二恶英对雌激素受体的干扰作用

核受体相关的肿瘤,如乳腺癌和前列腺癌的发生、发展主要依赖于性激素的分泌。环境内分泌干扰物如Ⅲ二恶英,可作为雌激素受体的诱导配体,直接或间接地与转录因子相互作用,从而干扰基因的转录。此外,二恶英还能使雌激素受体发生泛素化修饰,促进它的降解,并使雌激素依赖性的基因转录受到抑制,成为内分泌干扰因子。本文综述了二恶英的类雌激素效应、致癌性以及激素信号干扰的最新研究进展。     

外源雌激素的低剂量非线性效应研究进展

从传统意义上看,任何物质只要达到一定数量或浓度都会对机体产生毒性,而低于安全阈值则不具有相应的毒性。毒理学研究认为高剂量的化学物质可对生物体产生生物毒性效应,而最新研究则表明外源雌激素(xenoestrogens,XEs)可在不同组织水平表现出双向剂量效应(倒"U"型),尤其表现为低剂量非线性效应。XEs是一类典型的环境内分泌干扰物,其主要通过模拟或干扰体内正常雌激素的合成、代谢和转运,从而干扰正常的生物内分泌功能。XEs通过基因组途径和非基因组途径的联合作用产生低剂量非线性效应。本文综述了XEs在生物个体及细胞分子水平的低剂量非线性效应,阐述了XEs低剂量非线性效应的产生机理,介绍了环境痕量XEs的检测分析方法。在此基础上,对XEs低剂量非线性效应今后的研究方向进行了展望,以期为XEs环境生态安全和人体健康研究提供理论指导。     

siRNA诱导的DNA甲基化与肿瘤的发生

siRNA诱导的基因沉默最早只被认为是发生在细胞质内的转录后水平的调控过程,随着siRNA指导DNA甲基化现象的发现,已证实siRNA可以通过指导基因组表观修饰引起转录水平基因沉默.DNA甲基化曾被预言是致癌作用的一种表观遗传学机制,肿瘤发生过程中抑瘤基因异常沉默涉及到基因启动子区域DNA的甲基化.分析了这两个过程中内在的关系,探索siRNA对肿瘤细胞中基因异常表达的影响和作用.这将有助于肿瘤生物学和表观遗传学的研究,也会为研发防治肿瘤的新方法和新途径提供新的思路.     

2型糖尿病环境因素与DNA甲基化的研究进展

2 型糖尿病(Type 2 diabetes mellitus, T2DM)是由于遗传与环境因素共同作用而引起葡萄糖代谢紊乱的疾病。DNA甲基化修饰的研究发现环境因素可以通过影响DNA甲基化修饰, 显著地增加T2DM的患病风险。目前, T2DM环境相关基因的DNA甲基化修饰研究已在人及动物的不同组织中取得进展。此外, T2DM相关基因的甲基化研究主要集中在糖代谢、能量代谢、炎症等。文章系统地综述了目前T2DM致病环境因素与DNA甲基化研究进展。     

双酚A的内分泌干扰效应研究进展

双酚A(Bisphenol A, BPA)是一种危害生物体内分泌干扰效应的环境激素。近年来, 随着工农业的不断发展, 造纸行业、电子产品、食品包装等行业大量使用BPA, 国内外主要河流、湖泊都不同程度受到了BPA的污染。BPA通过富集会影响人类激素的合成、释放、转运, 进而影响人的生殖和发育。BPA的毒性效应主要包括内分泌干扰物、神经毒素、免疫毒素等方面, 这些致毒效应甚至会增加细胞癌变、畸变的可能性。此外BPA毒性替代物、BPA与其他物质结合的产物都增加了BPA毒性的多样性, 逐渐成为了危害人类生命安全的又一大隐患。通过研究BPA毒性效应以及近年来BPA的替代品, 了解双酚A的致毒机理, 为研究预防控制BPA污染对人类健康的影响提供参考依据。     

