Probing structural stability of chromatin assembly sorted from living cells
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The dynamic structure of individual nucleosomes was examined by stretching nucleosomal arrays with a feedback-enhanced optical trap. Forced disassembly of each nucleosome occurred in three stages. Analysis of the data using a simple worm-like chain model yields 76 bp of DNA released from the histone core at low stretching force. Subsequently, 80 bp are released at higher forces in two stages: full extension of DNA with histones bound, followed by detachment of histones. When arrays were relaxed before the dissociated state was reached, nucleosomes were able to reassemble and to repeat the disassembly process. The kinetic parameters for nucleosome disassembly also have been determined.
Linker DNA
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Chromatosome
Histone octamer
Linker DNA
Histone code
Solenoid
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Chromatin provides both a means to accommodate a large amount of genetic material in a small space and a means to package the same genetic material in different chromatin states. Transitions between chromatin states are enabled by chromatin-remodeling ATPases, which catalyze a diverse range of structural transformations. Biochemical evidence over the last two decades suggests that chromatin-remodeling activities may have emerged by adaptation of ancient DNA translocases to respond to specific features of chromatin. Here, we discuss such evidence and also relate mechanistic insights to our understanding of how chromatin-remodeling enzymes enable different in vivo processes. Chromatin provides both a means to accommodate a large amount of genetic material in a small space and a means to package the same genetic material in different chromatin states. Transitions between chromatin states are enabled by chromatin-remodeling ATPases, which catalyze a diverse range of structural transformations. Biochemical evidence over the last two decades suggests that chromatin-remodeling activities may have emerged by adaptation of ancient DNA translocases to respond to specific features of chromatin. Here, we discuss such evidence and also relate mechanistic insights to our understanding of how chromatin-remodeling enzymes enable different in vivo processes.
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ChIA-PET
Scaffold/matrix attachment region
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It was shown that after treatment by Ca2+- and Mg2+-dependent DNAses and subsequent dosed ultrasonication the fractions of active and relatively inactive chromatins isolated from liver cell nuclei of rats differing in age contain all main types of histones, but differ considerably in the relative amounts of individual fractions of these proteins. In all age groups studied the proteins of relatively inactive chromatin are largely histones, while the amount of non-histone proteins is higher in active chromatin. In the course of postnatal development the amount of histones in both chromatin fractions is increased and that of non-histone proteins is decreased. This is probably due to heterochromatization of the chromatin complex in liver cells with ageing. In the course of postnatal ontogenesis the spectrum of non-histone proteins in both chromatin fractions is changed.
Non-histone protein
Histone-modifying enzymes
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Dynamic changes in chromatin structure play an important role in transcription regulation. Recent studies have revealed two mechanisms that alter chromatin structure. One involves ATP-dependent chromatin remodeling, and the other involves acetylation of the core histone tails. We have previously purified and characterized a multi-subunit protein complex, NuRD, which possesses both nucleosome remodeling and histone deacetylase activities. Despite extensive biochemical characterization of the complex, little is known about the functions of its individual components. In this study, we focused on Mi2, a component of the NuRD complex. We found that, similar to the native NuRD complex, recombinant Mi2 is a DNA-dependent, nucleosome-stimulated ATPase. Kinetic analysis of the ATP hydrolysis reaction indicated that the differential stimulation of the Mi2 ATPase by DNA and nucleosomes were primarily due to their differential effects on the turnover number of the reaction. Furthermore, we demonstrated that recombinant Mi2 is an efficient nucleosome remodeling factor when compared to that of the native NuRD complex. Our results define the biochemical function of Mi2 and set the stage for understanding the mechanism of nucleosome remodeling in a defined reconstituted system.
SWI/SNF
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Inducer
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Analysis of in vivo chromatin remodeling at the PHO5 promoter of yeast led to the conclusion that remodeling removes nucleosomes from the promoter by disassembly rather than sliding away from the promoter. The catalytic activities required for nucleosome disassembly remain unknown. Transcriptional activation of the yeast PHO8 gene was found to depend on the chromatin-remodeling complex SWI/SNF, whereas activation of PHO5 was not. Here, we show that PHO8 gene circles formed in vivo lose nucleosomes upon PHO8 induction, indicative of nucleosome removal by disassembly. Our quantitative analysis of expression noise and chromatin-remodeling data indicates that the dynamics of continual nucleosome removal and reformation at the activated promoters of PHO5 and PHO8 are closely similar. In contrast to PHO5, however, activator-stimulated transcription of PHO8 appears to be limited mostly to the acceleration of promoter nucleosome disassembly with little or no acceleration of promoter transitions following nucleosome disassembly, accounting for the markedly lower expression level of PHO8.
SWI/SNF
Transcription
Solenoid
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Concatameric sea urchin 5S rDNA templates reconstituted with histones provide very popular chromatin models for many kinds of in vitro studies. We have used AFM to characterize the locational aspects of nucleosome occupation on one such array, the 208-12, by determining the internucleosomal- and end-distance distributions for arrays reconstituted to various subsaturating levels with nonacetylated or hyperacetylated HeLa histones. A simulation analysis of the experimental distributions confirms the qualitative conclusions and provides quantitative parameter values for the identified features. For nonacetylated arrays, the end-distance data demonstrate the nucleosome positioning ability of the 5S sequence and detect an enhanced preference for nucleosomes to bind at DNA termini. The internucleosomal-distance data provide clear evidence for cooperativity in nucleosome location on these templates, detectable even at subsaturated loading levels. Hyperacetylated arrays show no change in the preference of nucleosomes to bind at termini and a slight change in nucleosome positioning behavior but, most strikingly, little or no evidence for cooperativity in nucleosome location. Thus, acetylation of the N-terminal histone tails abolishes the cooperativity.
Cooperativity
Cooperative binding
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