Insight into molecular basis of curing of [PSI+] prion by overexpression of 104-kDa heat shock protein (Hsp104)

Yeast prions are a powerful model for understanding the dynamics of protein aggregation associated with a number of human neurodegenerative disorders. The AAA+ protein disaggregase Hsp104 can sever the amyloid fibrils produced by yeast prions. This action results in the propagation of "seeds" that are transmitted to daughter cells during budding. Overexpression of Hsp104 eliminates the [PSI+] prion but not other prions. Using biochemical methods we identified Hsp104 binding sites in the highly charged middle domain of Sup35, the protein determinant of [PSI+]. Deletion of a short segment of the middle domain (amino acids 129-148) diminishes Hsp104 binding and strongly affects the ability of the middle domain to stimulate the ATPase activity of Hsp104. In yeast, [PSI+] maintained by Sup35 lacking this segment, like other prions, is propagated by Hsp104 but cannot be cured by Hsp104 overexpression. These results provide new insight into the enigmatic specificity of Hsp104-mediated curing of yeast prions and sheds light on the limitations of the ability of Hsp104 to eliminate aggregates produced by other aggregation-prone proteins.     

Nucleotide exchange factors for Hsp70s are required for [URE3] prion propagation in Saccharomyces cerevisiae

The [URE3] and [PSI(+)] prions are infectious amyloid forms of Ure2p and Sup35p. Several chaperones influence prion propagation: Hsp104p overproduction destabilizes [PSI(+)], whereas [URE3] is sensitive to excess of Ssa1p or Ydj1p. Here, we show that overproduction of the chaperone, Sse1p, can efficiently cure [URE3]. Sse1p and Fes1p are nucleotide exchange factors for Ssa1p. Interestingly, deletion of either SSE1 or FES1 completely blocked [URE3] propagation. In addition, deletion of SSE1 also interfered with [PSI(+)] propagation.     

Mechanism of Prion Loss after Hsp104 Inactivation in Yeast

In vivo propagation of [PSI(+)], an aggregation-prone prion isoform of the yeast release factor Sup35 (eRF3), has previously been shown to require intermediate levels of the chaperone protein Hsp104. Here we perform a detailed study on the mechanism of prion loss after Hsp104 inactivation. Complete or partial inactivation of Hsp104 was achieved by the following approaches: deleting the HSP104 gene; modifying the HSP104 promoter that results in low level of its expression; and overexpressing the dominant-negative ATPase-inactive mutant HSP104 allele. In contrast to guanidine-HCl, an agent blocking prion proliferation, Hsp104 inactivation induced relatively rapid loss of [PSI(+)] and another candidate yeast prion, [PIN(+)]. Thus, the previously hypothesized mechanism of prion dilution in cell divisions due to the blocking of prion proliferation is not sufficient to explain the effect of Hsp104 inactivation. The [PSI(+)] response to increased levels of another chaperone, Hsp70-Ssa, depends on whether the Hsp104 activity is increased or decreased. A decrease of Hsp104 levels or activity is accompanied by a decrease in the number of Sup35(PSI+) aggregates and an increase in their size. This eventually leads to accumulation of huge agglomerates, apparently possessing reduced prion forming capability and representing dead ends of the prion replication cycle. Thus, our data confirm that the primary function of Hsp104 in prion propagation is to disassemble prion aggregates and generate the small prion seeds that initiate new rounds of prion propagation (possibly assisted by Hsp70-Ssa).     

Channel mutations in Hsp104 hexamer distinctively affect thermotolerance and prion-specific propagation

The yeast prion [PSI(+)] represents an aggregated state of the translation termination factor Sup35 resulting in the tendency of ribosomes to readthrough stop codons. In this study, we constructed an auxotrophic chromosomal marker, ura3-197 (nonsense allele), applicable to selection for loss of [PSI(+)] to [psi(-)]. Unlike [psi(-)] yeast strains, [PSI(+)] yeast strains exhibit nonsense suppression of the ura3-197 allele and are not viable in the presence of 5-fluoroorotic acid (5-FOA) that is converted to a toxic material by the readthrough product of Ura3. We selected 20 5-FOA-resistant, loss-of-[PSI(+)], mutants spontaneously or by transposon-mediated mutagenesis from ura3-197[PSI(+)] cells. All of the 20 [psi(-)] isolates were affected in Hsp104, a protein-remodelling factor. Although most of them were disabled in a normal Hsp104 function for thermotolerance, three single mutants, L462R, P557L and D704N, remained thermotolerant. Importantly, L462R and D704N also eliminate other yeast prions [URE3] and [PIN(+)], while P557L does not, suggesting that Hsp104 harbours a unique activity to prion propagation independent of its function in thermotolerance. The mutations that are specific to prion propagation are clustered around the lateral channel of the Hsp104 hexamer, suggesting a crucial and specific role of this channel for prion propagation.     

