Your search keyword '"codon reassignment"' showing total 9 results

1. A computational screen for alternative genetic codes in over 250,000 genomes

Author

Yekaterina Shulgina and Sean R Eddy

Subjects

genetic code, codon reassignment, tRNA, codetta, Medicine, Science, Biology (General), QH301-705.5

Abstract

The genetic code has been proposed to be a ‘frozen accident,’ but the discovery of alternative genetic codes over the past four decades has shown that it can evolve to some degree. Since most examples were found anecdotally, it is difficult to draw general conclusions about the evolutionary trajectories of codon reassignment and why some codons are affected more frequently. To fill in the diversity of genetic codes, we developed Codetta, a computational method to predict the amino acid decoding of each codon from nucleotide sequence data. We surveyed the genetic code usage of over 250,000 bacterial and archaeal genome sequences in GenBank and discovered five new reassignments of arginine codons (AGG, CGA, and CGG), representing the first sense codon changes in bacteria. In a clade of uncultivated Bacilli, the reassignment of AGG to become the dominant methionine codon likely evolved by a change in the amino acid charging of an arginine tRNA. The reassignments of CGA and/or CGG were found in genomes with low GC content, an evolutionary force that likely helped drive these codons to low frequency and enable their reassignment.

Published

2021

2. How tRNAs dictate nuclear codon reassignments: Only a few can capture non-cognate codons.

Author

Kollmar, Martin and Mühlhausen, Stefanie

Abstract

mRNA decoding by tRNAs and tRNA charging by aminoacyl-tRNA synthetases are biochemically separated processes that nevertheless in general involve the same nucleotides. The combination of charging and decoding determines the genetic code. Codon reassignment happens when a differently charged tRNA replaces a former cognate tRNA. The recent discovery of the polyphyly of the yeast CUG sense codon reassignment challenged previous mechanistic considerations and led to the proposal of the so-calledtRNA loss driven codon reassignmenthypothesis. Accordingly, codon capture is caused by loss of a tRNA or by mutations in the translation termination factor, subsequent reduction of the codon frequency through reduced translation fidelity and final appearance of a new cognate tRNA. Critical for codon capture are sequence and structure of the new tRNA, which must be compatible with recognition regions of aminoacyl-tRNA synthetases. The proposed hypothesis applies to all reported nuclear and organellar codon reassignments. [ABSTRACT FROM PUBLISHER]

Published

2017

3. Pathways of Genetic Code Evolution in Ancient and Modern Organisms.

Author

Sengupta, Supratim and Higgs, Paul

Subjects

*GENETIC code, *AMINO acids, *TRANSFER RNA, *BIOLOGICAL divergence, *DELETION mutation

Abstract

There have been two distinct phases of evolution of the genetic code: an ancient phase-prior to the divergence of the three domains of life, during which the standard genetic code was established-and a modern phase, in which many alternative codes have arisen in specific groups of genomes that differ only slightly from the standard code. Here we discuss the factors that are most important in these two phases, and we argue that these are substantially different. In the modern phase, changes are driven by chance events such as tRNA gene deletions and codon disappearance events. Selection acts as a barrier to prevent changes in the code. In contrast, in the ancient phase, selection for increased diversity of amino acids in the code can be a driving force for addition of new amino acids. The pathway of code evolution is constrained by avoiding disruption of genes that are already encoded by earlier versions of the code. The current arrangement of the standard code suggests that it evolved from a four-column code in which Gly, Ala, Asp, and Val were the earliest encoded amino acids. [ABSTRACT FROM AUTHOR]

Published

2015

4. Reversion of a fungal genetic code alteration links proteome instability with genomic and phenotypic diversification.

Author

Bezerra, Ana R., Simöe, João, Wanseon Lee, Rung, Johan, Weil, Tobias, Gut, Ivo G., Gut, Marta, Bayés, Mónica, Rizzetto, Lisa, Cavalieri, Duccio, Giovannini, Gloria, Bozza, Silvia, Romani, Luigina, Kapushesky, Misha, Moura, Gabriela R., and Santos, Manuel A. S.

