and in vitro amyloid-forming ability. Here we determined the overall structures of Ure2p filaments and related polymers of the prion domain fused to other globular proteins. Protease digestion of 25-nm diameter Ure2p filaments trimmed them to 4-nm filaments, which mass spectrometry showed to be composed of prion domain fragments, primarily residues approximately 1-70. Fusion protein filaments with diameters of 14-25 nm were also reduced to 4-nm filaments by proteolysis. The prion domain transforms from the most to the least protease-sensitive part upon filament formation in each case, implying that it undergoes a conformational change. Intact filaments imaged by cryo-electron microscopy or after vanadate staining by scanning transmission electron microscopy (STEM) revealed a central 4-nm core with attached globular appendages. STEM mass per unit length measurements of unstained filaments yielded 1 monomer per 0.45 nm in each case. These observations strongly support a unifying model whereby subunits in Ure2p filaments, as well as in fusion protein filaments, are connected by interactions between their prion domains, which form a 4-nm amyloid filament backbone, surrounded by the corresponding C-terminal moieties.

Assembly of the yeast prion Ure2p into protein fibrils. Thermodynamic and kinetic characterization

The [URE3] phenotype in Saccharomyces cerevisiae propagates by a prion mechanism, involving the aggregation of the normally soluble and highly helical protein Ure2. Previous data have shown that the protein spontaneously forms in vitro long, straight, insoluble fibrils at neutral pH that are similar to amyloids in that they bind Congo red and show green-yellow birefringence and have an increased resistance to proteolysis. These fibrils are not amyloids as they are devoid of a cross-beta core. Here we further document the mechanism of assembly of Ure2p into fibrils. The critical concentration for Ure2p assembly is measured, and the minimal size of the nuclei that are the precursors of Ure2p fibrils is determined. Our data indicate that the assembly process is irreversible. As a consequence, the critical concentration is very low. By analyzing the elongation rates of preformed fibrils and combining the results with single-fiber imaging experiments of a variant Ure2p labeled by fluorescent dyes, we reveal the polarity of the fibrils and differences in the elongation rates at their ends. These results bring novel insight in the process of Ure2p assembly into fibrils and the mechanism of propagation of yeast prions.

Conservation of the prion properties of Ure2p through evolution

The yeast inheritable [URE3] element corresponds to a prion form of the nitrogen catabolism regulator Ure2p. We have isolated several orthologous URE2 genes in different yeast species: Saccharomyces paradoxus, S. uvarum, Kluyveromyces lactis, Candida albicans, and Schizosaccharomyces pombe. We show here by in silico analysis that the GST-like functional domain and the prion domain of the Ure2 proteins have diverged separately, the functional domain being more conserved through the evolution. The more extreme situation is found in the two S. pombe genes, in which the prion domain is absent. The functional analysis demonstrates that all the homologous genes except for the two S. pombe genes are able to complement the URE2 gene deletion in a S. cerevisiae strain. We show that in the two most closely related yeast species to S. cerevisiae, i.e., S. paradoxus and S. uvarum, the prion domains of the proteins have retained the capability to induce [URE3] in a S. cerevisiae strain. However, only the S. uvarum full-length Ure2p is able to behave as a prion. We also show that the prion inactivation mechanisms can be cross-transmitted between the S. cerevisiae and S. uvarum prions.

Analysis of yeast prion aggregates with amyloid-staining compound in vivo

Yeast prions are protein-based genetic elements whose non-Mendelian patterns of inheritance are explained by their inheritance of altered conformations. Here we showed that aggregates made by overexpression of two different prion domains of Sup35 and Rnq1, were stained in yeast by thioflavin-S, an amyloid binding compound. These results suggested that yeast prion domains take the form of amyloid in vivo, and supported the idea that the self-propagating property of amyloids is responsible for the heritable traits of yeast prions.

