DNA去甲基化对细胞衰老的影响

５－氮杂胞嘧啶为ＤＮＡ甲基化转移产的抑制剂,用它处理细胞,使基因组ＤＮＡ去甲基化,结果发现,经５ａＺａＣ处理后的细胞衰老进程明显加快,这从另一侧面反映了ＤＮＡ甲基化与细胞衰老的关系。     

5-azaC对小麦幼苗生长及盐胁迫后DNA甲基化变异的影响

DNA甲基化是调节植物生长发育,调控逆境基因表达的表观遗传机制之一。该研究采用不同浓度的DNA甲基化抑制剂5-azaC处理耐盐性不同的春小麦种子,分析其对种子萌发及盐胁迫后叶片基因组DNA甲基化的影响,探究DNA甲基化与小麦耐盐性之间的相关性。结果表明:(1)5-azaC显著抑制幼苗根长伸长,降低根系鲜重和干重。(2)甲基化敏感扩增多态性(MSAP)分析发现,单独盐胁迫后甲基化水平上升, 5-azaC预处理材料经盐胁迫后甲基化水平呈下降趋势。(3)盐胁迫后基因组同时发生DNA去甲基化和DNA甲基化。敏盐品种‘新春6号’DNA去甲基化比率上升,DNA甲基化增加的比率下降;耐盐品种‘新春11号’DNA去甲基化比率和DNA甲基化增加的比率均上升,但去甲基化比率大于DNA甲基化增加的比率,说明盐胁迫引起的基因组DNA去甲基化为主,5-azaC预处理提高了盐胁迫下DNA去甲基化的比率。(4)DNA甲基化修饰位点序列分析发现,在核糖体亚基蛋白、蛋白激酶和转座子序列均存在DNA甲基化修饰现象,说明存在多种代谢途径共同参与了盐胁迫调控。     

MBD4/MED1的结构与功能

含甲基化CpG结合域蛋白质4(methyl-CpG-binding domain protein 4,MBD4)是MBD核蛋白家族中的一员,它包含一个能特异结合甲基化CpG的MBD结构域和一个具有糖苷酶活性的DNA糖苷酶结构域。该蛋白质能特异地结合甲基化CpG岛,并且在DNA错配修复、抑制转录和调节凋亡等过程中发挥重要功能,并与微卫星不稳定性密切相关。MBD4是一个重要的DNA损伤修复蛋白,多方面的报道表明其许多功能都牵涉到细胞衰老。本文就其结构与功能的研究进展作一综述。     

TET家族DNA羟化酶与5-hmC在肿瘤中的作用机制的研究进展

DNA甲基化失调引起基因表达异常是表观遗传学的一个显著特点。目前已知,由DNA甲基转移酶（DNA methyltransferases,DMNTs）催化DNA甲基化,其酶基因突变或表达异常引起DNA甲基化水平的改变。近期研究发现了一种DNA去甲基化酶--TET（Ten-Eleventranslocation）家族DNA羟化酶,能通过多种途径催化5-甲基胞嘧啶（5．methylcytosine,5-mC）去甲基化,从而调控DNA基化的平衡。5-羟甲基胞嘧啶（5-hydroxymethylcytosine,5-hmC）作为DNA去甲基化多重步骤中重要的中间产物,其水平在肿瘤的发生和发展时期发生显著变化。该文从TET家族蛋白展开,介绍TET蛋白的结构、功能及作用机制以及多种人类肿瘤中丁E丁家族基因与5-hmC水平的相关性及其对肿瘤发生发展、诊断预后等临床意义的研究进展。     

DNA甲基化的生物信息学研究进展

作为重要的表观遗传学现象之一,DNA甲基化对基因的表达发挥重要的调控功能．随着高通量检测技术的不断发展,对DNA甲基化的生物信息学研究也成为DNA甲基化研究中的一个非常活跃的热点．对生物信息学在DNA甲基化状态的预测、CpG岛不易被甲基化的机制研究、探索DNA甲基化同其他表观遗传学现象之间的关系以及DNA异常甲基化同癌症的发生和发展之间的关系等方面的研究进展进行综述．     

哺乳动物DNA甲基化修饰的动态调控机制

DNA甲基化是最主要的表观遗传修饰之一,主要发生在胞嘧啶第五位碳原子上,称为5-甲基胞嘧啶。哺乳动物DNA甲基化由从头DNA甲基转移酶DNMT3A/3B在胚胎发育早期建立。细胞分裂过程中甲基化模式的维持由DNA甲基转移酶DNMT1实现。TET家族蛋白氧化5-甲基胞嘧啶成为5-羟甲基胞嘧啶、5-醛基胞嘧啶和5-羧基胞嘧啶,从而起始DNA的去甲基化过程。这些DNA甲基化修饰酶精确调节DNA甲基化的动态过程,在整个生命发育过程中发挥重要作用,其失调也与多种疾病发生密切相关。本文对近年来DNA甲基化修饰酶的结构与功能研究进行讨论。     