Hsp104, Hsp70 and Hsp40 interplay regulates formation, growth and elimination of Sup35 prions

Self-templating amyloid forms of Sup35 constitute the yeast prion [PSI(+)]. How the protein-remodelling factor, Hsp104, collaborates with other chaperones to regulate [PSI(+)] inheritance remains poorly delineated. Here, we report how the Ssa and Ssb components of the Hsp70 chaperone system directly affect Sup35 prionogenesis and cooperate with Hsp104. We identify the ribosome-associated Ssb1:Zuo1:Ssz1 complex as a potent antagonist of Sup35 prionogenesis. The Hsp40 chaperones, Sis1 and Ydj1, preferentially interact with Sup35 oligomers and fibres compared with monomers, and facilitate Ssa1 and Ssb1 binding. Various Hsp70:Hsp40 pairs block prion nucleation by disassembling molten oligomers and binding mature oligomers. By binding fibres, Hsp70:Hsp40 pairs occlude prion recognition elements and inhibit seeded assembly. These inhibitory activities are partially relieved by the nucleotide exchange factor, Fes1. Low levels of Hsp104 stimulate prionogenesis and alleviate inhibition by some Hsp70:Hsp40 pairs. At high concentrations, Hsp104 eliminates Sup35 prions. This activity is reduced when Ssa1, or enhanced when Ssb1, is incorporated into nascent prions. These findings illuminate several facets of the chaperone interplay that underpins [PSI(+)] inheritance.     

URE3] prion propagation in Saccharomyces cerevisiae: requirement for chaperone Hsp104 and curing by overexpressed chaperone Ydj1p

The [URE3] nonchromosomal genetic element is an infectious form (prion) of the Ure2 protein, apparently a self-propagating amyloidosis. We find that an insertion mutation or deletion of HSP104 results in inability to propagate the [URE3] prion. Our results indicate that Hsp104 is a common factor in the maintenance of two independent yeast prions. However, overproduction of Hsp104 does not affect the stability of [URE3], in contrast to what is found for the [PSI(+)] prion, which is known to be cured by either overproduction or deficiency of Hsp104. Like Hsp104, the Hsp40 class chaperone Ydj1p, with the Hsp70 class Ssa1p, can renature proteins. We find that overproduction of Ydj1p results in a gradual complete loss of [URE3]. The involvement of protein chaperones in the propagation of [URE3] indicates a role for protein conformation in inheritance.     

Functions of yeast Hsp40 chaperone Sis1p dispensable for prion propagation but important for prion curing and protection from prion toxicity

Replication of amyloid-based yeast prions [PSI(+)], [URE3], and [PIN(+)] depends on the protein disaggregation machinery that includes Hsp104, Hsp70, and Hsp40 molecular chaperones. Yet, overexpressing Hsp104 cures cells of [PSI(+)] prions. An Hsp70 mutant (Ssa1-21p) antagonizes propagation of [PSI(+)] in a manner resembling elevated Hsp104. The major cytosolic Hsp40 Sis1p is the only Hsp40 required for replication of these prions, but its role in [PSI(+)] curing is unknown. Here we find that all nonessential functional regions of Sis1p are dispensable for [PSI(+)] propagation, suggesting that other Hsp40's might provide Hsp40 functions required for [PSI(+)] replication. Conversely, several Sis1p functions were important for promoting antiprion effects of both Ssa1-21p and Hsp104, which implies a link between the antiprion effects of these chaperones and suggests that Sis1p is a specific Hsp40 important for [PSI(+)] curing. These contrasting findings suggest that the functions of Hsp104 that are important for propagation and elimination of [PSI(+)] are either distinct or specified by different Hsp40's. This work also uncovered a growth inhibition caused by [PSI(+)] when certain functions of Sis1p were absent, suggesting that Sis1p protects cells from cytotoxicity caused by [PSI(+)] prions.     