Relationship between stability of folding intermediates and amyloid formation for the yeast prion Ure2p: a quantitative analysis of the effects of pH and buffer system

The dimeric yeast protein Ure2 shows prion-like behaviour in vivo and forms amyloid fibrils in vitro. A dimeric intermediate is populated transiently during refolding and is apparently stabilized at lower pH, conditions suggested to favour Ure2 fibril formation. Here we present a quantitative analysis of the effect of pH on the thermodynamic stability of Ure2 in Tris and phosphate buffers over a 100-fold protein concentration range. We find that equilibrium denaturation is best described by a three-state model via a dimeric intermediate, even under conditions where the transition appears two-state by multiple structural probes. The free energy for complete unfolding and dissociation of Ure2 is up to 50 kcal mol(-1). Of this, at least 20 kcal mol(-1) is contributed by inter-subunit interactions. Hence the native dimer and dimeric intermediate are significantly more stable than either of their monomeric counterparts. The previously observed kinetic unfolding intermediate is suggested to represent the dissociated native-like monomer. The native state is stabilized with respect to the dimeric intermediate at higher pH and in Tris buffer, without significantly affecting the dissociation equilibrium. The effects of pH, buffer, protein concentration and temperature on the kinetics of amyloid formation were quantified by monitoring thioflavin T fluorescence. The lag time decreases with increasing protein concentration and fibril formation shows pseudo-first order kinetics, consistent with a nucleated assembly mechanism. In Tris buffer the lag time is increased, suggesting that stabilization of the native state disfavours amyloid nucleation.

Internal initiation drives the synthesis of Ure2 protein lacking the prion domain and affects [URE3] propagation in yeast cells

The [URE3] phenotype in Saccharomyces cerevisiae is caused by the inactive, altered (prion) form of the Ure2 protein (Ure2p), a regulator of nitrogen catabolism. Ure2p has two functional domains: an N-terminal domain necessary and sufficient for prion propagation and a C-terminal domain responsible for nitrogen regulation. We show here that the mRNA encoding Ure2p possesses an IRES (internal ribosome entry site). Internal initiation leads to the synthesis of an N-terminally truncated active form of the protein (amino acids 94-354) lacking the prion-forming domain. Expression of the truncated Ure2p form (94-354) mediated by the IRES element cures yeast cells of the [URE3] phenotype. We assume that the balance between the full-length and truncated (94-354) Ure2p forms plays an important role in yeast cell physiology and differentiation.

The native-like conformation of Ure2p in fibrils assembled under physiologically relevant conditions switches to an amyloid-like conformation upon heat-treatment of the fibrils

The [URE3] phenotype in the yeast Saccharomyces cerevisiae is inherited by a prion mechanism involving self-propagating Ure2p aggregates. It is believed that assembly of intact Ure2p into fibrillar polymers that bind Congo Red and show yellow-green birefringence upon staining and are resistant to proteolysis is the consequence of a major change in the conformation of the protein. We recently dissected the assembly process of Ure2p and showed the protein to retain its native alpha-helical structure upon assembly into protein fibrils that are similar to amyloids in that they are straight, bind Congo red and show green-yellow birefringence and have an increased resistance to proteolysis (). Here we further show using specific ligand binding, FTIR spectroscopy and X-ray fiber diffraction that Ure2p fibrils assembled under physiologically relevant conditions are devoid of a cross-beta core. The X-ray fiber diffraction pattern of these fibrils reveals their well-defined axial supramolecular order. By analyzing the effect of heat-treatment on Ure2p fibrils we bring evidences for a large conformational change that occurs within the fibrils with the loss of the ligand binding capacity, decrease of the alpha helicity, the formation of a cross-beta core and the disappearance of the axial supramolecular order. The extent of the conformational change suggests that it is not limited to the N-terminal part of Ure2p polypeptide chain. We show that the heat-treated fibrils that possess a cross-beta core are unable to propagate their structural characteristic while native-like fibrils are. Finally, the potential evolution of native-like fibrils into amyloid fibrils is discussed.

Prions as protein-based genetic elements

Fungal prions are fascinating protein-based genetic elements. They alter cellular phenotypes through self-perpetuating changes in protein conformation and are cytoplasmically partitioned from mother cell to daughter. The four prions of Saccharomyces cerevisiae and Podospora anserina affect diverse biological processes: translational termination, nitrogen regulation, inducibility of other prions, and heterokaryon incompatibility. They share many attributes, including unusual genetic behaviors, that establish criteria to identify new prions. Indeed, other fungal traits that baffled microbiologists meet some of these criteria and might be caused by prions. Recent research has provided notable insight about how prions are induced and propagated and their many biological roles. The ability to become a prion appears to be evolutionarily conserved in two cases. [PSI(+)] provides a mechanism for genetic variation and phenotypic diversity in response to changing environments. All available evidence suggests that prions epigenetically modulate a wide variety of fundamental biological processes, and many await discovery.