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。     

基因组DNA甲基化修饰在胚胎干细胞分化过程中的作用

基因组DNA的甲基化修饰通常使基因转录失活,去甲基化或低甲基化则使基因转录活化。但是,胚胎干细胞向各种成体细胞分化过程中相关基因的转录活化与DNA甲基化修饰水平并不呈简单的正性或负性相关。因此,甲基化修饰调节基因转录是一个复杂的过程。目前,对甲基化修饰作用的研究主要集中在基因选择性活化、改变转录因子与靶基因的结合活性、与组蛋白修饰协同作用及其基因表达的阶段特异性等方面。     

MPTP诱导的帕金森病小鼠模型黑质脑组织DNA甲基化研究

为研究DNA甲基化在帕金森病发病机制中的作用,本研究用环境毒素1-甲基-4-苯基-1,2,3,6-四氢吡啶(MPTP)连续腹腔给药诱导小鼠帕金森病(Parkison's disease,PD)模型,应用ELISA检测小鼠黑质脑组织总体甲基化水平,应用实时荧光定量PCR方法检测DNA甲基转移酶表达水平,探讨MPTP诱导的小鼠PD模型黑质部位是否存在DNA甲基化异常.进一步应用甲基化DNA免疫共沉淀结合DNA甲基化芯片方法,构建MPTP诱导的小鼠PD模型黑质脑组织DNA甲基化谱,并寻找DNA甲基化修饰异常的PD相关基因对其进行验证.结果表明,模型组小鼠黑质脑组织DNA总体甲基化水平较对照组显著降低,Dnmt1的表达水平显著增高.利用DNA甲基化芯片在全基因组内筛选出甲基化差异修饰位点共48个,涉及44个基因,这些甲基化差异基因参与信号转导、分子转运、转录调控、发育、细胞分化、凋亡调控、氧化应激、蛋白质降解等生物学过程.在甲基化差异修饰基因中,对Uchl1基因及Arih2基因进行了甲基化水平以及表达水平的验证.结果表明,模型组小鼠黑质脑组织Uchl1启动子区域甲基化水平较对照组增高,m RNA及蛋白质表达水平降低,Arih2启动子区域甲基化水平较对照组降低,m RNA及蛋白质表达水平增高.实验结果进一步证实,DNA甲基化修饰异常在帕金森病发病机制中有重要作用,环境因素(如MPTP)可以通过改变DNA甲基化修饰参与帕金森病的发生发展.     

环境内分泌干扰物对生殖健康影响的研究进展

环境内分泌干扰物(environmental endocrine disruptors,EEDs)是指环境中天然存在或污染的能够干扰机体内自然激素的合成、分泌、转运、结合、作用和消除等过程,表现出拟自然激素或抗自然激素的生理学作用的一类化合物。它们与人们的生活密不可分,比如邻苯二甲酸酯类(PAEs)和双酚A(BPA),就广泛存在于食品包装、儿童玩具及生活用品中。大量实验证据以及流行病学的调查表明环境内分泌干扰物对动物雌激素、睾酮、甲状腺素、儿茶酚胺等呈现显著的干扰效应,是生殖障碍、出生缺陷、发育异常、代谢紊乱以及某些恶性肿瘤的发病率增加的原因之一。本文归纳了环境内分泌干扰物(EEDs)对生殖健康影响的研究进展。     

阿尔茨海默病DNA甲基化研究进展

阿尔茨海默病(Alzheimer’s disease,AD)又称老年痴呆症,是老年人中发病率最高的神经退行性疾病之一,以记忆和认知功能损伤为主要特征。AD与表观遗传学如DNA甲基化联系紧密。通常,基因启动子区域DNA高甲基化会抑制相关基因的表达。目前研究表明,诸多因素通过影响DNA甲基化修饰显著增加AD的患病风险,如环境、年龄及AD相关疾病。AD相关基因的DNA甲基化修饰研究已取得较大的进展,测试外周血中基因DNA甲基化修饰差异可为AD的预测、诊断及治疗开辟新的途径。该文就最近相关的DNA甲基化研究进展进行了系统阐述。     

Linking inter-individual variability to endocrine disruptors: insights for epigenetic inheritance

