The Y641C mutation of EZH2 alters substrate specificity for histone H3 lysine 27 methylation states

Mutations at tyrosine 641 (Y641F, Y641N, Y641S and Y641H) in the SET domain of EZH2 have been identified in patients with certain subtypes of non-Hodgkin lymphoma (NHL). These mutations were shown to change the substrate specificity of EZH2 for various methylation states of lysine 27 on histone H3 (H3K27). An additional mutation at EZH2 Y641 to cysteine (Y641C) was also found in one patient with NHL and in SKM-1 cells derived from a patient with myelodisplastic syndrome (MDS). The Y641C mutation has been reported to dramatically reduce enzymatic activity. Here, we demonstrate that while the Y641C mutation ablates enzymatic activity against unmethylated and monomethylated H3K27, it is superior to wild-type in catalyzing the formation of trimethylated H3K27 from the dimethylated precursor.     

EZH2: an emerging role in melanoma biology and strategies for targeted therapy

Histone modifications are increasingly being recognized as important epigenetic mechanisms that govern chromatin structure and gene expression. EZH2 is the catalytic subunit of the polycomb repressive complex 2 (PRC2), responsible for tri‐methylation of lysine 27 on histone 3 (H3K27me3) that leads to gene silencing. This highly conserved histone methyltransferase is found to be overexpressed in many different types of cancers including melanoma, where it is postulated to abnormally repress tumor suppressor genes. Somatic mutations have been identified in approximately 3% of melanomas, and activating mutations described within the catalytic SET domain of EZH2 confer its oncogenic activity. In the following review, we discuss the evidence that EZH2 is an important driver of melanoma progression and we summarize the progress of EZH2 inhibitors against this promising therapeutic target.     

Structure of the Catalytic Domain of EZH2 Reveals Conformational Plasticity in Cofactor and Substrate Binding Sites and Explains Oncogenic Mutations

Polycomb repressive complex 2 (PRC2) is an important regulator of cellular differentiation and cell type identity. Overexpression or activating mutations of EZH2, the catalytic component of the PRC2 complex, are linked to hyper-trimethylation of lysine 27 of histone H3 (H3K27me3) in many cancers. Potent EZH2 inhibitors that reduce levels of H3K27me3 kill mutant lymphoma cells and are efficacious in a mouse xenograft model of malignant rhabdoid tumors. Unlike most SET domain methyltransferases, EZH2 requires PRC2 components, SUZ12 and EED, for activity, but the mechanism by which catalysis is promoted in the PRC2 complex is unknown. We solved the 2.0 Å crystal structure of the EZH2 methyltransferase domain revealing that most of the canonical structural features of SET domain methyltransferase structures are conserved. The site of methyl transfer is in a catalytically competent state, and the structure clarifies the structural mechanism underlying oncogenic hyper-trimethylation of H3K27 in tumors harboring mutations at Y641 or A677. On the other hand, the I-SET and post-SET domains occupy atypical positions relative to the core SET domain resulting in incomplete formation of the cofactor binding site and occlusion of the substrate binding groove. A novel CXC domain N-terminal to the SET domain may contribute to the apparent inactive conformation. We propose that protein interactions within the PRC2 complex modulate the trajectory of the post-SET and I-SET domains of EZH2 in favor of a catalytically competent conformation.     

组蛋白变体H3.3 L27M突变与胶质瘤发生

组蛋白变体在基因表达等基本细胞过程中发挥重要调节功能。人类有5种H3变体,分别为H3.1、 H3.2、H3.3、着丝粒特异性CENP-A和睾丸特异性H3t。人H3.3有H3F3A和H3F3B两个基因编码。采用DNA全基因组测序的方法在儿童高级别胶质瘤如恶性胶质瘤（GBM）和弥漫性内在脑桥胶质瘤（DIPG）鉴定出高频的H3F3A突变。超过70%DIPG和30%GBM携带H3.3 K27M氨基酸错义突变（27位赖氨酸被甲硫氨酸代替）。H3.3 K27M通过与组蛋白H3K27甲基转移酶EZH2亚基相互作用而抑制多梳抑制复合物2（PRC2）活性并全面减少H3K27me3含量。因此H3.3 K27M突变重塑了表观修饰状态和基因表达模式,从而驱动肿瘤发生。K27M突变可作为分子标志物以更好区分儿童胶质瘤亚型,还可作为特异、敏感的预后标志物。通过抑制组蛋白去甲基化酶如JMJD3活性而增加H3K27甲基化可作为K27M突变胶质瘤治疗的有效策略。本文综述了组蛋白变体H3.3 K27M在胶质瘤中的突变模式、分子机制和临床应用。     

