Preferentially quantized linker DNA lengths in Saccharomyces cerevisiae

The exact lengths of linker DNAs connecting adjacent nucleosomes specify the intrinsic three-dimensional structures of eukaryotic chromatin fibers. Some studies suggest that linker DNA lengths preferentially occur at certain quantized values, differing one from another by integral multiples of the DNA helical repeat, approximately 10 bp; however, studies in the literature are inconsistent. Here, we investigate linker DNA length distributions in the yeast Saccharomyces cerevisiae genome, using two novel methods: a Fourier analysis of genomic dinucleotide periodicities adjacent to experimentally mapped nucleosomes and a duration hidden Markov model applied to experimentally defined dinucleosomes. Both methods reveal that linker DNA lengths in yeast are preferentially periodic at the DNA helical repeat ( approximately 10 bp), obeying the forms 10n+5 bp (integer n). This 10 bp periodicity implies an ordered superhelical intrinsic structure for the average chromatin fiber in yeast.     

Local geometry and elasticity in compact chromatin structure

The hierarchical packaging of DNA into chromatin within a eukaryotic nucleus plays a pivotal role in both the accessibility of genomic information and the dynamics of replication. Our work addresses the role of nanoscale physical and geometric properties in determining the structure of chromatin at the mesoscale level. We study the packaging of DNA in chromatin fibers by optimization of regular helical morphologies, considering the elasticity of the linker DNA as well as steric packing of the nucleosomes and linkers. Our model predicts a broad range of preferred helix structures for a fixed linker length of DNA; changing the linker length alters the predicted ensemble. Specifically, we find that the twist registry of the nucleosomes, as set by the internucleosome repeat length, determines the preferred angle between the nucleosomes and the fiber axis. For moderate to long linker lengths, we find a number of energetically comparable configurations with different nucleosome-nucleosome interaction patterns, indicating a potential role for kinetic trapping in chromatin fiber formation. Our results highlight the key role played by DNA elasticity and local geometry in regulating the hierarchical packaging of the genome.     

Nucleosome DNA repeat length and histone complement in a fungus exhibiting condensed chromatin

Fungal chromatins are reported to exhibit unusually short nucleosomal DNA repeat lengths. To test whether this is a phylogenetic feature of fungi or rather is correlated with an apparent absence of condensed chromatin in the organisms studied, we have examined the chromatin organization and the complement of basic nuclear proteins in the fungus Entomophthora, an organism which exhibits marked chromatin condensation. Micrococcal nuclease digestion of Entomophthora chromatin revealed a nucleosomal DNA repeat length of 197 +/- 1.2 base pairs (bp). This repeat length is 20-40 bp longer than that reported for any fungus. Entomophthora nucleosomes exhibited an HI-like protein which was much less basic than the HI histones reported for higher eukaryotes but which was similar in basicity to the HI histone reported for the fungus Neurospora. However, the nucleosomal DNA repeat length of Neurospora chromatin is reported to be unusually short, whereas that of Entomophthora was found to be typical of the repeat lengths observed for chromatins of higher eukaryotes. Thus, repeat length, at least in fungi, would not appear to be directly determined by the basicity of the fungal cognate of histone HI.     

Organization of internucleosomal DNA in rat liver chromatin

A detailed analysis of the length distribution of DNA in nucleosome dimers trimmed with exonuclease III and S1 nuclease suggests that the previously described variation of internucleosomal distance in rat liver occurs, at least for a subset of the nucleosomes, by integral multiples of the helical repeat of the DNA. Results obtained upon digestion of chromatin with DNase II further suggest that lengths of internucleosomal DNA are integral multiples of the helical repeat of the DNA plus approximately 5 bp. Restraints imposed by these features on the arrangement of nucleosomes along the fiber are discussed.     

Comparative analysis of the nucleosomal structure of rye,wheat and their relatives

Analysis of the structure of chromatin in cereal species using micrococcal nuclease (MNase) cleavage showed nucleosomal organization and a ladder with typical nucleosomal spacing of 175–185 bp. Probing with a set of DNA probes localized in the authentic telomeres, subtelomeric regions and bulk chromatin revealed that these chromosomal regions have nucleosomal organization but differ in size of nucleosomes and rate of cleavage between both species and regions. Chromatin from Secale and Dasypyrum cleaved more quickly than that from wheat and barley, perhaps because of their higher content of repetitive sequences with hairpin structures accessible to MNase cleavage. In all species, the telomeric chromatin showed more rapid cleavage kinetics and a shorter nucleosome length (160 bp spacing) than bulk chromatin. Rye telomeric repeat arrays were shortest, ranging from 8 kb to 50 kb while those of wheat ranged from 15 kb up to 175 kb. A gradient of sensitivity to MNase was detected along rye chromosomes. The rye-specific subtelomeric sequences pSc200 and pSc250 have nucleosomes of two lengths, those of the telomeric and of bulk nucleosomes, indicating that the telomeric structure may extended into the chromosomes. More proximal sequences common to rye and wheat, the short tandem-repeat pSc119.2 and rDNA sequence pTa71, showed longer nucleosomal sizes characteristic of bulk chromatin in both species. A strictly defined spacing arrangement (phasing) of nucleosomes was demonstrated along arrays of tandem repeats with different monomer lengths (118, 350 and 550 bp) by combining MNase and restriction enzyme digestion.     

