玉米杂交种及其亲本基因组DNA胞嘧啶甲基化水平研究

基因组DNA甲基化对基因表达起着重要的调控作用.本研究采用MSAP方法,对2个玉米杂交种及其相应亲本DNA 5'-CCG G位点胞嘧啶的甲基化水平进行分析,比较了2个玉米杂交种与其相应亲本的甲基化类型与差异.研究发现,2个玉米杂交种Mo17×Suwan 5和Suwan 1×太3221的F1代的甲基化敏感扩增多态性(MASP)比率分别为39.1%和40.1%,均略低于其相应的双亲(39.8%和39.7%、44.6%和43.2%).2个杂交种的全甲基化(双链CmCGG)率分别为24.4%和23.3%,而其相应亲本Mo17、Suwan 5、Suwan 1和太3221分别为17.1%、24.4%、24.6%和21.6%.4个玉米亲本的MASP比率变化范围为39.7%～44.6%,平均为41.8%,全甲基化比率为17.1%～24.6%,平均为21.9%.杂交种与其相应亲本比较有4种类型的变化A型,F1与其亲本甲基化模式相同;B型,去甲基化;C型,超甲基化;D型,次甲基化.杂交种F1代DNA的甲基化模式与其双亲比较,发生了较大的改变与调整.F1代基因组的杂合性与基因组DNA甲基化模式的重新调整有关.     

运用MSAP技术测定谷子基因组DNA胞嘧啶甲基化水平

DNA甲基化是真核生物一种重要的表观修饰形式。为了探讨谷子基因组DNA胞嘧啶甲基化的水平和模式,以谷子Setaria italica的两个品种朝谷58号和豫谷1号为实验材料,利用Eco RⅠ和HpaⅡ/MspⅠ双酶切建立适合于谷子基因组的甲基化敏感扩增多态性(MSAP)分析体系。结果表明,从100对MSAP选扩引物中,筛选出32对MSAP引物组合,在朝谷58号和豫谷1号中分别扩增产生1 615、1 482条清晰可辨且可重复的DNA条带,其中包括3种类型的甲基化条带,朝谷58号和豫谷1号的基因组中CCGG序列胞嘧啶甲基化水平分别为6.93%和8.77%。这种谷子不同品种间甲基化水平和分布位点的差异为从表观遗传学的角度培育新品种提供了初步的理论依据和参考。     

加勒比松种源苗期DNA甲基化多样性分析

为了解加勒比松(Pinus caribaea)种源的遗传多样性,利用甲基化敏感扩增多态性技术对加勒比松3个变种17个种源的DNA甲基化多样性进行了研究。结果表明,56对引物组合共扩增出425条谱带,其中多态性谱带422条,多态性百分率为99.25%。加勒比松种源幼苗半甲基化比率比全甲基化比率稍高,洪都拉斯加勒比松、古巴加勒比松和巴哈马加勒比松的DNA甲基化率分别为22.39%、22.29%和22.35%,差异不显著。加勒比松的DNA序列遗传多样性(H=0.4376)高于DNA甲基化多样性(H=0.3274),Mantel检验表明,基因组遗传变异与表观遗传变异不存在相关性(r=-0.171,P=0.16)。表观聚类与遗传聚类间存在较大差异,两种聚类分析结果均未将3个加勒比松变种分开。这表明加勒比松变种间的表观遗传变异极为丰富,能为加勒比松遗传改良提供优良种质资源。     

大花蕙兰子房授粉前后基因组DNA胞嘧啶甲基化状态的MSAP分析

应用甲基化敏感扩增多态性(Metyhfion sensitive amplified polymorphism,MSAP)技术分析了大花蕙兰(Cymbidium hybridium)授粉前后子房DNA甲基化状态的变化(甲基化水平和甲基化差异模式).采用72对引物进行选择性扩增,共得到5892条带,其中748条带为甲基化多态性带.结果显示DNA甲基化在大花蕙兰子房发育过程中发牛频繁,从授粉前后子房的总扩增位点甲基化水平(14%和11.4%)和全甲基化率(9.5%和7.8%)来看,授粉后都略低于未授粉子房,表明子房在授粉后的发育过程中在某些位点发生了去甲基化.除甲基化水平有变化外,大花蕙兰子房授粉前后的DNA甲幕化模式也存在较大差异,共榆测到14种带型,分为两大类(Ⅰ和Ⅱ型).其中,授粉前后DNA甲基化状态保持不变的位点较少,只占25.6%,归为Ⅰ型;大部分榆测位点(占74.4%,归为Ⅱ型)的DNA甲基化模式在授粉前后存在显著差异.上述结果表明,大化蕙兰子房发育过程中以DNA甲基化为代表的表观遗传调控起重要作用.本研究的开展将促进对与大花蕙兰子房发育相关的甲基化差异片段及受DNA甲基化调控的关键基因的克隆,进而为从表观遗传学这一新角度揭示大花蕙兰子房发育的分子机制奠定基础.     

