Protein-structure-guided discovery of functional mutations across 19 cancer types

Beifang Niu; Adam D. Scott; Sohini Sengupta; Matthew H. Bailey; Prag Batra; Jie Ning; Matthew A. Wyczalkowski; Wen Wei Liang; Qunyuan Zhang; Michael D. McLellan; Sam Q. Sun; Piyush Tripathi; Carolyn Lou; Kai Ye; R. Jay Mashl; John Wallis; Michael C. Wendl; Feng Chen; Li Ding

doi:10.1038/ng.3586

Protein-structure-guided discovery of functional mutations across 19 cancer types

Beifang Niu
, Adam D. Scott
, Sohini Sengupta
, Matthew H. Bailey
, Prag Batra
, Jie Ning
, Matthew A. Wyczalkowski
, Wen Wei Liang
, Qunyuan Zhang
, Michael D. McLellan
, Sam Q. Sun
, Piyush Tripathi
, Carolyn Lou
, Kai Ye
, R. Jay Mashl
, John Wallis
, Michael C. Wendl
, Feng Chen
, Li Ding

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

112 Scopus citations

Abstract

Local concentrations of mutations are well known in human cancers. However, their three-dimensional spatial relationships in the encoded protein have yet to be systematically explored. We developed a computational tool, HotSpot3D, to identify such spatial hotspots (clusters) and to interpret the potential function of variants within them. We applied HotSpot3D to >4,400 TCGA tumors across 19 cancer types, discovering >6,000 intra- and intermolecular clusters, some of which showed tumor and/or tissue specificity. In addition, we identified 369 rare mutations in genes including TP53, PTEN, VHL, EGFR, and FBXW7 and 99 medium-recurrence mutations in genes such as RUNX1, MTOR, CA3, PI3, and PTPN11, all mapping within clusters having potential functional implications. As a proof of concept, we validated our predictions in EGFR using high-throughput phosphorylation data and cell-line-based experimental evaluation. Finally, mutation-drug cluster and network analysis predicted over 800 promising candidates for druggable mutations, raising new possibilities for designing personalized treatments for patients carrying specific mutations.

Original language	English
Pages (from-to)	827-837
Number of pages	11
Journal	Nature Genetics
Volume	48
Issue number	8
DOIs	https://doi.org/10.1038/ng.3586
State	Published - 1 Aug 2016
Externally published	Yes

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Niu, B., Scott, A. D., Sengupta, S., Bailey, M. H., Batra, P., Ning, J., Wyczalkowski, M. A., Liang, W. W., Zhang, Q., McLellan, M. D., Sun, S. Q., Tripathi, P., Lou, C., Ye, K., Jay Mashl, R., Wallis, J., Wendl, M. C., Chen, F., & Ding, L. (2016). Protein-structure-guided discovery of functional mutations across 19 cancer types. Nature Genetics, 48(8), 827-837. https://doi.org/10.1038/ng.3586

@article{540e826ebc2d44a19f5b0996d2b9d86b,

title = "Protein-structure-guided discovery of functional mutations across 19 cancer types",

abstract = "Local concentrations of mutations are well known in human cancers. However, their three-dimensional spatial relationships in the encoded protein have yet to be systematically explored. We developed a computational tool, HotSpot3D, to identify such spatial hotspots (clusters) and to interpret the potential function of variants within them. We applied HotSpot3D to >4,400 TCGA tumors across 19 cancer types, discovering >6,000 intra- and intermolecular clusters, some of which showed tumor and/or tissue specificity. In addition, we identified 369 rare mutations in genes including TP53, PTEN, VHL, EGFR, and FBXW7 and 99 medium-recurrence mutations in genes such as RUNX1, MTOR, CA3, PI3, and PTPN11, all mapping within clusters having potential functional implications. As a proof of concept, we validated our predictions in EGFR using high-throughput phosphorylation data and cell-line-based experimental evaluation. Finally, mutation-drug cluster and network analysis predicted over 800 promising candidates for druggable mutations, raising new possibilities for designing personalized treatments for patients carrying specific mutations.",

