Influence of histone H5 on mononucleosome structure during differentiation in the avian erythroid series

Changes in nucleosome repeat length during avian erythroid development have been previously correlated with changes in H5 content. In order to determine the effects of H5 on the length of DNA in mononucleosomal particles as a function of differentiation, a two-dimensional electrophoretic system was used to analyse DNA and histones of particles generated by micrococcal nuclease digestion of nuclei from several stages of erythroid development. Although the relative proportions of H5- to H1-containing mononucleosomes increased during development, only in mature erythrocytes did H5 protect a greater length of linker DNA from micrococcal nuclease digestion than did H1. These results suggest that changes in average nucleosome repeat length during erythroid development can be attributed only partially to an increase in the proportion of H5-containing nucleosomes which contribute to this average.     

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.     

Interaction of maize chromatin-associated HMG proteins with mononucleosomes: role of core and linker histones

Two groups of plant chromatin-associated high mobility group (HMG) proteins, namely the HMGA family, typically containing four A/T-hook DNA-binding motifs, and the HMGB family, containing a single HMG-box DNA-binding domain, have been identified. We have examined the interaction of recombinant maize HMGA and five different HMGB proteins with mononucleosomes (containing approx. 165 bp of DNA) purified from micrococcal nuclease-digested maize chromatin. The HMGB proteins interacted with the nucleosomes independent of the presence of the linker histone H1, while the binding of HMGA in the presence of H1 differed from that observed in the absence of H1. HMGA and the HMGB proteins bound H1-containing nucleosome particles with similar affinity. The plant HMG proteins could also bind nucleosomes that were briefly treated with trypsin (removing the N-terminal domains of the core histones), suggesting that the histone N-termini are dispensable for HMG protein binding. In the presence of untreated nucleosomes and trypsinised nucleosomes, HMGB1 could be chemically crosslinked with a core histone, which indicates that the trypsin-resistant part of the histones within the nucleosome is the main interaction partner of HMGB1 rather than the histone N-termini. In conclusion, these results indicate that specific nucleosome binding of the plant HMGB proteins requires simultaneous DNA and histone contacts.     

Native HMGB1 protein inhibits repair of cisplatin-damaged nucleosomes in vitro

The high mobility group box (HMGB) 1 protein, one of the most abundant nuclear non-histone proteins has been known for its inhibitory effect on repair of DNA damaged by the antitumor drug cisplatin. Here, we report the first results that link HMGB1 to repair of cisplatin-treated DNA at nucleosome level. Experiments were carried out with three types of reconstituted nucleosomes strongly positioned on the damaged DNA: linker DNA containing nucleosomes (centrally and end-positioned) and core particles. The highest repair synthesis was registered with end-positioned nucleosomes, two and three times more efficient than that with centrally positioned nucleosomes and core particles, respectively. HMGB1 inhibited repair of linker DNA containing nucleosomes more efficiently than that of core particles. Just the opposite was the effect of the in vivo acetylated HMGB1: stronger repair inhibition was obtained with core particles. No inhibition was observed with HMGB1 lacking the acidic tail. Binding of HMGB1 proteins to different nucleosomes was also analysed. HMGB1 bound preferentially to damage nucleosomes containing linker DNA, while the binding of the acetylated protein was linker independent. We show that both the repair of cisplatin-damaged nucleosomes and its inhibition by HMGB1 are nucleosome position-dependent events which are accomplished via the acidic tail and modulated by acetylation.     

Pathway-dependent reconstitution of chromatin structure from separated constituents.

Chicken reticulocyte chromatin can be reassembled from its separated constituents, viz. DNA, H1 plus H5, core histones, and non-histone proteins, to yield a product resembling the native starting material by a series of structural criteria. In particular, it possesses nucleosomes separated by spacer regions; the particles contain DNA with a unit length of approximately 200 base pairs. The recovery of the correctly reassembled product depends critically on the annealing conditions: the components are initially mixed in 2 M NaCl and 5 M urea, and it seems to be important to remove urea at a relatively high salt concentration. The results suggest that the characteristic chromatin structure is formed only when core histones bind to DNA in their native conformation and are followed by the addition of H1 and H5 to the spacer regions.     

Novel nucleosomal particles containing core histones and linker DNA but no histone H1

Eukaryotic chromosomal DNA is assembled into regularly spaced nucleosomes, which play a central role in gene regulation by determining accessibility of control regions. The nucleosome contains ∼147 bp of DNA wrapped ∼1.7 times around a central core histone octamer. The linker histone, H1, binds both to the nucleosome, sealing the DNA coils, and to the linker DNA between nucleosomes, directing chromatin folding. Micrococcal nuclease (MNase) digests the linker to yield the chromatosome, containing H1 and ∼160 bp, and then converts it to a core particle, containing ∼147 bp and no H1. Sequencing of nucleosomal DNA obtained after MNase digestion (MNase-seq) generates genome-wide nucleosome maps that are important for understanding gene regulation. We present an improved MNase-seq method involving simultaneous digestion with exonuclease III, which removes linker DNA. Remarkably, we discovered two novel intermediate particles containing 154 or 161 bp, corresponding to 7 bp protruding from one or both sides of the nucleosome core. These particles are detected in yeast lacking H1 and in H1-depleted mouse chromatin. They can be reconstituted in vitro using purified core histones and DNA. We propose that these ‘proto-chromatosomes’ are fundamental chromatin subunits, which include the H1 binding site and influence nucleosome spacing independently of H1.     