The yeast prion Ure2p retains its native alpha-helical conformation upon assembly into protein fibrils in vitro

The yeast inheritable phenotype [URE3] is thought to result from conformational changes in the normally soluble and highly helical protein Ure2p. In vitro, the protein spontaneously forms long, straight, insoluble protein fibrils at neutral pH. Here we show that fibrils of intact Ure2p assembled in vitro do not possess the cross beta-structure of amyloid, but instead are formed by the polymerization of native-like helical subunits that retain the ability to bind substrate analogues. We further show that dissociation of the normally dimeric protein to its constituent monomers is a prerequisite for assembly into fibrils. By analysing the nature of early assembly intermediates, as well as fully assembled Ure2p fibrils using atomic force microscopy, and combining the results with experiments that probe the fidelity of the native fold in protein fibrils, we present a model for fibril formation, based on assembly of native-like monomers, driven by interactions between the N-terminal glutamine and asparagine-rich region and the C-terminal functional domain. The results provide a rationale for the effect of mutagenesis on prion formation and new insights into the mechanism by which this, and possibly other inheritable factors, can be propagated.

Similar and divergent features in mammalian and yeast prions

Mammalian transmissible spongiform encephalopathies are likely due to the propagation of an abnormal form of a constitutive protein instead of traditional genetic material (nucleic acids). Such infectious proteins, which are termed prions, exist in yeast. They are at the origin of a number of phenotypes that are inherited in a non-Mendelian manner. These prions are very useful to dissect the molecular events at the origin of this structure-based inheritance. The properties of mammalian and yeast prions are presented and compared. This review highlights a number of similarities and differences.

The HET-s prion protein of the filamentous fungus Podospora anserina aggregates in vitro into amyloid-like fibrils

The HET-s protein of Podospora anserina is a fungal prion. This protein behaves as an infectious cytoplasmic element that is transmitted horizontally from one strain to another. Under the prion form, the HET-s protein forms aggregates in vivo. The specificity of this prion model compared with the yeast prions resides in the fact that under the prion form HET-s causes a growth inhibition and cell death reaction when co-expressed with the HET-S protein from which it differs by 13 residues. Herein we describe the purification and initial characterization of recombinant HET-s protein expressed in Escherichia coli. The HET-s protein self-associates over time into high molecular weight aggregates. These aggregates greatly accelerate precipitation of the soluble form. HET-s aggregates appear as amyloid-like fibrils using electron microscopy. They bind Congo Red and show birefringence under polarized light. In the aggregated form, a HET-s fragment of approximately 7 kDa is resistant to proteinase K digestion. CD and FTIR analyses indicate that upon transition to the aggregated state, the HET-s protein undergoes a structural rearrangement characterized by an increase in antiparallel beta-sheet structure content. These results suggest that the [Het-s] prion element propagates in vivo as an infectious amyloid.

The utility of prions

Infectious, self-propagating protein aggregates (prions) as well as structurally related amyloid fibrils have traditionally been associated with neurodegenerative diseases in mammals. However, recent work in fungi indicates that prions are not simply aberrations of protein folding, but are in fact widespread, conserved, and in certain cases, apparently beneficial. Analysis of prion behavior in yeast has led to insights into the mechanisms of prion appearance and propagation as well as the effect of prions on cellular physiology and perhaps evolution. The prion-forming proteins of Saccharomyces cerevisiae are members of a larger class of Gln/Asn-rich proteins that is abundantly represented in the genomes of higher eukaryotes, raising the prospect of genetically programmed prion-like behavior in other organisms.

The [URE3] phenotype: evidence for a soluble prion in yeast

The aggregation of the two yeast proteins Sup35p and Ure2p is widely accepted as a model for explaining the prion propagation of the phenotypes [PSI+] and [URE3], respectively. Here, we demonstrate that the propagation of [URE3] cannot simply be the consequence of generating large aggregates of Ure2p, because such aggregation can be found in some conditions that are not related to the prion state of Ure2p. A comparison of [PSI+] and [URE3] aggregation demonstrates differences between these two prion mechanisms. Our findings lead us to propose a new unifying model for yeast prion propagation.