author = "Beifang Niu and Scott, \{Adam D.\} and Sohini Sengupta and Bailey, \{Matthew H.\} and Prag Batra and Jie Ning and Wyczalkowski, \{Matthew A.\} and Liang, \{Wen Wei\} and Qunyuan Zhang and McLellan, \{Michael D.\} and Sun, \{Sam Q.\} and Piyush Tripathi and Carolyn Lou and Kai Ye and \{Jay Mashl\}, R. and John Wallis and Wendl, \{Michael C.\} and Feng Chen and Li Ding",

year = "2016",

month = aug,

day = "1",

doi = "10.1038/ng.3586",

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Niu, B, Scott, AD, Sengupta, S, Bailey, MH, Batra, P, Ning, J, Wyczalkowski, MA, Liang, WW, Zhang, Q, McLellan, MD, Sun, SQ, Tripathi, P, Lou, C, Ye, K, Jay Mashl, R, Wallis, J, Wendl, MC, Chen, F & Ding, L 2016, 'Protein-structure-guided discovery of functional mutations across 19 cancer types', Nature Genetics, vol. 48, no. 8, pp. 827-837. https://doi.org/10.1038/ng.3586

TY - JOUR

T1 - Protein-structure-guided discovery of functional mutations across 19 cancer types

AU - Niu, Beifang

AU - Scott, Adam D.

AU - Sengupta, Sohini

AU - Bailey, Matthew H.

AU - Batra, Prag

AU - Ning, Jie

AU - Wyczalkowski, Matthew A.

AU - Liang, Wen Wei

AU - Zhang, Qunyuan

AU - McLellan, Michael D.

AU - Sun, Sam Q.

AU - Tripathi, Piyush

AU - Lou, Carolyn

AU - Ye, Kai

AU - Jay Mashl, R.

AU - Wallis, John

AU - Wendl, Michael C.

AU - Chen, Feng

AU - Ding, Li

PY - 2016/8/1

Y1 - 2016/8/1

N2 - Local concentrations of mutations are well known in human cancers. However, their three-dimensional spatial relationships in the encoded protein have yet to be systematically explored. We developed a computational tool, HotSpot3D, to identify such spatial hotspots (clusters) and to interpret the potential function of variants within them. We applied HotSpot3D to >4,400 TCGA tumors across 19 cancer types, discovering >6,000 intra- and intermolecular clusters, some of which showed tumor and/or tissue specificity. In addition, we identified 369 rare mutations in genes including TP53, PTEN, VHL, EGFR, and FBXW7 and 99 medium-recurrence mutations in genes such as RUNX1, MTOR, CA3, PI3, and PTPN11, all mapping within clusters having potential functional implications. As a proof of concept, we validated our predictions in EGFR using high-throughput phosphorylation data and cell-line-based experimental evaluation. Finally, mutation-drug cluster and network analysis predicted over 800 promising candidates for druggable mutations, raising new possibilities for designing personalized treatments for patients carrying specific mutations.

AB - Local concentrations of mutations are well known in human cancers. However, their three-dimensional spatial relationships in the encoded protein have yet to be systematically explored. We developed a computational tool, HotSpot3D, to identify such spatial hotspots (clusters) and to interpret the potential function of variants within them. We applied HotSpot3D to >4,400 TCGA tumors across 19 cancer types, discovering >6,000 intra- and intermolecular clusters, some of which showed tumor and/or tissue specificity. In addition, we identified 369 rare mutations in genes including TP53, PTEN, VHL, EGFR, and FBXW7 and 99 medium-recurrence mutations in genes such as RUNX1, MTOR, CA3, PI3, and PTPN11, all mapping within clusters having potential functional implications. As a proof of concept, we validated our predictions in EGFR using high-throughput phosphorylation data and cell-line-based experimental evaluation. Finally, mutation-drug cluster and network analysis predicted over 800 promising candidates for druggable mutations, raising new possibilities for designing personalized treatments for patients carrying specific mutations.

UR - https://www.scopus.com/pages/publications/84980028158

U2 - 10.1038/ng.3586

DO - 10.1038/ng.3586

M3 - 文章

C2 - 27294619

AN - SCOPUS:84980028158

SN - 1061-4036

VL - 48

SP - 827

EP - 837

JO - Nature Genetics

JF - Nature Genetics

IS - 8

ER -

Protein-structure-guided discovery of functional mutations across 19 cancer types

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