哺乳动物DNA甲基化修饰的动态调控机制

DNA甲基化是生命体最主要的表观遗传修饰之一。哺乳动物DNA甲基化主要发生在胞嘧啶第五位碳原子上,称为5-甲基胞嘧啶(5-methylcytosine,5m C)。哺乳动物DNA甲基化由从头DNA甲基转移酶DNMT3A/3B在胚胎发育早期建立,甲基化模式的维持由DNA甲基转移酶DNMT1实现。TET家族蛋白氧化5-甲基胞嘧啶起始DNA的去甲基化过程。这些DNA甲基化修饰酶精确调节DNA甲基化的动态过程,在整个生命发育过程中发挥重要作用,其失调也与多种疾病发生密切相关。现结合国内外同行研究进展,介绍课题组近年来对DNA甲基化修饰酶的结构与功能研究。     

不同倍性西瓜基因组DNA甲基化水平与模式的MSAP分析

DNA甲基化是表观遗传修饰的主要方式之一,在基因表达调控中发挥重要作用。本研究以不同倍性（2x、3x、4x）西瓜为试材,采用基于DNA甲基化敏感酶的扩增多态性分析（Methylation-Sensitive Ampliftcation Polymorphism,MSAP）方法,在全基因组水平上探究西瓜同源多倍化过程中DNA序列中CCGG位点的甲基化水平及模式变化特征。研究中选用23对选扩引物,共检测到1883个基因位点。二倍体、三倍体、四倍体中检测到的位点数分别为647、655和581;其中发生甲基化的位点数分别为181、150和159。相应的扩增总甲基化率分别为28．0％、22．9％和27．4％：全甲基化位点数分别为121、80和82,相应的全甲基化率分别为18．7％、12．2％和14．1％。进一步对不同倍性西瓜DNA甲基化模式的变化特征进行分析,结果显示：四倍体西瓜与二倍体西瓜相比有超过半数的位点（54．4％）DNA甲基化模式发生了变化,其与三倍体西瓜相比也有近一半的位点（45．4％）DNA甲基化模式发生了变化,并且变化趋势都以四倍体西瓜甲基化程度升高为主：而三倍体西瓜与二倍体西瓜相比．虽然也有41．6％的位点DNA甲基化模式发生了改变,但变化趋势以三倍体西瓜甲基化程度降低略占优势：与之相似,三倍体西瓜与四倍体相比较。甲基化的变化趋势也是以三倍体西瓜甲基化程度降低为主。以上结果表明：不同倍性西瓜中DNA甲基化事件虽均有发生．但不论是从总甲基化率还是全甲基化率来看,DNA甲基化水平与倍性高低关系不大．三倍体西瓜表现出较为显著的低甲基化水平特征。DNA甲基化模式的分析也表明。与二倍体及四倍体西瓜相比．三倍体西瓜DNA甲基化模式的调整主要以去甲基化为主。显示出三倍体西瓜基因组独特的DNA甲基化特征。本研究为进一步从表观遗传学的角度探讨西瓜的三倍体优?     

DNA甲基化方法研究现状

DNA的异常甲基化与肿瘤的发生发展密切相关。DNA甲基化已成为研究热点,有关研究方法发展迅速。甲基化研究方法大抵分为两大类：1．基因组DNA的甲基化检测;2．特定DNA片段的甲基化检测。目前的研究重点已转移到特定基因尤其是抑癌基因的甲基化。     

DNA甲基化/去甲基化与疾病概览

DNA甲基化(5m C)状态与疾病的发生发展密切相关,异常甲基化状态是肿瘤的重要特征,包括基因组整体甲基化水平降低和Cp G岛局部甲基化程度的异常升高。近期研究还发现,DNA甲基化可以继续氧化为DNA羟甲基化(5hm C),而5hm C可能是一种新的表观修饰或者参与DNA去甲基化。随着DNA甲基化测序技术的发展,可以得到全基因组单碱基分辨率的5m C和5hm C图谱,深入研究5m C和5hm C的动态变化对发育和肿瘤的影响,并期望找到潜在应用于肿瘤诊断和治疗的表观标志物。该文主要总结了DNA甲基化/去甲基化及其在肿瘤发生发展过程中的动态变化、潜在的表观标志物以及检测和治疗研究进展。     

p21Waf1/Cip1 plays a critical role in modulating senescence through changes of DNA methylation

