核小体定位模式及其与DNA甲基化位点分布的关系

核小体定位是指DNA双螺旋相对于组蛋白八联体的位置.核小体定位通过限制蛋白结合位点参与基因转录调控.本文利用实验检测的人类CD4+ T细胞核小体定位数据,研究了核小体定位在转录因子结合位点(TFBS)和转录起始位点(TSS)附近的分布模式,并分析了在TFBS和TSS周围,核小体定位与DNA甲基化之间的关系.结果表明,在休眠和激活的人类CD4+ T细胞中,部分TFBS和TSS周围的核小体定位在动态改变,即在定位和缺失两种状态之间切换.在TFBS周围,核小体定位和DNA甲基化存在一种互补模式,核小体定位与DNA低甲基化相联系;而在TSS周围,两者呈现同步模式,DNA高甲基化伴随高核小体水平.而且,在TFBS和TSS周围,DNA甲基化位点的分布呈周期模式.CD4+ T细胞被激活时,较少的转录因子启动了较多的基因.     

细胞重编程过程中核小体定位改变研究进展

细胞重编程是指在精卵结合或核移植过程中,核遗传物质的表观遗传标记发生删除和重塑,从而使已分化的细胞成为具有全能性的过程.发生细胞重编程的方法主要有细胞融合、体细胞核移植以及诱导多能干细胞等.核小体是染色质的基本结构及功能单位,是染色质的一级结构,核小体定位对基因的表达及细胞的状态有着重要的调控作用.细胞重编程过程中核小...     

基于遗传算法酵母核小体定位性质预测

在DNA序列上,定位模糊的特殊核小体与定位良好的普通核小体同时存在于染色体区域内,但由于二者的化学性质差异不明显,区分较为困难。本文针对实验核小体在真核基因转录起始位点周围的分布规律和保守性建立了一个核小体分布模型,并在前人所做的预测核小体位置的工作基础上,利用遗传算法寻找模型上不同性质核小体的分布中心,构建核小体定位性质判别准则,最终确定了转录起始位点上、下游定位良好和模糊核小体的位置。     

基于DNA弯曲度的H2A.Z核小体定位与修饰研究

在真核生物染色质中,H2A.Z是高度保守的组蛋白变异体,与转录调控、基因组的稳定性密切相关。为了探讨组蛋白修饰、DNA弯曲度与H2A.Z核小体定位三者之间的关联,在得到实验所测的相关数据后,利用MINE算法并结合皮尔逊相关系数在酵母全基因组的转录起始位点周围探讨了三者间的线性与非线性关系。其中MIC算法可以定量的得出数据之间关联度大小的值,用于衡量数据之间是否存在着关联,而皮尔逊相关系数则用于检查是否为线性关联。结果除了发现大部分组蛋白修饰种类和核小体定位之间存在着线性关联外,还探测到有两种组蛋白修饰数据(H4ac修饰与GCN4修饰)和核小体定位数据之间存在着以往未发现的非线性关系(大致呈正余弦函数),并从数据的生物背景(组蛋白修饰与核小体位置)上探讨了出现非线性现象的原因。     

蓝氏贾第虫核小体的初步研究

最原始的真核生物蓝氏贾第虫虽已有五种组蛋白,但以微球菌核酸酶水解却得不到规则的DNA片段。鉴于贾第虫的特殊进化地位,探讨其是否具有核小体结构,对于研究核小体的起源和进化具有重要的意义。采用改进的染色质铺展技术制备核小体并进行透射电镜观察。结果表明蓝氏贾第虫已有了直径约l0nm的核小体结构。作者认为核小体的形成可追溯到真核生物形成的初期甚至更早,核小体的完善则在真核生物形成之后。     