A defined structure of the 30 nm chromatin fibre which accommodates different nucleosomal repeat lengths

Earlier work on the condensation of chromatins of different repeat lengths into the 30 nm fibre has been surveyed and it is shown that the external geometry of the fibre must be the same for all the chromatins. This can only be fitted by a helical coiling of nucleosomes into a solenoid with the linker DNA disposed internally. On this basis, various models were calculated and compared with published electric dichroism data. The only good fit is found with a 'reverse-loop' model, where the linker DNA forms a complete turn into the hole of the solenoid, of opposite hand to the nucleosomal DNA superhelix. This gives a topological linking number of one per nucleosome and would resolve the 'linking number paradox' if the DNA screw is the same in chromatin as in solution. The feasibility of a reverse-loop for short linkers (down to 15 base pairs) was investigated by model building and kinks of approximately 120 degrees into both DNA grooves are described, which will allow such packing. There will, however, be a 'forbidden' range for the linker DNA length, between approximately 1 and 14 bp, corresponding to nucleosomal repeats of 163 and 176 bp.     

Partial purification, from Xenopus laevis oocytes, of an ATP-dependent activity required for nucleosome spacing in vitro.

A critical feature of chromatin with regard to structure and function is the regular spacing of nucleosomes. In vivo, spacing of nucleosomes occurs in at least two steps, but the mechanism is not understood. In this report, we have mimicked the two-step process in vitro. A novel spacing activity has been partially purified from Xenopus laevis ovaries. When this activity is added, either at the beginning or at the end of a nucleosomal assembly reaction, it can convert a DNA template consisting of irregularly spaced nucleosomes into a chromatin structure made up of regularly spaced nucleosomes with a repeat length of about 165 base pairs. The reaction requires ATP. Histone H1 is able to increase the nucleosomal repeat from 165 to 190 base pairs. This two-step increase in nucleosomal repeat length suggests that both the spacing activity and histone H1 contribute to generating repeat lengths of greater than 165 base pairs and that their contributions may be additive. Alternatively, the critical step in the spacing reaction may not be the formation of the 165-base pair repeat but may be the sliding of nucleosomes or the reorganization of the octamer structure induced by the spacing activity.     

Organization of 5S genes in chromatin of Xenopus laevis.

The chromatin organization of the genes coding for 5S RNA in Xenopus laevis has been investigated with restriction endonucleases and micrococcal nuclease. Digestion of nuclei from liver, kidney, blood and kidney cells maintained in culture with micrococcal nuclease reveals that these Xenopus cells and tissues have shorter nucleosome repeat lengths than the corresponding cells and tissues from other higher organisms. 5S genes are organized in nucleosomes with repeat lengths similar to those of the bulk chromatin in liver (178 bp) and cultured cells (165 bp); however, 5S gene chromatin in blood cells has a shorter nucleosome repeat (176 bp) than the bulk of the genome in these cells (184 bp). From an analysis of the 5S DNA fragments produced by extensive restriction endonuclease cleavage of chromatin in situ, no special arrangement of the nucleosomes with respect to the sequence of 5S DNA can be detected. The relative abundance of 5S gene multimers follows a Kuhn distribution, with about 57% of all HindIII sites cleaved. This suggests that HindIII sites can be cleaved both in the nucleosome core and linker regions.     

