利用分子量阵列平台进行特定序列甲基化分析的方法探讨

目的:探讨利用分子量阵列平台进行特定序列甲基化分析的方法。方法:通过对不同扩增条件和扩增效率及不同条件处理的质谱分析比较了MassArray平台进行甲基化分析的特点。结果:本研究通过与重亚硫酸盐测序结果比较证实,MassArray分子量阵列技术平台能够反映甲基化修饰的真实水平;通过不同条件下PCR扩增效率与甲基化分析的结果,发现扩增效率是制约MassArray分子量阵列技术平台甲基化分析的关键因素,而产物的放置时间和不同的处理没有明显影响甲基化分析。结论:Mas-sArray甲基化分析平台是高效快速检测甲基化修饰的平台,在使用过程中应该根据实际的实验条件,进行合理的质控。     

Hi-Meth：特定位点DNA甲基化高通量检测平台

胞嘧啶甲基化是DNA表观遗传修饰的主要类型之一,在维持正常细胞功能和调控基因表达中具有重要作用。重亚硫酸盐测序法(bisulfite sequencing PCR,BSP)是特异性位点DNA甲基化检测的通用方法,能明确目的片段中每一个CpG位点的甲基化状态,但此方法需要大量的单克隆测序,操作过程较繁琐、成本昂贵。因此,开发准确、高效、便捷的DNA甲基化检测技术对提升表观遗传研究效率具有重要意义。基于本课题组开发的高通量突变类型检测平台Hi-TOM (high-throughput tracking of mutations),我们进一步建立了特定位点DNA甲基化高通量检测平台Hi-Meth (high-throughput detection of DNA methylation)。DNA样品通过重亚硫酸盐处理之后,仅需一轮PCR扩增即可通过Hi-Meth平台获得特定位点DNA甲基化分析结果。利用Hi-Meth平台,对水稻不同基因启动子区域进行了DNA甲基化检测分析,并与基于BSP方法获得的结果进行了比较。结果表明,Hi-Meth策略与BSP策略检测结果基本一致。而且通过Hi-Meth平台可以更准确、便捷地获得特异性位点DNA甲基化分析结果。综上所述,Hi-Meth为特定DNA区域提供了重要的甲基化检测平台,对表观遗传研究具有重要意义。     

FHIT基因在宫颈癌细胞中的表达及其甲基化调控

目的：分析FHIT基因在宫颈癌细胞中表达情况以及甲基化的调控情况。方法：对RJC-1、SiHa、CS1213以及C4-1细胞进行培养,提取这些细胞的DNA并经过亚硫酸氢盐修饰,进行PCR反应和产物的检测。分析FHIT基因在宫颈癌细胞中表达情况以及甲基化的调控情况。结果：RJC-1、CS1213细胞仅有甲基化引物扩增出了目的条带,为完全甲基化状态。其他细胞则是甲基特异性引物与非甲基特异性引物共同扩增出73bp的目的条带,其状态为甲基化杂合性。通过5-aza-CdR处理细胞后,通过实时定量PCR检测FHIT mRNA的表达,显示处理后各种细胞中的FHIT mRNA的表达升高。结论：FHIT基因的甲基化是其表达下调的重要机制之一,是临床研究宫颈癌细胞的重要方向之一。     

叶酸缺乏对小鼠胚胎干细胞Nespas DMR区甲基化修饰的影响

目的：探讨叶酸缺乏对小鼠胚胎干细胞（ESCs）中Nespas差异甲基化区域（Differentially Methylated Region,DMR）甲基化修饰的影响以及叶酸浓度与甲基化水平的关系。方法：多种不同浓度叶酸处理小鼠ESCs,化学发光免疫分析法检测ESCs细胞内叶酸浓度。利用MassARRAY技术平台检测三种不同叶酸浓度处理后的ESCs中Nespas DMR启动子区,外显子区和内含子区甲基化修饰状态,并且分析Nespas DMR启动子区,外显子区和内含子区甲基化水平与叶酸浓度之间的关系。结果：无叶酸组（FF）小鼠ESCs细胞内叶酸浓度显著低于低叶酸组（FD）与正常叶酸组（FN）（P〈0.05）。Nespas DMR中启动子区、外显子区以及内含子区甲基化水平在FF组显著低于FD和FN组（P〈0.05）,并且Nespas DMR中启动子区以及内含子区甲基化水平与叶酸浓度存在显著的正相关（P〈0.05）。结论：叶酸缺乏影响小鼠ESCs中Nespas DMR区甲基化修饰的建立。     