基于DNA变形能的核小体定位预测方法研究进展

真核细胞中,作为染色质基本结构单元的核小体参与调控基因的转录、DNA复制、重组以及RNA剪接等诸多生物学过程。阐明核小体定位机制并准确预测核小体在染色体上的位置对解读染色质结构与功能有重要生物学意义。在过去30多年时间里,研究人员发展了多种预测核小体位置的方法。最理想的方法应考虑DNA序列、组蛋白修饰和染色质重塑等影响核小体定位的诸多因素,然而现实中,捕捉主要因素的模型也往往具有很高的鲁棒性和实用价值。DNA序列偏好性是在全基因组尺度上影响核小体定位的最重要因素之一,因此基于DNA序列的核小体定位预测方法也最常见。这种方法可大致分为两类,即基于DNA序列信息的生物信息学模型和基于DNA变形能的生物物理学模型。本文重点介绍生物物理学模型近些年取得的主要进展。     

核小体定位研究进展

核小体定位在诸如转录调控、DNA复制和修复等多种细胞过程中起着重要作用。基因组上核小体位置的确定涉及DNA、转录因子、组蛋白修饰酶和染色质重塑复合体之间的相互作用。核小体定位、组蛋白修饰、染色质重塑等问题已成为目前遗传学研究的热点——表观遗传学——的重要研究内容。文章从核小体定位基本概念、核小体定位与基因表达调控的关系、核小体定位实验研究和理论预测工作等几个方面总结了核小体定位的最新研究进展。     

基于位置权重矩阵的核小体识别及功能分析

为研究高通量的人类CD4+T细胞的核小体定位模式,使用迭代算法对核小体定位模式进行分类,并利用位置权重矩阵方法分别构建稳定核小体定位序列、动态核小体定位序列和连接区序列模型,通过十倍交叉验证评估模型性能,并与Segal方法与弯曲度方法进行比较,发现位置权重矩阵方法在敏感性、精度和准确性方面都具有一定优越性。同时采用滑窗法在全基因组选取候选序列进行核小体识别,挖掘核小体定位相关基因,并进行基因生物学进程功能富集分析,发现稳定与动态核小体、真实与潜在核小体对应的基因所参与调控的生物学过程各有不同,但也有一些生物学过程为不同类别核小体所共有,例如对细胞内大分子的调控功能。     

酵母基因组中核小体偏好展列的识别

应用多样性增量结合二次判别分析（Increment of Diversity with Quadratic Discriminant analysis, IDQD）方法,对酵母基因组中的核小体强/弱偏好序列进行了识别。10交叉检验的预测成功率超过了97％,受试者操作特性（receiver operating characteristic,ROC）曲线下面积达到了0．99,预测成功率高于现有SVM算法。最后利用构建好的分类器对酵母基因组中三类包含TATA盒基因的起始密码子ATC上游400nt下游100nt区域进行了分析。结果表明,IDQD算法有能力应用于基因组中核小体序列的识别。     

酵母基因组中核小体偏好序列的识别

应用多样性增量结合二次判别分析(Increment of Diversity with Quadratic Discriminant analysis,IDQD)方法,对酵母基因组中的核小体强/弱偏好序列进行了识别.10交叉检验的预测成功率超过了97%,受试者操作特性(receiver operating characteristic,ROC)曲线下面积达到了0.99,预测成功率高于现有SVM算法.最后利用构建好的分类器对酵母基因组中三类包含TATA盒基因的起始密码子ATG上游400nt下游100nt区域进行了分析.结果表明,IDQD算法有能力应用于基因组中核小体序列的识别.     

Biophysical characterization of the centromere-specific nucleosome from budding yeast

The centromeric DNA of all eukaryotes is assembled upon a specialized nucleosome containing a histone H3 variant known as CenH3. Despite the importance and conserved nature of this protein, the characteristics of the centromeric nucleosome are still poorly understood. In particular, the stoichiometry and DNA-binding properties of the CenH3 nucleosome have been the subject of some debate. We have characterized the budding yeast centromeric nucleosome by biochemical and biophysical methods and show that it forms a stable octamer containing two copies of the Cse4 protein and wraps DNA in a left-handed supercoil, similar to the canonical H3 nucleosome. The DNA-binding properties of the recombinant nucleosome are identical to those observed in vivo demonstrating that the octameric structure is physiologically relevant.     

