Antisuppressors in yeast

Allosuppressors in yeast

Five loci have been identified inSaccharomyces cerevisiaewhose function reduces suppressor activity in strains carrying ochre super-suppressor mutations. Recessive mutations which allow an increased level of suppression occur at these loci. In such mutants, termed allosuppressors, the serine-inserting suppressorSUPQ5suppresses ochre mutations in a [psi−] background and Class I tyrosine-inserting suppressors are lethal or have a reduced viability. Mutations at two allosuppressor loci,sal3 andsal4, have a lethal interaction with one another and with the extrachromosomal determinant [psi+]. This interaction is expressed in the absence of any suppressor mutation. All the mutant alleles of one allosuppressor locussal3 are cold sensitive. One allosuppressor mutation,sal4.2, is temperature-sensitive for growth, as well as for other aspects of its phenotypic expression; namely the expression ofSUPQ5and the lethal interactions with Class I super-suppressors, with [psi+] and withsal3. At low temperature (24 °C),sal3-sal4.2 double mutants weakly suppress the ochre mutationade2.1, but do not suppresshis5.2 orlys1.1. It is argued that the site of function of the products of these loci is ribosomal and that they are involved in chain termination at UAA codons. It is inferred that the [psi+] factor or its product affects protein synthesis by interaction with the ribosome.

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.

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.

Polypeptide chain termination in Saccharomyces cerevisiae

The study of translational termination in yeast has been approached largely through the identification of a range of mutations which either increase or decrease the efficiency of stop-codon recognition. Subsequent cloning of the genes encoding these factors has identified a number of proteins important for maintaining the fidelity of termination, including at least three ribosomal proteins (S5, S13, S28). Other non-ribosomal proteins have been identified by mutations which produce gross termination-accuracy defects, namely the SUP35 and SUP45 gene products which have closely-related higher eukaryote homologues (GST1-h and SUP45-h respectively) and which can complement the corresponding defective yeast proteins, implying that the yeast ribosome may be a good model for the termination apparatus existing in higher translation systems. While the yeast mitochondrial release factor has been cloned (Pel et al. 1992), the corresponding cytosolic RF has not yet been identified. It seems likely, however, that the identification of the gene encoding eRF could be achieved using a multicopy antisuppressor screen such as that employed to clone the E. coli prfA gene (Weiss et al. 1984). Identification of the yeast eRF and an investigation of its interaction with other components of the yeast translational machinery will no doubt further the definition of the translational termination process. While a large number of mutations have been isolated in which the efficiency of termination-codon recognition is impaired, it seems probable that a proportion of mutations within this class will comprise those where the accuracy of 'A' site codon-anticodon interaction is compromised: such defects would also have an effect on termination-codon suppression, allowing mis- or non-cognate tRNAs to bind stop-codons, causing nonsense suppression. The remainder of mutations affecting termination fidelity should represent mutations in genes coding for components of the termination apparatus, including the eRF: these mutations reduce the efficiency of termination, allowing nonsense suppression by low-efficiency natural suppressor tRNAs. Elucidation of the mechanism of termination in yeast will require discrimination between these two classes of mutations, thus allowing definition of termination-specific gene products.

Conservative system for dosage-dependent modulation of translational fidelity in eukaryotes

Variations in dosage of some genes can alter the level of translational fidelity. The Saccharomyces cerevisiae genes that act as dosage-dependent suppressors and/or modulators of suppression, are the following: some tRNA genes (for example, tRNA(Gln)) inducing readthrough by mispairing; genes coding for either translational elongation factor or other proteins taking part in translation; and some genes of unknown function. We suggest that the SUP35 protein is a factor which may play a major role in balance-dependent regulation of translational fidelity. Homologues of this genes have been identified in other yeast genera (Pichia), green algae (Chlamydomonas) and various animals including man. No homologies have been found in the polychaeta (Nereis) or in insects (Drosophila). Rates of evolution differ for two separate parts of the genes; the N-terminal part, which is important for ambiguous translation in Saccharomyces, is markedly variable in the organisms tested. However, the C-terminal part which is required for yeast viability has a common origin but a separate evolution from that of the EF-Tu protein family.