叶酸缺乏对小鼠胚胎干细胞Nespas DMR 区甲基化修饰的影响

目的：探讨叶酸缺乏对小鼠胚胎干细胞（ESCs）中Nespas 差异甲基化区域（Differentially Methylated Region, DMR）甲基化修 饰的影响以及叶酸浓度与甲基化水平的关系。方法：多种不同浓度叶酸处理小鼠ESCs,化学发光免疫分析法检测ESCs 细胞内叶 酸浓度。利用MassARRAY 技术平台检测三种不同叶酸浓度处理后的ESCs中Nespas DMR 启动子区,外显子区和内含子区甲基 化修饰状态,并且分析Nespas DMR 启动子区,外显子区和内含子区甲基化水平与叶酸浓度之间的关系。结果：无叶酸组（FF）小鼠 ESCs 细胞内叶酸浓度显著低于低叶酸组（FD）与正常叶酸组（FN）（P<0.05）。Nespas DMR 中启动子区、外显子区以及内含子区甲 基化水平在FF组显著低于FD 和FN 组（P<0.05）,并且Nespas DMR中启动子区以及内含子区甲基化水平与叶酸浓度存在显著 的正相关（P<0.05）。结论：叶酸缺乏影响小鼠ESCs 中Nespas DMR 区甲基化修饰的建立。     

甲基化特异性PCR检测FMR1 和XIST基因甲基化实验方法的建立

建立一种快速、灵敏的检测脆性X智障基因（Fragile X mental retardation, FMR1）和X染色体失活基因（X chromosome inactivation,XIST）甲基化的方法,用亚硫酸氢钠和对苯二酚对基因组DNA进行脱氨基修饰。以修饰后的DNA为模板,用两套不同的引物对：1对甲基化特异性引物和1对非甲基化特异性引物扩增FMR1基因（CGG）n重复序列区、FMR1 和XIST 基因的启动子区。PCR产物进一步克隆、测序。以亚硫酸氢钠和对苯二酚脱氨基修饰后的DNA为模板,进行PCR扩增后的产物与预期基因目的基因片段大小相符合,无非特异性扩增产物。测序结果表明,FMR1、XIST基因中的非甲基化的C碱基转变为U碱基,而CpG岛被甲基化的C碱基不改变。成功地建立了检测FMR1、XIST甲基化的方法,为实验室诊断脆性X综合征提供了新的方法。     

不同水陆环境中喜旱莲子草甲基化调控因子表达水平和差异表达基因启动子区甲基化状态分析

DNA甲基化是一种重要的表观遗传调控方式,参与对植物生长发育的调控,并在植物逆境胁迫响应中发挥作用。DNA甲基化的建立和维持是胞嘧啶甲基转移酶、染色质重塑酶、组蛋白修饰因子和去甲基化因子等协同作用的结果,环境胁迫能诱导植物体内DNA甲基化状态改变,进而改变基因表达水平和式样,影响植物的适应性。喜旱莲子草是一种恶性入侵植物,种内遗传多样性很低,主要依靠极强的表型可塑性侵占不同水陆生境。对克隆繁殖的喜旱莲子草个体进行不同时间的淹水处理,并用定量PCR方法检测16个DNA甲基化调控基因在不同处理条件下的表达水平和变化趋势,发现其中13个基因在不同处理时间点的表达水平有明显变化,且在淹水植株中多数基因在处理前期被强烈诱导上调表达。运用亚硫酸氢钠测序技术对两个在不同水陆条件下明显差异表达基因(Contig942和Contig23336)的上游启动子区甲基化动态进行分析,发现启动子区多个胞嘧啶位点的甲基化修饰状态在不同水陆条件下及淹水处理的不同时期呈现快速且可逆的动态变化,可能影响这些基因在不同环境条件下的表达水平。本研究结果能帮助了解喜旱莲子草表型可塑性变异和适应性发生的分子机理。     

PIK3CA基因突变的MassARRAY分子量阵列分析

目的：利用MassARRAY分子量阵列分析系统检测胃癌组织PIK3CA基因突变。方法：从胃癌石蜡包埋组织中提取基因组,PCR反应扩增目的基因片段,MassARRAY分子量阵列分析系统检测PIK3CA基因突变;焦磷酸测序验证检测结果。结果：中国西部地区144例胃癌组织样本中PIK3CA_E542K（1624G〉A）突变携带率为77．6％,PIK3C_LIE545K（1633G〉A）突变携带率为84％。MassARRAY分子量阵列分析系统检测结果与焦磷酸测序结果达到100％吻合。结论：建立了MassARRAY分子量阵列分析系统检测基因突变的方法,初步建立了中国西北地区汉族人群胃癌组织PIK3CA基因PIK3CA_E542K（1624G〉A）PIK3CA_E545K（1633G〉A）位点突变频数。     