Antagonistic interactions between yeast [PSI(+)] and [URE3] prions and curing of [URE3] by Hsp70 protein chaperone Ssa1p but not by Ssa2p

The yeast [PSI(+)], [URE3], and [PIN(+)] genetic elements are prion forms of Sup35p, Ure2p, and Rnq1p, respectively. Overexpression of Sup35p, Ure2p, or Rnq1p leads to increased de novo appearance of [PSI(+)], [URE3], and [PIN(+)], respectively. This inducible appearance of [PSI(+)] was shown to be dependent on the presence of [PIN(+)] or [URE3] or overexpression of other yeast proteins that have stretches of polar residues similar to the prion-determining domains of the known prion proteins. In a similar manner, [PSI(+)] and [URE3] facilitate the appearance of [PIN(+)]. In contrast to these positive interactions, here we find that in the presence of [PIN(+)], [PSI(+)] and [URE3] repressed each other's propagation and de novo appearance. Elevated expression of Hsp104 and Hsp70 (Ssa2p) had little effect on these interactions, ruling out competition between the two prions for limiting amounts of these protein chaperones. In contrast, we find that constitutive overexpression of SSA1 but not SSA2 cured cells of [URE3], uncovering a specific interaction between Ssa1p and [URE3] and a functional distinction between these nearly identical Hsp70 isoforms. We also find that Hsp104 abundance, which critically affects [PSI(+)] propagation, is elevated when [URE3] is present. Our results are consistent with the notion that proteins that have a propensity to form prions may interact with heterologous prions but, as we now show, in a negative manner. Our data also suggest that differences in how [PSI(+)] and [URE3] interact with Hsp104 and Hsp70 may contribute to their antagonistic interactions.     

A regulatory role of the Rnq1 nonprion domain for prion propagation and polyglutamine aggregates

Prions are infectious, self-propagating protein conformations. Rnq1 is required for the yeast Saccharomyces cerevisiae prion [PIN(+)], which is necessary for the de novo induction of a second prion, [PSI(+)]. Here we isolated a [PSI(+)]-eliminating mutant, Rnq1Delta100, that deletes the nonprion domain of Rnq1. Rnq1Delta100 inhibits not only [PSI(+)] prion propagation but also [URE3] prion and huntingtin's polyglutamine aggregate propagation in a [PIN(+)] background but not in a [pin(-)] background. Rnq1Delta100, however, does not eliminate [PIN(+)]. These findings are interpreted as showing a possible involvement of the Rnq1 prion in the maintenance of heterologous prions and polyQ aggregates. Rnq1 and Rnq1Delta100 form a sodium dodecyl sulfate-stable and Sis1 (an Hsp40 chaperone protein)-containing coaggregate in [PIN(+)] cells. Importantly, Rnq1Delta100 is highly QN-rich and prone to self-aggregate or coaggregate with Rnq1 when coexpressed in [pin(-)] cells. However, the [pin(-)] Rnq1-Rnq1Delta100 coaggregate does not represent a prion-like aggregate. These findings suggest that [PIN(+)] Rnq1-Rnq1Delta100 aggregates interact with other transmissible and nontransmissible amyloids to destabilize them and that the nonprion domain of Rnq1 plays a crucial role in self-regulation of the highly reactive QN-rich prion domain of Rnq1.     

Yeast [PSI+] prion aggregates are formed by small Sup35 polymers fragmented by Hsp104

The yeast [PSI+] determinant is related to formation of large prion-like aggregates of the conformationally altered Sup35 protein. Here, we show that these aggregates are composed of small Sup35 prion polymers and associated proteins. In contrast to other protein complexes of yeast lysates, but similarly to amyloid fibers, these polymers are insoluble in SDS at room temperature. The polymers on average are about 30-fold smaller than the aggregates and comprise from 8 to 50 Sup35 monomers. The size of polymers is characteristic of a given [PSI+] variant and differs between the variants. Blocked expression of Hsp104 chaperone causes gradual increase in the size of prion polymers, while inactivation of Hsp104 by guanidine HCl completely stops their fragmentation, which shows indispensability of Hsp104 for this process.     

