Specificity of prion assembly in vivo. [PSI+] and [PIN+] form separate structures in yeast

The yeast prions [PSI+] and [PIN+] are self-propagating amyloid aggregates of the Gln/Asn-rich proteins Sup35p and Rnq1p, respectively. Like the mammalian PrP prion "strains," [PSI+] and [PIN+] exist in different conformations called variants. Here, [PSI+] and [PIN+] variants were used to model in vivo interactions between co-existing heterologous amyloid aggregates. Two levels of structural organization, like those previously described for [PSI+], were demonstrated for [PIN+]. In cells with both [PSI+] and [PIN+] the two prions formed separate structures at both levels. Also, the destabilization of [PSI+] by certain [PIN+] variants was shown not to involve alterations in the [PSI+] prion size. Finally, when two variants of the same prion that have aggregates with distinct biochemical characteristics were combined in a single cell, only one aggregate type was propagated. These studies demonstrate the intracellular organization of yeast prions and provide insight into the principles of in vivo amyloid assembly.     

New aspects of research upon the yeast Saccharomyces cerevisiae [PSI+] prion

One of the key feature of prions is the ability to be stable in two alternative conformations. Besides the intensively studied mammalian prions, there are also prion proteins present in the yeast Saccharomyces cerevisiae. Research in this field has lead to opposite hypotheses that explain the sense of presence of [PSI+] prion in yeast cells. Some authors postulate e of role of the prions in the evolution of S. cerevisiae, whereas other investigators point out the negative influence of these particles upon the yeast physiology. In recent years, yeast prions are used for anti-prion drug screening, because of common features with mammalian prions. This work presents the most intensively studied fields of the research carried out on [PSI+] prion in yeast.     

Translation termination efficiency can be regulated in Saccharomyces cerevisiae by environmental stress through a prion-mediated mechanism

[PSI+] is a protein-based heritable phenotype of the yeast Saccharomyces cerevisiae which reflects the prion-like behaviour of the endogenous Sup35p protein release factor. [PSI+] strains exhibit a marked decrease in translation termination efficiency, which permits decoding of translation termination signals and, presumably, the production of abnormally extended polypeptides. We have examined whether the [PSI+]-induced expression of such an altered proteome might confer some selective growth advantage over [psi-] strains. Although otherwise isogenic [PSI+] and [psi-] strains show no difference in growth rates under normal laboratory conditions, we demonstrate that [PSI+] strains do exhibit enhanced tolerance to heat and chemical stress, compared with [psi-] strains. Moreover, we also show that the prion-like determinant [PSI+] is able to regulate translation termination efficiency in response to environmental stress, since growth in the presence of ethanol results in a transient increase in the efficiency of translation termination and a loss of the [PSI+] phenotype. We present a model to describe the prion-mediated regulation of translation termination efficiency and discuss its implications in relation to the potential physiological role of prions in S.cerevisiae and other fungi.     

The role of Sse1 in the de novo formation and variant determination of the [PSI+] prion

Yeast prions are a group of non-Mendelian genetic elements transmitted as altered and self-propagating conformations. Extensive studies in the last decade have provided valuable information on the mechanisms responsible for yeast prion propagation. How yeast prions are formed de novo and what cellular factors are required for determining prion "strains" or variants--a single polypeptide capable of existing in multiple conformations to result in distinct heritable phenotypes--continue to defy our understanding. We report here that Sse1, the yeast ortholog of the mammalian heat-shock protein 110 (Hsp110) and a nucleotide exchange factor for Hsp70 proteins, plays an important role in regulating [PSI+] de novo formation and variant determination. Overproduction of the Sse1 chaperone dramatically enhanced [PSI+] formation whereas deletion of SSE1 severely inhibited it. Only an unstable weak [PSI+] variant was formed in SSE1 disrupted cells whereas [PSI+] variants ranging from very strong to very weak were formed in isogenic wild-type cells under identical conditions. Thus, Sse1 is essential for the generation of multiple [PSI+] variants. Mutational analysis further demonstrated that the physical association of Sse1 with Hsp70 but not the ATP hydrolysis activity of Sse1 is required for the formation of multiple [PSI+] variants. Our findings establish a novel role for Sse1 in [PSI+] de novo formation and variant determination, implying that the mammalian Hsp110 may likewise be involved in the etiology of protein-folding diseases.     