Endocrine disrupting chemicals (EDCs) can induce a myriad of adverse health effects. An area of active investigation is the multi- and transgenerational inheritance of EDC-induced adverse health effects referring to the transmission of phenotypes across multiple generations via the germline. The inheritance of EDC-induced adverse health effects across multiple generations can occur independent of genetics, spurring much research into the transmission of underlying epigenetic mechanisms. Epigenetic mechanisms play important roles in the development of an organism and are responsive to environmental exposures. To date, rodent studies have demonstrated that acquired epigenetic marks, particularly DNA methylation, that are inherited following parental EDC exposure can escape embryonic epigenome reprogramming. The acquired epimutations can lead to subsequent adult-onset diseases. Increasing studies have reported inter-individual variations that occur with epigenetic inheritance. Factors that underlie differences among individuals could reveal previously unidentified mechanisms of epigenetic transmission. In this review, we give an overview of DNA methylation and posttranslational histone modification as the potential mechanisms for disease transmission, and define the requirements for multi- and transgenerational epigenetic inheritance. We subsequently evaluate rodent studies investigating how acquired changes in epigenetic marks especially DNA methylation across multiple generations can vary among individuals following parental EDC exposure. We also discuss potential sources of inter-individual variations and the challenges in identifying these variations. We conclude our review discussing the challenges in applying rodent generational studies to humans.

     

The mechanisms of transgenerational inheritance and their potential contribution to human phenotypes

As of today, classical genetics has already completed the majority of groundwork to describe the laws of inheritance, identify the causes of many human diseases, and dissect the mechanisms of transfer of genetic information from parents to offspring. However, recent studies indicate that inheritance of phenotypic traits may also occur through nongenetic factors, in particular, through epigenetic factors, that manifest their effects in a transgenerational fashion. This review discusses findings in the area of transgenerational inheritance that open a new era in modern genetics. We discuss the mechanisms of transgenerational inheritance, including DNA methylation, histone modifications, and noncoding RNA transfer, and give an overview of the approaches to detect transgenerational effects in humans.     

Unlocking the Arabidopsis epigenome

The patterns of DNA methylation, referred to as the “methylome”, must be faithfully propagated for proper development of plants and mammals. However, it has been unclear to which extent transgenerational epigenetic inheritance will be affected after DNA methylation distribution has been altered. Recently, three reports have addressed this issue in the model plant Arabidopsis thaliana. Here we revisit the results of these experiments addressing the stability of epigenetic inheritance within two populations of epigenetic recombinant inbred lines (epiRILs), in which mosaic epigenomes were subjected to inbreeding for multiple generations. The manner in which the epigenetic variation was induced differed between the two populations, one by adversely affecting chromatin remodeling and the second by impairing the maintenance of DNA methylation, yet the comparison of the results provides a broader view of transgenerational epigenetic inheritance that may find parallels in other organisms.     

Epigenetic Transgenerational Actions of Vinclozolin on Promoter Regions of the Sperm Epigenome

Previous observations have demonstrated that embryonic exposure to the endocrine disruptor vinclozolin during gonadal sex determination promotes transgenerational adult onset disease such as male infertility, kidney disease, prostate disease, immune abnormalities and tumor development. The current study investigates genome-wide promoter DNA methylation alterations in the sperm of F3 generation rats whose F0 generation mother was exposed to vinclozolin. A methylated DNA immunoprecipitation with methyl-cytosine antibody followed by a promoter tilling microarray (MeDIP-Chip) procedure was used to identify 52 different regions with statistically significant altered methylation in the sperm promoter epigenome. Mass spectrometry bisulfite analysis was used to map the CpG DNA methylation and 16 differential DNA methylation regions were confirmed, while the remainder could not be analyzed due to bisulfite technical limitations. Analysis of these validated regions identified a consensus DNA sequence (motif) that associated with 75% of the promoters. Interestingly, only 16.8% of a random set of 125 promoters contained this motif. One candidate promoter (Fam111a) was found to be due to a copy number variation (CNV) and not a methylation change, suggesting initial alterations in the germline epigenome may promote genetic abnormalities such as induced CNV in later generations. This study identifies differential DNA methylation sites in promoter regions three generations after the initial exposure and identifies common genome features present in these regions. In addition to primary epimutations, a potential indirect genetic abnormality was identified, and both are postulated to be involved in the epigenetic transgenerational inheritance observed. This study confirms that an environmental agent has the ability to induce epigenetic transgenerational changes in the sperm epigenome.     

