Characterising the loss-of-function impact of 5’ untranslated region variants in whole genome sequence data from 15,708 individuals

Whiffin, Nicola; Kj, Karczewski; Zhang, X; Chothani, Sonia; Smith, Miriam J.; Evans, D. Gareth; Am, Roberts; Nm, Quaife; Schäfer, Sebastian; Rackham, Owen J. L.; Alföldi, Jessica; Ah, O’Donnell-Luria; Lc, Francioli; Armean, Irina M.; Banks, Eric; Bergelson, Louis; Cibulskis, Kristian; Rl, Collins; Km, Connolly; Covarrubias, Miguel; Cummings, Beryl B.; Daly, Mark J.; Donnelly, Stacey; Farjoun, Yossi; Ferriera, Steven; Francioli, Laurent C.; Gabriel, Stacey; Ld, Gauthier; Gentry, Jeff; Gupta, Namrata; Jeandet, Thibault; Kaplan, Diane; Km, Laricchia; Llanwarne, Christopher; Minikel, Eric Vallabh; Munshi, Ruchi; Bm, Neale; Novod, Sam; Petrillo, Nikelle; Poterba, Timothy; Roazen, David; Ruano-Rubio,; Saltzman, Andrea; Ke, Samocha; Schleicher, Molly; Seed, Cotton; Solomonson, Matthew; Soto, José María Satizábal; Tiao, Grace; Tibbetts, Kathleen; Tolonen, Charlotte; Vittal, Christopher; Wade, Gordon; Wang, A; Wang, Q; Ware, JS; Na, Watts; Weisburd, Ben; Caa, Salinas; Ahmad, Tariq; Chen, Albert; Ardissino, Diego; Atzmon, Gil; Barnard, John; Beaugerie, Laurent; Benjamin, Emelia J.; Boehnke, Michael; Ll, Bonnycastle; Ep, Bottinger; Dw, Bowden; Bown, Matthew J.; Chambers, JC; Jc, Chan; Chasman, Deborah; J, Cho; Mk, Chung; Cohen, Bruce M.; Correa, Adolfo; Dabelea, Dana; Darbar, Dawood; Duggirala, Ravindranath; Dupuis, Josée; Pt, Ellinor; Elosúa, Roberto; Erdmann, Jeanette; Esko, Tõnu; Färkkilä, M.; Florez, José C.; Franke, André; Getz, Gad; Gläser, Benjamin; Sj, Glatt; Goldstein, DB; González, Clicerio; Groop, Leif; Haiman, Christopher; Hanis, Craig L.; Harms, Matthew B.; Hiltunen, Mikko; Mm, Holi; Cm, Hultman; Kallela, Mikko; Kaprio, Jaakko; Kathiresan, Sekar; Kim, Bonglee; Kim, Yoon Jun; Kirov, George; Kooner, Jaspal S.; Koskinen, Seppo; Hm, Krumholz; Kugathasan, Subramaniam; Sh, Kwak; Laakso, Markku; Lehtimäki, Terho; Loos, Ruth J.F.; Sa, Lubitz; Rc, Ma; Dg, MacArthur; Marrugat, Jaume; Km, Mattila; McCarroll, Steven A.; McCarthy, Mark I.; McGovern, Dermot; McPherson, Ruth; Jb, Meigs; Melander, Olle; Metspalu, Andres; Nilsson, P. Anders; Mc, O’Donovan; Öngür, Döst; Orozco, Lorena; Mj, Owen; Cn, Palmer; Palotie, Aarno; Ks, Park; Pato, Carlos N.; Ae, Pulver; Rahman, Normastura Abd; Am, Remes; Jd, Rioux; Ripatti, Samuli; Dm, Roden; Saleheen, Danish; Salomaa,; Nj, Samani; Scharf, Jeremiah M.; Schunkert, Heribert; Mb, Shoemaker; Sklar, Pamela; Soininen, Hilkka; Soko, H; Spector, Tim D.; Pf, Sullivan; Suvisaari, Jaana; Es, Tai; Yy, Teo; Tuomi, Tiinamaija; Tsuang, Ming T.; Turner, Dan; Tusié-Luna, Teresa; Vartiainen, Erkki; Watkins, Hugh; Rk, Weersma; Wessman, Maija; Jg, Wilson; Rj, Xavier; Sa, Cook; Barton, Pjr

doi:10.1101/543504

Cited by 11 publications

(20 citation statements)

References 36 publications

(31 reference statements)

