核小体定位的转录调控功能研究进展

核小体是真核生物染色质的基本组成单位,组蛋白八聚体在DNA 双螺旋上精确位置称为核小体定位．核小体定位已被证实在基因转录调控、DNA复制与修复、调控进化等过程中扮演着重要的角色．随着染色质免疫共沉淀-芯片(ChIP-chip)与染色质免疫共沉淀-测序(ChIP-seq)等高通量技术的出现,已测定了多种模式生物全基因组核小体定位图谱,掀起了一股核小体定位及其功能的研究热潮,并取得了一定的成果．本文介绍了核小体定位的概念,总结了核小体在启动子与编码区域内定位的基本模式．在此基础上,综述了核小体定位在转录起始、转录延伸、基因表达模式多样化以及可变剪接等方面的功能研究进展．     

Positioning of a Nucleosome on Mouse Satellite DNA Inserted into a Yeast Plasmid Is Determined by Its DNA Sequence and an Adjacent Nucleosome

It has earlier been shown that multiple positioning of nucleosomes on mouse satellite DNA is determined by its nucleotide sequence. To clarify whether other factors, such as boundary ones, can affect the positionings, we modified the environment of satellite DNA monomer by inserting it into a yeast plasmid between inducible GalCyc promoter and a structural region of the yeast FLP gene. We have revealed that the positions of nucleosomes on satellite DNA are identical to those detected upon reconstruction in vitro. The positioning signal (GAAAAA sequence) of satellite DNA governs nucleosome location at the adjacent nucleotide sequence as well. Upon promoter induction the nucleosome, translationally positioned on the GalCyc promoter, transfers to the satellite DNA and its location follows the positioning signal of the latter. Thus, the alternatives of positioning of a nucleosome on satellite DNA are controlled by its nucleotide sequence, though the choice of one of them is determined by the adjacent nucleosome.     

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.     

Sequence Signatures of Nucleosome Positioning in Caenorhabditis elegans

Our recent investigation in the protist Trichomonas vaginalis suggested a DNA sequence periodicity with a unit length of 120.9 nt, which represents a sequence signature for nucleosome positioning. We now extended our observation in higher eukaryotes and identified a similar periodicity of 175 nt in length in Caenorhabditis elegans. In the process of defining the sequence compositional characteristics, we found that the 10.5-nt periodicity, the sequence signature of DNA double helix, may not be sufficient for cross-nucleosome positioning but provides essential guiding rails to facilitate positioning. We further dissected nucleosome-protected sequences and identified a strong positive purine (AG) gradient from the 5′-end to the 3′-end, and also learnt that the nucleosome-enriched regions are GC-rich as compared to the nucleosome-free sequences as purine content is positively correlated with GC content. Sequence characterization allowed us to develop a hidden Markov model (HMM) algorithm for decoding nucleosome positioning computationally, and based on a set of training data from the fifth chromosome of C. elegans, our algorithm predicted 60%-70% of the well-positioned nucleosomes, which is 15%-20% higher than random positioning. We concluded that nucleosomes are not randomly positioned on DNA sequences and yet bind to different genome regions with variable stability, well-positioned nucleosomes leave sequence signatures on DNA, and statistical positioning of nucleosomes across genome can be decoded computationally based on these sequence signatures.     

A Comparison of In Vitro Nucleosome Positioning Mapped with Chicken,Frog and a Variety of Yeast Core Histones

Using high-throughput sequencing, we have mapped sequence-directed nucleosome positioning in vitro on four plasmid DNAs containing DNA fragments derived from the genomes of sheep, drosophila, human and yeast. Chromatins were prepared by reconstitution using chicken, frog and yeast core histones. We also assembled yeast chromatin in which histone H3 was replaced by the centromere-specific histone variant, Cse4. The positions occupied by recombinant frog and native chicken histones were found to be very similar. In contrast, nucleosomes containing the canonical yeast octamer or, in particular, the Cse4 octamer were assembled at distinct populations of locations, a property that was more apparent on particular genomic DNA fragments. The factors that may contribute to this variation in nucleosome positioning and the implications of the behavior are discussed.     

Sequence-directed Mapping of Nucleosome Positions

Abstract

A nucleosome DNA sequence probe is designed that combines recently derived RR/YY counter-phase and AA/TT in-phase periodical patterns. A simple nucleosome mapping procedure is introduced for prediction of the nucleosome positions in the sequence of interest, to serve as a guide for experimental studies of the chromatin structure.     

人类基因组核苷酸多态性位点核小体定位分析

研究人类基因组核苷酸多态性位点周围核小体的定位,对于分析核苷酸的变异机制有重要意义.分析了人类基因组单核苷酸多态性(SNP)位点、简单插入位点、插入删除位点和删除位点的分布规律,以及这些位点周围的核小体定位特征.结果表明:转录起始位点下游的核苷酸多态性位点分布呈现约211 bp的周期特征,单核苷多态位点另有一个146 bp的周期;约211 bp的周期与转录起始位点下游核小体的分布周期204 bp非常接近,146 bp的周期恰是核小体核心DNA的长度.这些结果说明核小体与多态性位点的分布关系密切.进一步研究证实,单核苷酸多态性位点多分布于核心DNA上,且多位于核心DNA的两端,这使得单核苷酸多态性位点具有146 bp周期,而插入、插入删除、删除多态性位点多分布于核小体排开区域,间隔约为204 bp.转录起始位点下游核小体等间隔的规则分布使得多态性位点的分布也具有周期性.研究表明,相对于核小体,不同类型变异发生的位置不同,核小体定位在基因组多态性位点的形成过程中具有重要作用.     

Nucleosome positioning and gene regulation

Recent genetic and biochemical studies have revealed critical information concerning the role of nucleosomes in eukaryotic gene regulation. Nucleosomes package DNA into a dynamic chromatin structure, and by assuming defined positions in chromatin, influence gene regulation. Nucleosomes can serve as repressors, presumably by blocking access to regulatory elements; consequently, the positions of nucleosomes relative to the location of cis-acting elements are critical. Some genes have a chromatin structure that is “preset,” ready for activation, while others require “remodeling” for activation. Nucleosome positioning may be determined by multiple factors, including histone–DNA interactions, boundaries defined by DNA structure or protein binding, and higher-order chromatin structure. © 1994 Wiley-Liss, Inc.     

DNA methylation, nucleosome formation and positioning.

Recent mapping of nucleosome positioning on several long gene regions subject to DNA methylation has identified instances of nucleosome repositioning by this base modification. The evidence for an effect of CpG methylation on nucleosome formation and positioning in chromatin is reviewed here in the context of the complex sequence-structure requirements of DNA wrapping around the histone octamer and the role of this epigenetic mark in gene repression.