DNA甲基化——肿瘤产生的一种表观遗传学机制

在人类基因组中,DNA甲基化是一种表观遗传修饰,它与肿瘤的发生关系密切。抑癌基因和DNA修复基因的高甲基化、重复序列DNA的低甲基化、某些印记基因的印记丢失与多种肿瘤的发生有关。目前研究发现,基因组中甲基化的水平不仅受DNA 甲基化转移酶（DNMT）的影响,还与组蛋白甲基化、叶酸摄入、RNA干扰等多种因素有关。DNA甲基化在基因转录过程中扮有重要角色,并与组蛋白修饰、染色质构型重塑共同参与转录调控。     

Inhibition of DNMT suppresses the stemness of colorectal cancer cells through down-regulating Wnt signaling pathway

Cancer stem cell (CSC) theory reveals a new insight into the understanding of tumorigenesis and metastasis. Recently, DNA methylation is suggested to be a potential epigenetic mechanism for maintenance of CSCs. What's more, studies have shown that DNA methyltransferase (DNMT) is essential for CSCs and deletion of DNMT can reduce tumorigenesis by limiting CSC pool. Therefore, targeting the epigenetic modifiers especially DNA methylation offers an optional strategy for treating human cancers. In the present study we found that DNMT inhibitor 5-Aza-2′-deoxycytidine (5-AzaDC) markedly reduced colorectal CSC abundance in vitro and suppressed liver metastatic tumor growth in vivo. And 5-AzaDC inhibited the expression of active β-catenin and down-regulated the Wnt signaling pathway. The Wnt inhibitors were frequently inactivated by promoter methylation in colorectal cancer; however analysis of TCGA data base showed that only the expression of SFRP1 was significantly reduced in tumors compared to normal tissues. In addition, restoring of SFRP1 expression inhibited the stem cell-like potential of colorectal cancer cells. Our results indicated that inhibition of DNMT blocked the self-renewal of colorectal CSCs and SFRP1 was essential for the maintenance of colorectal CSCs.     

Epigenetic therapy of cancer stem and progenitor cells by targeting DNA methylation machineries

Recent advances in stem cell biology have shed light on how normal stem and progenitor cells can evolve to acquire malignant characteristics during tumorigenesis. The cancer counterparts of normal stem and progenitor cells might be occurred through alterations of stem cell fates including an increase in self-renewal capability and a decrease in differentiation and/or apoptosis. This oncogenic evolution of cancer stem and progenitor cells, which often associates with aggressive phenotypes of the tumorigenic cells, is controlled in part by dysregulated epigenetic mechanisms including aberrant DNA methylation leading to abnormal epigenetic memory. Epigenetic therapy by targeting DNA methyltransferases (DNMT) 1, DNMT3A and DNMT3B via 5-Azacytidine (Aza) and 5-Aza-2’-deoxycytidine (Aza-dC) has proved to be successful toward treatment of hematologic neoplasms especially for patients with myelodysplastic syndrome. In this review, I summarize the current knowledge of mechanisms underlying the inhibition of DNA methylation by Aza and Aza-dC, and of their apoptotic- and differentiation-inducing effects on cancer stem and progenitor cells in leukemia, medulloblastoma, glioblastoma, neuroblastoma, prostate cancer, pancreatic cancer and testicular germ cell tumors. Since cancer stem and progenitor cells are implicated in cancer aggressiveness such as tumor formation, progression, metastasis and recurrence, I propose that effective therapeutic strategies might be achieved through eradication of cancer stem and progenitor cells by targeting the DNA methylation machineries to interfere their “malignant memory”.     

Increased DNA methyltransferase activity and DNA methylation following epidermal growth factor stimulation in ovarian cancer cells

Ovarian cancer progression is correlated with accumulation of aberrant CpG island methylation. In ovarian cancer, ascites fluid contains numerous Epidermal-Growth-Factor-Receptor (EGFR) activators, which could result in a tumor microenvironment of constant EGFR activation. Signaling pathways downstream of EGFR, such as Ras, regulate DNA methylation. We hypothesized that chronic EGFR activation could alter DNA methylation. We found that EGFR activation increased DNA methyltransferase (DNMT) activity acutely, as well as after long-term EGF treatment or expression of a mutationally activated EGFR. Furthermore, this increase in DNMT activity was dependent on EGFR catalytic activity and resulted in increased global DNA methylation. Additionally, treatment with the DNMT inhibitor/hypomethylating agent 5-Aza-2′-deoxycytidine (AZA) inhibited the EGF induced increase of both DNMT activity and global methylation. These data support a role for EGFR in the process of accumulated DNA methylation during ovarian cancer progression and suggest that epigenetic therapy may be beneficial for the treatment of ovarian cancer.Key words: ovarian cancer, DNA methylation, epidermal growth factor receptor, DNA methyltransferase, epigenetics, E-cadherin     