Computer simulation of the 30-nanometer chromatin fiber

A new Monte Carlo model for the structure of chromatin is presented here. Based on our previous work on superhelical DNA and polynucleosomes, it reintegrates aspects of the "solenoid" and the "zig-zag" models. The DNA is modeled as a flexible elastic polymer chain, consisting of segments connected by elastic bending, torsional, and stretching springs. The electrostatic interaction between the DNA segments is described by the Debye-Hückel approximation. Nucleosome core particles are represented by oblate ellipsoids; their interaction potential has been parameterized by a comparison with data from liquid crystals of nucleosome solutions. DNA and chromatosomes are linked either at the surface of the chromatosome or through a rigid nucleosome stem. Equilibrium ensembles of 100-nucleosome chains at physiological ionic strength were generated by a Metropolis-Monte Carlo algorithm. For a DNA linked at the nucleosome stem and a nucleosome repeat of 200 bp, the simulated fiber diameter of 32 nm and the mass density of 6.1 nucleosomes per 11 nm fiber length are in excellent agreement with experimental values from the literature. The experimental value of the inclination of DNA and nucleosomes to the fiber axis could also be reproduced. Whereas the linker DNA connects chromatosomes on opposite sides of the fiber, the overall packing of the nucleosomes leads to a helical aspect of the structure. The persistence length of the simulated fibers is 265 nm. For more random fibers where the tilt angles between two nucleosomes are chosen according to a Gaussian distribution along the fiber, the persistence length decreases to 30 nm with increasing width of the distribution, whereas the other observable parameters such as the mass density remain unchanged. Polynucleosomes with repeat lengths of 212 bp also form fibers with the expected experimental properties. Systems with larger repeat length form fibers, but the mass density is significantly lower than the measured value. The theoretical characteristics of a fiber with a repeat length of 192 bp where DNA and nucleosomes are connected at the core particle are in agreement with the experimental values. Systems without a stem and a repeat length of 217 bp do not form fibers.     

Higher-order structure of long repeat chromatin.

The higher-order structure of chromatin isolated from sea urchin sperm, which has a long nucleosomal DNA repeat length (approximately 240 bp), has been studied by electron microscopy and X-ray diffraction. Electron micrographs show that this chromatin forms 300 A filaments which are indistinguishable from those of chicken erythrocytes (approximately 212 bp repeat); X-ray diffraction patterns from partially oriented samples show that the edge-to-edge packing of nucleosomes in the direction of the 300 A filament axis, and the radial disposition of nucleosomes around it, are both similar to those of the chicken erythrocyte 300 A filament, which is described by the solenoid model. The invariance of the structure with increased linker DNA length is inconsistent with many other models proposed for the 300 A filament and, furthermore, means that the linker DNA must be bent. The low-angle X-ray scattering in the 300-400 A region both in vitro and in vivo differs from that of chicken erythrocyte chromatin. The nature of the difference suggests that 300 A filaments in sea urchin sperm in vivo are packed so tightly together that electron-density contrast between individual filaments is lost; this is consistent with electron micrographs of the chromatin in vitro.     

Influence of nucleosome structure on the three-dimensional folding of idealized minichromosomes.

BACKGROUND: The closed circular, multinucleosome-bound DNA comprising a minichromosome provides one of the best known examples of chromatin organization beyond the wrapping of the double helix around the core of histone proteins. This higher level of chain folding is governed by the topology of the constituent nucleosomes and the spatial disposition of the intervening protein-free DNA linkers. RESULTS: By simplifying the protein-DNA assembly to an alternating sequence of virtual bonds, the organization of a string of nucleosomes on the minichromosome can be treated by analogy to conventional chemical depictions of macromolecular folding in terms of the bond lengths, valence angles, and torsions of the chain. If the nucleosomes are evenly spaced and the linkers are sufficiently short, regular minichromosome structures can be identified from analytical expressions that relate the lengths and angles formed by the virtual bonds spanning the nucleosome-linker repeating units to the pitch and radius of the organized quaternary structures that they produce. CONCLUSIONS: The resulting models with 4-24 bound nucleosomes illustrate how a minichromosome can adopt the low-writhe folding motifs deduced from biochemical studies, and account for published images of the 30 nm chromatin fiber and the simian virus 40 (SV40) nucleohistone core. The marked sensitivity of global folding to the degree of protein-DNA interactions and the assumed nucleosomal shape suggest potential mechanisms for chromosome rearrangements upon histone modification.     

On the occurrence of nucleosome phasing in chromatin.

We have found that DNAase I digestion of yeast, HeLa and chicken erythrocyte nuclei produces a pattern of DNA fragments spaced 10 bases apart and extending to at least 300 bases. This "extended ladder" of DNA fragments is most clearly seen with yeast, and least clearly with chicken erythrocytes. The appearance of regular and discrete bands at sizes much larger than the repeat size shows that the core particles (140 bp of DNA + H2A, H2B, H3 H4) in at least some fraction of chromatin are spaced in a particular fashion, by discrete lengths of spacer DNA, and not randomly. Based on the abundance of small repeats in yeast and from experiments with nucleosome oligomers, we conclude that the extended ladder and nucleosomal phasing probably arise mainly from regions in the chromatin in which nucleosome cores are closely packed or closely spaced (140-160 bp X n). Contributions from less closely packed but still accurately phased nucleosomes, however, cannot be entirely excluded.     

