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

Nicola Whiffin; Konrad J Karczewski; Xiaolei Zhang; Sonia Chothani; Miriam J Smith; D Gareth Evans; Angharad M Roberts; Nicholas M Quaife; Sebastian Schafer; Owen Rackham; Jessica Alföldi; Anne H O’Donnell-Luria; Laurent C Francioli; Jessica Alföldi; Irina M. Armean; Eric Banks; Louis Bergelson; Kristian Cibulskis; Ryan L Collins; Kristen M. Connolly; Miguel Covarrubias; Beryl Cummings; Mark J. Daly; Stacey Donnelly; Yossi Farjoun; Steven Ferriera; Laurent Francioli; Stacey Gabriel; Laura D. Gauthier; Jeff Gentry; Namrata Gupta; Thibault Jeandet; Diane Kaplan; Konrad J. Karczewski; Kristen M. Laricchia; Christopher Llanwarne; Eric V. Minikel; Ruchi Munshi; Benjamin M Neale; Sam Novod; Anne H. O’Donnell-Luria; Nikelle Petrillo; Timothy Poterba; David Roazen; Valentin Ruano-Rubio; Andrea Saltzman; Tariq Ahmad; David Goldstein; Patrick F. Sullivan; James G. Wilson

doi:10.1101/543504

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

Nicola Whiffin, Konrad J Karczewski, Xiaolei Zhang, Sonia Chothani, Miriam J Smith, D Gareth Evans, Angharad M Roberts, Nicholas M Quaife, Sebastian Schafer, Owen Rackham, Jessica Alföldi, Anne H O’Donnell-Luria, Laurent C Francioli, Jessica Alföldi, Irina M. Armean, Eric Banks, Louis Bergelson, Kristian Cibulskis, Ryan L Collins, Kristen M. ConnollyMiguel Covarrubias, Beryl Cummings, Mark J. Daly, Stacey Donnelly, Yossi Farjoun, Steven Ferriera, Laurent Francioli, Stacey Gabriel, Laura D. Gauthier, Jeff Gentry, Namrata Gupta, Thibault Jeandet, Diane Kaplan, Konrad J. Karczewski, Kristen M. Laricchia, Christopher Llanwarne, Eric V. Minikel, Ruchi Munshi, Benjamin M Neale, Sam Novod, Anne H. O’Donnell-Luria, Nikelle Petrillo, Timothy Poterba, David Roazen, Valentin Ruano-Rubio, Andrea Saltzman, Tariq Ahmad, David Goldstein, Patrick F. Sullivan, James G. Wilson

Division of Evolution, Infection and Genomics

Research output: Other contribution › peer-review

Abstract

Upstream open reading frames (uORFs) are important tissue-specific cis-regulators of protein translation. Although isolated case reports have shown that variants that create or disrupt uORFs can cause disease, genetic sequencing approaches typically focus on protein-coding regions and ignore these variants. Here, we describe a systematic genome-wide study of variants that create and disrupt human uORFs, and explore their role in human disease using 15,708 whole genome sequences collected by the Genome Aggregation Database (gnomAD) project. We show that 14,897 variants that create new start codons upstream of the canonical coding sequence (CDS), and 2,406 variants disrupting the stop site of existing uORFs, are under strong negative selection. Furthermore, variants creating uORFs that overlap the CDS show signals of selection equivalent to coding missense variants, and uORF-perturbing variants are under strong selection when arising upstream of known disease genes and genes intolerant to loss-of-function variants. Finally, we identify specific genes where perturbation of uORFs is likely to represent an important disease mechanism, and report a novel uORF frameshift variant upstream of NF2 in families with neurofibromatosis. Our results highlight uORF-perturbing variants as an important and under-recognised functional class that can contribute to penetrant human disease, and demonstrate the power of large-scale population sequencing data to study the deleteriousness of specific classes of non-coding variants.