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“…uORF variation has been studied at the genome-wide scale using human SNPs and the results provide clear evidence of its association with genetic diseases. However, these studies only assessed single SNP effects that result in uORF initiation codon creation or stop codon loss (3, 8). We analyzed uORF variation by considering the integral effect of all homozygous SNPs and INDELs in each accession.…”

Section: Resultsmentioning

confidence: 99%

“…By 2009, 509 human genes had been identified with polymorphic uORFs and some of them have been experimentally associated with different human diseases, including malignancies, metabolic or neurologic disorders, and inherited syndromes. This trend became more striking recently with more genomic variation data released and analyzed (3, 8). In contrast, natural variation of plant uORFs has not yet been investigated, even though there are abundant publicly accessible genetic and phenotypic variation data, especially for Arabidopsis ( Arabidopsis thaliana ) and rice ( Oryza sativa L.).…”

Section: Introductionmentioning

confidence: 99%

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uORFlight: a vehicle towards uORF-mediated translational regulation mechanisms in eukaryotes

Niu

Zhou

Mou

et al. 2019

Preprint

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1 Upstream open reading frames (uORFs) are prevalent in eukaryotic mRNAs. They 2 act as a translational control element for precisely tuning the expression of the 3 downstream major open reading frame (mORF) with essential cellular functionalities. 4 uORF variation has been clearly associated with several human diseases. In contrast, 5 natural uORF variants in plants have not ever been identified or linked with any 6 phenotypic changes. The paucity of such evidence encouraged us to generate this 7 database-uORFlight (http://uorflight.whu.edu.cn). It facilitates the exploration of uORF 8 variation among different splicing models of Arabidopsis and rice genes. Most 9 importantly, users can evaluate uORF frequency among different accessions at the 10 population scale and find out the causal single nucleotide polymorphism (SNP) or 11 insertion/deletion (INDEL) which can be associated with phenotypic variation through 12 database mining or simple experiments. Such information will help to make hypotheses 13 of uORF function in plant development or adaption to changing environments on the 14 basis of the cognate mORF function. This database also curates plant uORF relevant 15 literature into distinct groups. To be broadly interesting, our database expands uORF 16 annotation into more species of fungi (Botrytis cinerea), plant (Brassica napus, Glycine 17 max, Gossypium raimondii, Medicago truncatula, Solanum lycopersicum, Solanum 18 tuberosum, Triticum aestivum and Zea mays), metazoan (Caenorhabditis elegans and 19 Drosophila melanogaster) and vertebrate (Homo sapiens, Mus musculus and Danio 20 rerio). Therefore, uORFlight will light up the runway toward how uORF genetic 21 variation determines phenotypic diversity and advance our understanding of 22 translational control mechanisms. 23 24 mediated by the cooperative action between different mRNA elements and trans-acting 1 factors (1). Upstream open reading frames (uORFs) are among the mRNA elements that 2 can confer precise control of protein translation. 3 A uORF initiation codon resides upstream of the coherent mORF, and will be first 4 encountered by 43S scanning ribosome (including 40S ribosomal subunit and eIF2 5 ternary complex). Sequentially, 60S subunit joins in and reconstitutes 80S ribosome for 6 uORF translation elongation, after which the 40S and 60S are disjointed and 40S may 7 remain associated with mRNA. Therefore, usually uORF translation is prioritized over 8 mORF, leading to hindered translation of the mORF. Only in situations where the 9 remaining 40S ribosomes regain fresh eIF2 ternary complex and other unknown 10 reinitiation factors, or when uORF initiation codon is bypassed by the scanning 11 ribosome, the downstream mORF has the chance to be translated (Figure 1a). The 12 former situation is termed as reinitiation and the latter as leaky scanning, two 13 mechanisms that have been accepted as an explanation of limited mORF expression 14 under normal growth and developmental conditions (2-4). Most importantly, a uORF 15 can confer selective mORF ...