The polycomb group protein EZH2 inhibits lung cancer cell growth by repressing the transcription factor Nrf2

EZH2 is a key component of the polycomb PRC2 complex and functions as a histone H3 Lys27 (H3K27) trimethyltransferase. Here we show that EZH2 is down-regulated in human non-small cell lung cancer and low EZH2 expression predicts poor survival. Further we demonstrate that EZH2 inhibits lung cancer cell proliferation and colony formation in vitro and growth in vivo. We found that EZH2 binds to the promoter of Nrf2, where it increases H3K27me3 and represses Nrf2 expression. Finally, Nrf2 seems to be essential for the hyper proliferation of lung cancer cells in the absence of EZH2.     

A lesson learned from the H3.3K27M mutation found in pediatric glioma

Glioblastoma (GBM) is the most aggressive primary brain tumor in human. Recent studies on high-grade pediatric GBM have identified two recurrent mutations (K27M and G34R/V) in genes encoding histone H3 (H3F3A for H3.3 and HIST1H3B for H3.1).^1,2 The two histone H3 mutations are mutually exclusive and give rise to tumors in different brain compartments.³ Recently, we⁴ and others⁵ have shown that the histone H3 K27M mutation specifically altered the di- and tri-methylation of endogenous histone H3 at Lys27. Genome-wide studies using ChIP-seq on H3.3K27M patient samples indicate a global reduction of H3K27me3 on chromatin. Remarkably, we also found a dramatic enrichment of H3K27me3 and EZH2 (the catalytic subunit H3K27 methyltransferase) at hundreds of gene loci in H3.3K27M patient cells. Here, we discuss potential mechanisms whereby H3K27me3 is enriched at chromatin loci in cells expressing the H3.3K27M mutation and report effects of Lys-to-Met mutations of other well-studied lysine residues of histone H3.1/H3.3 and H4 on the corresponding endogenous lysine methylation. We suggest that mutation(s) on histones may be found in a variety of human diseases, and the expression of mutant histones may help to address the function of histone lysine methylation and possibly other modifications in mammalian cells.     

Aberrant overexpression of EZH2 and H3K27me3 serves as poor prognostic biomarker for esophageal squamous cell carcinoma patients

It has been reported that the trimethylation of histone 3 on lysine 27 (H3K27me3) is required for enhancer of zeste homology 2 (EZH2)-mediated repression of various genes essential for tumorigenesis and tumor development. Here, we reported the expression of EZH2 and H3K27me3 in esophageal squamous cell carcinoma (ESCC) specimens was higher than the pericarcinoma esophageal specimens. Their expression was positively associated with the poor prognosis of ESCC patients. EZH2 expression, histological grade and distant lymph node metastasis were all independent factors for poor prognosis of ESCC. In addition, enforced expression of EZH2 in esophageal cancer-derived cells could increase the overall H3K27me3 level. Our results suggested the expression of EZH2 and H3K27me3 could serve as biomarkers in the prediction of ESCC patients’ survival and ESCC metastasis.     

Structural Context of Disease-Associated Mutations and Putative Mechanism of Autoinhibition Revealed by X-Ray Crystallographic Analysis of the EZH2-SET Domain

The enhancer-of-zeste homolog 2 (EZH2) gene product is an 87 kDa polycomb group (PcG) protein containing a C-terminal methyltransferase SET domain. EZH2, along with binding partners, i.e., EED and SUZ12, upon which it is dependent for activity forms the core of the polycomb repressive complex 2 (PRC2). PRC2 regulates gene silencing by catalyzing the methylation of histone H3 at lysine 27. Both overexpression and mutation of EZH2 are associated with the incidence and aggressiveness of various cancers. The novel crystal structure of the SET domain was determined in order to understand disease-associated EZH2 mutations and derive an explanation for its inactivity independent of complex formation. The 2.00 Å crystal structure reveals that, in its uncomplexed form, the EZH2 C-terminus folds back into the active site blocking engagement with substrate. Furthermore, the S-adenosyl-L-methionine (SAM) binding pocket observed in the crystal structure of homologous SET domains is notably absent. This suggests that a conformational change in the EZH2 SET domain, dependent upon complex formation, must take place for cofactor and substrate binding activities to be recapitulated. In addition, the data provide a structural context for clinically significant mutations found in the EZH2 SET domain.     

