An integrative ENCODE resource for cancer genomics

Jing Zhang; Donghoon Lee; Vineet K. Dhiman; Peng Jiang; Jie Xu; Patrick D. McGillivray; Hongbo Yang; Jason Liu; Matthew Meyerson; Declan Clarke; Mengting Gu; Shantao Li; Shaoke Lou; Jinrui Xu; Lucas Lochovsky; Matthew Ung; Lijia Ma; Shan Yu; Qin Cao; Arif Harmanci; Koon-Kiu Yan; Anurag Sethi; Gamze Gürsoy; Michael Rutenberg Schoenberg; Joel Rozowsky; Jonathan Warrell; Prashant S. Emani; Yucheng Yang; Timur R. Galeev; Xiangmeng Kong; Shuang Liu; Xiaotong Li; Jayanth Krishnan; Yanlin Feng; Juan Carlos Rivera‐Mulia; Jessika Adrian; James R. Broach; Michael J. Bolt; Jennifer Moran; Dominic Fitzgerald; Vishnu Dileep; Tingting Liu; Shenglin Mei; Takayo Sasaki; Claudia Trevilla‐García; Su Wang; Yanli Wang; Chongzhi Zang; Daifeng Wang; Robert J. Klein; M Snyder; David M. Gilbert; Kevin Y. Yip; Chao Cheng; Feng Yue; X. Shirley Liu; Kevin P. White; Mark Gerstein

doi:10.1038/s41467-020-14743-w

An integrative ENCODE resource for cancer genomics

Jing Zhang(Yale University), Donghoon Lee(Yale University), Vineet K. Dhiman(University of Chicago), Peng Jiang(Dana-Farber Cancer Institute), Jie Xu(Northwestern University), Patrick D. McGillivray(Yale University), Hongbo Yang(Northwestern University), Jason Liu(Yale University), Matthew Meyerson(Yale University), Declan Clarke(Yale University), Mengting Gu(Yale University), Shantao Li(Yale University), Shaoke Lou(Yale University), Jinrui Xu(Northwestern University), Lucas Lochovsky(Yale University), Matthew Ung(Dartmouth College), Lijia Ma(Westlake University), Shan Yu(University of Chicago), Qin Cao(Chinese University of Hong Kong), Arif Harmanci(The University of Texas Health Science Center at Houston), Koon-Kiu Yan(Yale University), Anurag Sethi(Yale University), Gamze Gürsoy(Yale University), Michael Rutenberg Schoenberg(Yale University), Joel Rozowsky(Yale University), Jonathan Warrell(Yale University), Prashant S. Emani(Yale University), Yucheng Yang(Yale University), Timur R. Galeev(Yale University), Xiangmeng Kong(Yale University), Shuang Liu(Yale University), Xiaotong Li(Yale University), Jayanth Krishnan(Yale University), Yanlin Feng(Yale University), Juan Carlos Rivera‐Mulia(Florida State University), Jessika Adrian(Stanford University), James R. Broach(Pennsylvania State University), Michael J. Bolt(University of Chicago), Jennifer Moran(University of Chicago), Dominic Fitzgerald(University of Chicago), Vishnu Dileep(Florida State University), Tingting Liu(Northwestern University), Shenglin Mei(Harvard University), Takayo Sasaki(Florida State University), Claudia Trevilla‐García(Florida State University), Su Wang(Harvard University), Yanli Wang(Pennsylvania State University), Chongzhi Zang(Office of Public Health Genomics), Daifeng Wang(University of Wisconsin–Madison), Robert J. Klein(Icahn School of Medicine at Mount Sinai), M Snyder(Stanford University), David M. Gilbert(Florida State University), Kevin Y. Yip(Chinese University of Hong Kong), Chao Cheng(Dartmouth College), Feng Yue(Northwestern University), X. Shirley Liu(Dana-Farber Cancer Institute), Kevin P. White(University of Illinois Chicago), Mark Gerstein(Yale University)

Nature Communications

July 29, 2020

10.1038/s41467-020-14743-w

Cited by 183Open Access

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Abstract

ENCODE comprises thousands of functional genomics datasets, and the encyclopedia covers hundreds of cell types, providing a universal annotation for genome interpretation. However, for particular applications, it may be advantageous to use a customized annotation. Here, we develop such a custom annotation by leveraging advanced assays, such as eCLIP, Hi-C, and whole-genome STARR-seq on a number of data-rich ENCODE cell types. A key aspect of this annotation is comprehensive and experimentally derived networks of both transcription factors and RNA-binding proteins (TFs and RBPs). Cancer, a disease of system-wide dysregulation, is an ideal application for such a network-based annotation. Specifically, for cancer-associated cell types, we put regulators into hierarchies and measure their network change (rewiring) during oncogenesis. We also extensively survey TF-RBP crosstalk, highlighting how SUB1, a previously uncharacterized RBP, drives aberrant tumor expression and amplifies the effect of MYC, a well-known oncogenic TF. Furthermore, we show how our annotation allows us to place oncogenic transformations in the context of a broad cell space; here, many normal-to-tumor transitions move towards a stem-like state, while oncogene knockdowns show an opposing trend. Finally, we organize the resource into a coherent workflow to prioritize key elements and variants, in addition to regulators. We showcase the application of this prioritization to somatic burdening, cancer differential expression and GWAS. Targeted validations of the prioritized regulators, elements and variants using siRNA knockdowns, CRISPR-based editing, and luciferase assays demonstrate the value of the ENCODE resource.

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