Ribosomal suppressors and antisuppressors in Podospora anserina: resistance to cycloheximide

Change in cytoplasmic ribosome properties during gametogenesis in the alga Chlamydomonas reinhardtii

Cytoplasmic (80S) ribosomes isolated from gametes and vegetative cells of the unicellular alga Chlamydomonas reinhardtii have been compared. Ribosomes of these two cell types differ in their susceptibility towards aminoglycoside antibiotics while their response to other antibiotics are similar. Electrophoregrams of ribosomal proteins show clear-cut differences between the two kinds of ribosomes.

Every ribosomal suppressor mutation in Aspergillus nidulans has a unique and highly pleiotropic phenotype

18 suppressors of alcR125 have been selected in Aspergillus nidulans. They have been located in genes as follows: 12 in suaA, 1 in suaB and 5 in suaC. Suppressors have been examined to see whether their phenotype is diagnostic for their genotype. Several new traits are described: conidial viability, cycloheximide resistance, fertility, suppression of niaD500, niaD501 and fwA1. These tests, added to those already in use, provide a battery of tests suitable for assigning suppressor mutations to physiological type (tRNA or ribosomal), and in one case to a specific gene since only suaA mutations suppressed fwA1. A very broad range of phenotypes was associated with suppressors such that every mutation had a unique phenotype. This indicates that the ribosomal suppressor mutations are in genes which code directly for ribosomal proteins, rather than genes which code for modifying enzymes.

Identification of two genes controlling kasugamycin resistance in the filamentous fungus Podospora anserina

We have investigated the effect of the ribosome-targeted antibiotic kasugamycin (ksg) inPodospora anserina. While ksg inhibits both growth and sporulation, it has a stronger inhibitory effect on the sporulation process. It was previously reported that sporulation ofPodosporacould be impaired when ribosomes translate with a too high accuracy, and since ksg was demonstrated to increase the ribosomal accuracy inE. coli, we wondered whether it would act similarly inPodospora. As a first approach we have isolated two mutations at different loci,Ks1andKs2, that increase the resistance to ksg at the level of both growth and sporulation. InterestinglyKs1−1also confers a decreased resistance to paromomycin, which is a mistranslation inducer. Characterization ofKs1−1andKs2−1mutants suggests that they could be ribosomal mutants.

Suppressors suaC109 and suaA101 of Aspergillus nidulans alter the ribosomal phenotype in vitro

A new homologous, cell-free system for protein synthesis has been devised for use with ribosomes and elongation factors from Aspergillus nidulans. Ribosome preparations from strains with either the suaA101 or suaC109 mutations have a higher misreading ratio (non-cognate:cognate amino acid incorporation) in the presence of hygromycin than controls. They can be classed as fidelity mutants. These results also prove that the mutations must be in genes coding for ribosomal proteins or enzymes which modify ribosomal proteins post-translationally. Alternatively, the genes could code for translation factors.

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.

Frameshift suppression by thyA mutants of Escherichia coli K-12

We have extended our previous study on the suppression of frameshift mutants by Escherichia coli thyA mutants by assaying suppression of 15 rIIB frameshift mutants of bacteriophage T4 on one of our suppressing thyA mutant strains. The majority of insertion mutants were suppressible, whereas none of the deletion mutants tested was suppressible. Frameshift suppression could be inhibited by adding thymidine to the assay medium, but was not affected by the presence of a restrictive rpsL mutation in the host strain. We suggest that the frameshift suppression event occurs at a nonsense codon generated by the frameshift mutation.

At least seven ribosomal proteins are involved in the control of translational accuracy in a eukaryotic organism

In the filamentous fungus Podospora anserina, ribosomal proteins of 60 mutants impaired in the control of translational fidelity have been submitted to electrophoretic analysis. The "four corners" system combining four different two-dimensional polyacrylamide gel electrophoretic systems has been used. An altered electrophoretic pattern has been observed for 12 mutants. In mutants su3, su12 and su11 (decreased translational fidelity), proteins S1, S7 and S8, respectively, are altered. For AS mutants (increased translational fidelity), proteins S9, S12 and S19, respectively, are altered in AS9, AS1 and AS6 mutants, and protein S29 is lacking in AS3 mutants. The data suggest that five of these genes (at least) are the structural genes for the relevant proteins (su3:S1, su12:S7, AS1:S12, AS6:S19, AS9:S9), while the AS3 gene may code for a modifying enzyme.

