GATA4 loss of function in liver cancer impedes precursor to hepatocyte transition
Francis O. Enane, … , Han Chong Toh, Yogen Saunthararajah
Francis O. Enane, … , Han Chong Toh, Yogen Saunthararajah
Published July 31, 2017
Citation Information: J Clin Invest. 2017;127(9):3527-3542. https://doi.org/10.1172/JCI93488.
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Research Article Genetics Oncology

GATA4 loss of function in liver cancer impedes precursor to hepatocyte transition

Abstract

The most frequent chromosomal structural loss in hepatocellular carcinoma (HCC) is of the short arm of chromosome 8 (8p). Genes on the remaining homologous chromosome, however, are not recurrently mutated, and the identity of key 8p tumor-suppressor genes (TSG) is unknown. In this work, analysis of minimal commonly deleted 8p segments to identify candidate TSG implicated GATA4, a master transcription factor driver of hepatocyte epithelial lineage fate. In a murine model, liver-conditional deletion of 1 Gata4 allele to model the haploinsufficiency seen in HCC produced enlarged livers with a gene expression profile of persistent precursor proliferation and failed hepatocyte epithelial differentiation. HCC mimicked this gene expression profile, even in cases that were morphologically classified as well differentiated. HCC with intact chromosome 8p also featured GATA4 loss of function via GATA4 germline mutations that abrogated GATA4 interactions with a coactivator, MED12, or by inactivating mutations directly in GATA4 coactivators, including ARID1A. GATA4 reintroduction into GATA4-haploinsufficient HCC cells or ARID1A reintroduction into ARID1A-mutant/GATA4-intact HCC cells activated hundreds of hepatocyte genes and quenched the proliferative precursor program. Thus, disruption of GATA4-mediated transactivation in HCC suppresses hepatocyte epithelial differentiation to sustain replicative precursor phenotype.

Authors

Francis O. Enane, Wai Ho Shuen, Xiaorong Gu, Ebrahem Quteba, Bartlomiej Przychodzen, Hideki Makishima, Juraj Bodo, Joanna Ng, Chit Lai Chee, Rebecca Ba, Lip Seng Koh, Janice Lim, Rachael Cheong, Marissa Teo, Zhenbo Hu, Kwok Peng Ng, Jaroslaw Maciejewski, Tomas Radivoyevitch, Alexander Chung, London Lucien Ooi, Yu Meng Tan, Peng-Chung Cheow, Pierce Chow, Chung Yip Chan, Kiat Hon Lim, Lisa Yerian, Eric Hsi, Han Chong Toh, Yogen Saunthararajah

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Figure 8

Recurrent inactivation of GATA4 coactivators in HCC.

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Recurrent inactivation of GATA4 coactivators in HCC. (A) Coactivators hi...
(A) Coactivators highly represented in the GATA4 protein interactome. Circle size indicates protein abundance in the GATA4 coimmunoprecipitate. (B) Coactivators frequently deleted and mutated (inactivating mutations) in primary HCC (n = 51). Similar results in the TCGA series are shown in Supplemental Figure 12. ARID1A reintroduction into ARID1A-mutated, GATA4 WT HCC cells (HepG2) induced terminal epithelial differentiation. Transfection with V5-tagged ARID1A expression vector versus empty vector control. (C) Cell counts were determined using an automated counter. (D) Changes in MYC and p27/CDKN1B protein levels were consistent with terminal differentiation. Western blot. (E) ARID1A reintroduction increased HNF4A and CEBPD expression. QRT-PCR (relative to nontransfected cells). ***P < 0.001, Wilcoxon rank sum test, 2-tailed. (F) Increased cytoplasmic to nuclear ratio of ARID1A transfected cells consistent with epithelial differentiation. Giemsa stain 96 hours after transfection. (G) Increased cell size (forward scatter) and granularity (side scatter) by flow cytometry consistent with epithelial differentiation 96 hours after transfection.