Nonsense suppression in yeast cells overproducing Sup35 (eRF3) is caused by its non-heritable amyloids

The [PSI+] prion determinant of Saccharomyces cerevisiae causes nonsense suppressor phenotype due to a reduced function of the translation termination factor Sup35 (eRF3) polymerized into amyloid fibrils. Prion state of the Rnq1 protein, [PIN+], is required for the [PSI+] de novo generation but not propagation. Yeast [psi-] [PIN+] cells overproducing Sup35 can exhibit nonsense suppression without generation of a stable [PSI+]. Here, we show that in such cells, most of Sup35 represents amyloid polymers, although the remaining Sup35 monomer is sufficient for normal translation termination. The presence of these polymers strictly depends on [PIN+], suggesting that their maintenance relies on efficient generation de novo rather than inheritance. Sup35 polymers contain Rnq1, confirming a hypothesis that Rnq1 polymers seed Sup35 polymerization. About 10% of cells overproducing Sup35 form colonies on medium selective for suppression, which suggests that the proportion of Sup35 monomers to polymers varies between cells of transformants, allowing selection of cells deficient for soluble Sup35. A hybrid Sup35 with the N-terminal domain replaced for 66 glutamine residues also polymerizes and can cause nonsense suppression when overproduced. The described polymers of these proteins differ from the [PSI+] polymers by poor heritability and very high frequency of the de novo appearance, thus being more similar to amyloids than to prions.     

PSI+] Prion transmission barriers protect Saccharomyces cerevisiae from infection: intraspecies 'species barriers'

[PSI+] is a prion of Sup35p, an essential translation termination and mRNA turnover factor. The existence of lethal [PSI+] variants, the absence of [PSI+] in wild strains, the mRNA turnover function of the Sup35p prion domain, and the stress reaction to prion infection suggest that [PSI+] is a disease. Nonetheless, others have proposed that [PSI+] and other yeast prions benefit their hosts. We find that wild Saccharomyces cerevisiae strains are polymorphic for the sequence of the prion domain and particularly in the adjacent M domain. Here we establish that these variations within the species produce barriers to prion transmission. The barriers are partially asymmetric in some cases, and evidence for variant specificity in barriers is presented. We propose that, as the PrP 129M/V polymorphism protects people from Creutzfeldt-Jakob disease, the Sup35p polymorphisms were selected to protect yeast cells from prion infection. In one prion incompatibility group, the barrier is due to N109S in the Sup35 prion domain and several changes in the middle (M) domain, with either the single N109S mutation or the group of M changes (without the N109S) producing a barrier. In another, the barrier is due to a large deletion in the repeat domain. All are outside the region previously believed to determine transmission compatibility. [SWI+], a prion of the chromatin remodeling factor Swi1p, was also proposed to benefit its host. We find that none of 70 wild strains carry this prion, suggesting that it is not beneficial.     

A mutation within the C-terminal domain of Sup35p that affects [PSI+] prion propagation

The epigenetic factor [PSI+] in the yeast Saccharomyces cerevisiae is due to the prion form of Sup35p. The N-terminal domain of Sup35p (N), alone or together with the middle-domain (NM), assembles in vitro into fibrils that induce [PSI+] when introduced into yeast cells. The Sup35p C-terminal domain (C), involved in translation termination, is essential for growth. The involvement of Sup35p C-terminal domain into [PSI+] propagation is subject to debate. We previously showed that mutation of threonine 341 within Sup35p C-domain affects translation termination efficiency. Here, we demonstrate that mutating threonine 341 to aspartate or alanine results in synthetic lethality with [PSI+] and weakening of [PSI+] respectively. The corresponding Sup35D and Sup35A proteins assemble into wild-type like fibrils in vitro, but with a slower elongation rate. Moreover, cross-seeding between Sup35p and Sup35A is inefficient both in vivo and in vitro, suggesting that the point mutation alters the structural properties of Sup35p within the fibrils. Thus, Sup35p C-terminal domain modulates [PSI+] prion propagation, possibly through a functional interaction with the N and/or M domains of the protein. Our results clearly demonstrate that Sup35p C-terminal domain plays a critical role in prion propagation and provide new insights into the mechanism of prion conversion.     