Folding of the yeast prion protein Ure2: kinetic evidence for folding and unfolding intermediates

The Saccharomyces cerevisiae non-Mendelian factor [URE3] propagates by a prion-like mechanism, involving aggregation of the chromosomally encoded protein Ure2. The N-terminal prion domain (PrD) of Ure2 is required for prion activity in vivo and amyloid formation in vitro. However, the molecular mechanism of the prion-like activity remains obscure. Here we measure the kinetics of folding of Ure2 and two N-terminal variants that lack all or part of the PrD. The kinetic folding behaviour of the three proteins is identical, indicating that the PrD does not change the stability, rates of folding or folding pathway of Ure2. Both unfolding and refolding kinetics are multiphasic. An intermediate is populated during unfolding at high denaturant concentrations resulting in the appearance of an unfolding burst phase and "roll-over" in the denaturant dependence of the unfolding rate constants. During refolding the appearance of a burst phase indicates formation of an intermediate during the dead-time of stopped-flow mixing. A further fast phase shows second-order kinetics, indicating formation of a dimeric intermediate. Regain of native-like fluorescence displays a distinct lag due to population of this on-pathway dimeric intermediate. Double-jump experiments indicate that isomerisation of Pro166, which is cis in the native state, occurs late in refolding after regain of native-like fluorescence. During protein refolding there is kinetic partitioning between productive folding via the dimeric intermediate and a non-productive side reaction via an aggregation prone monomeric intermediate. In the light of this and other studies, schemes for folding, aggregation and prion formation are proposed.

Structure and assembly properties of the yeast prion Ure2p

The non-Mendelian phenotype [URE3] is due to a transmissible conformational change of the protein Ure2. The infectious protein form of Ure2p has lost its function and gained the capacity to transform the active form of the protein into an inactive form. The molecular basis of this conversion process is unknown. There are however indications that the conformational changes at the origin of the propagation of the inactive form of Ure2p in yeast cells are similar to those at the origin of the transition of PrPC into the scrapie-associated PrPSc form of the protein. To better understand the nature of the conformational changes at the origin of prion propagation, we have purified, characterized biochemically, examined the assembly properties and solved the crystal structure of Ure2p. Our data are presented below and a number of conclusions dealing with the molecular basis of the conversion of soluble Ure2p into its amyloid-forming state are derived.

In vivo aggregation of the HET-s prion protein of the fungus Podospora anserina

We have proposed that the [Het-s] infectious cytoplasmic element of the filamentous fungus Podospora anserina is the prion form of the HET-s protein. The HET-s protein is involved in a cellular recognition phenomenon characteristic of filamentous fungi and known as heterokaryon incompatibility. Under the prion form, the HET-s protein causes a cell death reaction when co-expressed with the HET-S protein, from which it differs by only 13 amino acid residues. We show here that the HET-s protein can exist as two alternative states, a soluble and an aggregated form in vivo. As shown for the yeast prions, transition to the infectious prion form leads to aggregation of a HET-s--green fluorescent protein (GFP) fusion protein. The HET-s protein is aggregated in vivo when highly expressed. However, we could not demonstrate HET-s aggregation at wild-type expression levels, which could indicate that only a small fraction of the HET-s protein is in its aggregated form in vivo in wild-type [Het-s] strains. The antagonistic HET-S form is soluble even at high expression level. A double amino acid substitution in HET-s (D23A P33H), which abolishes prion infectivity, suppresses in vivo aggregation of the GFP fusion. Together, these results further support the model that the [Het-s] element corresponds to an abnormal self-perpetuating aggregated form of the HET-s protein.

