A novel nuclear genetic code alteration in yeasts and the evolution of codon reassignment in eukaryotes

Mühlhausen, Stefanie; Findeisen, Peggy; Plessmann, Uwe; Urlaub, Henning; Kollmar, Martin

doi:10.1101/gr.200931.115

Cited by 61 publications

(69 citation statements)

References 65 publications

(71 reference statements)

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“…It has occurred several times during yeast evolution as a result of distinct mechanisms (Mühlhausen et al 2016). In P. tannophilus , representing a basal lineage to the methylotroph clade, as well as in A. rubescens , a member of the Ascoidaceae family, the CUG codon specifies alanine instead of leucine or serine (Riley et al 2016).…”

Section: What Did We Learn From Comparative Genomics Of Other Saccharmentioning

confidence: 99%

“…In P. tannophilus , representing a basal lineage to the methylotroph clade, as well as in A. rubescens , a member of the Ascoidaceae family, the CUG codon specifies alanine instead of leucine or serine (Riley et al 2016). In P. tannophilus , reassignment followed tRNA loss (Mühlhausen et al 2016). Several different sense-to-sense codon reassignments are also observed in the mitochondrial genetic code of the Saccharomycetaceae yeasts (Ling et al 2014, for a recent overview).…”

Section: What Did We Learn From Comparative Genomics Of Other Saccharmentioning

confidence: 99%

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Genome Diversity and Evolution in the Budding Yeasts (Saccharomycotina)

2017

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Considerable progress in our understanding of yeast genomes and their evolution has been made over the last decade with the sequencing, analysis, and comparisons of numerous species, strains, or isolates of diverse origins. The role played by yeasts in natural environments as well as in artificial manufactures, combined with the importance of some species as model experimental systems sustained this effort. At the same time, their enormous evolutionary diversity (there are yeast species in every subphylum of Dikarya) sparked curiosity but necessitated further efforts to obtain appropriate reference genomes. Today, yeast genomes have been very informative about basic mechanisms of evolution, speciation, hybridization, domestication, as well as about the molecular machineries underlying them. They are also irreplaceable to investigate in detail the complex relationship between genotypes and phenotypes with both theoretical and practical implications. This review examines these questions at two distinct levels offered by the broad evolutionary range of yeasts: inside the best-studied Saccharomyces species complex, and across the entire and diversified subphylum of Saccharomycotina. While obviously revealing evolutionary histories at different scales, data converge to a remarkably coherent picture in which one can estimate the relative importance of intrinsic genome dynamics, including gene birth and loss, vs. horizontal genetic accidents in the making of populations. The facility with which novel yeast genomes can now be studied, combined with the already numerous available reference genomes, offer privileged perspectives to further examine these fundamental biological questions using yeasts both as eukaryotic models and as fungi of practical importance.

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Section: What Did We Learn From Comparative Genomics Of Other Saccharmentioning

confidence: 99%

Section: What Did We Learn From Comparative Genomics Of Other Saccharmentioning

confidence: 99%

Genome Diversity and Evolution in the Budding Yeasts (Saccharomycotina)

2017

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“…In effect, several protein‐coding genes are overlapping and termination codons are added after transcription. Moreover, the genetic code has been altered in response to the reductive forces such that it can be read with only 22 tRNA, whereas a minimum of 24 tRNA is required to read the standard genetic code . However, the mitochondrial genome in other organismal groups has not evolved under the same constraints on genome size.…”

Section: Discussionmentioning

confidence: 99%

Why mitochondria need a genome revisited

et al. 2016

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In this paper, we experimentally address the debate about why functional transfer of mitochondrial genes to the nucleus has been halted in some organismal groups and why cytosolic expression of mitochondrial proteins has proven remarkably difficult. By expressing all 13 human mitochondrial-encoded genes with strong mitochondrial-targeting sequences in the cytosol of human cells, we show that all proteins, except ATP8, are transported to the endoplasmic reticulum (ER). These results confirm and extend previous findings based on three mitochondrial genes lacking mitochondrial-targeting sequences that also were relocated to the ER during cytosolic expression. We conclude that subcellular protein targeting constitutes a major barrier to functional transfer of mitochondrial genes to the nuclear genome.

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“…Given the vast amount of new genomic and metagenomic DNA sequence information generated in the past few years, we document here the current knowledge of natural deviations from the standard genetic code (45, 61, 79, 92, 94, 98, 115, 125, 134, 157) (Figure 2) (Supplemental Figure 1). Previously, it was well known that Candida yeast reassigns the CUG codon from leucine (Leu) to serine (Ser) (60) and that many ciliates reassign either the UGA stop codon or both the UAA and the UAG stop codons to a canonical amino acid (12, 61, 88, 119) (Figure 2).…”

Section: Natural Expansion Of the Genetic Codementioning

confidence: 99%

Rewriting the Genetic Code

Mukai

Lajoie

Englert

et al. 2017

Annu. Rev. Microbiol.

135

128

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The genetic code—the language used by cells to translate their genomes into proteins that perform many cellular functions—is highly conserved throughout natural life. Rewriting the genetic code could lead to new biological functions such as expanding protein chemistries with noncanonical amino acids (ncAAs) and genetically isolating synthetic organisms from natural organisms and viruses. It has long been possible to transiently produce proteins bearing ncAAs, but stabilizing an expanded genetic code for sustained function in vivo requires an integrated approach: creating recoded genomes and introducing new translation machinery that function together without compromising viability or clashing with endogenous pathways. In this review, we discuss design considerations and technologies for expanding the genetic code. The knowledge obtained by rewriting the genetic code will deepen our understanding of how genomes are designed and how the canonical genetic code evolved.

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A novel nuclear genetic code alteration in yeasts and the evolution of codon reassignment in eukaryotes

Cited by 61 publications

References 65 publications

Genome Diversity and Evolution in the Budding Yeasts (Saccharomycotina)

Genome Diversity and Evolution in the Budding Yeasts (Saccharomycotina)

Why mitochondria need a genome revisited

Rewriting the Genetic Code

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