Distribution of linker DNA in relation to core DNA in H1 depleted nucleosomes.

The mode of interaction of histone H1 with the nucleosome is governed by the relative distribution of the linker with respect to the core DNA. Preliminary experiments (Simpson, R.T. 1978, Biochemistry, 17, 5524-5531) and tentative models (Thoma, F. et al. (1979), J. Cell. Biol., 83, 403-427) suggest that part of the linker complete two full turns of DNA around the histone core, probably by adding 10 base pairs at each end of the core DNA. In the present study Exonuclease III has been utilized to digest the 3' ends of H1 depleted nucleosomes. (i.e. the 195 base pair particle). The analysis of the resulting DNA fragments under denaturing conditions shows that the whole linker is distributed symmetrically with respect to the core DNA.     

Urea-induced binding of histone 1 to nucleosomes lacking linker DNA.

The binding of H1 (and H5) to nucleosome core particles was demonstrated by separating mononucleosomes according to their DNA size on acrylamide gels containing high molarity urea. The presence of urea causes a redistribution of H1 so that it associates with some particles of all linker lengths, including no linker. When the urea is removed the H1 remains associated with particles of all DNA sizes if the different size classes are not mixed with each other. Therefore, urea can effect the transfer of H1 from particles with linker to particles with no linker. When nucleosomes of uniform DNA fragment length, some containing and some lacking H1, are re-electrophoresed under native conditions, they migrate as two widely separated bands. The mobilities of these variants do not depend on linker length and are identical to the mobilities of native H1-containing and H1-lacking particles. When the same collection of particles is electrophoresed in the presence of high molarity urea they migrate with a uniform mobility. These results suggest that H1-containing nucleosomes are conformationally different from H1-lacking particles, but that this difference is eliminated when histone-histone interactions are disrupted by urea.     

Chromatin compaction at the mononucleosome level

Using a previously described FRET technique, we measured the distance between the ends of DNA fragments on which nucleosomes were reconstituted from recombinant and native histones. This distance was analyzed in its dependence on the DNA fragment length, concentration of mono- and divalent counterions, presence of linker histone H1, and histone modifications. We found that the linker DNA arms do not cross under all conditions studied but diverge slightly as they leave the histone core surface. Histone H1 leads to a global approach of the linker DNA arms, confirming the notion of a "stem structure". Increasing salt concentration also leads to an approach of the linker DNAs. To study the effect of acetylation, we compared chemically acetylated recombinant histones with histones prepared from HeLa cells, characterizing the sites of acetylation by mass spectroscopy. Nucleosomes from chemically acetylated histones have few modifications in the core domain and form nucleosomes normally. Acetylating all histones or selectively only H3 causes an opening of the nucleosome structure, indicated by the larger distances between the linker DNA ends. Selective acetylation of H4 distances the linker ends for short fragments but causes them to approach each other for fragments longer than 180 bp.     

Interaction of high mobility group proteins HMG 1 and HMG 2 with nucleosomes studied by gel electrophoresis

The binding of isolated high mobility group proteins HMG (1+2) with nucleosomes was studied using gel electrophoresis. The interaction of HMG (1+2) with mononucleosomes could be detected as a new discrete electrophoretic band with a decreased mobility only after cross-linking of HMG (1+2)-nucleosome complex by formaldehyde. Approximately two molecules of the large HMG proteins were bound per nucleosomal particle of a DNA length of 185 base pairs, lacking histones H1 and H5. Using the same techniques, no binding was observed with core particles of a DNA length of 145 base pairs.     

Studies on protein organization of nucleosomes using cross-linking

When chromosomal proteins in chromatin or in mononucleosomes were extensively cross-linked with an imido ester, the H1-containing nonameric histone complex was revealed. In this complex, histone H1 is connected with the octamer of core histones. The cross-linking of H1 to the octamer is realized preferentially through H2a and H3 histones. Some HMG (high mobility group) proteins located presumably in the linker regions of a nucleosome fiber also take part in the formation of dimers, possibly with the histones of a nucleosomal core. The results suggest mutual interactions between some linker-associated proteins and intranucleosomal histones. Experiments involving extensive cross-linking of proteins in the purified mononucleosome subfractions demonstrated differences in the organization of core histones between complete nucleosomes and nucleosomes lacking H1.Abbreviations HMG proteins high mobility group proteins - DMA dimethyladipimidate dihydrochloride - DMP dimethyl-3,3-dithio-bis-propionimidate dihydrochloride     

Histone-H1-dependent chromatin superstructures and the suppression of gene activity

