Phenotypic manifestation of epigenetic determinant [ISP+] in Saccharomyces serevisiae depends on combination of mutations in SUP35 and SUP45 genes

It is known that translation fidelity in Saccharomyces yeast is determined by factors of genetic and epigenetic (prion) nature. The work represents results of further analysis of strains containing non-chromosomal determinant [ISP+], described earlier. This determinant is involved in the control of translation fidelity and some of its properties indicate that it is a prion. [ISP+] manifests phenotypically as antisuppressor of two sup35 mutations and can be cured by guanidine hydrochloride (GuHCl). Here we have shown that sup35 mutants containing [ISP+] contain also additional sup45 mutations. These mutations cause amino acid replacements in different regions of eRF1 translation termination factor, encoded by SUP45 gene. Strains bearing sup35-25 mutation contain sup45 mutation, which causes amino acid replacement at position 400 of eRF1; strains bearing sup35-10 contain mutation causing replacement, which alters eRF1 at position 75. Thus, antisuppressor phenotype of [ISP+] strains depends on interaction of sup35 and sup45 mutations, as well as on the GuHCl-curable epigenetic determinant.     

Search for genes influencing the maintenance of the [<Emphasis Type="Italic">ISP</Emphasis><Superscript>+</Superscript>] prion-like antisuppressor determinant in yeast with the use of an insertion gene library

The prion-like determinant [ISP ⁺] manifests itself as an antisuppressor of certain sup35 mutations. To establish that [ISP ⁺] is indeed a new yeast prion, it is necessary to identify the gene that codes for the protein whose prion form is [ISP ⁺]. Analysis of the transformants obtained by transformation of an [ISP ⁺] strain with an insertion gene library revealed three genes controlling the [ISP ⁺] maintenance: UPF1, UPF2, and SFP1. SFP1 codes for a potentially prionogenic protein, which is enriched in Asn and Gln residues, and is thereby the most likely candidate for the [ISP ⁺] structural gene. UPF1 and UPF2 code for components of nonsense-mediated mRNA decay. The [ISP ⁺] elimination caused by UPF1 and UPF2 inactivation was reversible, and Upf1p and Upf2p were not functionally related to phosphatase Ppz1p, which influences the [ISP ⁺] manifestation. Possible mechanisms sustaining the influence of UPF1 and UPF2 on [ISP ⁺] maintenance are discussed.     

Prion-Dependent Lethality of sup45 Mutants in Saccharomyces cerevisiae

In yeast Saccharomyces cerevisiae translation termination factors eRF1 (Sup45) and eRF3 (Sup35) are encoded by the essential genes SUP45 and SUP35 respectively. Heritable aggregation of Sup35 results in formation of the yeast prion [PSI⁺]. It is known that combination of [PSI⁺] with some mutant alleles of the SUP35 or SUP45 genes in one and the same haploid yeast cell causes synthetic lethality. In this study, we perform detailed analysis of synthetic lethality between various sup45 nonsense and missense mutations on one hand, and different variants of [PSI⁺] on the other hand. Synthetic lethality with sup45 mutations was detected for [PSI⁺] variants of different stringencies. Moreover, we demonstrate for the first time that in some combinations, synthetic lethality is dominant and occurs at the postzygotic stage after only a few cell divisions. The tRNA suppressor SUQ5 counteracts the prion-dependent lethality of the nonsense alleles but not of the missense alleles of SUP45, indicating that the lethal effect is due to the depletion of Sup45. Synthetic lethality is also suppressed in the presence of the C-proximal fragment of Sup35 (Sup35C) that lacks the prion domain and cannot be included into the prion aggregates. Remarkably, the production of Sup35C in a sup45 mutant strain is also accompanied by an increase in the Sup45 levels, suggesting that translationally active Sup35 up-regulates Sup45 or protects it from degradation.Key Words: Sup45, Sup35, eRF1, eRF3, amyloid, [PSI⁺], translation termination, Saccharomyces cerevisiae     

The Genetic Control of the Formation and Propagation of the [PSI+] Prion of Yeast

It is over 40 years since it was first reported that the yeast Saccahromyces cerevisiae contains two unusual cytoplasmic ‘genetic’ elements: [PSI⁺] and [URE3]. Remarkably the underlying determinants are protein-based rather than nucleic acid-based, i.e., that they are prions, and we have already learnt much about their inheritance and phenotypic effects from the application of ‘classical’ genetic studies alongside the more modern molecular, cellular and biochemical approaches. Of particular value has been the exploitation of chemical mutagens and ‘antagonistic’ mutants which directly affect the replication and/or transmission of yeast prions. In this Chapter we describe what has emerged from the application of classical and molecular genetic studies, to the most intensively studied of the three native yeast prions, the [PSI⁺] prion.Key Words: yeast, [PSI], prion, SUP35/eRF3, SUP45/eRF1, antisuppressor, [PSI⁺] maintenance genes, Hsp104, prion antagonists     