MER-ERK信号通路调控H3K27me3甲基化酶和去甲基化酶基因表达的研究

在人的某些癌症细胞中,组蛋白H3K27me3甲基化酶EZH2基因存在过表达的现象,很多研究已经证明,这可能是受MEK ERK信号通路调控的.为了确定这种调控模式在小鼠细胞系中是否同样存在,以及MEK ERK信号通路是否同时调控H3K27me3甲基化酶EZH1基因和去甲基化酶UTX、JMJD3基因的表达,用RT PCR和Western印迹方法检测不同浓度的MEK ERK抑制剂U0126（0、10、20、40 μmol/L）对C2C12、C127、NIH3T3三种小鼠细胞系处理后,EZH1、EZH2基因和UTX、JMJD3基因表达变化.结果显示：MEK-ERK抑制剂处理后,3种细胞中EZH1和EZH2基因的表达与对照相比都有不同程度的降低,其中EZH2基因表达变化在C2C12、NIH3T3两种细胞达到显著水平(P<0.05). H3K27me3去甲基化酶UTX、JMJD3基因在3种细胞中表达均有升高,JMJD3升高达到显著水平（P<0.05).因此,在小鼠细胞系MEK ERK信号通路可能参与调控EZH2、JMJD3基因的表达,但对EZH1、UTX基因的表达调控作用不明显.
关键词MEK ERK信号通路;     

A Non-Active-Site SET Domain Surface Crucial for the Interaction of MLL1 and the RbBP5/Ash2L Heterodimer within MLL Family Core Complexes

The mixed lineage leukemia-1 (MLL1) enzyme is a histone H3 lysine 4 (H3K4) monomethyltransferase and has served as a paradigm for understanding the mechanism of action of the human SET1 family of enzymes that include MLL1–MLL4 and SETd1a,b. Dimethylation of H3K4 requires a sub-complex including WRAD (WDR5, RbBP5, Ash2L, and DPY-30), which binds to each SET1 family member forming a minimal core complex that is required for multiple lysine methylation. We recently demonstrated that WRAD is a novel histone methyltransferase that preferentially catalyzes H3K4 dimethylation in a manner that is dependent on an unknown non-active-site surface from the MLL1 SET domain. Recent genome sequencing studies have identified a number of human disease-associated missense mutations that localize to the SET domains of several MLL family members. In this investigation, we mapped many of these mutations onto the three-dimensional structure of the SET domain and noticed that a subset of MLL2 (KMT2D, ALR, MLL4)-associated Kabuki syndrome missense mutations map to a common solvent-exposed surface that is not expected to alter enzymatic activity. We introduced these mutations into the MLL1 SET domain and observed that all are defective for H3K4 dimethylation by the MLL1 core complex, which is associated with a loss of the ability of MLL1 to interact with WRAD or with the RbBP5/Ash2L heterodimer. Our results suggest that amino acids from this surface, which we term the Kabuki interaction surface or KIS, are required for formation of a second active site within SET1 family core complexes.     

Combined tazemetostat and MAPKi enhances differentiation of papillary thyroid cancer cells harbouring BRAFV600E by synergistically decreasing global trimethylation of H3K27

Clinical efficacy of differentiation therapy with mitogen-activated protein kinase inhibitors (MAPKi) for lethal radioiodine-refractory papillary thyroid cancer (RR-PTC) urgently needs to be improved and the aberrant trimethylation of histone H3 lysine 27 (H3K27) plays a vital role in BRAF^V600E-MAPK-induced cancer dedifferentiation and drug resistance. Therefore, dual inhibition of MAPK and histone methyltransferase (EZH2) may produce more favourable treatment effects. In this study, BRAF^V600E-mutant (BCPAP and K1) and BRAF-wild-type (TPC-1) PTC cells were treated with MAPKi (dabrafenib or selumetinib) or EZH2 inhibitor (tazemetostat), or in combination, and the expression of iodine-metabolizing genes, radioiodine uptake, and toxicity were tested. We found that tazemetostat alone slightly increased iodine-metabolizing gene expression and promoted radioiodine uptake and toxicity, irrespective of the BRAF status. However, MAPKi induced these effects preferentially in BRAF^V600E mutant cells, which was robustly strengthened by tazemetostat incorporation. Mechanically, MAPKi-induced decrease of trimethylation of H3K27 was evidently intensified by tazemetostat in BRAF^V600E-mutant cells. In conclusion, tazemetostat combined with MAPKi enhances differentiation of PTC cells harbouring BRAF^V600E through synergistically decreasing global trimethylation of H3K27, representing a novel differentiation strategy.     

