Dominant-Negative Histone H3 Lysine 27 Mutant Derepresses Silenced Tumor Suppressor Genes and Reverses the Drug-Resistant Phenotype in Cancer Cells

Phillip H Abbosh,Jason A Starkey,Curtis Balch,John S Montgomery,Eleanor G Zuhowski,Kate M Brannon,Milos Novotny,Annie P Moseman,Tim H.M Huang,Adam Golas,Merrill J Egorin,Kenneth P Nephew

doi:10.1158/0008-5472.can-05-3575

Abstract

Histone modifications and DNA methylation are epigenetic phenomena that play a critical role in many neoplastic processes, including silencing of tumor suppressor genes. One such histone modification, particularly at H3 and H4, is methylation at specific lysine (K) residues. Whereas histone methylation of H3-K9 has been linked to DNA methylation and aberrant gene silencing in cancer cells, no such studies of H3-K27 have been reported. Here, we generated a stable cell line overexpressing a dominant-negative point mutant, H3-K27R, to examine the role of that specific lysine in ovarian cancer. Expression of this construct resulted in loss of methylation at H3-K27, global reduction of DNA methylation, and increased expression of tumor suppressor genes. One of the affected genes, RASSF1, was shown to be a direct target of H3-K27 methylation-mediated silencing. By increasing DNA-platinum adduct formation, indicating increased access of the drug to target DNA sequences, removal of H3-K27 methylation resensitized drug-resistant ovarian cancer cells to the chemotherapeutic agent cisplatin. This increased platinum-DNA access was likely due to relaxation of condensed chromatin. Our results show that overexpression of mutant H3-K27 in mammalian cells represents a novel tool for studying epigenetic mechanisms and the Histone Code Hypothesis in human cancer. Such findings show the significance of H3-K27 methylation as a promising target for epigenetic-based cancer therapies.

Highlights

Chromatin structure affects numerous diverse aspects of cell biology, ranging from genomic integrity and telomere maintenance to gene activation and silencing
CP70 cells stably expressing H3-K27R protein were generated using the plasmid pIRESII-H3-K27R-enhanced green fluorescent protein (EGFP), encoding a bicistronic mRNA bisected by an internal ribosomal entry site
Because methylation of H3-K27 is widely associated with Polycomb group (PcG)-mediated gene silencing [2, 3, 6, 7], we examined expression of tumor suppressor genes frequently silenced in ovarian cancer [23,24,25], genes associated with cisplatin resistance [26], and genes identified as targets of PcG silencing [6]

Summary

Introduction

Chromatin structure affects numerous diverse aspects of cell biology, ranging from genomic integrity and telomere maintenance to gene activation and silencing. PcG complexes containing the histone methyltransferase E(z) (in Drosophila) or EZH2 (in humans) silence chromatin via methylation of H3-K27 [2, 5,6,7]. In normal fibroblasts, forced overexpression of EZH2 can induce transformation and increase invasiveness whereas EZH2 knockdown in cancer cells results in decreased proliferation [8, 9]. Another PcG gene, SU(Z), has been shown to be up-regulated in a number of human tumors and exists in a repressive complexes with EZH2 [10], further implicating PcG proteins and H3-K27 methylation in the development of tumor phenotypes

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Conclusion