Asymmetry and polarity of nucleosomes in chicken erythrocyte chromatin.

Nucleosome dimers containing, on average, a single molecule of histone H5 have been isolated from chicken erythrocyte nuclei and the associated DNA fragments cloned and sequenced. The average sequence organization of at least one of the two nucleosomes in the dimers is highly asymmetric and suggests that the torsional, as well as the axial, flexibility of DNA is a determinant of nucleosome positioning. On average the nucleosome dimer is a polar structure containing linker DNA of variable lengths. The sequences associated with H5 containing nucleosomes and core particles are sufficiently different to indicate that removal of histone H5 (or H1) from chromatin may result in the migration of the histone octamer and a consequent exposure of sites for regulatory proteins.     

Analysis of Histones Associated with Neuronal and Glial Nuclei Exhibiting Divergent DNA Repeat Lengths

Abstract: Total cerebral hemisphere nuclei purified from adult rabbit brain were subfractionated into neuronal and glial populations. Previous studies have shown that chromatin in neuronal nuclei is organized in an unusual nucleosome conformation compared with glial or kidney nuclei, i.e., a short DNA repeat length is present. We now analyze whether this difference in chromatin organization is associated with an alteration in the histone component of nucleosomes. Total histone isolated by acid/urea-protamine extraction of purified neuronal, glial, and kidney nuclei was analyzed by electrophoresis on SDS-polyacrylamide slab gels. Histone H1 that was selectively extracted from nuclei was also examined. Differences were not observed on SDS gels in the electrophoretic mobilities of histones associated with either the nucleosome core particle (histones H2A, H2B, H3, H4) or the nucleosome linker region (histone H1). Total histone and selectively extracted histone H1 were also analyzed on acid/urea slab gels that resolve histones on the basis of both molecular weight and charge differences. When analyzed in this system, differences with respect to electrophoretic mobility were not detected when comparing either selectively extracted histone H1 or total histone from neuronal and glial nuclei. Quantitative analyses were also performed and neuronal nuclei were found to contain less histone H1 per milligram DNA compared with glial or kidney nuclei. Neuronal nuclei also demonstrated a lower ratio of histone H1/core histone. These results suggest that the pronounced difference in chromatin organization in neuronal compared with glial nuclei, which is reflected by a short DNA repeat length in neurons, appears to be associated with quantitative differences in neuronal histone H1.     

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.     

Regulation of the higher-order structure of chromatin by histones H1 and H5

Chicken erythrocyte chromatins containing a single species of linker histone, H1 or H5, have been prepared, using reassembly techniques developed previously. The reconstituted complexes possess the conformation of native chicken erythrocyte chromatin, as judged by chemical and structural criteria; saturation is reached when two molecules of linker histone are bound per nucleosome, as in native erythrocyte chromatin, which the resulting material resembles in its appearance in the electron microscope and quantitatively in its linear condensation factor relative to free DNA. The periodicity of micrococcal nuclease-sensitive sites in the linker regions associated with histone H1 or H5 is 10.4 base pairs, suggesting that the spatial organization of the linker region in the higher-order structure of chromatin is similar to that in isolated nucleosomes. The susceptible sites are cut at differing frequencies, as previously found for the nucleosome cores, leading to a characteristic distribution of intensities in the digests. The scission frequency of sites in the linker DNA depends additionally on the identity of the linker histone, suggesting that the higher-order structure is subject to secondary modulation by the associated histones.     