Specificity of the mutator effect caused by disruption of the RAD1 excision repair gene of Saccharomyces cerevisiae

Disruption of RAD1, a gene controlling excision repair in the yeast Saccharomyces cerevisiae, increased the frequency of spontaneous forward mutation in a plasmid-borne copy of the SUP4-o gene. To characterize this effect in detail, a collection of 249 SUP4-o mutations arising spontaneously in the rad1 strain was analyzed by DNA sequencing. The resulting mutational spectrum was compared with that derived from an examination of 322 spontaneous SUP4-o mutations selected in an isogenic wild-type (RAD1) strain. This comparison revealed that the rad1 mutator phenotype was associated with increases in the frequencies of single-base-pair substitution, single-base-pair deletion, and insertion of the yeast retrotransposon Ty. In the rad1 strain, the relative fractions of these events and their distributions within SUP4-o exhibited features similar to those for spontaneous mutagenesis in the isogenic RAD1 background. The increase in the frequency of Ty insertion argues that Ty transposition can be activated by unrepaired spontaneous DNA damage, which normally would be removed by excision repair. We discuss the possibilities that either translesion synthesis, a reduced fidelity of DNA replication, or a deficiency in mismatch correction might be responsible for the majority of single-base-pair events in the rad1 strain.

Mutations in ADE3 reduce the efficiency of the omnipotent suppressor sup45-2

Mutations in a known yeast gene, ADE3, were shown to act as an antisuppressor, reducing the efficiency of the omnipotent suppressor, sup45-2. The ADE3 locus encodes the trifunctional enzyme C1-tetrahydrofolate synthase, which is required for the biosynthesis of purines, thymidylate, methionine, histidine, pantothenic acid and formylmethionyl-tRNA(fMet. The role of this enzyme in translational fidelity had not previously been suspected.

Genetic control of translational fidelity in yeast: molecular cloning and analysis of the allosuppressor gene SAL3

The fidelity of translation in the yeast Saccharomyces cerevisiae is controlled by a number of gene products. We have begun a molecular analysis of such genes and here describe the cloning and analysis of one of these genes, SAL3. Mutations at this locus, and at least four other unlinked loci (designated SAL1-SAL5), increase the efficiency of the tRNA ochre suppressor SUQ5, and are thus termed allosuppressors. We have cloned the SAL3 gene from a yeast genomic library by complementation of a sal3 mutation. Integration of the cloned sequence into the yeast chromosome was used to confirm that the SAL3 gene had been cloned. SAL3 gene is present in a single copy in the yeast genome, is transcribed into a 2.3-kb polyadenylated mRNA and encodes a protein of Mr 80,000. The size of the SAL3 gene product strongly suggests that it is not a ribosomal protein.

Antisuppressor mutations in Aspergillus nidulans: cold-resistant revertants of suppressor suaC109

Cold-resistant revertants of the cold-sensitive, ribosomal suppressorsuaC109have been isolated, with a view to obtaining mutations in new ribosomal protein genes. Many revertants had reduced suppressor activity and were classified as antisuppressor mutants. Both intragenic and extragenic reversions were found. In seven strains the extragenic reversion to cold resistance segregated with the antisuppressor phenotype, and these were designatedasumutations. Three of the fiveasugenes, C, B and D were mapped to linkage groups, I, II and V respectively. The antisuppressors are not gene-specific, although they mainly antagonize the activity of ribosomal suppressors. The antisuppressors altered all aspects of the phenotype of suppressorsuaC109including sensitivity to aminoglycoside antibiotics, and are therefore thought to be mutations in ribosomal protein genes.

