Nucleosome positioning can affect the function of a cis-acting DNA element in vivo

Positioning of nucleosomes has been proposed as one mechanism whereby the activity of DNA is regulated: cis-acting elements located in linker DNA might be more accessible for interaction with trans-acting protein factors than they would be if they were directly associated with histones in nucleosome core particles. The eleven base pairs constituting the autonomously replicating sequence (ARS) of the high-copy-number TRP1ARS1 plasmid of Saccharomyces cerevisiae are located in a linker region near the edge of a positioned nucleosome and form an origin of replication. Could nucleosome positioning render the ARS accessible for interaction with the proteins necessary for its function? I have tested this hypothesis by making deletions and an insertion to move the ARS into the nucleosome DNA and then examining the effects on ARS function. There is a marked decrease in copy number when the ARS is moved into the central DNA region of the nucleosome core particle, a region known to differ in structure and stability from the peripheral segments of nucleosome DNA.     

Local protein-DNA interactions may determine nucleosome positions on yeast plasmids

The structure of the nucleosome core particle, the basic structural subunit of chromatin, is well known. Although nucleosomes often appear to be positioned randomly with respect to DNA sequences, in some cases they seem to occupy precisely defined positions on the DNA. The yeast plasmid TRP1ARS1 contains three precisely positioned, stable nucleosomes, I, II and III, which are flanked by nuclease-sensitive regions. Our aim in the present study was to determine whether the positions of these three nucleosomes relate to (1) protein-DNA interactions; (2) the limited space between nuclease-sensitive regions, which is just long enough to accommodate three yeast nucleosomes (that is, boundary conditions); or (3) proximity to the putative origin of replication in one of the nuclease-sensitive regions. We have tested these alternatives by analysing the positions of nucleosomes after insertion of various lengths of DNA into this region and assembly of chromatin in vivo. Our results suggest that specific protein-DNA interactions are the most likely determinants of these nucleosome positions.     

Evidence for kinks in DNA folding in the nucleosome

The nucleosome subunit of chromatin consists of DNA folded around a histone core as a 1.8-turn left-handed solenoid. The crystal structure of the nucleosome core particle revealed that it has a dyad symmetry axis and that the minor helix groove faces outwards from the protein core. Richmond et al. noticed that the path traversed by the helix has severe bends at sites approximately one and four helix turns from the dyad axis. We have developed two photochemical methods to study the structure of DNA, and in particular that wrapped around the nucleosome core. One method depends on the sensitization of singlet oxygen production by an eosin analogue. We have monitored the rate at which excited state oxygen diffuses into contact with DNA base planes, and find that it attacks the nucleosome with high specificity. We have also mapped the DNA binding of the intercalating dye methylene blue, and conclude that it binds to the same sites accessible to oxygen by diffusion. On the basis of these results we suggest that the DNA in the nucleosome is bent or kinked at two sites, 1.5 helix turns from the dyad axis.     

Crystal structure of the human centromeric nucleosome containing CENP-A

In eukaryotes, accurate chromosome segregation during mitosis and meiosis is coordinated by kinetochores, which are unique chromosomal sites for microtubule attachment. Centromeres specify the kinetochore formation sites on individual chromosomes, and are epigenetically marked by the assembly of nucleosomes containing the centromere-specific histone H3 variant, CENP-A. Although the underlying mechanism is unclear, centromere inheritance is probably dictated by the architecture of the centromeric nucleosome. Here we report the crystal structure of the human centromeric nucleosome containing CENP-A and its cognate α-satellite DNA derivative (147 base pairs). In the human CENP-A nucleosome, the DNA is wrapped around the histone octamer, consisting of two each of histones H2A, H2B, H4 and CENP-A, in a left-handed orientation. However, unlike the canonical H3 nucleosome, only the central 121 base pairs of the DNA are visible. The thirteen base pairs from both ends of the DNA are invisible in the crystal structure, and the αN helix of CENP-A is shorter than that of H3, which is known to be important for the orientation of the DNA ends in the canonical H3 nucleosome. A structural comparison of the CENP-A and H3 nucleosomes revealed that CENP-A contains two extra amino acid residues (Arg?80 and Gly?81) in the loop 1 region, which is completely exposed to the solvent. Mutations of the CENP-A loop 1 residues reduced CENP-A retention at the centromeres in human cells. Therefore, the CENP-A loop 1 may function in stabilizing the centromeric chromatin containing CENP-A, possibly by providing a binding site for trans-acting factors. The structure provides the first atomic-resolution picture of the centromere-specific nucleosome.     

The structure of DNA in the nucleosome core

The 1.9-A-resolution crystal structure of the nucleosome core particle containing 147 DNA base pairs reveals the conformation of nucleosomal DNA with unprecedented accuracy. The DNA structure is remarkably different from that in oligonucleotides and non-histone protein-DNA complexes. The DNA base-pair-step geometry has, overall, twice the curvature necessary to accommodate the DNA superhelical path in the nucleosome. DNA segments bent into the minor groove are either kinked or alternately shifted. The unusual DNA conformational parameters induced by the binding of histone protein have implications for sequence-dependent protein recognition and nucleosome positioning and mobility. Comparison of the 147-base-pair structure with two 146-base-pair structures reveals alterations in DNA twist that are evidently common in bulk chromatin, and which are of probable importance for chromatin fibre formation and chromatin remodelling.     