Yeast prions, mammalian amyloidoses, and the problem of proteomic networks

Prion proteins are infective amyloids and cause several neurodegenerative diseases in humans and animals. In yeasts, prions are expressed as cytoplasmic heritable determinants of a protein nature. Yeast prion [PSI], which results from a conformational rearrangement and oligomerization of translation termination factor eRF3, is used as an example to consider the structural--functional relationships in a potentially prion molecule, specifics of its evolution, and interactions with other prions, which form so-called prion networks. In addition, the review considers the results of modeling mammalian prion diseases and other amyloidoses in yeast cells. A hypothesis of proteomic networks is proposed by analogy with prion networks, involving interactions of different amyloids in mammals.     

Destabilizing interactions among [PSI(+)] and [PIN(+)] yeast prion variants

The yeast Sup35 and Rnq1 proteins can exist in either the noninfectious soluble forms, [psi-] or [pin-], respectively, or the multiple infectious amyloid-like forms called [PSI+] or [PIN+] prion variants (or prion strains). It was previously shown that [PSI+] and [PIN+] prions enhance one another's de novo appearance. Here we show that specific prion variants of [PSI+] and [PIN+] disrupt each other's stable inheritance. Acquiring [PSI+] often impedes the inheritance of particular [PIN+] variants. Conversely, the presence of some [PIN+] variants impairs the inheritance of weak [PSI+] but not strong [PSI+] variants. These same [PIN+] variants generate a single-dot fluorescence pattern when a fusion of Rnq1 and green fluorescent protein is expressed. Another [PIN+] variant, which forms a distinctly different multiple-dot fluorescence pattern, does not impair [PSI+] inheritance. Thus, destabilization of prions by heterologous prions depends upon the variants involved. These findings may have implications for understanding interactions among other amyloid-forming proteins, including those associated with certain human diseases.     

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.     

The [PSI+] prion of yeast: a problem of inheritance

The [PSI(+)] prion of the yeast Saccharomyces cerevisiae was first identified by Brian Cox some 40 years ago as a non-Mendelian genetic element that modulated the efficiency of nonsense suppression. Following the suggestion by Reed Wickner in 1994 that such elements might be accounted for by invoking a prion-based model, it was subsequently established that the [PSI(+)] determinant was the prion form of the Sup35p protein. In this article, we review how a combination of classical genetic approaches and modern molecular and biochemical methods has provided conclusive evidence of the prion basis of the [PSI(+)] determinant. In so doing we have tried to provide a historical context, but also describe the results of more recent experiments aimed at elucidating the mechanism by which the [PSI(+)] (and other yeast prions) are efficiently propagated in dividing cells. While understanding of the [PSI(+)] prion and its mode of propagation has, and will continue to have, an impact on mammalian prion biology nevertheless the very existence of a protein-based mechanism that can have a beneficial impact on a cell's fitness provides equally sound justification to fully explore yeast prions.     

Novel non-Mendelian determinant involved in the control of translation accuracy in Saccharomyces cerevisiae.

Two cytoplasmically inherited determinants related by their manifestation to the control of translation accuracy were previously described in yeast. Cells carrying one of them, [PSI(+)], display a nonsense suppressor phenotype and contain a prion form of the Sup35 protein. Another element, [PIN(+)], determines the probability of de novo generation of [PSI(+)] and results from a prion form of several proteins, which can be functionally unrelated to Sup35p. Here we describe a novel nonchromosomal determinant related to the SUP35 gene. This determinant, designated [ISP(+)], was identified as an antisuppressor of certain sup35 mutations. We observed its loss upon growth on guanidine hydrochloride and subsequent spontaneous reappearance with high frequency. The reversible curability of [ISP(+)] resembles the behavior of yeast prions. However, in contrast to known prions, [ISP(+)] does not depend on the chaperone protein Hsp104. Though manifestation of both [ISP(+)] and [PSI(+)] is related to the SUP35 gene, the maintenance of [ISP(+)] does not depend on the prionogenic N-terminal domain of Sup35p and Sup35p is not aggregated in [ISP(+)] cells, thus ruling out the possibility that [ISP(+)] is a specific form of [PSI(+)]. We hypothesize that [ISP(+)] is a novel prion involved in the control of translation accuracy in yeast.     