Development of a yeast system to assay mutational specificity

We have developed a system wherein DNA alterations occurring in a target gene in the yeast Saccharomyces cerevisiae can be determined by DNA sequencing. The target gene, SUP4-o, an ochre suppressor allele of a yeast tyrosine tRNA gene, has been inserted into a shuttle vector (YCpMP2) which is maintained in yeast at a copy number of one per cell Mutations in SUP4-o are selected by virtue of their inactivation of suppressor activity. Rapid DNA preparations from these mutants are used to transform an appropriate bacterial strain. Since YCpMP2 also carries the M13 phage replication origin, superinfection of bacterial cells containing the plasmid with wild-type M13 phage yields single stranded YCpMP2 DNA suitable for dideoxynucleotide chain termination sequencing. We have used this system to examine mutations arising spontaneously in the SUP4-o gene. The spontaneous mutants occurred at a frequency of 3.2 X 10(-6)/viable cell, corresponding to a rate of 2.7 X 10(-7) events/cell division. Following bacterial transformation, 16% of the recovered plasmids tested displayed altered gel mobility consistent with loss of significant portions of the plasmid. Hybridization analysis of total yeast DNA and use of purified YCpMP2 revealed that these very large deletions were not generated in yeast but were associated with bacterial transformation. Among the SUP4-o mutants analyzed by DNA sequencing, we identified each type of single base pair substitution (transitions and transversions), small deletions of varying length (1-32 base pairs) and more extensive deletions of undetermined size. These results demonstrate that the SUP4-o system can be used to detect various types of mutation at numerous sites in a single eukaryotic gene and to characterize the DNA sequence changes responsible for the mutations selected.

An antisuppressor mutant of Saccharomyces cerevisiae deficient in isopentenylated tRNA has reduced delta 2-isopentenylpyrophosphate: tRNA-delta 2-isopentenyl transferase activity

We have previously reported the isolation and initial characterization of a mutation in Saccharomyces cerevisiae, designated mod5-1, that reduces the capacity of altered tyrosine tRNAs to suppress ochre nonsense mutations. The mutation results in the virtual elimination of the modified tRNA nucleoside, N6-delta 2-(isopentenyl) adenosine, normally found adjacent to the anticodons of certain tRNA species. We demonstrate here that MOD5 codes for delta 2-isopentenylpyrophosphate: tRNA-delta 2-isopentenyl transferase, or a protein that regulates its synthesis.

In vitro nonsense suppression in [psi+] and [psi-] cell-free lysates of Saccharomyces cerevisiae

An homologous in vitro assay for yeast nonsense suppressors was used to examine the effect of the cytoplasmically inherited genetic determinant [psi] on the efficiency of in vitro nonsense suppression. The efficiency of all three types of yeast tRNA-mediated nonsense suppressor (ochre, amber, and UGA) is much greater in cell-free lysates prepared from a sup+ [psi+] strain than in lysates prepared from an isogeneic sup+ [psi-] strain. Lysates prepared from a [psi-] strain, into which the [psi+] determinant was reintroduced by kar1-mediated cytoduction, support efficient suppression. Evidence is also presented that [psi-] lysates contain an inhibitor of in vitro nonsense suppression.

The yeast tRNATyr gene intron is essential for correct modification of its tRNA product

Precise deletion of the intervening sequence of a yeast tRNATyr ochre suppressor gene (SUP6) significantly reduced its suppressor activity relative to that of the unaltered gene. This is probably the result of the absence of the pseudouridine modification, normally present at the middle anticodon position of mature suppressor tRNA, in tRNA synthesized in vivo from the deleted gene.

Mutations affecting translational fidelity in the eucaryote Podospora anserina: characterization of two ribosomal restrictive mutations

Fifty-nine mutations that restrict suppressor efficiency were selected in the fungus Podospora anserina using four different screening methods. Previous genetic analysis has shown that these antisuppressors lie in six loci and that they could be similar to ribosomal restrictive mutations known in Escherichia coli. The present study deals with the response of two of them, AS1-1 and AS6-1, to paromomycin and low temperature both in vivo and in vitro. The data demonstrate that ribosomes of the mutant and double-mutant strains are equally resistant to the ambiguity effect of paromomycin. These data are the first demonstration of mutations that increase translational fidelity in eucaryotic organism.

