沙棘H3K9乙酰化修饰全基因组分析

为了绘制沙棘H3K9乙酰化修饰图谱,确定H3K9乙酰化修饰所调控的基因,该实验通过Western blot验证抗体与组蛋白的结合能力和ChIP-seq验证抗体富集效率,获得全基因组范围内沙棘H3K9乙酰化修饰图谱和调控基因。实验结果表明,H3K9ac抗体与复合物具有较强的结合能力。对富集到的DNA片段进行高通量测序,分别获得2.2×10~7和3.6×10~7条原始序列;唯一比对序列广泛分布于沙棘基因组中,并且在结构基因中的两端具有明显的富集。对富集区进行峰的预测结果显示,共预测出1 011个峰;对峰所处部位基因进行功能预测结果发现,H3K9ac对于沙棘细胞代谢和信号转导基因的表达具有重要调控作用。沙棘片段化DNA的富集以及高通量测序结果证明,抗体能够用于研究沙棘的组蛋白修饰类型,并且绘制了沙棘第一张H3K9乙酰化修饰遗传图谱草图,鉴定出沙棘H3K9乙酰化修饰所调控的基因,为今后研究组蛋白修饰对沙棘基因表达的调控方式奠定了基础。     

基于ChIP-seq的差异组蛋白修饰区域的筛选

组蛋白修饰是在基因组水平上起到重要调控作用的表观遗传修饰,随着ChIP-Seq的广泛使用,高通量数据的积累,为从全基因组研究组蛋白修饰模式奠定了基础。但目前缺乏在多样本间筛选疾病相关的调控区域的方法,因而本文开发了一种多细胞系的差异筛选算法来识别差异组蛋白修饰区域。本文通过窗口移动法来估计组蛋白修饰水平,并根据信息熵理论定量各个细胞系之间的差异。基于随机背景来确定差异显著性阈值。利用此算法来筛选人类全基因组9个细胞系间H3K4me3差异的区域,结果显示这些区域显著富集在基因启动子上和其他重要的染色质状态上,且与先前人们发现的活性启动子染色质状态显著重叠。通过文献挖掘进一步证实了与白血病相关的基因组标记。这些结果表明基于熵的策略可有效地挖掘多细胞系间以及与疾病相关的差异组蛋白修饰。     

Stress‐associated H3K4 methylation accumulates during postnatal development and aging of rhesus macaque brain

Epigenetic modifications are critical determinants of cellular and developmental states. Epigenetic changes, such as decreased H3K27me3 histone methylation on insulin/IGF1 genes, have been previously shown to modulate lifespan through gene expression regulation. However, global epigenetic changes during aging and their biological functions, if any, remain elusive. Here, we examined the histone modification H3K4 dimethylation (H3K4me2) in the prefrontal cortex of individual rhesus macaques at different ages by chromatin immunoprecipitation, followed by deep sequencing (ChIP‐seq) at the whole genome level. Through integrative analysis of the ChIP‐seq profiles with gene expression data, we found that H3K4me2 increased at promoters and enhancers globally during postnatal development and aging, and those that correspond to gene expression changes in cis are enriched for stress responses, such as the DNA damage response. This suggests that metabolic and environmental stresses experienced by an organism are associated with the progressive opening of chromatin. In support of this, we also observed increased expression of two H3K4 methyltransferases, SETD7 and DPY30, in aged macaque brain.     

Histone H3 methylation patterns in Brassica nigra, Brassica juncea, and Brassica carinata species

Core histones are subjected to various post-translational modifications, and one of them, most intensively studied in plants, is the methylation of histone H3. In the majority of analyzed plant species, dimethylation of H3 at lysine 9 (H3K9me2) is detected in heterochromatin domains, whereas methylation of H3 at lysine 4 (H3K4me2) is detected in euchromatin domains. The distribution of H3K9me2 in the interphase nucleus seems to be correlated with genome size, chromatin organization, but also with tissue specificity. In this paper, we present the analysis of the pattern and level of histone H3 methylation for two allotetraploid and one diploid Brassica species. We have found that the pattern of H3K9me2 in interphase nuclei from root meristematic tissue is comparable within the analyzed species and includes both heterochromatin and euchromatin, but the level of modification differs not only among species but even among nuclei in the same phase of the cell cycle within one species. Moreover, the differences in the level of H3K9me2 are not directly coupled with DNA content in the nuclei and are probably tissue specific.     

The SUVR4 histone lysine methyltransferase binds ubiquitin and converts H3K9me1 to H3K9me3 on transposon chromatin in Arabidopsis

Chromatin structure and gene expression are regulated by posttranslational modifications (PTMs) on the N-terminal tails of histones. Mono-, di-, or trimethylation of lysine residues by histone lysine methyltransferases (HKMTases) can have activating or repressive functions depending on the position and context of the modified lysine. In Arabidopsis, trimethylation of lysine 9 on histone H3 (H3K9me3) is mainly associated with euchromatin and transcribed genes, although low levels of this mark are also detected at transposons and repeat sequences. Besides the evolutionarily conserved SET domain which is responsible for enzyme activity, most HKMTases also contain additional domains which enable them to respond to other PTMs or cellular signals. Here we show that the N-terminal WIYLD domain of the Arabidopsis SUVR4 HKMTase binds ubiquitin and that the SUVR4 product specificity shifts from di- to trimethylation in the presence of free ubiquitin, enabling conversion of H3K9me1 to H3K9me3 in vitro. Chromatin immunoprecipitation and immunocytological analysis showed that SUVR4 in vivo specifically converts H3K9me1 to H3K9me3 at transposons and pseudogenes and has a locus-specific repressive effect on the expression of such elements. Bisulfite sequencing indicates that this repression involves both DNA methylation-dependent and -independent mechanisms. Transcribed genes with high endogenous levels of H3K4me3, H3K9me3, and H2Bub1, but low H3K9me1, are generally unaffected by SUVR4 activity. Our results imply that SUVR4 is involved in the epigenetic defense mechanism by trimethylating H3K9 to suppress potentially harmful transposon activity.