The yeast prions [PSI+] and [URE3] are molecular degenerative diseases

The yeast prions [URE3] and [PSI] are not found in wild strains, suggesting they are not an advantage. Prion-forming ability is not conserved, even within Saccharomyces, suggesting it is a disease. Prion domains have non-prion functions, explaining some conservation of sequence. However, in spite of the sequence being constrained in evolution by these non-prion functions, the prion domains vary more rapidly than the remainder of the molecule, and these changes produce a transmission barrier, suggesting that these changes were selected to block prion infection. Yeast prions [PSI] and [URE3] induce a cellular stress response (Hsp104 and Hsp70 induction), suggesting the cells are not happy about being infected. Recently, we showed that the array of [PSI] and [URE3] prions includes a majority of lethal or very toxic variants, a result not expected if either prion were an adaptive cellular response to stress.Key words: [URE3], [PSI⁺], prion, Sup35p, Ure2pfMammalian prions are uniformly fatal, but a lethal yeast prion would not be detected by the usual procedure, which requires growth of a colony under some selective condition. As a result, the prion variants commonly studied are quite mild in their effects. This circumstance has led to the suggestion that yeast prions actually benefit their host. Sup35p, the translation termination subunit whose amyloid becomes the [PSI⁺] prion, is essential for growth and Ure2p, the nitrogen regulation protein whose amyloid constitutes the [URE3] prion, is important for growth, with ure2 mutants showing noticeably slowed growth.When yeast prions were discovered,¹ we assumed they were diseases, by analogy with the mammalian diseases and the many non-prion amyloid diseases. Inactivating the essential Sup35p or the desireable Ure2p did not seem like a useful strategy. While control of either protein''s activity might be advantageous, and Ure2p activity control is the key to regulation of nitrogen catabolism, prion formation is a stochastic process, so it makes control of activity of these proteins random instead of appropriate to the circumstances. The [Het-s] prion changed that picture.² Here was a prion necessary for a normal function, heterokaryon incompatibility, and we suggested that it was the first beneficial prion.³     

Deletion of the Hsp70 chaperone gene SSB causes hypersensitivity to guanidine toxicity and curing of the [PSI+] prion by increasing guanidine uptake in yeast

Yeast Ssb proteins (Ssbp) are ribosome-associated Hsp70 chaperones that function in translation. Elevated levels of Ssbp enhance the ability of over-expressed Hsp104 chaperone to eliminate the yeast [PSI+] prion, while depletion of Ssbp reduces this effect. Millimolar concentrations of guanidine in the growth medium cure yeast cells of prions by inactivating Hsp104. Guanidine is also toxic to yeast, irrespective of the status of Hsp104 and [PSI+]. Strains that lack Ssbp are hypersensitive to guanidine toxicity. Here we show that ssb- cells have normal numbers of [PSI+] "seeds", but can be cured of [PSI+] using one-sixth of the guanidine concentration required to eliminate [PSI+] from SSB cells. Correspondingly, the level of intracellular guanidine was eight-fold higher in ssb- cells than in wild-type cells, which explains all effects of Ssbp depletion on susceptibility to guanidine. The sensitivity of wild-type cells to the effects of guanidine also correlated with guanidine uptake, which was enhanced at low temperature. Guanidine sensitivity of strains mutated in any of 16 ABC membrane transporters, which are implicated in multidrug resistance, was normal. We found that an erg6 mutant that has an altered membrane lipid composition was hypersensitive to guanidine toxicity, but the lipid composition of ssb- cells was identical to that of wild-type cells. Our results suggest that Ssbp depletion does not affect prion seed regeneration, and that elevated guanidine uptake by ssb- cells may be due to increased retention rather than to an alteration in active or passive transport of the compound.     

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.     

Interaction between yeast Sup45p (eRF1) and Sup35p (eRF3) polypeptide chain release factors: implications for prion-dependent regulation.