Developmental origins of transgenerational sperm DNA methylation epimutations following ancestral DDT exposure

Epigenetic alterations in the germline can be triggered by a number of different environmental factors from diet to toxicants. These environmentally induced germline changes can promote the epigenetic transgenerational inheritance of disease and phenotypic variation. In previous studies, the pesticide DDT was shown to promote the transgenerational inheritance of sperm differential DNA methylation regions (DMRs), also called epimutations, which can in part mediate this epigenetic inheritance. In the current study, the developmental origins of the transgenerational DMRs during gametogenesis have been investigated. Male control and DDT lineage F3 generation rats were used to isolate embryonic day 16 (E16) prospermatogonia, postnatal day 10 (P10) spermatogonia, adult pachytene spermatocytes, round spermatids, caput epididymal spermatozoa, and caudal sperm. The DMRs between the control versus DDT lineage samples were determined at each developmental stage. The top 100 statistically significant DMRs at each stage were compared and the developmental origins of the caudal epididymal sperm DMRs were assessed. The chromosomal locations and genomic features of the different stage DMRs were analyzed. Although previous studies have demonstrated alterations in the DMRs of primordial germ cells (PGCs), the majority of the DMRs identified in the caudal sperm originated during the spermatogonia stages in the testis. Interestingly, a cascade of epigenetic alterations initiated in the PGCs is required to alter the epigenetic programming during spermatogenesis to obtain the sperm epigenetics involved in the epigenetic transgenerational inheritance phenomenon.     

Plastics Derived Endocrine Disruptors (BPA,DEHP and DBP) Induce Epigenetic Transgenerational Inheritance of Obesity,Reproductive Disease and Sperm Epimutations

Environmental compounds are known to promote epigenetic transgenerational inheritance of adult onset disease in subsequent generations (F1–F3) following ancestral exposure during fetal gonadal sex determination. The current study was designed to determine if a mixture of plastic derived endocrine disruptor compounds bisphenol-A (BPA), bis(2-ethylhexyl)phthalate (DEHP) and dibutyl phthalate (DBP) at two different doses promoted epigenetic transgenerational inheritance of adult onset disease and associated DNA methylation epimutations in sperm. Gestating F0 generation females were exposed to either the “plastics” or “lower dose plastics” mixture during embryonic days 8 to 14 of gonadal sex determination and the incidence of adult onset disease was evaluated in F1 and F3 generation rats. There were significant increases in the incidence of total disease/abnormalities in F1 and F3 generation male and female animals from plastics lineages. Pubertal abnormalities, testis disease, obesity, and ovarian disease (primary ovarian insufficiency and polycystic ovaries) were increased in the F3 generation animals. Kidney and prostate disease were only observed in the direct fetally exposed F1 generation plastic lineage animals. Analysis of the plastics lineage F3 generation sperm epigenome previously identified 197 differential DNA methylation regions (DMR) in gene promoters, termed epimutations. A number of these transgenerational DMR form a unique direct connection gene network and have previously been shown to correlate with the pathologies identified. Observations demonstrate that a mixture of plastic derived compounds, BPA and phthalates, can promote epigenetic transgenerational inheritance of adult onset disease. The sperm DMR provide potential epigenetic biomarkers for transgenerational disease and/or ancestral environmental exposures.     

Understanding transgenerational epigenetic inheritance via the gametes in mammals

It is known that information that is not contained in the DNA sequence - epigenetic information - can be inherited from the parent to the offspring. However, many questions remain unanswered regarding the extent and mechanisms of such inheritance. In this Review, we consider the evidence for transgenerational epigenetic inheritance via the gametes, including cases of environmentally induced epigenetic changes. The molecular basis of this inheritance remains unclear, but recent evidence points towards diffusible factors, in particular RNA, rather than DNA methylation or chromatin. Interestingly, many cases of epigenetic inheritance seem to involve repeat sequences.