NaIO_4氧化–深度测序技术的优化用于检测微量RNA样品中小RNA 3′末端甲基化修饰

2′-O-甲基化是存在于多种小RNA 3′末端的修饰,具有重要的生物学功能。目前高通量研究小RNA 3′末端2′-O-甲基化的方法主要是NaIO_4氧化处理结合小RNA深度测序,但该方法需要3μg总RNA,难以用于研究少量细胞中小RNA的3′末端甲基化修饰。该研究通过调整NaIO_4氧化处理的条件以及测试有无甘油终止氧化反应对小RNA文库构建的影响,优化了适用于微量RNA的氧化条件,实现对10 ng小鼠睾丸样本总RNA中的小RNA 3′末端甲基化修饰的深度测序检测,建立了用于检测微量RNA样品中小RNA 3′末端甲基化修饰的方法,为检测少量细胞中小RNA的3′末端甲基化修饰提供了有效方法。     

高保真酶特异性检测大鼠SNP基因型新方法

目的应用高保真酶（Pfu）和3’末端修饰引物在单管双向等位基因特异性扩增（SB-ASA）中区分SNP基因型,建立高保真酶特异性检测SNP基因型的新方法。方法选取近交系大鼠SNP位点,以RS8149053为例,设计两个外部引物和两个等位基因特异性引物,四引物3’末端进行硫代磷酸化修饰,应用高保真聚合酶（Pfu）进行特异性扩增,扩增结果测序验证其可靠性。结果在RS8149053 SNP位点（C/T）上,等位基因型CC扩增出179 bp目的片段,基因型TT扩增出597 bp目的片段,基因型不同则扩增出分子量不同的片段,目的条带测序结果与Rat Genome Database数据库基因型结果一致,高保真酶扩增结果稳定且特异性强。结论高保真酶等位基因特异性扩增技术能有效降低假阳性率,是一种快速、特异的SNP基因分型新方法。     

High throughput SNP genotyping with two mini-sequencing assays

Single nucleotide polymorphisms (SNPs) are veryimportant markers that can be used in many areas such asevolutionary genetics [1], disease-susceptibility genes[2,3], personalized medicine and forensics. Only about20% of human polymorphisms are length polymorphisms,whereas about 80% of human polymorphisms areSNPs. Kruglyak et al. [4] reported that there were about11,000,000 SNPs in the world population. There are many kinds of SNP genotyping technology[5,6]: some are only suitable to low …     

Methylation-sensitive high resolution melting (MS-HRM): a new approach for sensitive and high-throughput assessment of methylation

In this article, we show that high resolution melting analysis (HRM) is a sensitive and specific method for the detection of methylation. Methylated DNA and unmethylated DNA acquire different sequences after bisulphite treatment resulting in PCR products with markedly different melting profiles. We used PCR to amplify both methylated and unmethylated sequences and assessed HRM for the determination of the methylation status of the MGMT promoter region. Reconstruction experiments showed that MGMT methylation could be detected at levels as low as 0.1%. Moreover, MS-HRM allows for estimation of the methylation level by comparing the melting profiles of unknown PCR products to the melting profiles of PCR products derived from standards with a known unmethylated to methylated template ratio. We used MS-HRM for the analysis of eight cell lines of known methylation status and a panel of colorectal cancer specimens. The simplicity and high reproducibility of the MS-HRM protocol makes MS-HRM the method of choice for methylation assessment in many diagnostic and research applications.     

A reassessment of semiquantitative analytical procedures for DNA methylation: comparison of bisulfite- and HpaII polymerase-chain-reaction-based methods

Two techniques in particular are used to study site-specific DNA methylation: genomic sequencing after bisulfite modification and polymerase chain reaction after digestion by a methylation-sensitive endonuclease (usually HpaII). Only the former methodology assesses the methylation status of all the cytosine residues in the DNA sequence, but it is so complex and time consuming that the latter procedure, though limited to the restriction sites recognized by the endonuclease(s) used, is often preferred at least for a first analysis. In this work we investigate differences between these two techniques in the assessment of DNA methylation and offer some suggestions on how to avoid uncorrected results. Although there is substantial accordance in the results obtained using these different techniques, we observed a general overestimate for methylation levels above 30% and a general underestimate for methylation levels below this value using the HpaII/PCR technique in the study of methylation of the 5'-flanking region of the mouse myogenin gene in cultured muscle cells and mouse tissues.     

