Comparative analysis of the structure of SUP2 genes in Pichia pinus and Saccharomyces cerevisiae

SUP2(SUP35) is an omnipotent suppressor gene, coding for an EF-1 alpha-like protein factor, involved in the control of translational accuracy in yeast Saccharomyces cerevisiae. A SUP2 gene analogue from yeast Pichia pinus was isolated by complementation of temperature-sensitive sup2 mutation of S. cerevisiae. Nucleotide sequence of the SUP2 gene of P. pinus codes for a protein of 82.4 kDa exceeding the SUP2 protein of S. cerevisiae for 6 kDa. The SUP2 gene product of P. pinus is similar to the Sup2 protein of S. cerevisiae by its structure and includes a highly conservative (76%) C-terminal region homologus to EF-1 alpha and a lowly conservative N-terminal region. The relation between the evolutionary conservativity of different regions of the Sup2 protein and their functional significance is discussed.     

The Sup35 Omnipotent Suppressor Gene Is Involved in the Maintenance of the Non-Mendelian Determinant [Psi(+)] in the Yeast Saccharomyces Cerevisiae

The SUP35 gene of yeast Saccharomyces cerevisiae encodes a 76.5-kD ribosome-associated protein (Sup35p), the C-terminal part of which exhibits a high degree of similarity to EF-1α elongation factor, while its N-terminal region is unique. Mutations in or overexpression of the SUP35 gene can generate an omnipotent suppressor effect. In the present study the SUP35 wild-type gene was replaced with deletion alleles generated in vitro that encode Sup35p lacking all or a part of the unique N-terminal region. These 5'-deletion alleles lead, in a haploid strain, simultaneously to an antisuppressor effect and to loss of the non-Mendelian determinant [psi(+)]. The antisuppressor effect is dominant while the elimination of the [psi(+)] determinant is a recessive trait. A set of the plasmid-borne deletion alleles of the SUP35 gene was tested for the ability to maintain [psi(+)]. It was shown that the first 114 amino acids of Sup35p are sufficient to maintain the [psi(+)] determinant. We propose that the Sup35p serves as a trans-acting factor required for the maintenance of [psi(+)].     

Domain structure and conserved epitopes of Sfb protein, the fibronectin-binding adhesin of Streptococcus pyogenes

Streptococcus pyogenes expresses a fibronectin-binding surface protein (Sfb protein) which mediates adherence to human epithelial cells. The nucleotide sequence of the sfb gene was determined and the primary sequence of the Sfb protein was analysed. The protein consists of 638 amino acids and comprises five structurally distinct domains. The protein starts with an N-terminal signal peptide followed by an aromatic domain. The central part of the protein is formed by four proline-rich repeats which are flanked by non-repetitive spacer sequences. A second repeat region, consisting of four repeats that are distinct from the proline repeats and have been shown to form the fibronectin-binding domain, is located in the Cterminal part of the protein. The protein ends with a typical cell wall and membrane anchor region. Comparative sequence analysis of the N-terminal aromatic domain revealed similarities with carbohydrate-binding sites of other proteins. The proline repeat region of the Sfb protein shares characteristic features with proline-rich repeats of functionally distinct surface proteins from pathogenic Gram-positive cocci. Immunoelectron microscopy revealed an even distribution of the fibronectin-binding domain of Sfb protein on the surface of streptococcal cells. Analyses of 38 sfb genes originating from different S. pyogenes isolates revealed primary sequence variability in regions coding for the N-termini of mature Sfb proteins, whereas sequences coding for the central and C-terminal repeats were highly conserved. The repeat sequences are postulated to act as target sites for intragenic recombination events that result in variable numbers of repeats within the different sfb genes. A model of the Sfb protein is presented.     

Deletion analysis of the SUP2 gene in Saccharomyces cerevisiae

The sup2 mutations of the yeast Saccharomyces cerevisiae or plasmid-mediated amplification of the wild type SUP2 gene lead to suppression of different types of nonsense mutations. The Sup2 protein includes a C-terminal region homologous to elongation factor EF-1 alpha and an unique N-terminal region. The SUP2 is an essential gene. The functional role of different regions of the SUP2 gene was investigated, by deleting them without disruption of the reading frame. Such constructs were maintained in yeast on episomal or centromeric plasmids. It was shown that the region, homologous to EF-1 alpha is necessary for viability, while the remaining N-terminal part is nonessential. The region of the first 154 amino acids is necessary and sufficient for the suppressor effect, caused by plasmid-mediated amplification of the SUP2 gene.     