The SUP45 and SUP35 genes of Saccharomyces cerevisiae encode polypeptide chain release factors eRF1 and eRF3, respectively. It has been suggested that the Sup35 protein (Sup35p) is subject to a heritable conformational switch, similar to mammalian prions, thus giving rise to the non-Mendelian [PSI+] nonsense suppressor determinant. In a [PSI+] state, Sup35p forms high-molecular-weight aggregates which may inhibit Sup35p activity, leading to the [PSI+] phenotype. Sup35p is composed of the N-terminal domain (N) required for [PSI+] maintenance, the presumably nonfunctional middle region (M), and the C-terminal domain (C) essential for translation termination. In this study, we observed that the N domain, alone or as a part of larger fragments, can form aggregates in [PSI+] cells. Two sites for Sup45p binding were found within Sup35p: one is formed by the N and M domains, and the other is located within the C domain. Similarly to Sup35p, in [PSI+] cells Sup45p was found in aggregates. The aggregation of Sup45p is caused by its binding to Sup35p and was not observed when the aggregated Sup35p fragments did not contain sites for Sup45p binding. The incorporation of Sup45p into the aggregates should inhibit its activity. The N domain of Sup35p, responsible for its aggregation in [PSI+] cells, may thus act as a repressor of another polypeptide chain release factor, Sup45p. This phenomenon represents a novel mechanism of regulation of gene expression at the posttranslational level.     

Propagation of the yeast prion-like [psi+] determinant is mediated by oligomerization of the SUP35-encoded polypeptide chain release factor.

The Sup35p protein of yeast Saccharomyces cerevisiae is a homologue of the polypeptide chain release factor 3 (eRF3) of higher eukaryotes. It has been suggested that this protein may adopt a specific self-propagating conformation, similar to mammalian prions, giving rise to the [psi+] nonsense suppressor determinant, inherited in a non-Mendelian fashion. Here we present data confirming the prion-like nature of [psi+]. We show that Sup35p molecules interact with each other through their N-terminal domains in [psi+], but not [psi-] cells. This interaction is critical for [psi+] propagation, since its disruption leads to a loss of [psi+]. Similarly to mammalian prions, in [psi+] cells Sup35p forms high molecular weight aggregates, accumulating most of this protein. The aggregation inhibits Sup35p activity leading to a [psi+] nonsense-suppressor phenotype. N-terminally altered Sup35p molecules are unable to interact with the [psi+] Sup35p isoform, remain soluble and improve the translation termination in [psi+] strains, thus causing an antisuppressor phenotype. The overexpression of Hsp104p chaperone protein partially solubilizes Sup35P aggregates in the [psi+] strain, also causing an antisuppressor phenotype. We propose that Hsp104p plays a role in establishing stable [psi+] inheritance by splitting up Sup35p aggregates and thus ensuring equidistribution of the prion-like Sup35p isoform to daughter cells at cell divisions.     

Overexpression of gene PPZ1 in the yeast Saccharomyces cerevisiae affects the efficiency of nonsense suppression

The phenomenon of nonsense suppression, which leads to the reading of stop codons as sense codons, may be related to disturbances in the operation of various components of the translation apparatus and the proteins interacting with them. The phosphatase Ppzlp is one of the factors affecting the nonsense suppression efficiency in the saccharomycete yeast. In this work, the impact of the overexpression of gene PPZ1 and its mutant allele PPZ1-R451L on the phenotypic expression of various mutant alleles of genes SUP35 and SUP45 or the yeast prion [PSI+] was analyzed. On the basis of the data obtained, a suggestion about the possible role of proteins Sup35p and Sup45p in the processes mediating the influence of gene PPZ1 overexpression on the efficiency of nonsense suppression is made.     

Prion diseases of yeast: amyloid structure and biology

Prion "variants" or "strains" are prions with the identical protein sequence, but different characteristics of the prion infection: e.g. different incubation periods for scrapie strains or different phenotype intensities for yeast prion variants. We have shown that infectious amyloids of the yeast prions [PSI+], [URE3] and [PIN+] each have an in-register parallel β-sheet architecture. Moreover, we have pointed out that this amyloid architecture can explain how one protein can faithfully transmit any of several conformations to new protein monomers. This explains how proteins can be genes.