Chaperones that cure yeast artificial [PSI+] and their prion-specific effects

The [PSI(+)] nonsense-suppressor determinant of Saccharomyces cerevisiae results from the ability of Sup35 (eRF3) translation termination factor to undergo prion-like aggregation [1]. Although this process is autocatalytic, in vivo it depends on the chaperone Hsp104, whose lack or overexpression can cure [PSI(+)] [2]. Overproduction of the chaperone protein Ssb1 increased the [PSI(+)] curing by excess Hsp104, although it had no effect on its own, and excess chaperone protein Ssa1 protected [PSI(+)] against Hsp104 [3,4]. We used an artificial [PSI(+)(PS)] based on the Sup35 prion-forming domain from yeast Pichia methanolica [5] to find other prion-curing factors. Both [PSI(+)(PS)] and [PSI(+)] have prion 'strains', differing in their suppressor efficiency and mitotic stability. We show that [PSI(+)(PS)] and a 'weak' strain of [PSI(+)] can be cured by overexpression of chaperones Ssa1, Ssb1 and Ydj1. The ability of different chaperones to cure [PSI(+)(PS)] showed significant prion strain specificity, which could be related to variation in Sup35 prion structure. Our results imply that homologs of these chaperones may be active against mammalian prion and amyloid diseases.     

Differences in the curing of [PSI+] prion by various methods of Hsp104 inactivation

[PSI(+)] yeast, containing the misfolded amyloid conformation of Sup35 prion, is cured by inactivation of Hsp104. There has been controversy as to whether inactivation of Hsp104 by guanidine treatment or by overexpression of the dominant negative Hsp104 mutant, Hsp104-2KT, cures [PSI(+)] by the same mechanism- inhibition of the severing of the prion seeds. Using live cell imaging of Sup35-GFP, overexpression of Hsp104-2KT caused the foci to increase in size, then decrease in number, and finally disappear when the cells were cured, similar to that observed in cells cured by depletion of Hsp104. In contrast, guanidine initially caused an increase in foci size but then the foci disappeared before the cells were cured. By starving the yeast to make the foci visible in cells grown with guanidine, the number of cells with foci was found to correlate exactly with the number of [PSI(+)] cells, regardless of the curing method. Therefore, the fluorescent foci are the prion seeds required for maintenance of [PSI(+)] and inactivation of Hsp104 cures [PSI(+)] by preventing severing of the prion seeds. During curing with guanidine, the reduction in seed size is an Hsp104-dependent effect that cannot be explained by limited severing of the seeds. Instead, in the presence of guanidine, Hsp104 retains an activity that trims or reduces the size of the prion seeds by releasing Sup35 molecules that are unable to form new prion seeds. This Hsp104 activity may also occur in propagating yeast.     

Guanidine hydrochloride inhibits the generation of prion "seeds" but not prion protein aggregation in yeast

[PSI(+)] strains of the yeast Saccharomyces cerevisiae replicate and transmit the prion form of the Sup35p protein but can be permanently cured of this property when grown in millimolar concentrations of guanidine hydrochloride (GdnHCl). GdnHCl treatment leads to the inhibition of the replication of the [PSI(+)] seeds necessary for continued [PSI(+)] propagation. Here we demonstrate that the rate of incorporation of newly synthesized Sup35p into the high-molecular-weight aggregates, diagnostic of [PSI(+)] strains, is proportional to the number of seeds in the cell, with seed number declining (and the levels of soluble Sup35p increasing) in the presence of GdnHCl. GdnHCl does not cause breakdown of preexisting Sup35p aggregates in [PSI(+)] cells. Transfer of GdnHCl-treated cells to GdnHCl-free medium reverses GdnHCl inhibition of [PSI(+)] seed replication and allows new prion seeds to be generated exponentially in the absence of ongoing protein synthesis. Following such release the [PSI(+)] seed numbers double every 20 to 22 min. Recent evidence (P. C. Ferreira, F. Ness, S. R. Edwards, B. S. Cox, and M. F. Tuite, Mol. Microbiol. 40:1357-1369, 2001; G. Jung and D. C. Masison, Curr. Microbiol. 43:7-10, 2001), together with data presented here, suggests that curing yeast prions by GdnHCl is a consequence of GdnHCl inhibition of the activity of molecular chaperone Hsp104, which in turn is essential for [PSI(+)] propagation. The kinetics of elimination of [PSI(+)] by coexpression of a dominant, ATPase-negative allele of HSP104 were similar to those observed for GdnHCl-induced elimination. Based on these and other data, we propose a two-cycle model for "prionization" of Sup35p in [PSI(+)] cells: cycle A is the GdnHCl-sensitive (Hsp104-dependent) replication of the prion seeds, while cycle B is a GdnHCl-insensitive (Hsp104-independent) process that converts these seeds to pelletable aggregates.     