Chimeric Yeast Prions with Unstable Inheritance

The Saccharomyces cerevisiae [PSI] factor, a cytoplasmic omnipotent nonsense suppressor, is a conformationally changed (prion) form of translation termination factor eRF3 (Sup35p). Induction and maintenance of the [PSI] factor depend on the prionizing peptide located in the N domain of Sup35p. The N domain of Sup35p was fused with phosphoribosylaminoimidazole carboxylase (Ade2p), a purine biosynthesis enzyme, and the hybrid protein (NM-Sup35p::Ade2p) was tested for induction of the [PSI] factor. Transformation with a centromeric plasmid carrying the gene for NM-Sup35p::Ade2p induced a [PSI]-like factor in yeast cells, which was evident from efficient nonsense suppression. The suppressor effect depended on the presence of the prionizing peptide both in the hybrid protein and in Sup35p synthesized from the chromosomal gene, as well as on the presence of the prion-like [PIN] factor in the cell.     

Amino acid replacements in the Serratia marcescens haemolysin ShlA define sites involved in activation and secretion

The haemolysin of Serratia marcescens (ShlA) is translocated through the cytoplasmic membrane by the signal peptide-dependent export apparatus. Translocation across the outer membrane (secretion) is mediated by the ShIB protein. Only the secreted form of ShlA is haemolytic. ShIB also converts in vitro inactive ShlA (ShlA*), synthesized in the absence of ShIB, into the haemolytic form (a process termed activation). To define regions in ShlA involved in both processes, ShlA derivatives were isolated and tested for secretion and activation. Analysis of C-terminally truncated proteins (ShlA) assigned the secretion signal to the amino-terminal 238 residues of ShlA. Trypsin cleavage of a secreted ShlA' derivative yielded a 15kDa N-terminal fragment, by which a haemolytically inactive ShlA* protein could be activated in vitro. It is suggested that the haemolysin activation site is located in this N-terminal fragment. Replacement of asparagine-69 and asparagine-109 by isoleucine yielded inactive haemolysin derivatives. Both asparagine residues are part of two short sequence motifs, reading Ala-Asn-Pro-Asn, which are critical to both activation and secretion. These point mutants as well as N-terminal deletion derivatives which were not activated by ShIB were activated by adding a non-haemolytic N-terminal fragment synthesized in an ShIB⁺ strain (complementation). Apparently the activated N-terminal fragment substituted for the missing activation of the ShlA derivatives and directed them into the erythrocyte membrane, where they formed pores. It is concluded that activation is only required for initiation of pore formation, and that in vivo activation and secretion are tightly coupled processes. Complementation may also indicate that haemolysin oligomers form the pores.     

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 products of the SUP45 (eRF1) and SUP35 genes interact to mediate translation termination in Saccharomyces cerevisiae.

The product of the yeast SUP45 gene (Sup45p) is highly homologous to the Xenopus eukaryote release factor 1 (eRF1), which has release factor activity in vitro. We show, using the two-hybrid system, that in Saccharomyces cerevisiae Sup45p and the product of the SUP35 gene (Sup35p) interact in vivo. The ability of Sup45p C-terminally tagged with (His)6 to specifically precipitate Sup35p from a cell lysate was used to confirm this interaction in vitro. Although overexpression of either the SUP45 or SUP35 genes alone did not reduce the efficiency of codon-specific tRNA nonsense suppression, the simultaneous overexpression of both the SUP35 and SUP45 genes in nonsense suppressor tRNA-containing strains produced an antisuppressor phenotype. These data are consistent with Sup35p and Sup45p forming a complex with release factor properties. Furthermore, overexpression of either Xenopus or human eRF1 (SUP45) genes also resulted in anti-suppression only if that strain was also overexpressing the yeast SUP35 gene. Antisuppression is a characteristic phenotype associated with overexpression of both prokaryote and mitochondrial release factors. We propose that Sup45p and Sup35p interact to form a release factor complex in yeast and that Sup35p, which has GTP binding sequence motifs in its C-terminal domain, provides the GTP hydrolytic activity which is a demonstrated requirement of the eukaryote translation termination reaction.     