The paradox of viable <Emphasis Type="Italic">sup45</Emphasis> STOP mutations: a necessary equilibrium between translational readthrough,activity and stability of the protein

The mechanisms leading to non-lethality of nonsense mutations in essential genes are poorly understood. Here, we focus on the factors influencing viability of yeast cells bearing premature termination codons (PTCs) in the essential gene SUP45 encoding translation termination factor eRF1. Using a dual reporter system we compared readthrough efficiency of the natural termination codon of SUP45 gene, spontaneous sup45-n (nonsense) mutations, nonsense mutations obtained by site-directed mutagenesis (76Q → TAA, 242R → TGA, 317L → TAG). The nonsense mutations in SUP45 gene were shown to be situated in moderate contexts for readthrough efficiency. We showed that readthrough efficiency of some of the mutations present in the sup45 mutants is not correlated with full-length Sup45 protein amount. This resulted from modification of both sup45 mRNA stability which varies 3-fold among sup45-n mutants and degradation rate of mutant Sup45 proteins. Our results demonstrate that some substitutions in the place of PTCs decrease Sup45 stability. The viability of sup45 nonsense mutants is therefore supported by diverse mechanisms that control the final amount of functional Sup45 in cells.     

Interactions of [NSI +] prion-like determinant with SUP35 and VTS1 genes in Saccharomyces cerevisiae

Previously we characterized [NSI ⁺], determinant, that possesses the features of a yeast prion. This determinant causes the nonsense suppression in strains that bear different N-substituted variants of Sup35p, which is a translation release factor eRF3. As a result of the genomic screen, we identified VTS1, the overexpression of which is a phenotypic copy of [NSI ⁺]. Here, we analyzed the influence of SUP35 and VTS1 on [NSI ⁺]. We demonstrated nonsense suppression in the [NSI ⁺] strains, which appears when SUP35 expression was decreased or against a background of general defects in the fidelity of translation termination. [NSI ⁺] has also been shown to increase VTS1 mRNA amounts. These findings facilitate the insight into the mechanisms of nonsense suppression in the [NSI ⁺] strains and narrow the range of candidates for [NSI ⁺] determinant.     

A Systematic Evaluation of the Function of the Protein-Remodeling Factor Hsp104 in [PSI+] Prion Propagation in S. cerevisiae by Comprehensive Chromosomal Mutations

The yeast prion [PSI⁺] represents an aggregated state of the translational release factor Sup35 (eRF3) and deprives termination complexes of functional Sup35, resulting in nonsense codon suppression. Protein-remodeling factor Hsp104 is involved in thermotolerance and [PSI⁺] propagation, however the structure-and-function relationship of Hsp104 for [PSI⁺] remains unclear. In this study, we engineered 58 chromosomal hsp104 mutants that affect residues considered structurally or functionally relevant to Hsp104 remodeling activity, yet most remain to be examined for their significance to [PSI⁺] in the same genetic background. Many of these hsp104 mutants were affected both in thermotolerance and [PSI⁺] propagation. However, nine mutants were impaired exclusively for [PSI⁺], while two mutants were impaired exclusively for thermotolerance. Mutations exclusively affecting [PSI⁺] are clustered around the lateral channel of the Hsp104 hexamer. These findings suggest that Hsp104 possesses shared as well as distinct remodeling activities for stress-induced protein aggregates and [PSI⁺] prion aggregates and that the lateral channel plays a role specific to [PSI⁺] prion propagation.     

Comparative assay of amyloid and prion contents in yeast cells

Amyloid contents were quantitatively assayed in crude yeast lysates treated with thioflavin T that specifically stained amyloid fibrils. We demonstrated that guanidine hydrochloride (GuHCl) treatment and overexpression of Hsp104p chaperone resulted in the elimination of the [PSI ⁺] factor and that the stable decline in amyloid contents followed from the reduced fluorescence intensity (IF) of thioflavin T. Overexpression of the SUP35 gene coding the protein prionizable to [PSI ⁺] results in the generation of [PSI ⁺] clones with increased thioflavin T IF. Transmission of [PSI ⁺] factor by cytoduction in crossings of recipients with low IF was also accompanied by stable IF enhancement in cytoductants, indicating enriched amyloid contents. Thus, in model experiments, modifying the quantity of [PSI ⁺] factor, a yeast prion amyloid, the change in thioflavin T IF corresponds to the expected shift in amyloid contents, the IF shift behaving as a cytoplasm hereditary determinant. It is concluded that thioflavin T IF allows for the quantitative estimation of amyloid contents in cells. The stable mitotic IF shift induced by agents affecting the prion composition permits the quantitative evaluation of prion contribution into amyloid pool. It is possible to assume that the monitoring of thiophlavin T IF shifts under the exposure of agents affecting prion pattern may be helpful to disclose previously unknown prions in yeast strains.     