I have identified a chromatin particle containing DNA as large as 20-40 kb that migrates as a discrete entity on agarose gels. With increasing nuclease digestion, the particle becomes cleaved in the linker regions between nucleosomes, but remains intact, probably held together by the outer histones, H1 and H5. By hybridization analysis, inactive genes are found in these particles. Active genes (and their flanking sequences) are also found in particles containing H1 and H5, but in contrast to inactive supranucleosome particles, active polynucleosome particles are not held together after cleavage of linker DNA. This suggests that H1 cross-links adjacent nucleosomes in inactive regions and that H1 is bound differently in expressed regions. The results raise the possibility that the marked degree of suppression of repressed, tissue-specific genes may be determined, in part, by their assembly into these inactive supranucleosome structures.     

Nucleosomes Shape DNA Polymorphism and Divergence

An estimated 80% of genomic DNA in eukaryotes is packaged as nucleosomes, which, together with the remaining interstitial linker regions, generate higher order chromatin structures [1]. Nucleosome sequences isolated from diverse organisms exhibit ∼10 bp periodic variations in AA, TT and GC dinucleotide frequencies. These sequence elements generate intrinsically curved DNA and help establish the histone-DNA interface. We investigated an important unanswered question concerning the interplay between chromatin organization and genome evolution: do the DNA sequence preferences inherent to the highly conserved histone core exert detectable natural selection on genomic divergence and polymorphism? To address this hypothesis, we isolated nucleosomal DNA sequences from Drosophila melanogaster embryos and examined the underlying genomic variation within and between species. We found that divergence along the D. melanogaster lineage is periodic across nucleosome regions with base changes following preferred nucleotides, providing new evidence for systematic evolutionary forces in the generation and maintenance of nucleosome-associated dinucleotide periodicities. Further, Single Nucleotide Polymorphism (SNP) frequency spectra show striking periodicities across nucleosomal regions, paralleling divergence patterns. Preferred alleles occur at higher frequencies in natural populations, consistent with a central role for natural selection. These patterns are stronger for nucleosomes in introns than in intergenic regions, suggesting selection is stronger in transcribed regions where nucleosomes undergo more displacement, remodeling and functional modification. In addition, we observe a large-scale (∼180 bp) periodic enrichment of AA/TT dinucleotides associated with nucleosome occupancy, while GC dinucleotide frequency peaks in linker regions. Divergence and polymorphism data also support a role for natural selection in the generation and maintenance of these super-nucleosomal patterns. Our results demonstrate that nucleosome-associated sequence periodicities are under selective pressure, implying that structural interactions between nucleosomes and DNA sequence shape sequence evolution, particularly in introns.     

CENP-A-containing nucleosomes: easier disassembly versus exclusive centromeric localization

CENP-A is a histone variant that replaces conventional H3 in nucleosomes of functional centromeres. We report here, from reconstitutions of CENP-A- and H3-containing nucleosomes on linear DNA fragments and the comparison of their electrophoretic mobility, that CENP-A induces some positioning of its own and some unwrapping at the entry-exit relative to canonical nucleosomes on both 5 S DNA and the alpha-satellite sequence on which it is normally loaded. This steady-state unwrapping was quantified to 7(+/-2) bp by nucleosome reconstitutions on a series of DNA minicircles, followed by their relaxation with topoisomerase I. The unwrapping was found to ease nucleosome invasion by exonuclease III, to hinder the binding of a linker histone, and to promote the release of an H2A-H2B dimer by nucleosome assembly protein 1 (NAP-1). The (CENP-A-H4)2 tetramer was also more readily destabilized with heparin than the (H3-H4)2 tetramer, suggesting that CENP-A has evolved to confer its nucleosome a specific ability to disassemble. This dual relative instability is proposed to facilitate the progressive clearance of CENP-A nucleosomes that assemble promiscuously in euchromatin, especially as is seen following CENP-A transient over-expression.     

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.     

A critical role for linker DNA in higher-order folding of chromatin fibers

Nucleosome-nucleosome interactions drive the folding of nucleosomal arrays into dense chromatin fibers. A better physical account of the folding of chromatin fibers is necessary to understand the role of chromatin in regulating DNA transactions. Here, we studied the unfolding pathway of regular chromatin fibers as a function of single base pair increments in linker length, using both rigid base-pair Monte Carlo simulations and single-molecule force spectroscopy. Both computational and experimental results reveal a periodic variation of the folding energies due to the limited flexibility of the linker DNA. We show that twist is more restrictive for nucleosome stacking than bend, and find the most stable stacking interactions for linker lengths of multiples of 10 bp. We analyzed nucleosomes stacking in both 1- and 2-start topologies and show that stacking preferences are determined by the length of the linker DNA. Moreover, we present evidence that the sequence of the linker DNA also modulates nucleosome stacking and that the effect of the deletion of the H4 tail depends on the linker length. Importantly, these results imply that nucleosome positioning in vivo not only affects the phasing of nucleosomes relative to DNA but also directs the higher-order structure of chromatin.     