It has been reported that genomic DNA methylation decreases gradually during cell culture and an organism's aging. However, less is known about the methylation changes of age-related specific genes in aging. p21(Waf1/Cip1) and p16(INK4a) are cyclin-dependent kinase (Cdk) inhibitors that are critical for the replicative senescence of normal cells. In this study, we show that p21(Waf1/Cip1) and p16(INK4a) have different methylation patterns during the aging process of normal human 2BS and WI-38 fibroblasts. p21(Waf1/Cip1) promoter is gradually methylated up into middle-aged fibroblasts but not with senescent fibroblasts, whereas p16(INK4a) is always unmethylated in the aging process. Correspondently, the protein levels of DNA methyltransferase 1 (DNMT1) and DNMT3a increase from young to middle-aged fibroblasts but decrease in the senescent fibroblasts, while DNMT3b decreases stably from young to senescent fibroblasts. p21(Waf1/Cip1) promoter methylation directly represses its expression and blocks the radiation-induced DNA damage-signaling pathway by p53 in middle-aged fibroblasts. More importantly, demethylation by 5-aza-CdR or DNMT1 RNA interference (RNAi) resulted in an increased p21(Waf1/Cip1) level and premature senescence of middle-aged fibroblasts demonstrated by cell growth arrest and high beta-Galactosidase expression. Our results suggest that p21(Waf1/Cip1) but not p16(INK4a) is involved in the DNA methylation mediated aging process. p21(Waf1/Cip1) promoter methylation may be a critical biological barrier to postpone the aging process.     

DNA甲基化作用与鼠肝细胞的老化

本文比较了不同年龄的鼠肝ＤＮＡ甲基化酶活力及ＤＮＡ甲基化水平,发现它们均与鼠龄呈反相关。又以不同年龄的鼠肝ＤＮＡ为模板,检验了其体外转录活力,发现其与鼠龄呈正相关。     

Global remodeling of the mouse DNA methylome during aging and in response to calorie restriction

Aging is characterized by numerous molecular changes, such as accumulation of molecular damage and altered gene expression, many of which are linked to DNA methylation. Here, we characterize the blood DNA methylome across 16 age groups of mice and report numerous global, region‐ and site‐specific features, as well as the associated dynamics of methylation changes. Transition of the methylome throughout lifespan was not uniform, with many sites showing accelerated changes in late life. The associated genes and promoters were enriched for aging‐related pathways, pointing to a fundamental link between DNA methylation and control of the aging process. Calorie restriction both shifted the overall methylation pattern and was accompanied by its gradual age‐related remodeling, the latter contributing to the lifespan‐extending effect. With age, both highly and poorly methylated sites trended toward intermediate levels, and aging was accompanied by an accelerated increase in entropy, consistent with damage accumulation. However, the entropy effects differed for the sites that increased, decreased and did not change methylation with age. Many sites trailed behind, whereas some followed or even exceeded the entropy trajectory and altered the developmental DNA methylation pattern. The patterns we observed in certain genomic regions were conserved between humans and mice, suggesting common principles of functional DNA methylome remodeling and its critical role in aging. The highly resolved DNA methylome remodeling provides an excellent model for understanding systemic changes that characterize the aging process.     

Whole-genome methylation analysis of aging human tissues identifies age-related changes in developmental and neurological pathways

Age-associated changes in the DNA methylation state can be used to assess the pace of aging. However, it is not understood what mechanisms drive these changes and whether these changes affect the development of aging phenotypes and the aging process in general. This study was aimed at gaining a more comprehensive understanding of aging-related methylation changes across the whole genome, and relating these changes to biological functions. It has been shown that skeletal muscle and blood monocytes undergo typical changes with aging. Using whole-genome bisulfite sequencing, we sought to characterize the genome-wide changes in methylation of DNA derived from both skeletal muscle and blood monocytes, and link these changes to specific genes and pathways through enrichment analysis. We found that methylation changes occur with aging at the locations enriched for developmental and neuronal pathways regulated in these two peripheral tissues. These results contribute to our understanding of changes in epigenome in human aging.     