Original language	Undefined
Number of pages	32
DOIs	https://doi.org/10.1101/543504
Publication status	Published - 7 Feb 2019

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Whiffin, N., Karczewski, K. J., Zhang, X., Chothani, S., Smith, M. J., Evans, D. G., Roberts, A. M., Quaife, N. M., Schafer, S., Rackham, O., Alföldi, J., O’Donnell-Luria, A. H., Francioli, L. C., Alföldi, J., Armean, I. M., Banks, E., Bergelson, L., Cibulskis, K., Collins, R. L., ... Wilson, J. G. (2019, Feb 7). Characterising the loss-of-function impact of 5’ untranslated region variants in whole genome sequence data from 15,708 individuals. https://doi.org/10.1101/543504

@misc{8177ecb3e5f5494c8043acb31baaa676,

title = "Characterising the loss-of-function impact of 5{\textquoteright} untranslated region variants in whole genome sequence data from 15,708 individuals",

abstract = "Upstream open reading frames (uORFs) are important tissue-specific cis-regulators of protein translation. Although isolated case reports have shown that variants that create or disrupt uORFs can cause disease, genetic sequencing approaches typically focus on protein-coding regions and ignore these variants. Here, we describe a systematic genome-wide study of variants that create and disrupt human uORFs, and explore their role in human disease using 15,708 whole genome sequences collected by the Genome Aggregation Database (gnomAD) project. We show that 14,897 variants that create new start codons upstream of the canonical coding sequence (CDS), and 2,406 variants disrupting the stop site of existing uORFs, are under strong negative selection. Furthermore, variants creating uORFs that overlap the CDS show signals of selection equivalent to coding missense variants, and uORF-perturbing variants are under strong selection when arising upstream of known disease genes and genes intolerant to loss-of-function variants. Finally, we identify specific genes where perturbation of uORFs is likely to represent an important disease mechanism, and report a novel uORF frameshift variant upstream of NF2 in families with neurofibromatosis. Our results highlight uORF-perturbing variants as an important and under-recognised functional class that can contribute to penetrant human disease, and demonstrate the power of large-scale population sequencing data to study the deleteriousness of specific classes of non-coding variants.",

author = "Nicola Whiffin and Karczewski, {Konrad J} and Xiaolei Zhang and Sonia Chothani and Smith, {Miriam J} and Evans, {D Gareth} and Roberts, {Angharad M} and Quaife, {Nicholas M} and Sebastian Schafer and Owen Rackham and Jessica Alf{\"o}ldi and O{\textquoteright}Donnell-Luria, {Anne H} and Francioli, {Laurent C} and Jessica Alf{\"o}ldi and Armean, {Irina M.} and Eric Banks and Louis Bergelson and Kristian Cibulskis and Collins, {Ryan L} and Connolly, {Kristen M.} and Miguel Covarrubias and Beryl Cummings and Daly, {Mark J.} and Stacey Donnelly and Yossi Farjoun and Steven Ferriera and Laurent Francioli and Stacey Gabriel and Gauthier, {Laura D.} and Jeff Gentry and Namrata Gupta and Thibault Jeandet and Diane Kaplan and Karczewski, {Konrad J.} and Laricchia, {Kristen M.} and Christopher Llanwarne and Minikel, {Eric V.} and Ruchi Munshi and Neale, {Benjamin M} and Sam Novod and O{\textquoteright}Donnell-Luria, {Anne H.} and Nikelle Petrillo and Timothy Poterba and David Roazen and Valentin Ruano-Rubio and Andrea Saltzman and Tariq Ahmad and David Goldstein and Sullivan, {Patrick F.} and Wilson, {James G.}",

year = "2019",

month = feb,

day = "7",

doi = "10.1101/543504",

language = "Undefined",

type = "Other",

}

Whiffin, N, Karczewski, KJ, Zhang, X, Chothani, S, Smith, MJ , Evans, DG, Roberts, AM, Quaife, NM, Schafer, S, Rackham, O, Alföldi, J, O’Donnell-Luria, AH, Francioli, LC, Alföldi, J, Armean, IM, Banks, E, Bergelson, L, Cibulskis, K, Collins, RL, Connolly, KM, Covarrubias, M, Cummings, B, Daly, MJ, Donnelly, S, Farjoun, Y, Ferriera, S, Francioli, L, Gabriel, S, Gauthier, LD, Gentry, J, Gupta, N, Jeandet, T, Kaplan, D, Karczewski, KJ, Laricchia, KM, Llanwarne, C, Minikel, EV, Munshi, R, Neale, BM, Novod, S, O’Donnell-Luria, AH, Petrillo, N, Poterba, T, Roazen, D, Ruano-Rubio, V, Saltzman, A, Ahmad, T, Goldstein, D, Sullivan, PF & Wilson, JG 2019, Characterising the loss-of-function impact of 5’ untranslated region variants in whole genome sequence data from 15,708 individuals.. https://doi.org/10.1101/543504

TY - GEN

T1 - Characterising the loss-of-function impact of 5’ untranslated region variants in whole genome sequence data from 15,708 individuals

AU - Whiffin, Nicola

AU - Karczewski, Konrad J

AU - Zhang, Xiaolei

AU - Chothani, Sonia

AU - Smith, Miriam J

AU - Evans, D Gareth

AU - Roberts, Angharad M

AU - Quaife, Nicholas M

AU - Schafer, Sebastian

AU - Rackham, Owen

AU - Alföldi, Jessica

AU - O’Donnell-Luria, Anne H

AU - Francioli, Laurent C

AU - Alföldi, Jessica

AU - Armean, Irina M.

