Synthetic Essentiality of Chromatin Remodelling Factor CHD1 in PTEN-deficient Cancer

Overview

Journal Nature

Specialty Science

Date 2017 Feb 7

PMID 28166537

Citations 116

Authors

Di Zhao

Xin Lu

Guocan Wang

Zhengdao Lan

Wenting Liao

Jun Li

Xin Liang

Jasper Robin Chen

Sagar Shah

Xiaoying Shang

Ming Tang

Pingna Deng

Prasenjit Dey

Deepavali Chakravarti

Peiwen Chen

Denise J Spring

Nora M Navone

Patricia Troncoso

Jianhua Zhang

Y Alan Wang

Ronald A DePinho

Affiliations

Soon will be listed here.

Abstract

Synthetic lethality and collateral lethality are two well-validated conceptual strategies for identifying therapeutic targets in cancers with tumour-suppressor gene deletions. Here, we explore an approach to identify potential synthetic-lethal interactions by screening mutually exclusive deletion patterns in cancer genomes. We sought to identify 'synthetic-essential' genes: those that are occasionally deleted in some cancers but are almost always retained in the context of a specific tumour-suppressor deficiency. We also posited that such synthetic-essential genes would be therapeutic targets in cancers that harbour specific tumour-suppressor deficiencies. In addition to known synthetic-lethal interactions, this approach uncovered the chromatin helicase DNA-binding factor CHD1 as a putative synthetic-essential gene in PTEN-deficient cancers. In PTEN-deficient prostate and breast cancers, CHD1 depletion profoundly and specifically suppressed cell proliferation, cell survival and tumorigenic potential. Mechanistically, functional PTEN stimulates the GSK3β-mediated phosphorylation of CHD1 degron domains, which promotes CHD1 degradation via the β-TrCP-mediated ubiquitination-proteasome pathway. Conversely, PTEN deficiency results in stabilization of CHD1, which in turn engages the trimethyl lysine-4 histone H3 modification to activate transcription of the pro-tumorigenic TNF-NF-κB gene network. This study identifies a novel PTEN pathway in cancer and provides a framework for the discovery of 'trackable' targets in cancers that harbour specific tumour-suppressor deficiencies.

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