Sequence and molecular analysis of the nifL gene of Azotobacter vinelandii

In both Klebsiella pneumoniae and Azotobacter vinelandii the nifL gene, which encodes a negative regulator of nitrogen fixation, lies immediately upstream of nifA. We have sequenced the A. vinelandii nifL gene and found that it is more homologous in its C-terminal domain to the histidine protein kinases (HPKs) than Is K. pneumoniae NifL. In particular A. vinelandii NifL contains a conserved histidine at a position shown to be phosphorylated in other systems. Both NifL proteins are homologous in their N-termini to a part of the Halobacterium halobium bat gene product; Bat is involved in regulation of bacterio-opsin, the expression of which is oxygen sensitive. The same region showed homology to the haembinding N-terminai domain of the Rhizobium meliloti fixL gene product, an oxygen-sensing protein. Like K. pneumoniae NifL, A. vinelandii NifL is shown here to prevent expression of nif genes in the presence of NH⁺₄ or oxygen. The sequences found homologous in the C-terminal regions of NifL, FixL and Bat might therefore be involved in oxygen binding or sensing. An in-frame deletion mutation in the nifL coding region resulted in loss of repression by NH⁺₄ and the mutant excreted high amounts of ammonia during nitrogen fixation, thus confirming a phenotype reported earlier for an insertion mutation. In addition, nifLA are cotranscribed in A. vinelandii as in K. pneumoniae, but expression from the A. vinelandii promoter requires neither RpoN nor NtrC.     

Suppression of Nonsense and Frameshift Mutations Obtained by Different Methods for Inactivating the Translation Termination Factor eRF3 in Yeast Saccharomyces cerevisiae

Mutations in genes of omnipotent nonsense suppressors SUP35 and SUP45 in yeast Saccharomyces cerevisiae encoding translation termination factors eRF3 and eRF1, respectively, and prionization of the eRF3 protein may lead to the suppression of some frameshift mutations (CPC mutations). Partial inactivation of the translation termination factor eRF3 was studied in strains with unstable genetically modified prions and also in transgenic yeast S. cerevisiae strains with the substitution of the indigenous SUP35 gene for its homolog from Pichia methanolica or for a recombinant S. cerevisiae SUP35gene. It was shown that this partial inactivation leads not only to nonsense suppression, but also to suppression of the frameshift lys2-90 mutation. Possible reasons for the correlation between nonsense suppression and suppression of the CPC lys2-90 mutation and mechanisms responsible for the suppression of CPC mutations during inactivation of translation termination factors are discussed.     

Prion protein gene polymorphisms in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae genome encodes several proteins that, in laboratory strains, can take up a stable, transmissible prion form. In each case, this requires the Asn/Gln-rich prion-forming domain (PrD) of the protein to be intact. In order to further understand the evolutionary significance of this unusual property, we have examined four different prion genes and their corresponding PrDs, from a number of naturally occurring strains of S. cerevisiae. In 4 of the 16 strains studied we identified a new allele of the SUP35 gene (SUP35delta19) that contains a 19-amino-acid deletion within the N-terminal PrD, a deletion that eliminates the prion property of Sup35p. In these strains a second prion gene, RNQ1, was found to be highly polymorphic, with eight different RNQ1 alleles detected in the six diploid strains studied. In contrast, for one other prion gene (URE2) and the sequence of the NEW1 gene encoding a PrD, no significant degree of DNA polymorphism was detected. Analysis of the naturally occurring alleles of RNQ1 and SUP35 indicated that the various polymorphisms identified were associated with DNA tandem repeats (6, 12, 33, 42 or 57 bp) within the coding sequences. The expansion and contraction of DNA repeats within the RNQ1 gene may provide an evolutionary mechanism that can ensure rapid change between the [PRION+] and [prion-] states.     

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.     

Mechanism of inhibition of Psi+ prion determinant propagation by a mutation of the N-terminus of the yeast Sup35 protein.

The SUP35 gene of Saccharomyces cerevisiae encodes the polypeptide chain release factor eRF3. This protein (also called Sup35p) is thought to be able to undergo a heritable conformational switch, similarly to mammalian prions, giving rise to the cytoplasmically inherited Psi+ determinant. A dominant mutation (PNM2 allele) in the SUP35 gene causing a Gly58-->Asp change in the Sup35p N-terminal domain eliminates Psi+. Here we observed that the mutant Sup35p can be converted to the prion-like form in vitro, but such conversion proceeds slower than that of wild-type Sup35p. The overexpression of mutant Sup35p induced the de novo appearance of Psi+ cells containing the prion-like form of mutant Sup35p, which was able to transmit its properties to wild-type Sup35p both in vitro and in vivo. Our data indicate that this Psi+-eliminating mutation does not alter the initial binding of Sup35p molecules to the Sup35p Psi+-specific aggregates, but rather inhibits its subsequent prion-like rearrangement and/or binding of the next Sup35p molecule to the growing prion-like Sup35p aggregate.     