W8, a new Sup35 prion strain,transmits distinctive information with a conserved assembly scheme

ABSTRACT

Prion strains are different self-propagating conformers of the same infectious protein. Three strains of the [PSI] prion, infectious forms of the yeast Sup35 protein, have been previously characterized in our laboratory. Here we report the discovery of a new [PSI] strain, named W8. We demonstrate its robust cellular propagation as well as the protein-only transmission. To reveal strain-specific sequence requirement, mutations that interfered with the propagation of W8 were identified by consecutive substitution of residues 5–55 of Sup35 by proline and insertion of glycine at alternate sites in this segment. Interestingly, propagating W8 with single mutations at residues 5–7 and around residue 43 caused the strain to transmute. In contrast to the assertion that [PSI] existed as a dynamic cloud of sub-structures, no random drift in transmission characteristics was detected in mitotically propagated W8 populations. Electron diffraction and mass-per-length measurements indicate that, similar to the 3 previously characterized strains, W8 fibers are composed of about 1 prion molecule per 4.7-Å cross-β repeat period. Thus differently folded single Sup35 molecules, not dimeric and trimeric assemblies, form the basic repeating units to build the 4 [PSI] strains.     

Ribosomal proteins of yeast strains carrying mutations which affect the efficiency of nonsense suppression

Summary We have examined the ribosomal proteins of strains of Saccharomyces cerevisiae which differ in the efficiency with which ochre nonsense mutations are suppressed. The strains in which ochre suppression is poor were [psi]^- or carried antisuppressor mutations; those in which suppression was highly efficient were [psi]⁺ or carried allosuppressor mutations. The ribosomal proteins of these strains, as judged by two-dimensional polyacrylamide gel electrophoresis, were indistinguishable from those of wild-type.     

Modification of [PSI +] prion properties by combining amino acid changes in N-terminal domain of Sup35 protein

The prion [PSI ⁺] is an amyloid isoform of the release factor eRF3 encoded by the SUP35 gene in Saccharomyces cerevisiae yeast. Naturally occurring amyloid complexes have been studied for a long time, yet their structural organization is still not well understood. The formation of amyloid forms of the wild-type Sup35 protein (Sup35p) is directed by its N-terminal portion, which forms a superpleated β-sheet structure. We previously constructed five mutants, each of which carried a replacement in two consecutive amino acids, one in each of the oligopeptide repeats (OR) and in the Sup35p N-terminal region. Mutations sup35-M1 (YQ46-47KK) and sup35-M2 (QQ61-62KK) lead to the compete loss of prion conformation. Three other mutants, i.e., sup35-M3 (QQ70-71KK), sup35-M4 (QQ80-81KK), and sup35-M5 (QQ89-90KK), formed functional prions. In the current study, we investigated the contribution of each mutant peptide to the stability of the prion and aggregation properties, and compared the effects of single mutants and combinations of different mutant alleles. Studies were carried out in yeast strains designed to carry single or a combination of different SUP35 alleles. Based on our analysis, we propose a model that clarifies the 3D organization of the β-sheet within the prion. We also provide evidence that sup35-M2 and sup35-M4 mutations change the 3D structure of prion complexes. We propose that the destabilization of prion complexes in these mutants is due to the decreased efficiency of the fragmentation of the prion aggregates by chaperone complexes.     

Regulation of release factor expression using a translational negative feedback loop: A systems analysis

The essential eukaryote release factor eRF1, encoded by the yeast SUP45 gene, recognizes stop codons during ribosomal translation. SUP45 nonsense alleles are, however, viable due to the establishment of feedback-regulated readthrough of the premature termination codon; reductions in full-length eRF1 promote tRNA-mediated stop codon readthrough, which, in turn, drives partial production of full-length eRF1. A deterministic mathematical model of this eRF1 feedback loop was developed using a staged increase in model complexity. Model predictions matched the experimental observation that strains carrying the mutant SUQ5 tRNA (a weak UAA suppressor) in combination with any of the tested sup45^UAA nonsense alleles exhibit threefold more stop codon readthrough than that of an SUQ5 yeast strain. The model also successfully predicted that eRF1 feedback control in an SUQ5 sup45^UAA mutant would resist, but not completely prevent, imposed changes in eRF1 expression. In these experiments, the introduction of a plasmid-borne SUQ5 copy into a sup45^UAA SUQ5 mutant directed additional readthrough and full-length eRF1 expression, despite feedback. Secondly, induction of additional sup45^UAA mRNA expression in a sup45^UAA SUQ5 strain also directed increased full-length eRF1 expression. The autogenous sup45 control mechanism therefore acts not to precisely control eRF1 expression, but rather as a damping mechanism that only partially resists changes in release factor expression level. The validated model predicts that the degree of feedback damping (i.e., control precision) is proportional to eRF1 affinity for the premature stop codon. The validated model represents an important tool to analyze this and other translational negative feedback loops.     