大花蕙兰子房授粉前后基因组DNA 胞嘧啶甲基化状态的MSAP 分析

应用甲基化敏感扩增多态性(Methylation sensitive amplified polymorphism, MSAP) 技术分析了大花蕙兰( Cymbidium hybridium) 授粉前后子房DNA 甲基化状态的变化(甲基化水平和甲基化差异模式) 。采用72 对引物进行选择性扩增, 共得到5892 条带, 其中748 条带为甲基化多态性带。结果显示DNA 甲基化在大花蕙兰子房发育过程中发生频繁, 从授粉前后子房的总扩增位点甲基化水平(14%和11. 4%) 和全甲基化率(9.5%和7.8% ) 来看, 授粉后都略低于未授粉子房, 表明子房在授粉后的发育过程中在某些位点发生了去甲基化。除甲基化水平有变化外, 大花蕙兰子房授粉前后的DNA 甲基化模式也存在较大差异, 共检测到14 种带型, 分为两大类( Ⅰ 和Ⅱ 型)。其中, 授粉前后DNA 甲基化状态保持不变的位点少, 只占25.6% , 归为Ⅰ型; 大部分检测位点( 占74.4% , 归为Ⅱ型) 的DNA 甲基化模式在授粉前后存在显著差异。上述结果表明, 大花蕙兰子房发育过程中以DNA 甲基化为代表的表观遗传调控起重要作用。本研究的开展将促进对与大花蕙兰子房发育相关的甲基化差异片段及受DNA 甲基化调控的关键基因的克隆, 进而为从表观遗传学这一新角度揭示大花蕙兰子房发育的分子机制奠定基础。     

甘露醇对拟南芥基因组DNA甲基化的影响

以拟南芥（Arabidopsis thaliana）为材料,研究不同浓度甘露醇处理下拟南芥幼苗生长发育及其基因组DNA的甲基化水平和变化模式。结果表明,用50、100、150和200mmol·L―1甘露醇处理拟南芥种子会对拟南芥幼苗的形态特征和生长态势产生影响;甲基化敏感扩增多态性（methylation-sensitive amplification polymorphism,MSAP）分析表明,经50、100、150和200mmol·L―1甘露醇处理后,基因组DNA甲基化比率分别为17.75%、21.15%、15.49%和46.10%。甘露醇处理使拟南芥发生基于DNA甲基化水平和模式改变的表观遗传变异。与对照相比,在50、100、150和200mmol·L-1甘露醇处理下拟南芥幼苗基因组DNA的甲基化和去甲基化比率分别为5.78%、15.48%、10.71%、33.73%及10.98%、5.36%、8.33%、7.69%。由此推测,5-甲基胞嘧啶百分含量随着甘露醇胁迫的增强而发生不同程度的变化。     

马哈利樱桃矮化砧的DNA甲基化水平及模式分析

该研究利用MSAP技术,对25株矮化马哈利樱桃和25株半矮化马哈利樱桃进行甲基化水平和模式分析,以探讨其矮化的表观性状与其基因组甲基化修饰的关系。结果表明:(1)从64对引物中筛选出15对引物,在半矮化组中共扩增4 577个条带,其中半甲基化336个,全甲基化1 274个;在矮化组中共扩增4 444个条带,其中半甲基化349个,全甲基化1 383个;t检验和方差分析表明,矮化组与半矮化组在总甲基化水平和全甲基化水平上差异极显著,在半甲基化水平上差异显著,矮化组甲基化水平高于半矮化组。(2)半矮化组单态性位点23个,多态性位点136个;矮化组单态性位点17个,多态性位点142个,表明矮化组多态性高于半矮化组。(3)多态性类型分析表明,矮化组出现A4类型的频率较半矮化组高,A2类型的频率较半矮化组低,即矮化组中发生超甲基化的位点多于半矮化组,且‘马哈利’基因组甲基化多态性位点主要发生在双链内侧甲基化位点以及超甲基化位点上。研究认为,马哈利樱桃矮化和半矮化的基因组甲基化水平及模式存在差异,马哈利砧木的矮化性状与其基因组甲基化修饰有关。     