Search for ribosomal mutants in Podospora anserina: genetic analysis of cold-sensitive mutants

Twenty-four cold-sensitive (prototrophic) mutants were isolated after UV mutagenesis of protoplasts of the fungusPodospora anserina. Genetic analysis of these mutants was performed in order to detect those among them which were most likely to be impaired in translational fidelity. The 24 mutations belonged to 24 different genes. One half of the mutants were pleiotropic and displayed an altered phenotype: growth rate at the permissive temperature, germination of the spores, fertility and/or sporulation. Nine mutants differed from wild-type in their resistance levels to cycloheximide, trichodermin and/or paromomycin. Several mutations were linked to known ribosomal loci. Two mutations behaved like informational antisuppressors: one is allelic to the previously describedAs3gene and the other one defines a new antisuppressor gene,AS6.

A mutant of Saccharomyces cerevisiae that exhibits multiple isoacceptors for several of its transfer RNAs

A strain of Saccharomyces cerevisiae, known to produce multiple isoaccepting forms of several tRNA's which differ from a standard wild type strain, has been studied genetically. The multiple isoaccepting tRNA phenotype behaves as if it is caused by a single recessive mutation. Five tetrads were analyzed and all showed a 2:2 segregation of mutant to wild type profiles for Phe-tRNA Phe. Furthermore, the multiple isoacceptors for the other tRNA's in the mutant strain are probably caused by the same mutation, since Tyr-tRNA Tyr and Val-tRNA Val also exhibit 2:2 segregation for mutant versus wild type tRNA profiles and the segregation pattern is the same as that for Phe-tRNA Phe.

The extrachromosomal control of nonsense suppression in yeast: an analysis of the elimination of [psi+] in the presence of a nuclear gene PNM

When a [psi-] strain of yeast mutates to [psi+], the efficiency of suppression by certain ochre suppressors is increased. The [psi+] phenotype is inherited extrachromosomally. There is a nuclear gene, PNM, which, when mutant, causes loss of the [psi+] phenotype. PNM- is dominant to PNM+ and a heterozygous diploid gradually loses the ability over successive generations, to produce PNM+ [psi+] spores. This paper describes the kinetics of this elimination and the data obtained are discussed in relation to two models of the molecular nature of the [psi] genetic determinant--one considering the [psi] determinant as an autonomous nucleic acid, the other treating the possibility that the [psi] nucleic acid is that which codes for rRNA in the nuclear genome.

Genetic analysis of antisuppressor mutants in the fission yeast Schizosaccharomyces pombe

Fourteen unlinked sin genes could be mutated to recessive antisuppressor alleles preventing the expression of suppressors in the fission yeast Schizosaccharomyces pombe. cyh1 alleles, resistant to the ribosomal inhibitor cycloheximide, also have some antisuppressor effect. The genetical and physiological characterization of these mutants is consistent with the hypothesis that they affect components of the messenger RNA translation machinery such as tRNA modifying enzymes or ribosomal proteins.

Suppressor-specificity of antisuppressors in yeast

Eighteen mutations ofSaccharomyces cerevisiae, at eight loci, isolated as antisuppressors ofSUPQ2, an ochre-suppressing allele ofSUP11, were crossed with three other suppressors.

They were found to abolish the ability ofSUP2(inserting tyrosine), to suppress the ochre mutationsade2.1andcan1.100, but not its ability, to suppresshis5.2orlys1.1.When coupled with any antisuppressor,SUPQ5, inserting serine, was also unable to suppressade2.1, but the suppression of other ochre mutations varied from oneasu-SUPQ5strain to another. No antisuppressor affected the ability ofSUP11-am, an amber-suppressing allele ofSUP11, to suppresstrp1.1, an amber mutation.

Genetic evidence of ribosomal antisuppressors in Podospora anserina

Antisuppressors were screened for with the help of informational suppressors in Podospores anserina. Four mutations in the AS1 locus and two in the AS2 locus were isolated, using allele non specific suppressors supposed to be ribosomal ambiguity mutations. Four mutations in the AS3 locus and 45 in the AS4 locus were obtained, using a nonsense (t-RNA like) suppressor. All antisuppressors are partially dominant. Most mutations in the AS4 locus are lethal. The four mutants at the AS3 locus and 6 out of the 8 viable mutants at the AS4 locus are cold sensitive. Phenotypic properties and action spectra of the antisuppressors suggest that they are restrictive ribosomal mutations.