Crystal structures of the yeast prion Ure2p functional region in complex with glutathione and related compounds

The [URE3] phenotype in yeast Saccharomyces cerevisiae is due to an altered prion form of Ure2p, a protein involved in nitrogen catabolism. To understand possible conformational changes at the origin of prion propagation, we previously solved the crystal structure of the Ure2p functional region [Bousset et al. (2001) Structure 9, 39-46]. We showed the protein to have a fold similar to that of the beta class of glutathione S-transferases (GSTs). Here we report crystal structures of the Ure2p functional region (extending from residues 95-354) in complex with glutathione (GSH), the substrate of all GSTs, and two widely used GST inhibitors, namely, S-hexylglutathione and S-p-nitrobenzylglutathione. In a manner similar to what is observed in many GSTs, ligand binding is not accompanied by a significant change in the conformation of the protein. We identify one GSH and one hydrophobic electrophile binding site per monomer as observed in all other GSTs. The sulfur group of GSH, that conjugates electrophiles, is located near the amide group of Asn124, allowing a hydrogen bond to be formed. Biochemical data indicate that GSH binds to Ure2p with high affinity. Its binding affects Ure2p oligomerization but has no effect on the assembly of the protein into amyloid fibrils. Despite results indicating that Ure2p lacks GST activity, we propose that Ure2p is a member of the GST superfamily that may describe a novel GST class. Our data bring new insights into the function of the Ure2p active region.

Induction of distinct [URE3] yeast prion strains

[URE3] is a non-Mendelian genetic element in Saccharomyces cerevisiae, which is caused by a prion-like, autocatalytic conversion of the Ure2 protein (Ure2p) into an inactive form. The presence of [URE3] allows yeast cells to take up ureidosuccinic acid in the presence of ammonia. This phenotype can be used to select for the prion state. We have developed a novel reporter, in which the ADE2 gene is controlled by the DAL5 regulatory region, which allows monitoring of Ure2p function by a colony color phenotype. Using this reporter, we observed induction of different [URE3] prion variants ("strains") following overexpression of the N-terminal Ure2p prion domain (UPD) or full-length Ure2p. Full-length Ure2p induced two types of [URE3]: type A corresponds to conventional [URE3], whereas the novel type B variant is characterized by relatively high residual Ure2p activity and efficient curing by coexpression of low amounts of a UPD-green fluorescent protein fusion protein. Overexpression of UPD induced type B [URE3] but not type A. Both type A and B [URE3] strains, as well as weak and strong isolates of type A, were shown to stably maintain different prion strain characteristics. We suggest that these strain variants result from different modes of aggregation of similar Ure2p monomers. We also demonstrate a procedure to counterselect against the [URE3] state.

Strong growth polarity of yeast prion fiber revealed by single fiber imaging

Using the yeast prion as a model, we have developed a novel system to observe the growth of individual prion fibers directly. NM fragments, the prion-determining region of the yeast protein Sup35p, were labeled by either red or green fluorescent dyes, and the fiber growth was observed under a fluorescence microscope. When green-Sup35NM was added to the preformed fibers made of red-Sup35NM, 70-97% of green fibers grew unidirectionally, from only one end of individual red fibers, whereas the remainder grew from both ends. Similarly, the majority of red fibers grew from only one end of green fibers when the order of addition was reversed. Sonication of preformed fibers to expose fresh ends did not change the results, excluding a possibility of occasional deformation of one end as the reason of the apparent unidirectional growth. These results indicate the polarity of Sup35 prion fibers and impose constraints on the models of fiber growth.

Pressure denaturation of the yeast prion protein Ure2

Denaturation of the Saccharomyces cerevisiae prion protein Ure2 was investigated using hydrostatic pressure. Pressures of up to 600 MPa caused only limited perturbation of the structure of the 40-kDa dimeric protein. However, nondenaturing concentrations of GdmCl in combination with high pressure resulted in complete unfolding of Ure2 as judged by intrinsic fluorescence. The free energy of unfolding measured by pressure denaturation or by GdmCl denaturation is the same, indicating that pressure does not induce dimer dissociation or population of intermediates in 2 M GdmCl. Pressure-induced changes in 5 M GdmCl suggest residual structure in the denatured state. Cold denaturation under pressure at 200 MPa showed that unfolding begins below -5 degrees C and Ure2 is more susceptible to cold denaturation at low ionic strength. Results obtained using two related protein constructs, which lack all or part of the N-terminal prion domain, were very similar.