不同生理年龄毛竹DNA甲基化的MSAP分析

为分析竹子年龄变化与基因组DNA甲基化之间的相关性,以5年、31年和>60年起源(从种子萌发年龄算起)的毛竹当年生叶片为材料,采用35对引物对其进行MSAP检测。结果表明:3个年龄段的总甲基化率和全甲基化率分别为24.44%、28.21%、32.12%和16.57%、19.41%、21.23%;发生DNA甲基化的变异位点为52.3%,去甲基化变异位点为10.3%。可以看出,随着年龄的增加,毛竹基因组DNA甲基化敏感多态性呈上升趋势。总甲基化率单因素方差分析的结果表明相同年龄的毛竹个体间没有差异(P=0.307>0.05),而不同年龄间的差异达极显著水平(P<0.001)。同时,对所用引物组合进行分析后发现有6对引物(E3/HM2、E3/HM6、E3/HM7、E4/HM5、E4/HM6和E5/HM5)扩增出的位点与总趋势显著相关,为进一步开展深入研究奠定基础。     

土霉素胁迫下拟南芥基因组DNA甲基化的MSAP分析

以拟南芥 (Arabidopsis thaliana)为材料,研究不同土霉素浓度下拟南芥幼苗生长发育及基因组DNA的甲基化水平和变化模式。结果表明,3、5、7\,9 μmol/L土霉素胁迫对拟南芥幼苗的根长和株高有显著抑制作用;但对拟南芥幼苗的侧根数量有显著促进作用。甲基化敏感扩增多态性 (methylation-sensitive amplification polymorphism, MSAP)分析表明,经3、5、7\,9 μmol/L土霉素处理后基因组DNA甲基化比率分别为17.91%、12.50%、11.81%和14.62%,均低于对照 (18.18%)。结果表明,拟南芥经土霉素胁迫后存在基于 DNA甲基化水平和模式改变的表观遗传变异,5-甲基胞嘧啶百分含量的变化无统一趋势或规律。与对照相比,3、5、7\,9 μmol/L土霉素胁迫下拟南芥幼苗基因组DNA的甲基化和去甲基化分别为13.29%、9.22%、8.03%、12.59%和2.80%、4.26％、5.11%、4.90％。由此推测,DNA甲基化可能是植物适应土霉素胁迫机制的机制之一。     

低剂量重离子辐射对水稻种子和幼苗DNA甲基化的影响

为了研究低剂量重离子辐射对植物产生的表观遗传学效应,采用高传能线密度（62．2keV／μm）和低剂量（2Gy）的放射性束流^12C对水稻（Oryzasativa,japonica）的干种子和幼苗进行辐射。采用甲基化敏感限制性酶切多态性分析（MSAP）的方法对材料基因组CCGG位点的甲基化状态进行检测。共选用12对选择性引物扩增了共800个条带,其中有65个条带（8．13％）在种子辐射后发现呈多态性,而只有10个条带（1．3％）在幼苗辐射后发现呈多态性。统计学分析显示高能量低剂量的重离子对水稻种子和幼苗的基因组甲基化状态都产生了影响,而且种子受到辐射后产生的甲基化改变明显高于幼苗（P=0．011）。另外,甲基化和去甲基化变化类型的分析也表明种子和幼苗辐射后发生甲基化变化的趋势也不相同。     

湿加松无性系表型遗传多样性研究

以35个湿加松（Pinus elliottii×P.caribaea Morelet var.hondurensis）无性系为试验材料,对其8个表型性状进行相关性分析、聚类分析及主成分分析研究,并深入探讨了遗传多样性水平,为湿加松无性系利用及良种选育提供科学依据。结果表明：（1）生长性状变异系数介于12.31~29.28%,均值为22.90%;多样性指数介于1.61~1.80,均值为1.69。形质性状变异系数介于13.34~47.25%,均值为26.86%;多样性指数介于1.50~1.94,均值为1.77。表明湿加松无性系遗传变异较为丰富,遗传多样性水平较高。（2）8对表型性状两两间有11对呈极显著正相关,5对呈显著正相关。选定材积为该材料育种选择的主要指标,其次为树高。（3）采用系统聚类法在欧式距离为12的时候将35个无性系分为6大类群,部分来源相同或父本相同的聚为一类,说明它们在表型上的变异较小。（4）针对8个表型性状做主成分分析提取了3个主成分,累积贡献率达86.00%,主要代表了6个性状,以此来表达所有供试材料的综合变异情况。     