Mutations relieving hypersensitivity to paromomycin caused by ribosomal suppressors in Podospora anserina

In the fungusPodospora anserina, mutations were selected which relieved the hypersensitivity to paromomycin caused by four suppressors assumed to be ribosomal ambiguity mutations (su1–31,su1–49,su1–60,su2–5). Our first purpose was to isolate new antisuppressor mutations and in fact a new antisuppressor gene,AS7was uncovered. TheAS7–1mutant displays a pleiotropic phenotype and particularly a sporulation defect. On the other hand, a newsu1mutant was obtained which acts as a suppressor and also as an antisuppressor: it can specifically reduce the suppressor effect of certainsu2mutations. This property of somesu1andsu2mutations was already known. Apart from these mutations probably involved in the control of translational fidelity, six mutations conferring cross-resistance to paromomycin and neomycin were isolated. While four of them are localized in thePm1andPm2loci previously identified, the two others define a new gene which controls paromomycin and neomycin resistance,Pm3. Strains carrying thePm3–1allele are sensitive to temperature at the level of growth and sporulation. The three last mutations which were obtained confer no mutant phenotype when separated from thesu1background. They are closely linked to thesu2locus.

Analysis of revertants of a ribosomal mutation in Podospora anserina: evidence for new ribosomal mutations which confer hypersensitivity to paromomycin

This paper describes the analysis of cold-resistant revertants of a cold-sensitive mutant. Pm1-1 is a ribosomal mutation screened for its paromomycin resistance. Suppression of its cold sensitivity occurs with two kinds of external mutations localized in two different loci. One of them, PmB, is assumed to be a ribosomal gene. PmB mutations confer hypersensitivity to paromomycin in vivo as well as in vitro in a cell-free protein synthesis system.

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.

Ribosomal suppressors and antisuppressors in Podospora anserina: altered susceptibility to paromomycin and relationships between genetic and phenotypic suppression

Informational suppressors and antisuppressors have been previously isolated in Podospora anserina, and their properties suggest that they could be ribosomal mutants involved in the control of translational fidelity. In this paper we present results concerning relationships between these mutants and paromomycin, an aminoglycoside antibiotic known to stimulate translational errors. The mutants were found to manifest an altered growth sensitivity to this drug as compared with the wild-type strain: Most of the suppressors were more sensitive and, in contrast, most of the antisuppressors were more resistant to paromomycin. Moreover, phenotypic suppression of an auxotrophic mutation by paromomycin was observed only if a suppressor and an antisuppressor had been introduced in the strain. These results suggest that ambiguity levels could be altered in the suppressor and antisuppressor strains. In addition, paromomycin was shown to abolish sporulation, which suggests relationships between mistranslation and a step of cellular differentiation.

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.

Search for ribosomal mutants in Podospora anserina: genetic analysis of mutants resistant to paromomycin

It has recently been shown that paromomycin, an antibiotic of the aminoglycoside family, is also active on eukaryotic cytoplasmic ribosomes. In the fungus Podospora anserina, genetic analysis of ten mutants resistant to high doses of paromomycin shows that this resistance is caused by mutations in two different nuclear genes. These mutants display pleiotropic phenotypes (cold sensitivity, mycelium and spore appearance and coloration, cross-resistance to other antibiotics). Double mutants are either lethal or very altered and unstable. Moreover, the cytochrome spectra of these mutants seem to indicate that cytoplasmic protein synthesis is affected. The mutants also display a slight suppressor effect. We can therefore assume that these mutations affect cytoplasmic ribosomes.

Cold-sensitivity of a double mutant strain combining two ribosomal mutations in the ascomycete Podospora anserina

A double mutant strain combining two ribosomal mutations conferring resistance to cycloheximide exhibits a cold-sensitive phenotype. At low temperature the biosynthesis of the 60S subunit is impaired. Genetic analysis of cold-resistant revertants have shown that this double mutant strain can be used efficiently to isolate new ribosomal mutations.