Prions affect the appearance of other prions: the story of [PIN(+)]

Prions are self-propagating protein conformations. Recent research brought insight into prion propagation, but how they first appear is unknown. We previously established that the yeast non-Mendelian trait [PIN(+)] is required for the de novo appearance of the [PSI(+)] prion. Here, we show that the presence of prions formed by Rnq1 or Ure2 is sufficient to make cells [PIN(+)]. Thus, [PIN(+)] can be caused by more than one prion. Furthermore, an unbiased functional screen for [PIN(+)] prions uncovered the known prion gene, URE2, the proposed prion gene, NEW1, and nine novel candidate prion genes all carrying prion domains. Importantly, the de novo appearance of Rnq1::GFP prion aggregates also requires the presence of other prions, suggesting the existence of a general mechanism by which the appearance of prions is enhanced by heterologous prion aggregates.

The elimination of the yeast [PSI+] prion by guanidine hydrochloride is the result of Hsp104 inactivation

In the yeast Saccharomyces cerevisiae, Sup35p (eRF3), a subunit of the translation termination complex, can take up a prion-like, self-propagating conformation giving rise to the non-Mendelian [PSI+] determinant. The replication of [PSI+] prion seeds can be readily blocked by growth in the presence of low concentrations of guanidine hydrochloride (GdnHCl), leading to the generation of prion-free [psi-] cells. Here, we provide evidence that GdnHCl blocks seed replication in vivo by inactivation of the molecular chaperone Hsp104. Although growth in the presence of GdnHCl causes a modest increase in HSP104 expression (20-90%), this is not sufficient to explain prion curing. Rather, we show that GdnHCl inhibits two different Hsp104-dependent cellular processes, namely the acquisition of thermotolerance and the refolding of thermally denatured luciferase. The inhibitory effects of GdnHCl protein refolding are partially suppressed by elevating the endogenous cellular levels of Hsp104 using a constitutive promoter. The kinetics of GdnHCl-induced [PSI+] curing could be mimicked by co-expression of an ATPase-negative dominant HSP104 mutant in an otherwise wild-type [PSI+] strain. We suggest that GdnHCl inactivates the ATPase activity of Hsp104, leading to a block in the replication of [PSI+] seeds.

Mutation processes at the protein level: is Lamarck back?

The experimental evidence accumulated for the last half of the century clearly suggests that inherited variation is not restricted to the changes in genomic sequences. The prion model, originally based on unusual transmission of certain neurodegenerative diseases in mammals, provides a molecular mechanism for the template-like reproduction of alternative protein conformations. Recent data extend this model to protein-based genetic elements in yeast and other fungi. Reproduction and transmission of yeast protein-based genetic elements is controlled by the "prion replication" machinery of the cell, composed of the protein helpers responsible for the processes of assembly and disassembly of protein structures and multiprotein complexes. Among these, the stress-related chaperones of Hsp100 and Hsp70 groups play an important role. Alterations of levels or activity of these proteins result in "mutator" or "antimutator" affects in regard to protein-based genetic elements. "Protein mutagens" have also been identified that affect formation and/or propagation of the alternative protein conformations. Prion-forming abilities appear to be conserved in evolution, despite the divergence of the corresponding amino acid sequences. Moreover, a wide variety of proteins of different origins appear to possess the ability to form amyloid-like aggregates, that in certain conditions might potentially result in prion-like switches. This suggests a possible mechanism for the inheritance of acquired traits, postulated in the Lamarckian theory of evolution. The prion model also puts in doubt the notion that cloned animals are genetically identical to their genome donors, and suggests that genome sequence would not provide a complete information about the genetic makeup of an organism.

Stability, folding, dimerization, and assembly properties of the yeast prion Ure2p