Genetic maps for Pinus elliottii var. elliottii and P. caribaea var. hondurensis using AFLP and microsatellite markers

Genetic maps for individual Pinus elliottii var. elliottii and P. caribaea var. hondurensis trees were generated using a pseudo-testcross mapping strategy. A total of 329 amplified fragment length polymorphic (AFLP) and 12 microsatellite markers were found to segregate in a sample of 93 interspecfic F(1) progeny. The male P. caribaea var. hondurensis parent was more heterozygous than the female P. elliottii var. elliottii parent with 19% more markers segregating on the male side. Framework maps were constructed using a LOD 5 threshold for grouping and interval support threshold of LOD 2. The framework map length for the P. elliottii var. elliottii megagametophyte parent (1,170 cM Kosambi; 23 linkage groups) was notably smaller than the P. caribaea var. hondurensis pollen parent (1,658 cM Kosambi; 27 linkage groups). The difference in map lengths was assumed to be due to sex-related recombination variation, which has been previously reported for pines, as the difference in map lengths not be accounted for by the larger number of markers mapping to the P. caribaea var. hondurensis parent - 109 compared with 78 in P. elliottii var. elliottii parent. Based on estimated genome sizes for these species, the framework maps for P. elliottii var. elliottii and P. caribaea var. hondurensis covered 82% and 88% of their respective genomes. The pseudo-testcross strategy was extended to include AFLP and microsatellite markers in an intercross configuration. These comprehensive maps provided further genome coverage, 1,548 and 1,828 cM Kosambi for P. elliottii var. elliottii and P. caribaea var. hondurensis, respectively, and enabled homologous linkage groups to be identified in the two parental maps. Homologous linkage groups were identified for 11 out of 24 P. elliottii var. elliottii and 10 out of 25 P. caribaea var. hondurensis groups. A higher than expected level of segregation distortion was found for both AFLP and microsatellite markers. An explanation for this segregation distortion was not clear, but it may be at least in part due to genetic mechanisms for species isolation in this wide cross.     

Methylation-dependent fragment separation: direct detection of DNA methylation by capillary electrophoresis of PCR products from bisulfite-converted genomic DNA

Fundamental to understanding the role of cytosine (C) methylation in genomic DNA (gDNA) is the need for robust analysis methods to determine the location and degree of this modification. We report a novel method for methylation detection by denaturing capillary electrophoresis (CE) using standard fragment analysis conditions. Bisulfite treatment of gDNA will selectively deaminate C but not 5-methylcytosine (5mC). Amplicons generated from bisulfite-converted gDNA are analyzed immediately after PCR using a 6-carboxy fluorescein (6-FAM) dye-labeled primer. The amplicons from methylated and unmethylated gDNA separate based solely on base composition due to the presence of multiple C versus thymine (T) differences. By direct detection of PCR amplicons following PCR using primers that anneal independent of methylation status, the overall workflow from gDNA sample input to data analysis is relatively simple. Furthermore, the same PCR product is suitable for additional analyses such as direct sequencing, cloning and sequencing, single-base extension, and post-PCR incorporation of a modified dCTP, the latter of which allows resolution of amplicons with as little as a single C/T difference. We show the utility of this novel CE detection assay by analyzing the hypermethylated region of the fragile-X FMR1 locus.     

Absence of global genomic cytosine methylation pattern erasure during medaka (Oryzias latipes) early embryo development

Two techniques were used to analyze global genomic 5-methyl cytosine methylation at CCGG sites of medaka embryo DNA. DNA was labeled by incorporation of microinjected radiolabeled deoxynucleotide into one-cell embryos. After Hpa II or Msp I digestion the radiolabeled DNA was fractionated in agarose gels and the distribution of label quantified throughout each sample lane to detect differences in fragment distribution. Alternately isolated DNA was digested with Hpa II or Msp I and the resulting generated termini end-labeled. The end-labeled digestion products were then analyzed for fragment distribution after gel fractionation. These techniques proved to be extremely sensitive, allowing comparison of genomic DNA methylation values from as few as 640 fish cells. The data suggest that in medaka embryos the vast majority (>90%) of genomic DNA is methylated at CCGG sites. Furthermore, these data support the conclusion that the extent of methylation at these sites does not change or changes very little during embryogenesis (from 16 cells to the hatchling). These data argue against active demethylation, or loss of methylation patterns by dilution, during the developmental stages between the one cell zygote and gastrulation. From a comparative viewpoint, these data may indicate that mammals and fishes methylate and demethylate their genomes in very different manners during development.     