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

uORFlight: a vehicle towards uORF-mediated translational regulation mechanisms in eukaryotes

Niu

Zhou

Mou

et al. 2019

Preprint

View full text Add to dashboard Cite

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“…Upstream open reading frames (uORFs) are short sequences within 5'UTRs that regulate the rate at which the downstream coding sequence is translated into protein. Variants that create or disrupt uORFs (uORF-perturbing variants) have been shown to cause rare disease (Calvo, Pagliarini and Mootha, 2009;Whiffin et al, 2020). We recently used data from the Genome Aggregation Database (gnomAD) to systematically characterise the deleteriousness of different categories of uORF-perturbing variants and prioritise those that are more likely to be disease causing (Whiffin et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Variants that create or disrupt uORFs (uORF-perturbing variants) have been shown to cause rare disease (Calvo, Pagliarini and Mootha, 2009;Whiffin et al, 2020). We recently used data from the Genome Aggregation Database (gnomAD) to systematically characterise the deleteriousness of different categories of uORF-perturbing variants and prioritise those that are more likely to be disease causing (Whiffin et al, 2020). Current variant annotation approaches focus on the impact of protein-coding variants, with only limited annotation of predicted consequences for non-coding variants.…”

Section: Introductionmentioning

confidence: 99%

Annotating high-impact 5’untranslated region variants with the UTRannotator

Zhang

Wakeling

Ware

et al. 2020

Preprint

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Current tools to annotate the predicted effect of genetic variants are heavily biased towards protein-coding sequence. Variants outside of these regions may have a large impact on protein expression and/or structure and can lead to disease, but this effect can be challenging to predict. Consequently, these variants are poorly annotated using standard tools. We have developed a plugin to the Ensembl Variant Effect Predictor, the UTRannotator, that annotates variants in 5'untranslated regions (5'UTR) that create or disrupt upstream open reading frames (uORFs). We investigate the utility of this tool using the ClinVar database, providing an annotation for 30.8% of all 5'UTR (likely) pathogenic variants, and highlighting 31 variants of uncertain significance as candidates for further follow-up. We will continue to update the UTR annotator as we gain new knowledge on the impact of variants in UTRs.

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“…In other work, AS was shown to regulate domains leading to the rewiring of PPI networks in cancer 32 . Similarly, APA has been postulated as a mechanism to escape microRNA regulation by shortening 3' UTR regions 33,34 , alternative TSS are believed to regulate the inclusion of Upstream Open Reading Frames (uORFs) that control translational rates [35][36][37] and NMD has been proposed to regulate gene expression in cancer and neural systems 38,39 .…”

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confidence: 99%

tappAS: a comprehensive computational framework for the analysis of the functional impact of differential splicing

Fuente

Arzalluz-Luque

Tardáguila

et al. 2019

Preprint

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Traditionally, the functional analysis of gene expression data has used pathway and network enrichment algorithms. These methods are usually gene rather than transcript centric and hence fall short to unravel functional roles associated to posttranscriptional regulatory mechanisms such as Alternative Splicing (AS) and Alternative PolyAdenylation (APA), jointly referred here as Alternative Transcript Processing (AltTP). Moreover, short-read RNA-seq has serious limitations to resolve full-length transcripts, further complicating the study of isoform expression. Recent advances in long-read sequencing open exciting opportunities for studying isoform biology and function. However, there are no established bioinformatics methods for the functional analysis of isoform-resolved transcriptomics data to fully leverage these technological advances. Here we present a novel framework for Functional Iso-Transcriptomics analysis (FIT). This framework uses a rich isoform-level annotation database of functional domains, motifs and sites -both coding and noncoding-and introduces novel analysis methods to interrogate different aspects of the functional relevance of isoform complexity. The Functional Diversity Analysis (FDA) evaluates the variability at the inclusion/exclusion of functional domains across annotated transcripts of the same gene. Parameters can be set to evaluate if AltTP partially or fully disrupts functional elements. FDA is a measure of the potential of a multiple isoform transcriptome to have a functional impact. By combining these functional labels with expression data, the Differential Analysis Module evaluates the relative contribution of transcriptional (i.e. gene level) and post-transcriptional (i.e. transcript/protein levels) regulation on the biology of the system. Measures of inclusion of NLS, transmembrane domains or DNA binding motifs, for example.Some of these findings were experimentally validated by others and us.In summary, we propose a novel framework for the functional analysis of transcriptomes at isoform resolution. We anticipate the tappAS tool will be an important resource for the adoption of the Functional Iso-Transcriptomics analysis by functional genomics community.

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Characterising the loss-of-function impact of 5’ untranslated region variants in whole genome sequence data from 15,708 individuals

Cited by 11 publications

References 36 publications

uORFlight: a vehicle towards uORF-mediated translational regulation mechanisms in eukaryotes

uORFlight: a vehicle towards uORF-mediated translational regulation mechanisms in eukaryotes

Annotating high-impact 5’untranslated region variants with the UTRannotator

tappAS: a comprehensive computational framework for the analysis of the functional impact of differential splicing

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