The [URE3] factor of Saccharomyces cerevisiae propagates by a prion-like mechanism and corresponds to the loss of the function of the cellular protein Ure2. The molecular basis of the propagation of this phenotype is unknown. We recently expressed Ure2p in Escherichia coli and demonstrated that the N-terminal region of the protein is flexible and unstructured, while its C-terminal region is compactly folded. Ure2p oligomerizes in solution to form mainly dimers that assemble into fibrils [Thual et al. (1999) J. Biol. Chem. 274, 13666-13674]. To determine the role played by each domain of Ure2p in the overall properties of the protein, specifically, its stability, conformation, and capacity to assemble into fibrils, we have further analyzed the properties of Ure2p N- and C-terminal regions. We show here that Ure2p dimerizes through its C-terminal region. We also show that the N-terminal region is essential for directing the assembly of the protein into a particular pathway that yields amyloid fibrils. A full-length Ure2p variant that possesses an additional tryptophan residue in its N-terminal moiety was generated to follow conformational changes affecting this domain. Comparison of the overall conformation, folding, and unfolding properties, and the behavior upon proteolytic treatments of full-length Ure2p, Ure2pW37 variant, and Ure2p C-terminal fragment reveals that Ure2p N-terminal domain confers no additional stability to the protein. This study reveals the existence of a stable unfolding intermediate of Ure2p under conditions where the protein assembles into amyloid fibrils. Our results contradict the intramolecular interaction between the N- and C-terminal moieties of Ure2p and the single unfolding transitions reported in a number of previous studies.

Structure of the globular region of the prion protein Ure2 from the yeast Saccharomyces cerevisiae

BACKGROUND

The [URE3] non-Mendelian element of the yeast S. cerevisiae is due to the propagation of a transmissible form of the protein Ure2. The infectivity of Ure2p is thought to originate from a conformational change of the normal form of the prion protein. This conformational change generates a form of Ure2p that assembles into amyloid fibrils. Hence, knowledge of the three-dimensional structure of prion proteins such as Ure2p should help in understanding the mechanism of amyloid formation associated with a number of neurodegenerative diseases.

RESULTS

Here we report the three-dimensional crystal structure of the globular region of Ure2p (residues 95--354), also called the functional region, solved at 2.5 A resolution by the MAD method. The structure of Ure2p 95--354 shows a two-domain protein forming a globular dimer. The N-terminal domain is composed of a central 4 strand beta sheet flanked by four alpha helices, two on each side. In contrast, the C-terminal domain is entirely alpha-helical. The fold of Ure2p 95--354 resembles that of the beta class glutathione S-transferases (GST), in line with a weak similarity in the amino acid sequence that exists between these proteins. Ure2p dimerizes as GST does and possesses a potential ligand binding site, although it lacks GST activity.

CONCLUSIONS

The structure of the functional region of Ure2p is the first crystal structure of a prion protein. Structure comparisons between Ure2p 95--354 and GST identified a 32 amino acid residues cap region in Ure2p exposed to the solvent. The cap region is highly flexible and may interact with the N-terminal region of the partner subunit in the dimer. The implication of this interaction in the assembly of Ure2p into amyloid fibrils is discussed.

Cell biology. Sowing the protein seeds of prion propagation

Ever since Prusiner first proposed his radical "protein-only" hypothesis to explain how certain infectious proteins (prions) are transmitted from one mammal to another in the absence of DNA or RNA, scientists have been trying to prove him right (or wrong). The study of mammalian prions, such as those causing Creutzfeldt-Jakob disease in humans, scrapie in sheep and mad cow disease in cattle, has been slow to yield answers. However, as Tuite discusses in his Perspective, the Sup35p and Ure2p proteins of yeast that exist in both normal and infectious forms are providing evidence that the "protein-only" hypothesis may be right (Sparrer et al.).

The yeast prion [URE3] can be greatly induced by a functional mutated URE2 allele

The non-Mendelian element [URE3] of yeast is considered to be a prion form of the Ure2 protein. The [URE3] phenotype occurs at a frequency of 10(-5) in haploid yeast strains, is reversible, and its frequency is increased by overexpressing the URE2 gene. We created a new mutant of the Ure2 protein, called H2p, which results in a 1000-fold increase in the rate of [URE3] occurrence. To date, only the overexpression of various C-terminal truncated mutants of Ure2p gives rise to a comparable level. The h2 allele is, thus, the first characterized URE2 allele that induces prion formation when expressed at a low level. By shuffling mutated and wild-type domains of URE2, we also created the first mutant Ure2 protein that is functional and induces prion formation. We demonstrate that the domains of URE2 function synergistically in cis to induce [URE3] formation, which highlights the importance of intramolecular interactions in Ure2p folding. Additionally, we show using a green fluorescent protein (GFP) fusion protein that the h2 allele exhibits numerous filiform structures that are not generated by the wild-type protein.

