Whole DNA methylome profiling in mice exposed to secondhand smoke

Aberration of DNA methylation is a prime epigenetic mechanism of carcinogenesis. Aberrant DNA methylation occurs frequently in lung cancer, with exposure to secondhand smoke (SHS) being an established risk factor. The causal role of SHS in the genesis of lung cancer, however, remains elusive. To investigate whether SHS can cause aberrant DNA methylation in vivo, we have constructed the whole DNA methylome in mice exposed to SHS for a duration of 4 mo, both after the termination of exposure and at ensuing intervals post-exposure (up to 10 mo). Our genome-wide and gene-specific profiling of DNA methylation in the lung of SHS-exposed mice revealed that all groups of SHS-exposed mice and controls share a similar pattern of DNA methylation. Furthermore, the methylation status of major repetitive DNA elements, including long-interspersed nuclear elements (LINE L1), intracisternal A particle long-terminal repeat retrotransposons (IAP-LTR), and short-interspersed nuclear elements (SINE B1), in the lung of all groups of SHS-exposed mice and controls remains comparable. The absence of locus-specific gain of DNA methylation and global loss of DNA methylation in the lung of SHS-exposed mice within a timeframe that precedes neoplastic-lesion formation underscore the challenges of lung cancer biomarker development. Identifying the initiating events that cause aberrant DNA methylation in lung carcinogenesis may help improve future strategies for prevention, early detection and treatment of this highly lethal disease.     

Whole DNA methylome profiling in mice exposed to secondhand smoke

Aberration of DNA methylation is a prime epigenetic mechanism of carcinogenesis. Aberrant DNA methylation occurs frequently in lung cancer, with exposure to secondhand smoke (SHS) being an established risk factor. The causal role of SHS in the genesis of lung cancer, however, remains elusive. To investigate whether SHS can cause aberrant DNA methylation in vivo, we have constructed the whole DNA methylome in mice exposed to SHS for a duration of 4 mo, both after the termination of exposure and at ensuing intervals post-exposure (up to 10 mo). Our genome-wide and gene-specific profiling of DNA methylation in the lung of SHS-exposed mice revealed that all groups of SHS-exposed mice and controls share a similar pattern of DNA methylation. Furthermore, the methylation status of major repetitive DNA elements, including long-interspersed nuclear elements (LINE L1), intracisternal A particle long-terminal repeat retrotransposons (IAP-LTR), and short-interspersed nuclear elements (SINE B1), in the lung of all groups of SHS-exposed mice and controls remains comparable. The absence of locus-specific gain of DNA methylation and global loss of DNA methylation in the lung of SHS-exposed mice within a timeframe that precedes neoplastic-lesion formation underscore the challenges of lung cancer biomarker development. Identifying the initiating events that cause aberrant DNA methylation in lung carcinogenesis may help improve future strategies for prevention, early detection and treatment of this highly lethal disease.     

异源DNA导入水稻诱发活跃反转子Tos17发生可遗传DNA甲基化变异

用水稻(Oryza sativa L.)内源反转座子Tos17为探针,经Southern杂交在5种含有野生稻(Zizania latifolia Griseb)(菰)DNA片段的水稻渐渗杂交系中检测到了可遗传DNA甲基化变异.在分析的4种甲基化敏感限制性内切酶中,每种酶切都发生了亲本杂交片段的消失和新片段的出现.发生甲基化变异的位点包括对称和不对称的胞嘧啶碱基,也包括腺嘌呤碱基.序列分析表明,与水稻亲本比较,所研究的5种渐渗杂交系在Tos17的2个重要区域(5'-LTR和RT)均未发生序列变异.但甲基化敏感-序列特异性PCR分析证实,每种渐渗杂交系在这2个区域内均发生了广泛的DNA甲基化变异.而且,在2种渐渗杂交系中发现5'-LTR和RT区域的甲基化变异存在协同性.甲基化变异可稳定遗传给后代.因为已有的研究表明,在这5种渐渗杂交系中异源DNA导入均导致了Tos17的激活和转座,因此可以推测DNA甲基化在调控Tos17活性中可能具有一定作用.但反转座子激活和甲基化变异之间的确切关系尚有待进一步研究.     