Structure of nucleosomes and organization of internucleosomal DNA in chromatin

We have compared the mononucleosomal pattern produced by micrococcal nuclease digestion of condensed and unfolded chromatin and chromatin in nuclei from various sources with the repeat length varying from 165 to 240 base-pairs (bp). Upon digestion of isolated H1-containing chromatin of every tested type in a low ionic strength solution (unfolded chromatin), a standard series of mononucleosomes (MN) was formed: the core particle, MN145, and H1-containing, MN165, MN175, MN185, MN195, MN205 and MN215 (the indexes give an approximate length of the nucleosomal DNA that differs in these particles by an integral number of 10 bp). In addition to the pattern of unfolded chromatin, digestion of whole nuclei or condensed chromatin (high ionic strength of Ca2+) gave rise to nuclei-specific, H1-lacking MN155. Digestion of H1-lacking chromatin produced only MN145, MN155 and MN165 particles, indicating that the histone octamer can organize up to 165 bp of nucleosomal DNA. Although digestion of isolated sea urchin sperm chromatin (repeat length of about 240 bp) at a low ionic strength gave a typical "unfolded chromatin pattern", digests of spermal nuclei contained primarily MN145, MN155, MN235 and MN245 particles. A linear arrangement of histones along DNA (primary organization) of the core particle was found to be preserved in the mononucleosomes, with the spacer DNA length from 10 to 90 bp on one (in MN155) or both sides of core DNA being a multiple of about 10 bp. In MN235, the core particle occupies preferentially a central position with the length of the spacer DNA on both sides of the core DNA being usually about 30 + 60 or 40 + 50 bp. Histone H1 is localized at the ends of these particles, i.e. close to the centre of the spacer DNA. The finding that globular part of histones H3 and sea urchin sperm H2B can covalently bind to spacer DNA suggests their involvement in the organization of chromatin superstructure. Our data indicate that decondensation of chromatin is accompanied by rearrangement of histone H1 on the spacer DNA sites adjacent to the core particle and thus support a solenoid model for the chromatin superstructure in nuclei in which the core DNA together with the spacer DNA form a continuous superhelix.     

Primary organization of nucleosomes containing all five histories and DNA 175 and 165 base-pairs long

The sequential arrangement of histones along DNA in nucleosomes containing all five histones and DNA about 165 and 175 base-pairs in length has been determined. The data provide evidence that core histones (H2A, H2B, H3 and H4) are arranged in nucleosomes and nucleosome core particles in a largely similar way with the following differences. (1) On nucleosomal DNA about 175 basepairs long core histones are probably shifted by 20 nucleotides on one DNA strand and by 10 nucleotides on the complementary DNA strand from the 5′ end. On nucleosomal DNA 165 base-pairs long, histones appear to be shifted by 10 nucleotides from the 5′ end of DNA on both the DNA strands. (2) Histone H3 is extended beyond core DNA and is bound to the 3′ end of DNA about 175 nucleotides long. Thus, core histones span the whole length of nucleosomal DNA. (3) Histone H2A seems to be absent from the central region of nucleosomal DNA. These results indicate that during the preparation of core particles, some rearrangement of histones or some of their regions occurs.Histone H1 has been shown to be bound mainly to the ends of nucleosomal DNA and, along the whole DNA length, to the gap regions that are free of core histones.     

The effect of histone H1 on the compaction of oligonucleosomes. A quasielastic light scattering study

The structural properties of H1-depleted oligonucleosomes are investigated by the use of quasielastic laser light scattering, thermal denaturation and circular dichroism and compared to those of H1-containing oligomers. To obtain information on the role of histone H1 in compaction of nucleosomes, translational diffusion coefficients (D) are determined for mono-to octanucleosomes over a range of ionic strength. The linear dependences of D on the number of nucleosomes show that the conformation of stripped oligomers is very extended and does not change drastically with increasing the ionic strength while the rigidness of the chain decreases due to the folding of linker DNA. The results prove that the salt-induced condensation is much smaller for H1-depleted than for H1-containing oligomers and that histone H1 is necessary for the formation of a supercoiled structure of oligonucleosomes, already present at low ionic strength.     

Tetrameric structure of centromeric nucleosomes in interphase Drosophila cells

Centromeres, the specialized chromatin structures that are responsible for equal segregation of chromosomes at mitosis, are epigenetically maintained by a centromere-specific histone H3 variant (CenH3). However, the mechanistic basis for centromere maintenance is unknown. We investigated biochemical properties of CenH3 nucleosomes from Drosophila melanogaster cells. Cross-linking of CenH3 nucleosomes identifies heterotypic tetramers containing one copy of CenH3, H2A, H2B, and H4 each. Interphase CenH3 particles display a stable association of approximately 120 DNA base pairs. Purified centromeric nucleosomal arrays have typical “beads-on-a-string” appearance by electron microscopy but appear to resist condensation under physiological conditions. Atomic force microscopy reveals that native CenH3-containing nucleosomes are only half as high as canonical octameric nucleosomes are, confirming that the tetrameric structure detected by cross-linking comprises the entire interphase nucleosome particle. This demonstration of stable half-nucleosomes in vivo provides a possible basis for the instability of centromeric nucleosomes that are deposited in euchromatic regions, which might help maintain centromere identity.     

Tetrameric Structure of Centromeric Nucleosomes in Interphase Drosophila Cells

Centromeres, the specialized chromatin structures that are responsible for equal segregation of chromosomes at mitosis, are epigenetically maintained by a centromere-specific histone H3 variant (CenH3). However, the mechanistic basis for centromere maintenance is unknown. We investigated biochemical properties of CenH3 nucleosomes from Drosophila melanogaster cells. Cross-linking of CenH3 nucleosomes identifies heterotypic tetramers containing one copy of CenH3, H2A, H2B, and H4 each. