A genome-wide positioning systems network algorithm for in silico drug repurposing

Feixiong Cheng; Weiqiang Lu; Chuang Liu; Jiansong Fang; Yuan Hou; Diane E. Handy; Ruisheng Wang; Yuzheng Zhao; Yi Yang; Jin Huang; David E. Hill; Marc Vidal; Charis Eng; Joseph Loscalzo

doi:10.1038/s41467-019-10744-6

A genome-wide positioning systems network algorithm for in silico drug repurposing

Feixiong Cheng
, Weiqiang Lu
, Chuang Liu
, Jiansong Fang
, Yuan Hou
, Diane E. Handy
, Ruisheng Wang
, Yuzheng Zhao
, Yi Yang
, Jin Huang
, David E. Hill
, Marc Vidal
, Charis Eng
, Joseph Loscalzo^*

^*Corresponding author for this work

School of Life Sciences

Cleveland Clinic Foundation
Case Western Reserve University
Hangzhou Normal University
Harvard University
East China University of Science and Technology
Dana-Farber Cancer Institute

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

183 Scopus citations

Abstract

Recent advances in DNA/RNA sequencing have made it possible to identify new targets rapidly and to repurpose approved drugs for treating heterogeneous diseases by the ‘precise’ targeting of individualized disease modules. In this study, we develop a Genome-wide Positioning Systems network (GPSnet) algorithm for drug repurposing by specifically targeting disease modules derived from individual patient’s DNA and RNA sequencing profiles mapped to the human protein-protein interactome network. We investigate whole-exome sequencing and transcriptome profiles from ~5,000 patients across 15 cancer types from The Cancer Genome Atlas. We show that GPSnet-predicted disease modules can predict drug responses and prioritize new indications for 140 approved drugs. Importantly, we experimentally validate that an approved cardiac arrhythmia and heart failure drug, ouabain, shows potential antitumor activities in lung adenocarcinoma by uniquely targeting a HIF1α/LEO1-mediated cell metabolism pathway. In summary, GPSnet offers a network-based, in silico drug repurposing framework for more efficacious therapeutic selections.

Original language	English
Article number	3476
Journal	Nature Communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-10744-6
State	Published - 1 Dec 2019

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10.1038/s41467-019-10744-6

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title = "A genome-wide positioning systems network algorithm for in silico drug repurposing",

abstract = "Recent advances in DNA/RNA sequencing have made it possible to identify new targets rapidly and to repurpose approved drugs for treating heterogeneous diseases by the {\textquoteleft}precise{\textquoteright} targeting of individualized disease modules. In this study, we develop a Genome-wide Positioning Systems network (GPSnet) algorithm for drug repurposing by specifically targeting disease modules derived from individual patient{\textquoteright}s DNA and RNA sequencing profiles mapped to the human protein-protein interactome network. We investigate whole-exome sequencing and transcriptome profiles from \textasciitilde{}5,000 patients across 15 cancer types from The Cancer Genome Atlas. We show that GPSnet-predicted disease modules can predict drug responses and prioritize new indications for 140 approved drugs. Importantly, we experimentally validate that an approved cardiac arrhythmia and heart failure drug, ouabain, shows potential antitumor activities in lung adenocarcinoma by uniquely targeting a HIF1α/LEO1-mediated cell metabolism pathway. In summary, GPSnet offers a network-based, in silico drug repurposing framework for more efficacious therapeutic selections.",

author = "Feixiong Cheng and Weiqiang Lu and Chuang Liu and Jiansong Fang and Yuan Hou and Handy, \{Diane E.\} and Ruisheng Wang and Yuzheng Zhao and Yi Yang and Jin Huang and Hill, \{David E.\} and Marc Vidal and Charis Eng and Joseph Loscalzo",

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doi = "10.1038/s41467-019-10744-6",

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AU - Cheng, Feixiong

AU - Lu, Weiqiang

AU - Liu, Chuang

AU - Fang, Jiansong

AU - Hou, Yuan

AU - Handy, Diane E.

AU - Wang, Ruisheng

AU - Zhao, Yuzheng

AU - Yang, Yi

AU - Huang, Jin

AU - Hill, David E.

AU - Vidal, Marc

AU - Eng, Charis

AU - Loscalzo, Joseph

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Recent advances in DNA/RNA sequencing have made it possible to identify new targets rapidly and to repurpose approved drugs for treating heterogeneous diseases by the ‘precise’ targeting of individualized disease modules. In this study, we develop a Genome-wide Positioning Systems network (GPSnet) algorithm for drug repurposing by specifically targeting disease modules derived from individual patient’s DNA and RNA sequencing profiles mapped to the human protein-protein interactome network. We investigate whole-exome sequencing and transcriptome profiles from ~5,000 patients across 15 cancer types from The Cancer Genome Atlas. We show that GPSnet-predicted disease modules can predict drug responses and prioritize new indications for 140 approved drugs. Importantly, we experimentally validate that an approved cardiac arrhythmia and heart failure drug, ouabain, shows potential antitumor activities in lung adenocarcinoma by uniquely targeting a HIF1α/LEO1-mediated cell metabolism pathway. In summary, GPSnet offers a network-based, in silico drug repurposing framework for more efficacious therapeutic selections.

AB - Recent advances in DNA/RNA sequencing have made it possible to identify new targets rapidly and to repurpose approved drugs for treating heterogeneous diseases by the ‘precise’ targeting of individualized disease modules. In this study, we develop a Genome-wide Positioning Systems network (GPSnet) algorithm for drug repurposing by specifically targeting disease modules derived from individual patient’s DNA and RNA sequencing profiles mapped to the human protein-protein interactome network. We investigate whole-exome sequencing and transcriptome profiles from ~5,000 patients across 15 cancer types from The Cancer Genome Atlas. We show that GPSnet-predicted disease modules can predict drug responses and prioritize new indications for 140 approved drugs. Importantly, we experimentally validate that an approved cardiac arrhythmia and heart failure drug, ouabain, shows potential antitumor activities in lung adenocarcinoma by uniquely targeting a HIF1α/LEO1-mediated cell metabolism pathway. In summary, GPSnet offers a network-based, in silico drug repurposing framework for more efficacious therapeutic selections.

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A genome-wide positioning systems network algorithm for in silico drug repurposing

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