Methylation of p16 and Ras association domain family protein 1a during colorectal malignant transformation

Accurate assessment of gene methylation in formalin-fixed, paraffin-embedded archived tissue (FF-PEAT) by microdissection remains challenging because the tissue volume is small and DNA is damaged. In addition, methods for methylation assessment, such as methylation-specific PCR (MSP), require sodium bisulfite modification (SBM) on purified DNA, which causes major loss of DNA. On-slide SBM, in which DNA is modified in situ before isolation of tumor cells, eliminates DNA purification steps and allows histology-oriented assessment of gene methylation. This study describes a protocol and use of on-slide SBM using 20 FF-PEAT of colorectal cancers with intratumoral adenoma components to detect accumulation of gene methylation during colorectal malignant transformation. Deparaffinized tissue sections were incubated in sodium bisulfite solution for 8 hours at 60 degrees C, stained with hematoxylin, and then microdissected. Proteinase K lysate was directly used as a template in subsequent PCR. Using on-slide SBM, 282-bp-long bisulfite direct sequencing was possible. Yield of modified DNA was 2.6-fold greater than standard SBM on average. The mean conversion rate was 97%, and false-positive or false-negative results were not observed in subsequent MSP. Intratumoral heterogeneity by accumulation of p16 and Ras association domain family protein 1a methylation during malignant transformation were shown by MSP comparing cancer with adenoma parts within a single section. On-slide SBM is applicable in most methylation studies using FF-PEAT. It allows detailed, intratumoral analysis of methylation heterogeneity within solid tumors. On-slide SBM will significantly improve our approach and understanding of epigenetic events in minimal disease and the carcinogenic process.     

Accurate quantification of DNA methylation using combined bisulfite restriction analysis coupled with the Agilent 2100 Bioanalyzer platform

DNA methylation is the best-studied epigenetic modification and describes the conversion of cytosine to 5-methylcytosine. The importance of this phenomenon is that aberrant promoter hypermethylation is a common occurrence in cancer and is frequently associated with gene silencing. Various techniques are currently available for the analysis of DNA methylation. However, accurate and reproducible quantification of DNA methylation remains challenging. In this report, we describe Bio-COBRA (combined bisulfite restriction analysis coupled with the Agilent 2100 Bioanalyzer platform), as a novel approach to quantitative DNA methylation analysis. The combination of a well-established method, COBRA, which interrogates DNA methylation via the restriction enzyme analysis of PCR-amplified bisulfite treated DNAs, with the Bioanalyzer platform allows for the rapid and quantitative assessment of DNA methylation patterns in large sample sets. The sensitivity and reproducibility of Bio-COBRA make it a valuable tool for the analysis of DNA methylation in clinical samples, which could aid in the development of diagnostic and prognostic parameters with respect to disease detection and management.     

一种快速高效的全基因组甲基化CpG岛富集方法的建立

高甲基化的CpG岛所致基因表观遗传学转录失活已经成为肿瘤表观基因组学研究的重要内容。现在已有很多检测CpG岛甲基化的方法,但由于各自的局限,还没有建立一种能快速在全基因组水平上进行甲基化CpG岛的富集方法。本研究利用甲基化结合蛋白MBD2b具有特异性结合甲基化DNA的特性, 建立了一种基于DNA免疫共沉淀技术的全基因组甲基化CpG岛的富集方法。在大肠杆菌中表达重组的GST-MBD2b蛋白,通过Glutathione Sepharose 4B对重组蛋白进行纯化,制备成亲和层析柱,利用在不同的盐离子强度下甲基化DNA和非甲基化DNA的结合能力不同,对甲基化DNA进行富集。用甲基化酶SssI处理过的DNA片段与非甲基化DNA片段进行富集效率的检测,发现0.5M KCl的浓度是甲基化DNA片段和非甲基化DNA片段得以分开的临界条件。样品的富集效率用Real Time PCR进行检测。结果表明,这种方法能够实现对全基因组甲基化DNA的有效富集且最高的富集倍数可达到100多倍。富集到的甲基化DNA可以进行后续的定量PCR, DNA测序和全基因组芯片的分析等工作,为大规模分析全基因组CpG 岛甲基化的改变奠定了基础。     

Covalent genomic DNA modification patterns revealed by denaturing gradient gel blots

Several approaches are used to survey genomic DNA methylation patterns, including Southern blot, PCR, and microarray strategies. All of these methods are based on the use of methylation-sensitive isoschizomer restriction enzyme pairs and/or sodium bisulfite treatment of genomic DNA. They have many limitations, including PCR bias, lack of comprehensive assessment of methylated sites, labor-intensive protocols, and/or the need for expensive equipment. Since the presence of 5-methylcytosine alters the melting properties of DNA molecules, denaturing gradient gel blots (DGG blots), a gene scanning technique which detects differences in DNA fragments based on differential melting behavior, were used to examine genomic modification patterns in normal tissues. Variations in melting behavior, observed as restriction fragment melting polymorphisms (RFMPs), were detected in various tissues from single individuals in all human and mouse genes tested, suggesting the presence of widespread differential cell type-specific DNA modification. Additional DGG blot experiments comparing genomic DNA to unmethylated cloned DNA suggested that the melting variants were most likely caused by DNA methylation differences. The results suggest that the use of DGG blots can provide a comprehensive and rapid method for comparing complex in vivo DNA modification patterns in normal adult somatic cells.