Scrapie infectivity is independent of amyloid staining properties of the N-terminally truncated prion protein

The prion protein undergoes a profound conformational change when the cellular isoform (PrP(C)) is converted into the disease-causing form (PrP(Sc)). Limited proteolysis of PrP(Sc) produces PrP 27-30, which readily polymerizes into amyloid. To study the relationship between PrP amyloid and infectivity, we employed organic solvents that perturb protein conformation. Hexafluoro-2-propanol (HFIP), which promotes alpha-helix formation, modified the ultrastructure of PrP amyloid and decreased the beta-sheet content as well as prion infectivity. HFIP reversibly decreased the binding of Congo red dye to the PrP amyloid rods while inactivation of prion infectivity was irreversible. In contrast, 1,1,1-trifluoro-2-propanol (TFIP) did not inactivate prion infectivity but like HFIP, TFIP did alter the morphology of the rods and abolished Congo red binding. Solubilization using various solvents and detergents produced monomeric and dimeric PrP that lacked infectivity. Proteinase K resistance of detergent-treated PrP 27-30 showed no correlation with scrapie infectivity. Our results separate prion infectivity from the amyloid properties of PrP 27-30 and underscore the dependence of prion infectivity on PrP(Sc) conformation. These findings also demonstrate that the specific beta-sheet-rich structures required for prion infectivity can be differentiated from those required for amyloid formation.

Prions of yeast as heritable amyloidoses

Two infectious proteins (prions) of Saccharomyces cerevisiae have been identified by their unusual genetic properties: (1) reversible curability, (2) de novo induction of the infectious prion form by overproduction of the protein, and (3) similar phenotype of the prion and mutation in the chromosomal gene encoding the protein. [URE3] is an altered infectious form of the Ure2 protein, a regulator of nitrogen catabolism, while [PSI] is a prion of the Sup35 protein, a subunit of the translation termination factor. The altered form of each is inactive in its normal function, but is able to convert the corresponding normal protein into the same altered inactive state. The N-terminal parts of Ure2p and Sup35p (the "prion domains") are responsible for prion formation and propagation and are rich in asparagine and glutamine residues. Ure2p and Sup35p are aggregated in vivo in [URE3]- and [PSI]-containing cells, respectively. The prion domains can form amyloid in vitro, suggesting that amyloid formation is the basis of these two prion diseases. Yeast prions can be cured by growth on millimolar concentrations of guanidine. An excess or deficiency of the chaperone Hsp104 cures the [PSI] prion. Overexpression of fragments of Ure2p or certain fusion proteins leads to curing of [URE3].

The prion domain of yeast Ure2p induces autocatalytic formation of amyloid fibers by a recombinant fusion protein

The Ure2 protein from Saccharomyces cerevisiae has been proposed to undergo a prion-like autocatalytic conformational change, which leads to inactivation of the protein, thereby generating the [URE3] phenotype. The first 65 amino acids, which are dispensable for the cellular function of Ure2p in nitrogen metabolism, are necessary and sufficient for [URE3] (Masison & Wickner, 1995), leading to designation of this domain as the Ure2 prion domain (UPD). We expressed both UPD and Ure2 as glutathione-S-transferase (GST) fusion proteins in Escherichia coli and observed both to be initially soluble. Upon cleavage of GST-UPD by thrombin, the released UPD formed ordered fibrils that displayed amyloid-like characteristics, such as Congo red dye binding and green-gold birefringence. The fibrils exhibited high beta-sheet content by Fourier transform infrared spectroscopy. Fiber formation proceeded in an autocatalytic manner. In contrast, the released, full-length Ure2p formed mostly amorphous aggregates; a small amount polymerized into fibrils of uniform size and morphology. Aggregation of Ure2p could be seeded by UPD fibrils. Our results provide biochemical support for the proposal that the [URE3] state is caused by a self-propagating inactive form of Ure2p. We also found that the uncleaved GST-UPD fusion protein could polymerize into amyloid fibrils by a strictly autocatalytic mechanism, forcing the GST moiety of the protein to adopt a new, beta-sheet-rich conformation. The findings on the GST-UPD fusion protein indicate that the ability of the prion domain to mediate a prion-like conversion process is not specific for or limited to the Ure2p.