Dephosphorylation-induced EZH2 activation mediated RECK downregulation by ERK1/2 signaling

The reversion-inducing cysteine-rich protein with Kazal motifs (RECK) gene, a widely known cancer inhibitor, could effectively suppress cancer metastasis and angiogenesis. Downregulation or loss of RECK expression frequently occurs during cancer progression. However, the mechanism underlying RECK dysregulation has not been fully elucidated. Herein, we reported for the first time that enhancer of zeste homolog 2 (EZH2), a histone methyltransferase, could epigenetically attenuate RECK expression via catalyzing H3K27 trimethylation (H3K27me3) within the RECK promoter. Furthermore, we also proved, for the first time, the involvement of EZH2 in the inhibition of RECK by extracellular signal-related kinases (ERK)-1/2 signaling. Next, we revealed that the modulation of the enzymic activity of EZH2 resulting from posttranslational phosphorylation at the serine-21 site was responsible for the increased enrichment of H3K27me3 at the RECK promoter region by ERK1/2 signaling. Collectively, the results of our study shed more light on the mechanisms responsible for the dysregulation of RECK by the ERK1/2 pathway.     

Targeting EZH2 as a novel therapeutic strategy for sorafenib‐resistant thyroid carcinoma

Thyroid carcinoma is the most common endocrine malignancy. Surgery, post‐operative selective iodine‐131 and thyroid hormone suppression were the most common methods for the therapy of thyroid carcinoma. Although most patients with differentiated thyroid carcinoma (DTC) showed positive response for these therapeutic methods, some patients still have to face the radioactive iodine (RAI)‐refractory problems. Sorafenib is an oral multikinase inhibitor for patients with advanced RAI refractory DTC. However, the side effects and drug resistance of sorafenib suggest us to develop novel drugs and strategies for the therapy of thyroid carcinoma. In this study, we firstly found that patients with sorafenib resistance showed no significant change in rapidly accelerated fibrosarcoma and VEGFR expression levels compared with sorafenib sensitive patients. Moreover, a further miRNAs screen by qRT‐PCR indicated that miR‐124‐3p and miR‐506‐3p (miR‐124/506) were remarkably reduced in sorafenib insensitive patients. With a bioinformatics prediction and functional assay validation, we revealed that enhancer of zeste homolog 2 (EZH2) was the direct target for miR‐124/506. Interestingly, we finally proved that the sorafenib resistant cells regained sensitivity for sorafenib by EZH2 intervention with miR‐124/506 overexpression or EZH2 inhibitor treatment in vitro and in vivo, which will lead to the decreased tri‐methylation at lysine 27 of histone H3 (H3K27me3) and increased acetylated lysine 27 of histone H3 (H3K27ac) levels. Therefore, we conclude that the suppression of EZH2 represents a potential target for thyroid carcinoma therapy.     

Design and synthesis of (E)-1,2-diphenylethene-based EZH2 inhibitors

Enhancer of zeste homolog 2 (EZH2) serves as the catalytic subunit of the polycomb repression complex 2 (PRC2), which is implicated in cancer progression metastasis and poor prognosis. Based on our EZH2 inhibitor SKLB1049 with low nanomolar activity, we extended the “tail” region to get a series of (E)-1,2-diphenylethene derivatives as novel EZH2 inhibitors. SAR exploration and preliminary assessment led to the discovery of the potent novel EZH2 inhibitor 9b (EZH2^WT IC₅₀ = 22.0 nM). Compound 9b inhibited the proliferation of WSU-DLCL2 and SU-DHL-4 cell lines (IC₅₀ = 1.61 µM and 2.34 µM, respectively). The biological evaluation showed that 9b was a potent inhibitor for wild-type EZH2 and greatly reduced the overall levels of H3K27me3 in a concentration-dependent manner. Further study indicated that 9b could significantly induce apoptosis of SU-DHL-4 cells. These findings indicated that 9b would be an attractive lead compound for further optimization and evaluation.