盐透析体外组装核小体及检测方法

核小体是构成真核生物染色质的基本结构单位,体内研究核小体及染色质结构受到诸多因素限制,体外重构核小体结构是研究与核小体及染色质结构相关课题的一种重要的方法手段.实验将ES1,CS1以及601DNA序列克隆到载体中,通过PCR大量扩增回收得到目的DNA条带,表达纯化了4种组蛋白且装配成组蛋白八聚体,在盐透析的条件下组装形成核小体结构,利用EB染色以及Biotin标记的方法分析检测了形成核小体的效率.结果显示,在盐透析的条件下,可以有效的组装形成核小体结构,而且随着组蛋白八聚体与DNA的比例增加,核小体的形成效率显著提高.本实验为核小体定位、染色质重塑及组蛋白变体等表观遗传学以及结构生物学领域的研究奠定一定的基础.     

Intrinsic coupling of lagging-strand synthesis to chromatin assembly

Fifty per cent of the genome is discontinuously replicated on the lagging strand as Okazaki fragments. Eukaryotic Okazaki fragments remain poorly characterized and, because nucleosomes are rapidly deposited on nascent DNA, Okazaki fragment processing and nucleosome assembly potentially affect one another. Here we show that ligation-competent Okazaki fragments in Saccharomyces cerevisiae are sized according to the nucleosome repeat. Using deep sequencing, we demonstrate that ligation junctions preferentially occur near nucleosome midpoints rather than in internucleosomal linker regions. Disrupting chromatin assembly or lagging-strand polymerase processivity affects both the size and the distribution of Okazaki fragments, suggesting a role for nascent chromatin, assembled immediately after the passage of the replication fork, in the termination of Okazaki fragment synthesis. Our studies represent the first high-resolution analysis--to our knowledge--of eukaryotic Okazaki fragments in vivo, and reveal the interconnection between lagging-strand synthesis and chromatin assembly.     

Structure and mechanism of the chromatin remodelling factor ISW1a

Site-specific recognition of DNA in eukaryotic organisms depends on the arrangement of nucleosomes in chromatin. In the yeast Saccharomyces cerevisiae, ISW1a and related chromatin remodelling factors are implicated in establishing the nucleosome repeat during replication and altering nucleosome position to affect gene activity. Here we have solved the crystal structures of S. cerevisiae ISW1a lacking its ATPase domain both alone and with DNA bound at resolutions of 3.25?? and 3.60??, respectively, and we have visualized two different nucleosome-containing remodelling complexes using cryo-electron microscopy. The composite X-ray and electron microscopy structures combined with site-directed photocrosslinking analyses of these complexes suggest that ISW1a uses a dinucleosome substrate for chromatin remodelling. Results from a remodelling assay corroborate the dinucleosome model. We show how a chromatin remodelling factor could set the spacing between two adjacent nucleosomes acting as a 'protein ruler'.     

Determinants of nucleosome organization in primary human cells

Nucleosomes are the basic packaging units of chromatin, modulating accessibility of regulatory proteins to DNA and thus influencing eukaryotic gene regulation. Elaborate chromatin remodelling mechanisms have evolved that govern nucleosome organization at promoters, regulatory elements, and other functional regions in the genome. Analyses of chromatin landscape have uncovered a variety of mechanisms, including DNA sequence preferences, that can influence nucleosome positions. To identify major determinants of nucleosome organization in the human genome, we used deep sequencing to map nucleosome positions in three primary human cell types and in vitro. A majority of the genome showed substantial flexibility of nucleosome positions, whereas a small fraction showed reproducibly positioned nucleosomes. Certain sites that position in vitro can anchor the formation of nucleosomal arrays that have cell type-specific spacing in vivo. Our results unveil an interplay of sequence-based nucleosome preferences and non-nucleosomal factors in determining nucleosome organization within mammalian cells.     

The histone H3.3 chaperone HIRA is essential for chromatin assembly in the male pronucleus

In sexually reproducing animals, a crucial step in zygote formation is the decondensation of the fertilizing sperm nucleus into a DNA replication-competent male pronucleus. Genome-wide nucleosome assembly on paternal DNA implies the replacement of sperm chromosomal proteins, such as protamines, by maternally provided histones. This fundamental process is specifically impaired in sésame (ssm), a unique Drosophila maternal effect mutant that prevents male pronucleus formation. Here we show that ssm is a point mutation in the Hira gene, thus demonstrating that the histone chaperone protein HIRA is required for nucleosome assembly during sperm nucleus decondensation. In vertebrates, HIRA has recently been shown to be critical for a nucleosome assembly pathway independent of DNA synthesis that specifically involves the H3.3 histone variant. We also show that nucleosomes containing H3.3, and not H3, are specifically assembled in paternal Drosophila chromatin before the first round of DNA replication. The exclusive marking of paternal chromosomes with H3.3 represents a primary epigenetic distinction between parental genomes in the zygote, and underlines an important consequence of the critical and highly specialized function of HIRA at fertilization.     

对于核小体定位检测方法的比较研究

在真核细胞中,核小体是组成染色质的基本结构单位,是由DNA紧密缠绕在组蛋白八聚体上所形成的一个复合体结构。而DNA与组蛋白的结合并不是固定不变的,没有核小体结合的DNA区域易于各种调节蛋白的接近与结合。因此人们怀疑核小体的定位与基因的转录调节之间存在某种内在联系。对现行的核小体定位的检测方法进行了归类,并对其优缺点进行了分析整理。对更深入的探索核小体定位检测方法的应用有一定意义。     

基因学说的深化与发展

DNA双螺旋结构的建立是20世纪最为重要的发现之一。随后确立的中心法则使人们对于生命的本质有了更为深入的了解,基因克隆和重组技术则为人们提供了一种更为强大的改造自然的能力。回顾现代生物学发展的历程,可以清楚的看到,DNA作为遗传信息的载体和其双螺旋结构的发现所占据的重要地位。而对人类基因组的测序又为人们提供了一个更为广阔的视野,使得从整体上研究生命过程成为可能,从而使人们进入了“后基因组时代”。