Ultra-sensitive immunodetection of 5'methyl cytosine for DNA methylation analysis on oligonucleotide microarrays.

For the determination of methylation levels in genomic regulatory DNA sequences a high-sensitive assay for detecting 5'methyl-cytosines (5'mC) in non-bisulfite-treated DNA has been established. The system is designed for the application of immunofluorescence using a monoclonal antibody that specifically recognizes 5'mC in single-stranded DNA hybridized to oligonucleotide microarrays. For assay readout an ultra-sensitive fluorescence scanner with submicrometer resolution was used. To minimize autofluorescence 150-microm thin glass slides with an aldehyde-functionalized surface were developed. These methodological improvements allowed the detection of 5'mC in synthetic oligonucleotides hybridized to microarrays with atto molar analytical sensitivity. Using enzymatic fragmented genomic DNA from myeloid leukemia tumor cell lines differences in the methylation status of gene regulatory sequences for E-cadherin, p15/CDKN2b and p16/CDKN2a were demonstrated. Thus, this novel technique can potentially be used for DNA methylation analysis in various scientific fields.     

植物DNA甲基化及胁迫诱导的变异

DNA中碱基的化学修饰近年来一直是生命科学领域研究的热点之一。DNA甲基化是一种常见的表观遗传现象,它能在不改变DNA序列的前提下改变遗传表型。各种胁迫因素能诱导植物DNA甲基化产生变异,但其应答胁迫机制仍然未知。本文对植物DNA甲基化研究进展进行了综述,结合本课题组的研究结果,对7Li离子束注入、~(60)CO-γ射线诱变诱导产生的DNA甲基化变异进行了报道,以期为DNA甲基化可能参与涉及植物的表型可塑性提供一定的依据。     

Analysis of DNA methylation in cotton hybrids and their parents

The possible role of methylation in the performance of heterosis has been analyzed in many crops. To further study this possibility, we investigated both the differences in cytosine methylation patterns between cotton heterotic hybrids/nonheterotic hybrids and their parental lines and the change in methylation level from seedling stage to flowering stage by using the methylation-sensitive amplified polymorphism (MSAP) method. The results showed that the number of demethylation loci in highly heterotic hybrids was greater that in lowly heterotic hybrids, and the level of DNA cytosine methylation in cotton at the seedling stage is higher than that of the flowering stage. The altered methylation patterns at low-copy genomic regions can be confirmed by DNA gel blot analysis. A total of 39 fragments that showed different methylation patterns were cloned and sequenced. The methylation status of these genes was modified differentially in hybrid and parents, suggesting that these genes might play a role in the performance of heterosis. Published in Russian in Molekulyarnaya Biologiya, 2008, Vol. 42, No. 2, pp. 195–205. The text was submitted by the authors in English.     

环境因素对DNA甲基化的影响

在哺乳动物中, DNA甲基化是指在DNA 甲基转移酶(DNA-methyl transferase, DNMT)的作用下, 以S-腺苷甲硫氨酸提供甲基供体, 将其甲基转移到脱氧胞嘧啶环第5位碳原子形成甲基化脱氧胞嘧啶的共价修饰。DNA甲基化改变组蛋白和DNA之间的相互作用, 使染色质构象发生改变从而影响基因的表达, 总体来说DNA甲基化水平与基因的表达呈负相关。越来越多的报道证实, 环境因素可以影响表观遗传修饰, 其并没有涉及遗传信息的改变, 所以在一定范围内可以解释表型变化。文章围绕环境因素(温度、营养供给、异常化学因子、早期环境刺激和辐射等)对DNA甲基化产生的影响进行综述, 这些影响包括亲代和子代DNA甲基化的改变及子代行为和表型变化等方面, 以期进一步阐释环境因素与基因互作的关系。