Chromatin reconstituted from tandemly repeated cloned DNA fragments and core histones: a model system for study of higher order structure

We describe a model system for study of chromatin structure at levels above that of the nucleosome. A series of fragments with lengths ranging from 172 to 207 bp tandemly repeated three to greater than 50 times was prepared; each repeat contains the region important in forming a positioned core particle on a sea urchin 5S rRNA gene upon in vitro association with histones. The tandemly repeated sequences can be studied as linear DNA fragments or as relaxed or supercoiled circular molecules. A number of criteria indicate that nucleosomes position correctly on all the tandemly repeated elements. Measurement of the change in linking number per core particle led to a value of -1.0. Both length and repeat number dependent changes in conformation of the nucleoproteins are observed. We discuss the possibility that some ordered higher level chromatin structure can form with DNA and core histones alone.     

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.     

Nucleosome rearrangement in vitro. 1. Two phases of salt-induced nucleosome migration in nuclei

We have investigated the salt- and temperature-induced rearrangement of nucleosomes in both intact and H1-depleted nuclei from human cells. In agreement with previous reports on the rearrangement of nucleosomes in isolated chromatin or chromatin fragments, we observed a decrease in the average nucleosome repeat length following incubation of nuclei at 37 degrees C in elevated salt concentrations. However, this decrease occurred in two distinct phases. First, incubation of H1-depleted nuclei at 37 degrees C for as little as 10 min in low-salt, isotonic buffer (containing 0.025 M KCl) resulted in a shift in the limiting repeat value from approximately 190 to 168 base pairs (bp). A similar shift was observed for intact nuclei incubated at 37 degrees C for 1 h in buffer containing near-physiological salt concentrations (i.e., 0.175 M KCl). This limiting repeat value was maintained in both intact and H1-depleted nuclei up to a salt concentration of 0.45 M KCl in the incubation buffer. Second, at salt concentrations of 0.625 M KCl, a limiting repeat of approximately 146 bp was obtained, and the nuclei had clearly lysed. During the first shift in repeat length, little additional exchange of nuclear proteins occurred compared to nuclei kept on ice in a low-salt buffer. This was the case even though the conditions used to monitor exchange were optimized by using a high DNA to chromatin ratio. On the other hand, a significant increase in the exchange of nuclear proteins, and formation of nucleosomes on the naked DNA, was observed during the shift in repeat length to 146 bp.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNase I digestion reveals alternating asymmetrical protection of the nucleosome by the higher order chromatin structure

DNase I was used to probe the higher order chromatin structure in whole nuclei. The digestion profiles obtained were the result of single-stranded cuts and were independent of pH, type of divalent ion and chromatin repeat length. Furthermore, the protection from digestion of the DNA at the entry/exit points on the nucleosome was found to be caused not by the H1/H5 histone tails, but by the compact structure that these proteins support. In order to resolve symmetry ambiguities, DNase I digestion fragments over several nucleosome repeat lengths were analysed quantitatively and compared with computer simulations using combinations of the experimentally obtained rate constants (some of which were converted to 0 to simulate steric protection from DNase I digestion). A clear picture of precisely defined, alternating, asymmetrically protected nucleosomes emerged. The linker DNA is inside the fibre, while the nucleosomes are positioned above and below a helical path and/or with alternating orientation towards the dyad axis. The dinucleosomal modulation of the digestion patterns comes from alternate protection of cutting sites inside the nucleosome and not from alternating exposure to the enzyme of the linker DNA.     

Possible nucleosome arrangements in the higher-order structure of chromatin

Consideration has been given to possible sequences of nucleosomes which can produce a ‘thick fibre’-like structure. Only a few basic requirements were imposed: (i) the thick fibre is a regular single helix with about 7 nucleosomes per turn; (ii) the nucleosomes are equidistant along the polynuclesome chain; (iii) the helix is flexible having variable pitch. It was found that in addition to the straightforward sequential arrangement there is only one other nonsequential arrangement which satisfies these requirements. This is a helix with around 8 nucleosomes per turn in which all nucleosomes are identically placed. It is possible in the region of 200 to 218 ± 10 base pairs (b.p.) DNA repeats lengths. The linker DNA is straight or almost straight and crosses the internal ‘hollow’ cylinder which is not occupied by nucleosomes. This structure satisfies the experimental data for the distance distribution function, and the observed mass per unit length and changes noted in the mass per unit length. Further, if it is assumed that the core particle axis of symmetry is in the plane of the two linkers and bisects them then this makes the core particles oblique to the thick fibre radii with alternate angles of ± 20 to 30°. This orientation of the nucleosomes can explain the DNA digestion patterns obtained with DNase II and with DNase I.