Project description:While the “universal” genetic code is now known not to be universal, and stop codons can have multiple meanings, one regularity remains, namely that for a given sense codon there is a unique translation. Examining CUG usage in yeasts that have transferred CUG away from leucine, we here report the first example of dual coding: Ascoidea asiatica stochastically encodes CUG as both serine and leucine. This is deleterious as evidenced by CUG codons being rare, never at conserved serine/leucine residues and predominantly in lowly expressed genes. Related yeasts solve the problem by loss-of-function of one of the two tRNAs. This dual-coding is consistent with the tRNA-loss driven codon reassignment hypothesis and provides a unique example of a proteome that cannot be deterministically predicted.

Project description:Candida yeasts causing human infections are spread across the yeast phylum with Candida glabrata being related to Saccharomyces cerevisiae, Candida krusei grouping to Pichia spp., and Candida albicans, Candida parapsilosis and Candida tropicalis belonging to the CTG-clade. The latter lineage contains yeasts with an altered genetic code translating CUG codons as serine using a serine-tRNA with a mutated anticodon. It has been suggested that the CTG-clade CUG codons are mistranslated to a small extent as leucine due to mischarging of the serine-tRNA(CAG). The mistranslation was suggested to result in variable surface proteins explaining fast host adaptation and pathogenicity. Here, we re-assessed this potential mistranslation by high-resolution mass spectrometry-based proteogenomics of multiple CTG-clade yeasts, various C. albicans strains, isolated from colonized and from infected human body sites, and C. albicans grown in yeast and hyphal forms.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.

Project description:In the yeast genera Saccharomycopsis and Ascoidea, nuclear genes use a non-standard genetic code in which CUG codons are translated as serine instead of leucine, due to the presence of a tRNA-Ser with the unusual anticodon CAG. However, some species in this ‘CUG-Ser2’ clade also contain an ancestral tRNA-Leu gene with the same anticodon. One of these species, Ascoidea asiatica, has been shown to have a stochastic proteome in which proteins contain approximately 50% Ser and 50% Leu at CUG codon sites, whereas previously examined Saccharomycopsis species translate CUG only as Ser. Here, we investigated the presence, conservation, and possible functionality of the tRNA-Leu(CAG) gene in the genus Saccharomycopsis. We analyzed the genomes of 33 strains, including almost all known species of Saccharomycopsis, and found that most of them contain both tRNA-Ser(CAG) and tRNA-Leu(CAG) genes. The tRNA-Leu(CAG) gene is evolving faster than tRNA-Ser(CAG) and it has been lost in two species, S. microspora and S. synnaedendra. We deleted the single tRNA-Leu(CAG) gene in S. capsularis and found that it is not essential. Bioinformatic analysis suggested that some CUG codon sites in Saccharomycopsis species may be translated as Leu, specifically in genes with functions in meiosis or sporulation, but mass spectrometry of sporulating S. capsularis and S. fermentans cultures showed only CUG-Ser translation. Cloverleaf structures of tRNA-Leu(CAG) from all Saccharomycopsis species contain mutations that are likely to make them non-functional in translation, but the evolutionary conservation of the gene leads us to propose that it has been retained for an unknown non-translational role.