Effect of salt on the binding of the linker histone H1 to DNA and nucleosomes

The linker histones are involved in the salt-dependent folding of the nucleosomes into higher-order chromatin structures. To better understand the mechanism of action of these histones in chromatin, we studied the interactions of the linker histone H1 with DNA at various histone/DNA ratios and at different ionic strengths. In direct competition experiments, we have confirmed the binding of H1 to superhelical DNA in preference to linear or nicked circular DNA forms. We show that the electrophoretic mobility of the H1/supercoiled DNA complex decreases with increasing H1 concentrations and increases with ionic strengths. These results indicate that the interaction of the linker histone H1 with supercoiled DNA results in a soluble binding of H1 with DNA at low H1 or salt concentrations and aggregation at higher H1 concentrations. Moreover, we show that H1 dissociates from the DNA or nucleosomes at high salt concentrations. By the immobilized template pull-down assay, we confirm these data using the physiologically relevant nucleosome array template.     

ACF catalyses chromatosome movements in chromatin fibres

Nucleosome-remodelling factors containing the ATPase ISWI, such as ACF, render DNA in chromatin accessible by promoting the sliding of histone octamers. Although the ATP-dependent repositioning of mononucleosomes is readily observable in vitro, it is unclear to which extent nucleosomes can be moved in physiological chromatin, where neighbouring nucleosomes, linker histones and the folding of the nucleosomal array restrict mobility. We assembled arrays consisting of 12 nucleosomes or 12 chromatosomes (nucleosomes plus linker histone) from defined components and subjected them to remodelling by ACF or the ATPase CHD1. Both factors increased the access to DNA in nucleosome arrays. ACF, but not CHD1, catalysed profound movements of nucleosomes throughout the array, suggesting different remodelling mechanisms. Linker histones inhibited remodelling by CHD1. Surprisingly, ACF catalysed significant repositioning of entire chromatosomes in chromatin containing saturating levels of linker histone H1. H1 inhibited the ATP-dependent generation of DNA accessibility by only about 50%. This first demonstration of catalysed chromatosome movements suggests that the bulk of interphase euchromatin may be rendered dynamic by dedicated nucleosome-remodelling factors.     

DNA associated with nucleosomes in plants.

50 to 55% of tobacco and barley nuclear DNA is accessible to micrococcal endonuclease digestion. The DNA fragments resulting from a mild endonuclease treatment are multiples of a basic unit of 194 +/- 6 base pairs in tobacco and 195 +/- 6 base pairs in barley. After extensive digestion, a DNA fragment of approximately 140 base pairs is predominant. Hence the "extra-core" or "linker"-DNA is 55 base pairs long. Other fragments having 158 and less than 140 base pairs are present as well. Treatment with DNase I results in multiples of 10 bases when analysed under denaturating conditions. These results show that the general organization of the DNA within the nucleosomes is about the same in higher plants as in other higher eukaryotes.     

Change in linker DNA conformation upon histone H1.5 binding to nucleosome: Fluorescent microscopy of single complexes

A method for fluorescently labeled DNA synthesis, which makes it possible to assemble mononucleosomes with 40 bp linkers, was developed. Cy3 and Cy5 labels were introduced into the linkers at distances of 10 bp before the first nucleotide and 15 bp after the last nucleotide of the nucleosome positioning DNA sequence, respectively. Without histone H1.5, f luorescence microscopy of single complexes revealed two equally probable states of nucleosomes. The states were different in the linker conformation: the open one with the energy transfer efficiency (E) between the labels of 0.06 and the closed one with E = 0.37, when the linkers are brought together. Binding of histone H1.5 with nucleosomes occurs in a range of nanomolar concentrations, and the complex formation rate is significantly higher as compared with its dissociation rate. The significant convergence of the DNA linkers (E = 0.73) is observed in these complexes together with the higher conformation uniformity in the region where the labels are localized. The developed nucleosomal constructs represent highly sensitive f luorescent sensors that can be used for the analysis of structural linker rearrangements. Also, in combination with microscopy of single complexes, they are suitable for studying the structure of complexes of nucleosomes with different chromatin architectural proteins.