Depletion in the levels of the release factor eRF1 causes a reduction in the efficiency of translation termination in yeast

In Saccharomyces cerevisiae, translation termination is mediated by a complex of two proteins, eRF1 and eRF3, encoded by the SUP45and SUP35 genes, respectively. Mutations in the SUP45 gene were selected which enhanced suppression by the weak ochre (UAA) suppressor tRNA^SerSUQ5. In each of four such allo-suppressor alleles examined, an in-frame ochre (TAA) mutation was present in the SUP45 coding region; therefore each allele encoded both a truncated eRF1 protein and a full-length eRF1 polypeptide containing a serine missense substitution at the premature UAA codon. The full-length eRF1 generated by UAA read-through was present at sub-wild-type levels. In an suq5⁺ (i.e. non-suppressor) background none of the truncated eRF1 polypeptides were able to support cell viability, with the loss of only 27 amino acids from the C-terminus being lethal. The reduced eRF1 levels in these sup45 mutants did not lead to a proportional reduction in the levels of ribosome-bound eRF3, indicating that eRF3 can bind the ribosome independently of eRF1. A serine codon inserted in place of the premature stop codon at codon 46 in the sup45–22 allele did not generate an allosuppressor pheno-type, thereby ruling out this‘missense’mutation as the cause of the allosuppressor phenotype. These data indicate that the cellular levels of eRF1 are important for ensuring efficient translation termination in yeast.     

Association between defects of karyogamy and translation termination in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Mutants capable of a high frequency of cytoduction (Hfc⁺) were obtained in a haploid strain of Saccharomyces cerevisiae, suggesting impaired cytogamy. Nine of the 68 Hfc⁺ mutants showed the antisuppressor effect with respect to mutations of the SUP35 and SUP45 genes, which code for translation termination factors, or to the [PSI ⁺] factor, which is the prion form of Sup35. Cosegregation of the characters higher frequency of cytoduction and antisuppression was demonstrated for three Hfc⁺ mutants. One (HFC12-2) of the Hfc⁺ mutations exerted a dominant antisuppressor effect with respect to [PSI ⁺] and had no effect on [PSI ⁺] maintenance. On the strength of the results, an interaction was assumed for translation termination components and cytoskeleton proteins, which play a role in karyogamy in yeasts.Translated from Genetika, Vol. 41, No. 2, 2005, pp. 178–186.Original Russian Text Copyright © 2005 by Borchsenius, Repnevskaya, Kurischko, Inge-Vechtomov.     

Effect of Charged Residues in the N-domain of Sup35 Protein on Prion [PSI+] Stability and Propagation

Recent studies have shown that Sup35p prion fibrils probably have a parallel in-register β-structure. However, the part(s) of the N-domain critical for fibril formation and maintenance of the [PSI⁺] phenotype remains unclear. Here we designed a set of five SUP35 mutant alleles (sup35^KK) with lysine substitutions in each of five N-domain repeats, and investigated their effect on infectivity and ability of corresponding proteins to aggregate and coaggregate with wild type Sup35p in the [PSI⁺] strain. Alleles sup35-M1 (Y46K/Q47K) and sup35-M2 (Q61K/Q62K) led to prion loss, whereas sup35-M3 (Q70K/Q71K), sup35-M4 (Q80K/Q81K), and sup35-M5 (Q89K/Q90K) were able to maintain the [PSI⁺] prion. This suggests that the critical part of the parallel in-register β-structure for the studied [PSI⁺] prion variant lies in the first 63–69 residues. Our study also reveals an unexpected interplay between the wild type Sup35p and proteins expressed from the sup35^KK alleles during prionization. Both Sup35-M1p and Sup35-M2p coaggregated with Sup35p, but only sup35-M2 led to prion loss in a dominant manner. We suggest that in the fibrils, Sup35p can bind to Sup35-M1p in the same conformation, whereas Sup35-M2p only allowed the Sup35p conformation that leads to the non-heritable fold. Mutations sup35-M4 and sup35-M5 influence the structure of the prion forming region to a lesser extent, and can lead to the formation of new prion variants.