异源DNA导入水稻诱发活跃反转子Tos17发生可遗传DNA甲基化变异(英文)

用水稻(OryzasativaL.)内源反转座子Tos17为探针,经Southern杂交在5种含有野生稻(ZizanialatifoliaGriseb.)(菰)DNA片段的水稻渐渗杂交系中检测到了可遗传DNA甲基化变异。在分析的4种甲基化敏感限制性内切酶中,每种酶切都发生了亲本杂交片段的消失和新片段的出现。发生甲基化变异的位点包括对称和不对称的胞嘧啶碱基,也包括腺嘌呤碱基。序列分析表明,与水稻亲本比较,所研究的5种渐渗杂交系在Tos17的2个重要区域(5'-LTR和RT)均未发生序列变异。但甲基化敏感-序列特异性PCR分析证实,每种渐渗杂交系在这2个区域内均发生了广泛的DNA甲基化变异。而且,在2种渐渗杂交系中发现5'-LTR和RT区域的甲基化变异存在协同性。甲基化变异可稳定遗传给后代。因为已有的研究表明,在这5种渐渗杂交系中异源DNA导入均导致了Tos17的激活和转座,因此可以推测DNA甲基化在调控Tos17活性中可能具有一定作用。但反转座子激活和甲基化变异之间的确切关系尚有待进一步研究。     

DNA methylation profiling in cancer: From single nucleotides towards the methylome

The genomic DNA methylation pattern (methylome) is a cell epigenetic program that controls the expression of genetic information. The methylation pattern substantially changes in early carcinogenesis. A detailed survey of the methylcytosine distribution in the genome in norm and pathology is of immense importance for a better understanding of the etiology of cancer and its early diagnosis. The techniques available make it possible to simultaneously examine many samples (high-throughput analysis) and to examine large genome loci or even the total methylome (large-scale analysis). The review considers the main trends in the development of new approaches to DNA methylation and describes the techniques most commonly used in the field, their application, and results. Emphasis is placed on the use of various DNA microarrays (oligonucleotide microarrays, BAC arrays, etc.) as a method of choice for epigenetic analysis of tumors. Alternative sequence-based techniques of methylation analysis are discussed. The use of large-scale analysis to identify new epigenetic markers and to develop an epigenetic classification of neoplasms is considered.     

DNA甲基化修饰与干细胞分化

干细胞自我更新及分化潜能一方面是内源性转录因子相互协调控制的结果,另一方面表观遗传修饰也起着重要的作用。该文综述了DNA甲基化修饰的机理、哺乳动物DNA甲基化的特点以及干细胞分化的DNA甲基化修饰。     

Drugging the methylome: DNA methylation and memory

Over the past decade, since epigenetic mechanisms were first implicated in memory formation and synaptic plasticity, dynamic DNA methylation reactions have been identified as integral to long-term memory formation, maintenance, and recall. This review incorporates various new findings that DNA methylation mechanisms are important regulators of non-Hebbian plasticity mechanisms, suggesting that these epigenetic mechanisms are a fundamental link between synaptic plasticity and metaplasticity. Because the field of neuroepigenetics is so young and the biochemical tools necessary to probe gene-specific questions are just now being developed and used, this review also speculates about the direction and potential of therapeutics that target epigenetic mechanisms in the central nervous system and the unique pharmacokinetic and pharmacodynamic properties that epigenetic therapies may possess. Mapping the dynamics of the epigenome in response to experiential learning, even a single epigenetic mark in isolation, remains a significant technical and bioinformatic hurdle facing the field, but will be necessary to identify changes to the methylome that govern memory-associated gene expression and effectively drug the epigenome.     

DNA methylation and healthy human aging

The process of aging results in a host of changes at the cellular and molecular levels, which include senescence, telomere shortening, and changes in gene expression. Epigenetic patterns also change over the lifespan, suggesting that epigenetic changes may constitute an important component of the aging process. The epigenetic mark that has been most highly studied is DNA methylation, the presence of methyl groups at CpG dinucleotides. These dinucleotides are often located near gene promoters and associate with gene expression levels. Early studies indicated that global levels of DNA methylation increase over the first few years of life and then decrease beginning in late adulthood. Recently, with the advent of microarray and next‐generation sequencing technologies, increases in variability of DNA methylation with age have been observed, and a number of site‐specific patterns have been identified. It has also been shown that certain CpG sites are highly associated with age, to the extent that prediction models using a small number of these sites can accurately predict the chronological age of the donor. Together, these observations point to the existence of two phenomena that both contribute to age‐related DNA methylation changes: epigenetic drift and the epigenetic clock. In this review, we focus on healthy human aging throughout the lifetime and discuss the dynamics of DNA methylation as well as how interactions between the genome, environment, and the epigenome influence aging rates. We also discuss the impact of determining ‘epigenetic age’ for human health and outline some important caveats to existing and future studies.     