Hsp70 targets Hsp100 chaperones to substrates for protein disaggregation and prion fragmentation

Hsp100 and Hsp70 chaperones in bacteria, yeast, and plants cooperate to reactivate aggregated proteins. Disaggregation relies on Hsp70 function and on ATP-dependent threading of aggregated polypeptides through the pore of the Hsp100 AAA(+) hexamer. In yeast, both chaperones also promote propagation of prions by fibril fragmentation, but their functional interplay is controversial. Here, we demonstrate that Hsp70 chaperones were essential for species-specific targeting of their Hsp100 partner chaperones ClpB and Hsp104, respectively, to heat-induced protein aggregates in vivo. Hsp70 inactivation in yeast also abrogated Hsp104 targeting to almost all prions tested and reduced fibril mobility, which indicates that fibril fragmentation by Hsp104 requires Hsp70. The Sup35 prion was unique in allowing Hsp70-independent association of Hsp104 via its N-terminal domain, which, however, was nonproductive. Hsp104 overproduction even outcompeted Hsp70 for Sup35 prion binding, which explains why this condition prevented Sup35 fragmentation and caused prion curing. Our findings indicate a conserved mechanism of Hsp70-Hsp100 cooperation at the surface of protein aggregates and prion fibrils.     

Role of Hsp104 in the propagation and inheritance of the [Het-s] prion

The chaperones of the ClpB/HSP100 family play a central role in thermotolerance in bacteria, plants, and fungi by ensuring solubilization of heat-induced protein aggregates. In addition in yeast, Hsp104 was found to be required for prion propagation. Herein, we analyze the role of Podospora anserina Hsp104 (PaHsp104) in the formation and propagation of the [Het-s] prion. We show that DeltaPaHsp104 strains propagate [Het-s], making [Het-s] the first native fungal prion to be propagated in the absence of Hsp104. Nevertheless, we found that [Het-s]-propagon numbers, propagation rate, and spontaneous emergence are reduced in a DeltaPaHsp104 background. In addition, inactivation of PaHsp104 leads to severe meiotic instability of [Het-s] and abolishes its meiotic drive activity. Finally, we show that DeltaPaHSP104 strains are less susceptible than wild type to infection by exogenous recombinant HET-s(218-289) prion amyloids. Like [URE3] and [PIN(+)] in yeast but unlike [PSI(+)], [Het-s] is not cured by constitutive PaHsp104 overexpression. The observed effects of PaHsp104 inactivation are consistent with the described role of Hsp104 in prion aggregate shearing in yeast. However, Hsp104-dependency appears less stringent in P. anserina than in yeast; presumably because in Podospora prion propagation occurs in a syncitium.     

Hsp70 chaperones as modulators of prion life cycle: novel effects of Ssa and Ssb on the Saccharomyces cerevisiae prion [PSI+

[PSI(+)] is a prion isoform of the yeast release factor Sup35. In some assays, the cytosolic chaperones Ssa1 and Ssb1/2 of the Hsp70 family were previously shown to exhibit "pro-[PSI(+)]" and "anti-[PSI(+)]" effects, respectively. Here, it is demonstrated for the first time that excess Ssa1 increases de novo formation of [PSI(+)] and that pro-[PSI(+)] effects of Ssa1 are shared by all other Ssa proteins. Experiments with chimeric constructs show that the peptide-binding domain is a major determinant of differences in the effects of Ssa and Ssb proteins on [PSI(+)]. Surprisingly, overproduction of either chaperone increases loss of [PSI(+)] when Sup35 is simultaneously overproduced. Excess Ssa increases both the average size of prion polymers and the proportion of monomeric Sup35 protein. Both in vivo and in vitro experiments uncover direct physical interactions between Sup35 and Hsp70 proteins. The proposed model postulates that Ssa stimulates prion formation and polymer growth by stabilizing misfolded proteins, which serve as substrates for prion conversion. In the case of very large prion aggregates, further increase in size may lead to the loss of prion activity. In contrast, Ssb either stimulates refolding into nonprion conformation or targets misfolded proteins for degradation, in this way counteracting prion formation and propagation.     