DNA methyl transferase 1: regulatory mechanisms and implications in health and disease

DNA methylation serves as the principal form of post-replicative epigenetic modification. It is intricately involved in gene regulation and silencing in eukaryotic cells, making significant contributions to cell phenotype. Much of it is mitotically inherited; some is passed on from one filial generation to the next. Establishment and maintenance of DNA methylation patterns in mammals is governed by three catalytically active DNA methyltransferases – DNMT3a, DNMT3b and DNMT1. While the first two are responsible mainly for de novo methylation, DNMT1 maintains the methylation patterns by preferentially catalyzing S-adenosyl methionine-dependant transfer of a methyl group to cytosine at hemimethylated CpG sites generated as a result of semi-conservative DNA replication. DNMT1 contains numerous regulatory domains that fine-tune associated catalytic activities, deregulation of which is observed in several diseases including cancer. In this minireview, we analyze the regulatory mechanisms of various sub-domains of DNMT1 protein and briefly discuss its pathophysiological and pharmacological implications. A better understanding of DNMT1 function and structure will likely reveal new applications in the treatment of associated diseases.     

DNA甲基化对子宫内膜异位症(EMs)的作用及其调控机制

表观遗传通过DNA甲基化、组蛋白修饰、染色质重塑、以及microRNA等调控方式来实现对基因表达、DNA复制和基因组稳定性的控制。DNA甲基化是目前研究的最为广泛的表观遗传修饰方式之一,可调控真核生物的基因表达。DNA甲基化在哺乳动物发育、肿瘤发生发展及人类其他疾病中均发挥着至关重要的作用。DNA甲基化状态的改变已被视为人类肿瘤细胞的生物标志之一。EMs虽是一种良性妇科疾病,但伴有细胞增殖、侵袭性及远处种植转移等肿瘤的特点。最新研究发现,DNA甲基化可能与子宫内膜异位症(EMs)的发生存在密切的关系并认为EMs从根本上是一种表观遗传学疾病。由于表观遗传修饰都是可逆的过程,这就为EMs的治疗提供了一种新的途径。本文就DNA甲基化在EMs中的发生发展中的作用及其调控的分子机制,以及在诊断治疗中作用的最新研究进展做一综述。     

DNA甲基化对子宫内膜异位症（EMs）的作用及其调控机制

表观遗传通过DNA甲基化、组蛋白修饰、染色质重塑、以及microRNA等调控方式来实现对基因表达、DNA复制和基因组稳定性的控制。DNA甲基化是目前研究的最为广泛的表观遗传修饰方式之一,可调控真核生物的基因表达。DNA甲基化在哺乳动物发育、肿瘤发生发展及人类其他疾病中均发挥着至关重要的作用。DNA甲基化状态的改变已被视为人类肿瘤细胞的生物标志之一。EMs虽是一种良性妇科疾病,但伴有细胞增殖、侵袭性及远处种植转移等肿瘤的特点。最新研究发现,DNA甲基化可能与子宫内膜异位症（EMs）的发生存在密切的关系并认为EMs从根本上是一种表观遗传学疾病。由于表观遗传修饰都是可逆的过程,这就为EMs的治疗提供了一种新的途径。本文就DNA甲基化在EMs中的发生发展中的作用及其调控的分子机制,以及在诊断治疗中作用的最新研究进展做一综述。     

DNMT1 but not its interaction with the replication machinery is required for maintenance of DNA methylation in human cells

DNA methylation plays a central role in the epigenetic regulation of gene expression in vertebrates. Genetic and biochemical data indicated that DNA methyltransferase 1 (Dnmt1) is indispensable for the maintenance of DNA methylation patterns in mice, but targeting of the DNMT1 locus in human HCT116 tumor cells had only minor effects on genomic methylation and cell viability. In this study, we identified an alternative splicing in these cells that bypasses the disrupting selective marker and results in a catalytically active DNMT1 protein lacking the proliferating cell nuclear antigen-binding domain required for association with the replication machinery. Using a mechanism-based trapping assay, we show that this truncated DNMT1 protein displays only twofold reduced postreplicative DNA methylation maintenance activity in vivo. RNA interference-mediated knockdown of this truncated DNMT1 results in global genomic hypomethylation and cell death. These results indicate that DNMT1 is essential in mouse and human cells, but direct coupling of the replication of genetic and epigenetic information is not strictly required.     