基于希尔伯特-黄变换的核小体定位特征提取

核小体是染色体折叠的整体结构,它们的空间分布与基因组活动的调节密切相关,是基因工程和表观遗传的重要研究领域。为进一步研究核小体定位特征的物种间差异性,将希尔伯特-黄变换(HHT)引入到酵母和果蝇两个不同物种的定位信号中,从多个角度客观分析核小体定位信号特征在两个物种间的差异性。在此基础上,对酵母和果蝇核小体分布的周期特征和进化印记进行尺度和频域分析,结果表明酵母和果蝇染色体在组织结构上存在显著差异。本文研究思路为准确提取信号瞬时频率提供了前提条件。     

Prediction of nucleosome rotational positioning in yeast and human genomes based on sequence-dependent DNA anisotropy

Background

An organism’s DNA sequence is one of the key factors guiding the positioning of nucleosomes within a cell’s nucleus. Sequence-dependent bending anisotropy dictates how DNA is wrapped around a histone octamer. One of the best established sequence patterns consistent with this anisotropy is the periodic occurrence of AT-containing dinucleotides (WW) and GC-containing dinucleotides (SS) in the nucleosomal locations where DNA is bent in the minor and major grooves, respectively. Although this simple pattern has been observed in nucleosomes across eukaryotic genomes, its use for prediction of nucleosome positioning was not systematically tested.

Results

We present a simple computational model, termed the W/S scheme, implementing this pattern, without using any training data. This model accurately predicts the rotational positioning of nucleosomes both in vitro and in vivo, in yeast and human genomes. About 65 – 75% of the experimentally observed nucleosome positions are predicted with the precision of one to two base pairs. The program is freely available at http://people.rit.edu/fxcsbi/WS_scheme/. We also introduce a simple and efficient way to compare the performance of different models predicting the rotational positioning of nucleosomes.

Conclusions

This paper presents the W/S scheme to achieve accurate prediction of rotational positioning of nucleosomes, solely based on the sequence-dependent anisotropic bending of nucleosomal DNA. This method successfully captures DNA features critical for the rotational positioning of nucleosomes, and can be further improved by incorporating additional terms related to the translational positioning of nucleosomes in a species-specific manner.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2105-15-313) contains supplementary material, which is available to authorized users.     

Effect of DNA length and H4 acetylation on the thermal stability of reconstituted nucleosome particles

To examine the factors involved with nucleosome stability, we reconstituted nonacetylated particles containing various lengths (192, 162, and 152 base pairs) of DNA onto the Lytechinus variegatus nucleosome positioning sequence in the absence of linker histone. We characterized the particles and examined their thermal stability. DNA of less than chromatosome length (168 base pairs) produces particles with altered denaturation profiles, possibly caused by histone rearrangement in those core-like particles. We also examined the effects of tetra-acetylation of histone H4 on the thermal stability of reconstituted nucleosome particles. Tetra-acetylation of H4 reduces the nucleosome thermal stability by 0.8 degrees C as compared with nonacetylated particles. This difference is close to values published comparing bulk nonacetylated nucleosomes and core particles to ones enriched for core histone acetylation, suggesting that H4 acetylation has a dominant effect on nucleosome particle energetics.     

Computational prediction of nucleosome positioning by calculating the relative fragment frequency index of nucleosomal sequences

We developed an accurate method to predict nucleosome positioning from genome sequences by refining the previously developed method of Peckham et al. (2007) [19]. Here, we used the relative fragment frequency index we developed and a support vector machine to screen for nucleosomal and linker DNA sequences. Our twofold cross-validation revealed that the accuracy of our method based on the area under the receiver operating characteristic curve was 81%, whereas that of Peckham’s method was 75% when both of two nucleosomal sequence data obtained from independent experiments were used for validation. We suggest that our method is more effective in predicting nucleosome positioning.