Integrative annotation of variants from 1092 humans: Application to cancer genomics

1000 Genomes Project Consortium

doi:10.1126/science.1235587

Integrative annotation of variants from 1092 humans: Application to cancer genomics

1000 Genomes Project Consortium

Quantitative Health Sciences

Research output: Contribution to journal › Article › peer-review

245 Scopus citations

Abstract

Interpreting variants, especially noncoding ones, in the increasing number of personal genomes is challenging. We used patterns of polymorphisms in functionally annotated regions in 1092 humans to identify deleterious variants; then we experimentally validated candidates. We analyzed both coding and noncoding regions, with the former corroborating the latter. We found regions particularly sensitive to mutations ("ultrasensitive") and variants that are disruptive because of mechanistic effects on transcription-factor binding (that is, " motif-breakers"). We also found variants in regions with higher network centrality tend to be deleterious. Insertions and deletions followed a similar pattern to single-nucleotide variants, with some notable exceptions (e.g., certain deletions and enhancers). On the basis of these patterns, we developed a computational tool (FunSeq), whose application to ∼90 cancer genomes reveals nearly a hundred candidate noncoding drivers.

Original language	English (US)
Article number	1235587
Journal	Science
Volume	342
Issue number	6154
DOIs	https://doi.org/10.1126/science.1235587
State	Published - Oct 4 2013

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@article{328f94fad6f74332b14c73e9aca4a95a,

title = "Integrative annotation of variants from 1092 humans: Application to cancer genomics",

abstract = "Interpreting variants, especially noncoding ones, in the increasing number of personal genomes is challenging. We used patterns of polymorphisms in functionally annotated regions in 1092 humans to identify deleterious variants; then we experimentally validated candidates. We analyzed both coding and noncoding regions, with the former corroborating the latter. We found regions particularly sensitive to mutations ({"}ultrasensitive{"}) and variants that are disruptive because of mechanistic effects on transcription-factor binding (that is, {"} motif-breakers{"}). We also found variants in regions with higher network centrality tend to be deleterious. Insertions and deletions followed a similar pattern to single-nucleotide variants, with some notable exceptions (e.g., certain deletions and enhancers). On the basis of these patterns, we developed a computational tool (FunSeq), whose application to ∼90 cancer genomes reveals nearly a hundred candidate noncoding drivers.",

author = "{1000 Genomes Project Consortium} and E. Khurana and Y. Fu and V. Colonna and Mu, {X. J.} and Kang, {H. M.} and T. Lappalainen and A. Sboner and L. Lochovsky and J. Chen and A. Harmanci and J. Das and A. Abyzov and S. Balasubramanian and K. Beal and D. Chakravarty and D. Challis and Y. Chen and D. Clarke and L. Clarke and F. Cunningham and Evani, {U. S.} and P. Flicek and R. Fragoza and E. Garrison and Gibbs, {R. A.} and G{\"u}m{\"u}{\c s}, {Z. H.} and J. Herrero and N. Kitabayashi and Y. Kong and K. Lage and V. Liluashvili and Lipkin, {S. M.} and MacArthur, {D. G.} and G. Marth and D. Muzny and Pers, {T. H.} and GRS Ritchie and Rosenfeld, {J. A.} and C. Sisu and X. Wei and M. Wilson and Y. Xue and F. Yu and Dermitzakis, {E. T.} and H. Yu and Rubin, {M. A.} and C. Tyler-Smith and M. Gerstein and Altshuler, {D. M.} and Durbin, {R. M.}",

year = "2013",

month = oct,

day = "4",

doi = "10.1126/science.1235587",

language = "English (US)",

volume = "342",

journal = "Science",

issn = "0036-8075",

publisher = "American Association for the Advancement of Science",

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TY - JOUR

T1 - Integrative annotation of variants from 1092 humans

T2 - Application to cancer genomics

AU - 1000 Genomes Project Consortium

AU - Khurana, E.

AU - Fu, Y.

AU - Colonna, V.

AU - Mu, X. J.

AU - Kang, H. M.

AU - Lappalainen, T.

AU - Sboner, A.

AU - Lochovsky, L.

AU - Chen, J.

AU - Harmanci, A.

AU - Das, J.

AU - Abyzov, A.

AU - Balasubramanian, S.

AU - Beal, K.

AU - Chakravarty, D.

AU - Challis, D.

AU - Chen, Y.

AU - Clarke, D.

AU - Clarke, L.

AU - Cunningham, F.

AU - Evani, U. S.

AU - Flicek, P.

AU - Fragoza, R.

AU - Garrison, E.

AU - Gibbs, R. A.

AU - Gümüş, Z. H.

AU - Herrero, J.

AU - Kitabayashi, N.

AU - Kong, Y.

AU - Lage, K.

AU - Liluashvili, V.

AU - Lipkin, S. M.

AU - MacArthur, D. G.

AU - Marth, G.

AU - Muzny, D.

AU - Pers, T. H.

AU - Ritchie, GRS

AU - Rosenfeld, J. A.

AU - Sisu, C.

AU - Wei, X.

AU - Wilson, M.

AU - Xue, Y.

AU - Yu, F.

AU - Dermitzakis, E. T.

AU - Yu, H.

AU - Rubin, M. A.

AU - Tyler-Smith, C.

AU - Gerstein, M.

AU - Altshuler, D. M.

AU - Durbin, R. M.

PY - 2013/10/4

Y1 - 2013/10/4

N2 - Interpreting variants, especially noncoding ones, in the increasing number of personal genomes is challenging. We used patterns of polymorphisms in functionally annotated regions in 1092 humans to identify deleterious variants; then we experimentally validated candidates. We analyzed both coding and noncoding regions, with the former corroborating the latter. We found regions particularly sensitive to mutations ("ultrasensitive") and variants that are disruptive because of mechanistic effects on transcription-factor binding (that is, " motif-breakers"). We also found variants in regions with higher network centrality tend to be deleterious. Insertions and deletions followed a similar pattern to single-nucleotide variants, with some notable exceptions (e.g., certain deletions and enhancers). On the basis of these patterns, we developed a computational tool (FunSeq), whose application to ∼90 cancer genomes reveals nearly a hundred candidate noncoding drivers.

AB - Interpreting variants, especially noncoding ones, in the increasing number of personal genomes is challenging. We used patterns of polymorphisms in functionally annotated regions in 1092 humans to identify deleterious variants; then we experimentally validated candidates. We analyzed both coding and noncoding regions, with the former corroborating the latter. We found regions particularly sensitive to mutations ("ultrasensitive") and variants that are disruptive because of mechanistic effects on transcription-factor binding (that is, " motif-breakers"). We also found variants in regions with higher network centrality tend to be deleterious. Insertions and deletions followed a similar pattern to single-nucleotide variants, with some notable exceptions (e.g., certain deletions and enhancers). On the basis of these patterns, we developed a computational tool (FunSeq), whose application to ∼90 cancer genomes reveals nearly a hundred candidate noncoding drivers.

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DO - 10.1126/science.1235587

M3 - Article

C2 - 24092746

AN - SCOPUS:84885639776

SN - 0036-8075

VL - 342

JO - Science

JF - Science

IS - 6154

M1 - 1235587

ER -

Integrative annotation of variants from 1092 humans: Application to cancer genomics

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