大鼠衰老过程中脑细胞DNA与c－Ha－ras原癌基因的甲基化

用ＭｓｐⅠ／ＨｐａⅡ酶解电泳法和高效液相色谱（ＨＰＬＣ）两种方法进行比较,研究了不同年龄大鼠的肝、脑细胞基因组ＤＮＡ的甲基化程度。从酶解电泳图谱可观察到,肝、脑细胞基因组ＤＮＡ甲基化在青年鼠和老年鼠之间没有差异。但用具有高分辨率的高效液相色谱测量ＤＮＡ中５－ｍＣ的含量时发现,老年鼠脑细胞ＤＮＡ甲基化程度较大年鼠的下降６２％,而肝细胞ＤＮＡ甲基化程度在老年鼠与青年鼠之间并没有显著差异。这些结果提示：（１）用常规的酶解电泳法所分析的ＤＮＡ甲基化结果并不能反映整个基因组ＤＮＡ甲基化的水平。（２）衰老过程中,不同组织ＤＮＡ甲基化的改变存在差异,引起这种差异的原因可能与组织的增殖和分化程度有关。进一步分析脑细胞原癌基因ｃ－Ｈａ－ｒａｓ的甲基化水平,无论ＭｓｐⅠ酶切图谱,还是ＨｐａⅡ酶切图谱均可观察到分子大小为１９ｋｂ、７．５ｋｂ、１．３ｋｂ、０．９ｋｂ的四条阳性带,说明该基因未发生甲基化,且与年龄无关。     

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.     

Mitotic inheritance of DNA methylation: more than just copy and paste

Decades of investigation on DNA methylation have led to deeper insights into its metabolic mechanisms and biological functions.This understanding was fueled by the recent development of genome editing tools and our improved capacity for analyzing the global DNA methylome in mammalian cells.This review focuses on the maintenance of DNA methylation patterns during mitotic cell division.We discuss the latest discoveries of the mechanisms for the inheritance of DNA methylation as a stable epigenetic memory.We also highlight recent evidence showing the rapid turnover of DNA methylation as a dynamic gene regulatory mechanism.A body of work has shown that altered DNA methylomes are common features in aging and disease.We discuss the potential links between methylation maintenance mechanisms and diseaseassociated methylation changes.     

DNA methylation,an epigenetic mechanism connecting folate to healthy embryonic development and aging

Experimental studies demonstrated that maternal exposure to certain environmental and dietary factors during early embryonic development can influence the phenotype of offspring as well as the risk of disease development at the later life. DNA methylation, an epigenetic phenomenon, has been suggested as a mechanism by which maternal nutrients affect the phenotype of their offspring in both honeybee and agouti mouse models. Phenotypic changes through DNA methylation can be linked to folate metabolism by the knowledge that folate, a coenzyme of one-carbon metabolism, is directly involved in methyl group transfer for DNA methylation. During the fetal period, organ-specific DNA methylation patterns are established through epigenetic reprogramming. However, established DNA methylation patterns are not immutable and can be modified during our lifetime by the environment. Aberrant changes in DNA methylation with diet may lead to the development of age-associated diseases including cancer. It is also known that the aging process by itself is accompanied by alterations in DNA methylation. Diminished activity of DNA methyltransferases (Dnmts) can be a potential mechanism for the decreased genomic DNA methylation during aging, along with reduced folate intake and altered folate metabolism. Progressive hypermethylation in promoter regions of certain genes is observed throughout aging, and repression of tumor suppressors induced by this epigenetic mechanism appears to be associated with cancer development. In this review, we address the effect of folate on early development and aging through an epigenetic mechanism, DNA methylation.     

DNA modification, differentiation, and transformation

Substantial evidence has accumulated over the last 5 years that the methylation of cytosine residues in vertebrate DNA is implicated in the control of gene expression. We have used analogs of cytidine, modified in the 5 position, as specific inhibitors of DNA methylation to probe the relationship between this process and cellular differentiation. 5-Azacytidine effected marked changes in the differentiated state of cultured cells and induced the formation of biochemically differentiated muscle, fat, and chondrocytes from mouse fibroblast cell lines. Since the analog is a powerful inhibitor of DNA methylation, we suggest that this inhibition is causally related to the mechanism of phenotypic conversion. DNA extracted from cells treated with 5-azacytidine was hemimethylated and was used as an efficient acceptor of methyl groups in an in vitro reaction in the presence of eukaryotic methylases. In vitro methylation was inhibited if the substrate DNA was preincubated with a diverse range of chemical carcinogens including benzo(a)pyrene diolepoxide. Thus, chemical carcinogens may induce changes in gene expression by alteration of cellular methylation patterns. Recent experiments have also demonstrated that freshly explanted diploid fibroblasts from mice, hamsters, and humans lose substantial quantities of 5-methylcytosine during cell division and aging in culture. Taken together, these experiments suggest that the genomic distribution of 5-methylcytosine might have importance in normal differentiation and also in the aberrant gene expression found in cancer and senescence in culture.