Subjects

*FUNGAL genetics, *SPECIES diversity, *LEUCINE, *CANDIDA albicans, *BACTERIAL genetics, *SERINE, *HETEROZYGOSITY

Abstract

Many fungi restructured their proteomes through incorporation of serine (Ser) at thousands of protein sites coded by the leucine (Leu) CUG codon. How these fungi survived this potentially lethal genetic code alteration and its relevance for their biology are not understood. Interestingly, the human pathogen Candida albicans maintains variable Ser and Leu incorporation levels at CUG sites, suggesting that this atypical codon assignment flexibility provided an effective mechanism to alter the genetic code. To test this hypothesis, we have engineered C albicans strains to misincorporate increasing levels of Leu at protein CUG sites. Tolerance to the misincorporations was very high, and one strain accommodated the complete reversion of CUG identity from Ser back to Leu. Increasing levels of Leu misincorporation decreased growth rate, but production of phenotypic diversity on a phenotypic array probing various metabolic networks, drug resistance, and host immune cell responses was impressive. Genome resequencing revealed an increasing number of genotype changes at polymorphic sites compared with the control strain, and 80% of Leu misincorporation resulted in complete loss of heterozygosity in a large region of chromosome V. The data unveil unanticipated links between gene translational fidelity, proteome instability and variability, genome diversification, and adaptive phenotypic diversity. They also explain the high heterozygosity of the C albicans genome and open the door to produce microorganisms with genetic code alterations for basic and applied research. [ABSTRACT FROM AUTHOR]

Published

2013

5. A deviant genetic code in the green alga-derived plastid in the dinoflagellate Lepidodinium chlorophorum

Author

Matsumoto, Takuya, Ishikawa, Sohta A., Hashimoto, Tetsuo, and Inagaki, Yuji

Subjects

*DINOFLAGELLATES, *GREEN algae, *PLASTIDS, *GENETIC code, *ENDOSYMBIOSIS, *NUCLEOTIDE sequence

Abstract

Abstract: We here report a deviant genetic code, in which AUA is read as methionine (Met) instead of isoleucine (Ile), in the green alga-derived plastid in the dinoflagellate Lepidodinium chlorophorum. Although L. chlorophorum cDNA sequences of 11 plastid-encoded genes were deposited in the GenBank database, the non-canonical usage of AUA in this dinoflagellate plastid has been overlooked prior to this study. We compared 11 plastid-encoded genes of L. chlorophorum with the corresponding genes of 17 green algal plastids. Intriguingly, AUA often occurred in the L. chlorophorum sequences at codon positions that are predominantly occupied by Met amongst the green algal sequences. Coincidentally, the L. chlorophorum sequences utilized few AUA codons at the positions predominantly occupied by Ile amongst the green algal sequences. These observations clearly indicated that both AUA and AUG encode Met, while AUU and AUC encode Ile, in the L. chlorophorum plastid. Despite the rapidly-evolving nature of L. chlorophorum plastid-encoded genes, our statistical tests incorporating the deviant code suggest no significant difference in amino acid composition among the L. chlorophorum plastid and the green algal plastids considered in this study. Finally, the possible evolutionary events required for the reassignment of AUA from Ile to Met in Lepitodinium plastids were discussed. [Copyright &y& Elsevier]

Published

2011

6. Development of the genetic code: Insights from a fungal codon reassignment

Author

Moura, Gabriela R., Paredes, João A., and Santos, Manuel A.S.

Subjects

*TRANSFER RNA, *GENETIC code, *FUNGAL genetics, *PROTEIN synthesis, *BIOLOGICAL evolution, *AMINO acid synthesis, *NUCLEOSIDES, *CANDIDA

Abstract

Abstract: The high conservation of the genetic code and its fundamental role in genome decoding suggest that its evolution is highly restricted or even frozen. However, various prokaryotic and eukaryotic genetic code alterations, several alternative tRNA-dependent amino acid biosynthesis pathways, regulation of tRNA decoding by diverse nucleoside modifications and recent in vivo incorporation of non-natural amino acids into prokaryotic and eukaryotic proteins, show that the code evolves and is surprisingly flexible. The cellular mechanisms and the proteome buffering capacity that support such evolutionary processes remain unclear. Here we explore the hypothesis that codon misreading and reassignment played fundamental roles in the development of the genetic code and we show how a fungal codon reassignment is enlightening its evolution. [Copyright &y& Elsevier]

Published

2010

7. Codons AGA and AGG are read as glycine in ascidian mitochondria.

Author

Yokobori, Shin-ichi, Ueda, Takuya, and Watanabe, Kimitsuna

Abstract

A 1.2-kb DNA fragment of the cytochrome oxidase subunit I (CO I) gene of mitochondria isolated from an ascidian, Halocynthia roretzi, was amplified by polymerase chain reaction (PCR) and sequenced. Codons AGA and AGG appeared in its reading frame, indicating that these are sense codons in this organelle. Sequence comparisons with the corresponding regions of other animal mitochondrial CO I genes suggest that codons AGA and AGG correspond to glycine in the ascidian mitochondrial genome, but not to serine as in most invertebrate genomes, nor to stops as in vertebrate genomes. The other codons are identical to those of vertebrate mitochondria. [ABSTRACT FROM AUTHOR]