AU - Banks, Eric

AU - Bergelson, Louis

AU - Cibulskis, Kristian

AU - Collins, Ryan L

AU - Connolly, Kristen M.

AU - Covarrubias, Miguel

AU - Cummings, Beryl

AU - Daly, Mark J.

AU - Donnelly, Stacey

AU - Farjoun, Yossi

AU - Ferriera, Steven

AU - Francioli, Laurent

AU - Gabriel, Stacey

AU - Gauthier, Laura D.

AU - Gentry, Jeff

AU - Gupta, Namrata

AU - Jeandet, Thibault

AU - Kaplan, Diane

AU - Karczewski, Konrad J.

AU - Laricchia, Kristen M.

AU - Llanwarne, Christopher

AU - Minikel, Eric V.

AU - Munshi, Ruchi

AU - Neale, Benjamin M

AU - Novod, Sam

AU - O’Donnell-Luria, Anne H.

AU - Petrillo, Nikelle

AU - Poterba, Timothy

AU - Roazen, David

AU - Ruano-Rubio, Valentin

AU - Saltzman, Andrea

AU - Ahmad, Tariq

AU - Goldstein, David

AU - Sullivan, Patrick F.

AU - Wilson, James G.

PY - 2019/2/7

Y1 - 2019/2/7

N2 - Upstream open reading frames (uORFs) are important tissue-specific cis-regulators of protein translation. Although isolated case reports have shown that variants that create or disrupt uORFs can cause disease, genetic sequencing approaches typically focus on protein-coding regions and ignore these variants. Here, we describe a systematic genome-wide study of variants that create and disrupt human uORFs, and explore their role in human disease using 15,708 whole genome sequences collected by the Genome Aggregation Database (gnomAD) project. We show that 14,897 variants that create new start codons upstream of the canonical coding sequence (CDS), and 2,406 variants disrupting the stop site of existing uORFs, are under strong negative selection. Furthermore, variants creating uORFs that overlap the CDS show signals of selection equivalent to coding missense variants, and uORF-perturbing variants are under strong selection when arising upstream of known disease genes and genes intolerant to loss-of-function variants. Finally, we identify specific genes where perturbation of uORFs is likely to represent an important disease mechanism, and report a novel uORF frameshift variant upstream of NF2 in families with neurofibromatosis. Our results highlight uORF-perturbing variants as an important and under-recognised functional class that can contribute to penetrant human disease, and demonstrate the power of large-scale population sequencing data to study the deleteriousness of specific classes of non-coding variants.

AB - Upstream open reading frames (uORFs) are important tissue-specific cis-regulators of protein translation. Although isolated case reports have shown that variants that create or disrupt uORFs can cause disease, genetic sequencing approaches typically focus on protein-coding regions and ignore these variants. Here, we describe a systematic genome-wide study of variants that create and disrupt human uORFs, and explore their role in human disease using 15,708 whole genome sequences collected by the Genome Aggregation Database (gnomAD) project. We show that 14,897 variants that create new start codons upstream of the canonical coding sequence (CDS), and 2,406 variants disrupting the stop site of existing uORFs, are under strong negative selection. Furthermore, variants creating uORFs that overlap the CDS show signals of selection equivalent to coding missense variants, and uORF-perturbing variants are under strong selection when arising upstream of known disease genes and genes intolerant to loss-of-function variants. Finally, we identify specific genes where perturbation of uORFs is likely to represent an important disease mechanism, and report a novel uORF frameshift variant upstream of NF2 in families with neurofibromatosis. Our results highlight uORF-perturbing variants as an important and under-recognised functional class that can contribute to penetrant human disease, and demonstrate the power of large-scale population sequencing data to study the deleteriousness of specific classes of non-coding variants.

UR - https://doi.org/10.1101/543504

U2 - 10.1101/543504

DO - 10.1101/543504

M3 - Other contribution

ER -

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

Abstract

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