A SWI/SNF-like factor from chicken liver that disrupts nucleosomes and transfers histone octamers in cis and trans

ATP-dependent chromatin remodeling factors have been implicated in nuclear processes involving DNA. Here we report partial purification and characterization of an ATP-dependent chromatin remodeling activity from chicken liver. Nuclear extract from chicken liver was fractionated chromatographically to enrich proteins immunoreacting to antibodies against components of human SWI/SNF, namely BRG1, BAF170, BAF155, and BAF57. Immunoreactivity to these antibodies elutes with a mass of about 2MDa on Sepharose CL-6B gel filtration, suggesting that they constitute a SWI/SNF-like complex (SLC). The SLC displays three chromatin-remodeling activities, viz. nucleosome disruption, octamer transfer, and nucleosome sliding (octamer transfer in cis). We further show that components of SLC, as revealed by immunoreactivity to the above antibodies, display a dynamic nucleocytoplasmic distribution and colocalize with RNA polymerase II in the liver nuclei. This report contributes to the understanding of phylogenetic generality of chromatin remodeling factors in eukaryotes.     

技术与方法体外组装含有组蛋白变体H2A.Z及H3.3的核小体

核小体是构成真核生物染色质的基本结构单位,组蛋白变体H2A.Z及H3.3对染色质结构及基因转录过程发挥着重要的调控作用。体内研究核小体及染色质结构受到诸多因素限制,体外重构含有H2A.Z及H3.3的核小体结构是研究与组蛋白变体相关基因表达调控的重要方法之一。实验表达纯化了6种组蛋白,在复性的过程中装配了含有H2A.Z和H3.3的组蛋白八聚体。基于DNA序列10bp周期性及序列模体设计了3条易于形成核小体的DNA序列,通过PCR大量扩增的方法,回收了标记Cy3荧光分子的目的DNA序列。采用盐透析法体外组装了含有H2A.Z和H3.3的核小体结构,利用荧光标记、EB染色及考马斯亮蓝染色检测了含有组蛋白变体的核小体形成效率及形成过程的吉布斯自由能变化。结果发现,设计的3条DNA序列可以有效地组装形成含有组蛋白电梯的核小体结构,而且随着组蛋白八聚体与DNA比例的增加,核小体的形成效率显著提高;采用Cy3荧光标记可以灵敏且定量地计算组装过程的吉布斯自由能。该方法的建立对研究组蛋白变体相关的结构生物学及转录调控等具有一定的意义。     

ATP-dependent chromatin remodeling by the Saccharomyces cerevisiae homologous recombination factor Rdh54

Saccharomyces cerevisiae RDH54 is a key member of the evolutionarily conserved RAD52 epistasis group of genes needed for homologous recombination and DNA double strand break repair. The RDH54-encoded protein possesses a DNA translocase activity and functions together with the Rad51 recombinase in the D-loop reaction. By chromatin immunoprecipitation (ChIP), we show that Rdh54 is recruited, in a manner that is dependent on Rad51 and Rad52, to a site-specific DNA double strand break induced by the HO endonuclease. Because of its relatedness to Swi2/Snf2 chromatin remodelers, we have asked whether highly purified Rdh54 possesses chromatin-remodeling activity. Importantly, our results show that Rdh54 can mobilize a mononucleosome along DNA and render nucleosomal DNA accessible to a restriction enzyme, indicative of a chromatin-remodeling function. Moreover, Rdh54 co-operates with Rad51 in the utilization of naked or chromatinized DNA as template for D-loop formation. We also provide evidence for a strict dependence of the chromatin-remodeling attributes of Rdh54 on its ATPase activity and N-terminal domain. Interestingly, an N-terminal deletion mutant (rdh54Delta102) is unable to promote Rad51-mediated D-loop formation with a chromatinized template, while retaining substantial activity with naked DNA. These features of Rdh54 suggest a role of this protein factor in chromatin rearrangement during DNA recombination and repair.     

Breaths,Twists, and Turns of Atomistic Nucleosomes

Gene regulation programs establish cellular identity and rely on dynamic changes in the structural packaging of genomic DNA. The DNA is packaged in chromatin, which is formed from arrays of nucleosomes displaying different degree of compaction and different lengths of inter-nucleosomal linker DNA. The nucleosome represents the repetitive unit of chromatin and is formed by wrapping 145–147 basepairs of DNA around an octamer of histone proteins. Each of the four histones is present twice and has a structured core and intrinsically disordered terminal tails. Chromatin dynamics are triggered by inter- and intra-nucleosome motions that are controlled by the DNA sequence, the interactions between the histone core and the DNA, and the conformations, positions, and DNA interactions of the histone tails. Understanding chromatin dynamics requires studying all these features at the highest possible resolution. For this, molecular dynamics simulations can be used as a powerful complement or alternative to experimental approaches, from which it is often very challenging to characterize the structural features and atomic interactions controlling nucleosome motions. Molecular dynamics simulations can be performed at different resolutions, by coarse graining the molecular system with varying levels of details. Here we review the successes and the remaining challenges of the application of atomic resolution simulations to study the structure and dynamics of nucleosomes and their complexes with interacting partners.