Regulation of the Hsp104 Middle Domain Activity Is Critical for Yeast Prion Propagation

Molecular chaperones play a significant role in preventing protein misfolding and aggregation. Indeed, some protein conformational disorders have been linked to changes in the chaperone network. Curiously, in yeast, chaperones also play a role in promoting prion maintenance and propagation. While many amyloidogenic proteins are associated with disease in mammals, yeast prion proteins, and their ability to undergo conformational conversion into a prion state, are proposed to play a functional role in yeast biology. The chaperone Hsp104, a AAA+ ATPase, is essential for yeast prion propagation. Hsp104 fragments large prion aggregates to generate a population of smaller oligomers that can more readily convert soluble monomer and be transmitted to daughter cells. Here, we show that the middle (M) domain of Hsp104, and its mobility, plays an integral part in prion propagation. We generated and characterized mutations in the M-domain of Hsp104 that are predicted to stabilize either a repressed or de-repressed conformation of the M-domain (by analogy to ClpB in bacteria). We show that the predicted stabilization of the repressed conformation inhibits general chaperone activity. Mutation to the de-repressed conformation, however, has differential effects on ATP hydrolysis and disaggregation, suggesting that the M-domain is involved in coupling these two activities. Interestingly, we show that changes in the M-domain differentially affect the propagation of different variants of the [PSI+] and [RNQ+] prions, which indicates that some prion variants are more sensitive to changes in the M-domain mobility than others. Thus, we provide evidence that regulation of the M-domain of Hsp104 is critical for efficient prion propagation. This shows the importance of elucidating the function of the M-domain in order to understand the role of Hsp104 in the propagation of different prions and prion variants.     

Requirements of Hsp104p activity and Sis1p binding for propagation of the [RNQ+] prion

The formation and maintenance of prions in the yeast Saccharomyces cerevisiae is highly regulated by the cellular chaperone machinery. The most important player in this regulation is Hsp104p, which is required for the maintenance of all known prions.

The requirements for other chaperones, such as members of the Hsp40 or Hsp70 families, vary with each individual prion. [RNQ+] cells do not have a phenotype that is amenable to genetic screens to identify cellular factors important in prion propagation. Therefore, we used a chimeric construct that reports the [RNQ+] status of cells to perform a screen for mutants that are unable to maintain [RNQ+]. We found eight separate mutations in Hsp104p that caused [RNQ+] cells to become [rnq-]. These mutations also caused the loss of the [PSI+] prion. The expression of one of these mutants, Hsp104p-E190K, showed differential loss of the [RNQ+] and [PSI+] prions in the presence of wild type Hsp104p. Hsp104p-E190K inefficiently propagated [RNQ+] and was unable to maintain [PSI+]. The mutant was unable to act on other in vivo substrates, as strains carrying it were not thermotolerant. Purified recombinant Hsp104p-E190K showed a reduced level of ATP hydrolysis as compared to wild type protein. This is likely the cause of both prion loss and lack of in vivo function. Furthermore, it suggests that [RNQ+] requires less Hsp104p activity to maintain transmissible protein aggregates than Sup35p. Additionally, we show that the L94A mutation in Rnq1p, which reduces its interaction with Sis1p, prevents Rnq1p from maintaining a prion and inducing [PSI+].     

Destruction or potentiation of different prions catalyzed by similar Hsp104 remodeling activities

Yeast prions are protein-based genetic elements that self-perpetuate changes in protein conformation and function. A protein-remodeling factor, Hsp104, controls the inheritance of several yeast prions, including those formed by Sup35 and Ure2. Perplexingly, deletion of Hsp104 eliminates Sup35 and Ure2 prions, whereas overexpression of Hsp104 purges cells of Sup35 prions, but not Ure2 prions. Here, we used pure components to dissect how Hsp104 regulates prion formation, growth, and division. For both Sup35 and Ure2, Hsp104 catalyzes de novo prion nucleation from soluble, native protein. Using a distinct mechanism, Hsp104 fragments both prions to generate new prion assembly surfaces. For Sup35, the fragmentation endpoint is an ensemble of noninfectious, amyloid-like aggregates and soluble protein that cannot replicate conformation. In vivid distinction, the endpoint of Ure2 fragmentation is short prion fibers with enhanced infectivity and self-replicating ability. These advances explain the distinct effects of Hsp104 on the inheritance of the two prions.