Molecular characterization of PeSOS1: the putative Na+/H+ antiporter of Populus euphratica

Populus euphratica is a salt-tolerant tree species growing in semi-arid saline areas. A Na⁺/H⁺ antiporter gene was successfully isolated from this species through RACE cloning, and named PeSOS1. The isolated cDNA was 3665 bp long and contained a 3438 bp open reading frame that was predicted to encode a 127-kDa protein with 12 hypothetical transmembrane domains in the N-terminal part and a long hydrophilic cytoplasmic tail in the C-terminal part. The amino acid sequence of this PeSOS1 gene showed 64% identity with the previously isolated SOS1 gene from the glycophyte Arabidopsis thaliana. The level of protein expressed by PeSOS1 in the leaves of P. euphratica was significantly up-regulated in the presence of high (200 mM) concentrations of NaCl, while the mRNA level in the leaves remained relatively constant. Immunoanalysis suggested that the protein encoded by PeSOS1 is localized in the plasma membrane. Expression of PeSOS1 partially suppressed the salt sensitive phenotypes of the EP432 bacterial strain, which lacks the activity of the two Na⁺/H⁺ antiporters EcNhaA and EcNhaB. These results suggest that PeSOS1 may play an essential role in the salt tolerance of P. euphratica and may be useful for improving salt tolerance in other tree species. Yuxia Wu and Nan Ding contributed equally to this work.     

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.     

Partial Inactivation of Translation Termination Factors Causes Suppression of Frameshift Mutations in the Yeast Saccharomyces cerevisiae

Special search for frameshift mutations, which are suppressed by the cytoplasmic [PSI] factor and by omnipotent nonsense suppressors (recessive mutations in theSUP35and SUP45genes), partially inactivating a translation termination complex, was initiated in theLYS2gene in the yeast Saccharomyces cerevisiae.Mutations were obtained after exposure to UV light and treatment with a mixture of 1,6- and 1,8-dinitropyrene (DNP). This mixture was shown to induce mutations of the frameshift type with a high frequency. The majority of these mutations were insertions of one A or T, which is in good agreement with the data obtained in studies of DNP-induced mutagenesis in other eukaryotes. Frameshift suppression was shown on the example of the mutation obtained in this work (lys2-90), which carried the insertion of an extra T in the sequence of five T. This frameshift suppression was first shown to occur in the presence of the [PSI] factor (i.e., due to the prionization of the translation release factor eRF3) and as a result of mutations in genes SUP35orSUP45, which partially inactivate translation termination factors eRF3 and eRF1, respectively. Alternative mechanisms of programmed translational frameshifting in the course of translation and the possibility of enhancing the effectiveness of such frameshifting in the presence of the [PSI] factor are considered.     

A role for the proteasome in the turnover of Sup35p and in [PSI+] prion propagation

Yeast prions are superb models for understanding the mechanisms of self‐perpetuating protein aggregates formation. [PSI⁺] stands among the most documented yeast prions and results from self‐assembly of the translation termination factor Sup35p into protein fibrils. A plethora of cellular factors were shown to affect [PSI⁺] formation and propagation. Clearance of Sup35p prion particles is however poorly understood and documented. Here, we investigated the role of the proteasome in the degradation of Sup35p and in [PSI⁺] prion propagation. We found that cells lacking the RPN4 gene, which have reduced intracellular proteasome pools, accumulated Sup35p and have defects in [PSI⁺] formation and propagation. Sup35p is degraded in vitro by the 26S and 20S proteasomes in a ubiquitin‐independent manner, generating an array of amyloidogenic peptides derived from its prion‐domain. We also demonstrate the formation of a proteasome‐resistant fragment spanning residues 83–685 which is devoid of the prion‐domain that is essential for [PSI⁺] propagation. Most important was the finding that the 26S and 20S proteasomes degrade Sup35p fibrils in vitro and abolish their infectivity. Our results point to an overlooked role of the proteasome in clearing toxic protein aggregates, and have important implications for a better understanding of the life cycle of infectious protein assemblies.