Published

1993

8. Development of the genetic code: Insights from a fungal codon reassignment

Author

João A. Paredes, Manuel A. S. Santos, and Gabriela Moura

Subjects

Evolution, Genetic code, Biophysics, Biology, Biochemistry, Genome, Codon reassignment, Evolution, Molecular, Structural Biology, Candida albicans, Genetics, Protein biosynthesis, Selection, Genetic, Codon, tRNA, Molecular Biology, Candida, chemistry.chemical_classification, Fungi, Cell Biology, Amino acid, chemistry, Genetic Code, Protein synthesist, Codon usage bias, Proteome, Transfer RNA, RNA, Codon usage, Protein synthesis, Synonymous substitution, Mistranslation

Abstract

The high conservation of the genetic code and its fundamental role in genome decoding suggest that its evolution is highly restricted or even frozen. However, various prokaryotic and eukaryotic genetic code alterations, several alternative tRNA-dependent amino acid biosynthesis pathways, regulation of tRNA decoding by diverse nucleoside modifications and recent in vivo incorporation of non-natural amino acids into prokaryotic and eukaryotic proteins, show that the code evolves and is surprisingly flexible. The cellular mechanisms and the proteome buffering capacity that support such evolutionary processes remain unclear. Here we explore the hypothesis that codon misreading and reassignment played fundamental roles in the development of the genetic code and we show how a fungal codon reassignment is enlightening its evolution. published

Published

2009

9. Reversion of a fungal genetic code alteration links proteome instability with genomic and phenotypic diversification

Author

Lisa Rizzetto, Wanseon Lee, João Simões, Misha Kapushesky, Tobias Weil, Gabriela Moura, Johan Rung, Duccio Cavalieri, Luigina Romani, Mònica Bayés, Ana R. Bezerra, Gloria Giovannini, Ivo Gut, Silvia Bozza, Manuel A. S. Santos, and Marta Gut

Subjects

Proteome, Evolution, Biology, Genome, Polymorphism, Single Nucleotide, Genomic Instability, Codon reassignment, Loss of heterozygosity, Evolution, Molecular, Fungal Proteins, 03 medical and health sciences, Mice, Genetic variation, Candida albicans, Animals, Humans, Codon, Gene, tRNA, 030304 developmental biology, 2. Zero hunger, Genetics, 0303 health sciences, Fungal protein, Multidisciplinary, 030306 microbiology, Genetic Carrier Screening, Genetic Variation, RNA, Fungal, Dendritic Cells, Biological Sciences, Genetic code, Mice, Inbred C57BL, Phenotype, Genetic Code, Transfer RNA, Female, Genome, Fungal, Settore BIO/19 - MICROBIOLOGIA GENERALE

Abstract

Many fungi restructured their proteomes through incorporation of serine (Ser) at thousands of protein sites coded by the leucine (Leu) CUG codon. How these fungi survived this potentially lethal genetic code alteration and its relevance for their biology are not understood. Interestingly, the human pathogen Candida albicans maintains variable Ser and Leu incorporation levels at CUG sites, suggesting that this atypical codon assignment flexibility provided an effective mechanism to alter the genetic code. To test this hypothesis, we have engineered C. albicans strains to misincorporate increasing levels of Leu at protein CUG sites. Tolerance to the misincorporations was very high, and one strain accommodated the complete reversion of CUG identity from Ser back to Leu. Increasing levels of Leu misincorporation decreased growth rate, but production of phenotypic diversity on a phenotypic array probing various metabolic networks, drug resistance, and host immune cell responses was impressive. Genome resequencing revealed an increasing number of genotype changes at polymorphic sites compared with the control strain, and 80% of Leu misincorporation resulted in complete loss of heterozygosity in a large region of chromosome V. The data unveil unanticipated links between gene translational fidelity, proteome instability and variability, genome diversification, and adaptive phenotypic diversity. They also explain the high heterozygosity of the C. albicans genome and open the door to produce microorganisms with genetic code alterations for basic and applied research. We thank Alexander Johnson for providing the C. albicans strains and plasmids and Judith Berman, Csaba Pál, and Dieter Söll for their useful comments and suggestions on the manuscript. The study was funded by the European Union Framework Program 7 (EUFP7) Sybaris Consortium Project 242220 and the Portuguese Science Foundation through Fundo Europeu de Desenvolvimento Regional (FEDER/FCT) Project PTDC/BIA-MIC/099826/2008. published

Published

2013