Cancer-type regulation of MIG-6 expression by inhibitors of methylation and histone deacetylation

Epigenetic silencing is one of the mechanisms leading to inactivation of a tumor suppressor gene, either by DNA methylation or histone modification in a promoter regulatory region. Mitogen inducible gene 6 (MIG-6), mainly known as a negative feedback inhibitor of the epidermal growth factor receptor (EGFR) family, is a tumor suppressor gene that is associated with many human cancers. To determine if MIG-6 is inactivated by epigenetic alteration, we identified a group of human lung cancer and melanoma cell lines in which its expression is either low or undetectable and studied the effects of methylation and of histone deacetylation on its expression. The DNA methyltransferase (DNMT) inhibitor 5-aza-2'-deoxycytidine (5-aza-dC) induced MIG-6 expression in melanoma cell lines but little in lung cancer lines. By contrast, the histone deacetylase (HDAC) inhibitor trichostatin A (TSA) induced MIG-6 expression in lung cancer lines but had little effect in melanoma lines. However, the MIG-6 promoter itself did not appear to be directly affected by either methylation or histone deacetylation, indicating an indirect regulatory mechanism. Luciferase reporter assays revealed that a short segment of exon 1 in the MIG-6 gene is responsible for TSA response in the lung cancer cells; thus, the MIG-6 gene can be epigenetically silenced through an indirect mechanism without having a physical alteration in its promoter. Furthermore, our data also suggest that MIG-6 gene expression is differentially regulated in lung cancer and melanoma.     

Increased DNA methyltransferase activity and DNA methylation following epidermal growth factor stimulation in ovarian cancer cells

Ovarian cancer progression is correlated with accumulation of aberrant CpG island methylation. In ovarian cancer, ascites fluid contains numerous Epidermal-Growth-Factor-Receptor (EGFR) activators, which could result in a tumor microenvironment of constant EGFR activation. Signaling pathways downstream of EGFR, such as Ras, regulate DNA methylation. We hypothesized that chronic EGFR activation could alter DNA methylation. We found that EGFR activation increased DNA methyltransferase (DNMT) activity acutely, as well as after long-term EGF treatment or expression of a mutationally activated EGFR. Furthermore, this increase in DNMT activity was dependent on EGFR catalytic activity and resulted in increased global DNA methylation. Additionally, treatment with the DNMT inhibitor/hypomethylating agent 5-Aza-2’-deoxycytidine (AZA) inhibited the EGF induced increase of both DNMT activity and global methylation. These data support a role for EGFR in the process of accumulated DNA methylation during ovarian cancer progression and suggest that epigenetic therapy may be beneficial for the treatment of ovarian cancer.     

Decreased miR-30b-5p expression by DNMT1 methylation regulation involved in gastric cancer metastasis

miRNAs have emerged as crucial regulators in the regulation of development as well as human diseases, especially tumorigenesis. The aims of this study are to evaluate miR-30b-5p expression pattern and mechanism in gastric carcinogenesis due to which remains to be determined. Expression of miR-30b-5p was analyzed in 51 gastric cancer cases and 4 cell lines by qRT-PCR. The effect of DNA methylation on miR-30b-5p expression was assessed by MSP and BGS. In order to know whether DNMT1 increased miR-30b-5p promoter methylation, DNMT1 was depleted in cell lines AGS and BGC-823. The role of miR-30b-5p on cell migration was evaluated by wound healing assays. Decreased expression of miR-30b-5p was found in gastric cancer samples. In tumor, the expression level of miR-30b-5p was profound correlated with lymph node metastasis (P = 0.019). The level of miR-30b-5p may be restored by DNA demethylation and DNMT1 induced miR-30b-5p promoter methylation. In vitro functional assays implied that enforced miR-30b-5p expression affected cell migration, consistent with tissues analysis. Our findings uncovered that miR-30b-5p is significantly diminished in gastric cancer tissues, providing the first insight into the epigenetic mechanism of miR-30b-5p down-regulation, induced by DNMT1, and the role of miR-30b-5p in gastric cancer carcinogenesis. Overexpression of miR-30b-5p inhibited cell migration. Thus, miR-30b-5p may represent a potential therapeutic target for gastric cancer therapy.