DNA甲基化与肿瘤

表观遗传指不涉及DNA序列改变的,可随细胞分裂而遗传的基因组修饰作用;DNA甲基化是其中研究最多的基因表达调节机制。异常DNA甲基化可致肿瘤发生,它亦是肿瘤基因诊断和治疗的靶点。文章介绍DNA甲基化基本概念、作用效果及其可能机制;并讨论异常DNA甲基化与肿瘤的关联,包括肿瘤中DNA异常甲基化原因、异常甲基化致瘤机制及基因甲基化研究在肿瘤诊治中的应用等。     

植物DNA甲基化及其表观遗传作用

表观遗传学(epigenetics)是研究没有DNA序列变化的、可遗传的基因表达的改变。目前研究表明,表观遗传学在植物生长发育过程中起着极其重要的作用,主要通过包括DNA甲基化、RNA干涉、基因组印记、转基因沉默等多个方面来调控植物的生长发育。其中,DNA甲基化是表观遗传学的最重要研究内容之一,是调节基因组功能的重要手段。现对植物DNA甲基化的特征、维持机制、调控机制、表观遗传作用及其研究方法进行简要论述。     

DNA Methylation and Epigenotypes

The science of epigenetics is the study of all those mechanisms that control the unfolding of the genetic program for development and determine the phenotypes of differentiated cells. The pattern of gene expression in each of these cells is called the epigenotype. The best known and most thoroughly studied epigenetic mechanism is DNA methylation, which provides a basis both for the switching of gene activities, and the maintenance of stable phenotypes. The human epigenome project is the determination of the pattern of DNA methylation in multiple cell types. Some methylation sites, such as those in repeated genetic elements, are likely to be the same in all cell types, but genes with specialized functions will have distinct patterns of DNA methylation. Another project for the future is the study of the reprogramming of the genome in gametogenesis and early development. Much is already known about the de novo methylation of tumor suppressor genes in cancer cells, but the significance of epigenetic defects during ageing and in some familial diseases remains to be determined.     

DNA甲基转移酶的表达调控及主要生物学功能

DNA甲基化是表观遗传学的重要部分, 同组蛋白修饰相互作用, 通过改变染色质结构, 调控基因表达。在哺乳类细胞或人体细胞中, DNA甲基化与细胞的增殖、衰老、癌变等生命现象有着重大关系。对催化DNA甲基化的DNA甲基转移酶(DNA methyltransferase, Dnmt)的研究可以揭示DNA甲基化对基因表达调控的机制, 从而研究与之相关的重要生命活动。文章以DNA甲基转移酶作为切入点, 探讨DNA甲基转移酶在基因表达调控中发挥的作用及其主要生物学功能。     

DNA methylation regulates Microtubule-associated tumor suppressor 1 in human non-small cell lung carcinoma

Microtubule associated tumor suppressor 1 (MTUS1) has been recognized as a tumor suppressor gene in multiple cancers. However, the molecular mechanisms underlying the regulation of MTUS1 are yet to be investigated. This study aimed to clarify the significance of DNA methylation in silencing MTUS1 expression. We report that MTUS1 acts as tumor suppressor in non-small cell lung carcinoma (NSCLC). Analysis of in silico database and subsequent knockdown of DNMT1 suggested an inverse correlation between DNMT1 and MTUS1 function. Interestingly, increased methylation at MTUS1 promoter is associated with low expression of MTUS1. Treatment with DNA methyltransferases (DNMTs) inhibitor, 5-aza-2′-deoxycytidine (AZA) leads to both reduced promoter methylation accompanied with enrichment of H3K9Ac and enhanced MTUS1 expression. Remarkably, knockdown of MTUS1 showed increased proliferation and migration of NSCLC cells in contrast to diminished proliferation and migration, upon treatment with AZA. We concluded that low expression of MTUS1 correlates to DNA methylation and histone deacetylation in human NSCLC.     

Association between hypermethylation of DNA repetitive elements in white blood cell DNA and early-onset colorectal cancer

Changes in the methylation levels of DNA from white blood cells (WBCs) are putatively associated with an elevated risk for several cancers. The aim of this study was to investigate the association between colorectal cancer (CRC) and the methylation status of three DNA repetitive elements in DNA from peripheral blood. WBC DNA from 539 CRC cases diagnosed before 60 years of age and 242 sex and age frequency-matched healthy controls from the Australasian Colorectal Cancer Family Registry were assessed for methylation across DNA repetitive elements Alu, LINE-1 and Sat2 using MethyLight. The percentage of methylated reference (PMR) of cases and controls was calculated for each marker. Odds ratios (ORs) and 95% confidence intervals (CIs) were estimated using multivariable logistic regression adjusted for potential confounders. CRC cases demonstrated a significantly higher median PMR for LINE-1 (p < 0.001), Sat2 (p < 0.001) and Alu repeats (p = 0.02) when compared with controls. For each of the DNA repetitive elements, individuals with PMR values in the highest quartile were significantly more likely to have CRC compared with those in the lowest quartile (LINE-1 OR = 2.34, 95%CI = 1.48–3.70; p < 0.001, Alu OR = 1.83, 95%CI = 1.17–2.86; p = 0.01, Sat2 OR = 1.72, 95%CI = 1.10–2.71; p = 0.02). When comparing the OR for the PMR of each marker across subgroups of CRC, only the Alu marker showed a significant difference in the 5-fluoruracil treated and nodal involvement subgroups (both p = 0.002). This association between increasing methylation levels of three DNA repetitive elements in WBC DNA and early-onset CRC is novel and may represent a potential epigenetic biomarker for early CRC detection.