A unified model for the surveillance of translation in diverse noncoding sequences

Kesner, Jordan; Chen, Ziheng; Aparicio, Alexis A; Wu, Xuebing

doi:10.1101/2022.07.20.500724

Cited by 7 publications

(6 citation statements)

References 89 publications

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“…Similarly, this enrichment could reflect evolutionary pressure to avoid expression of unwanted products, balanced against the advantage of occasionally allowing novelty to emerge. The overrepresentation of TM domains, perhaps coupled with the absence of other signals, could be part of a surveillance mechanism that detects and degrades aberrant translation products, similarly to what was found in a recent preprint 20 .…”

Section: Discussionsupporting

confidence: 56%

Intergenic regions of Saccharomycotina yeasts are enriched in potential to form transmembrane domains

Tassios

Nikolaou

Vakirlis

2022

Preprint

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Intergenic genomic regions have essential regulatory and structural roles that impose constraints on their sequences. But regions that do not currently encode proteins, also carry the potential to do so in the future. De novo gene emergence, the evolution of novel genes out of previously non-coding sequences has now been established as a potent force for genomic novelty. Recently, it was shown that intergenic regions in the genome ofS. cerevisiaeharbor pervasive cryptic potential to, if theoretically translated, form transmembrane domains (TM domains) more frequently than expected by chance, a property that we refer to as TM-forming enrichment. The source and biological relevance of this property is unknown. Here we expand the investigation into the TM-forming potential of intergenic regions to the entire Saccharomycotina budding yeast subphylum, in an effort to explain this property and understand its importance. We find pervasive but variable enrichment in TM-forming potential across the subphylum, regardless of the composition and average size of intergenic regions. This cryptic property is evenly spread across the genome, cannot be explained by the hydrophobic content of the sequence, and does not appear to localize to regions containing regulatory motifs. This TM-forming enrichment specifically, and not the actual TM-forming potential, is associated, across genomes, with more TM domains in evolutionarily young genes. Our findings shed light on this newly discovered feature of yeast genomes and constitute a first step towards understanding its evolutionary importance.

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Section: Discussionsupporting

confidence: 56%

Intergenic regions of Saccharomycotina yeasts are enriched in potential to form transmembrane domains

Tassios

Nikolaou

Vakirlis

2022

Preprint

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Section: Discussionsupporting

confidence: 53%

Intergenic Regions of Saccharomycotina Yeasts are Enriched in Potential to Encode Transmembrane Domains

Tassios

Nikolaou

Vakirlis

2023

Molecular Biology and Evolution

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Intergenic genomic regions have essential regulatory and structural roles that impose constraints on their sequences. But regions that do not currently encode proteins also carry the potential to do so in the future. De novo gene emergence, the evolution of novel genes out of previously non-coding sequences has now been established as a potent force for genomic novelty. Recently, it was shown that intergenic regions in the genome of S. cerevisiae harbor pervasive cryptic potential to, if theoretically translated, form transmembrane domains (TM domains) more frequently than expected by chance given their nucleotide composition, a property that we refer to as TM-forming enrichment. The source and biological relevance of this property is unknown. Here we expand the investigation into the TM-forming potential of intergenic regions to the entire Saccharomycotina budding yeast subphylum, in an effort to explain this property and understand its importance. We find pervasive but variable enrichment in TM-forming potential across the subphylum regardless of the composition and average size of intergenic regions. This cryptic property is evenly spread across the genome, cannot be explained by the hydrophobic content of the sequence, and does not appear to localize to regions containing regulatory motifs. This TM-forming enrichment specifically, and not the actual TM-forming potential, is associated, across genomes, with more TM domains in evolutionarily young genes. Our findings shed light on this newly discovered feature of yeast genomes and constitute a first step towards understanding its evolutionary importance.

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“…Recent research in yeast has revealed a significant enrichment of transmembrane domains 16,22 (TMDs) within putative peptides of de novo ORFs, suggesting an association with cellular membranes. Notably, many studies identified de novo ORFs in yeast 22,59 and small nORFs in humans 14,67 that localize to diverse cellular membranes, such as ER, vacuole, endosome, or mitochondria. These findings have raised the possibility that de novo ORFs could play a role in a range of transport processes, such as ion, amino acid, and protein transport across cellular membranes.…”

Section: Discussionmentioning

confidence: 99%

Massively integrated coexpression analysis reveals transcriptional regulation, evolution and cellular implications of the noncanonical translatome

Rich

Acar

Carvunis

2023

Preprint

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Cells transcribe and translate thousands of noncanonical open reading frames (nORFs) whose impacts on cellular phenotypes are unknown. Here, we investigated nORF transcription, evolution, and potential cellular roles using a coexpression approach. We measured coexpression between ~6,000 nORFs and ~6000 canonical ORFs (cORFs) in the Saccharomyces cerevisiae genome by massively integrating thousands of RNA sequencing samples and developing a dedicated computational framework that accounts for low expression levels. Our findings reveal that almost all cORFs are strongly coexpressed with at least one nORF. However, almost half of nORFs are not strongly coexpressed with any cORFs and form entirely new transcription modules. Many nORFs recently evolved de novo in genomic regions that were non-coding in the Saccharomyces ancestor. Coexpression profiles suggest that half of de novo nORFs are functionally associated with conserved genes involved in cellular transport or homeostasis. Furthermore, we discovered that de novo ORFs located downstream of conserved genes leverage their neighbors' transcripts resulting in high expression levels. Where a de novo nORF emerges could be just as important as its sequence for shaping how it can influence cellular phenotype. Our coexpression dataset serves as an unprecedented resource for unraveling how nORFs integrate into cellular networks, contribute to cellular phenotypes and evolve.

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A unified model for the surveillance of translation in diverse noncoding sequences

Cited by 7 publications

References 89 publications

Intergenic regions of Saccharomycotina yeasts are enriched in potential to form transmembrane domains

Intergenic regions of Saccharomycotina yeasts are enriched in potential to form transmembrane domains

Intergenic Regions of Saccharomycotina Yeasts are Enriched in Potential to Encode Transmembrane Domains

Massively integrated coexpression analysis reveals transcriptional regulation, evolution and cellular implications of the noncanonical translatome

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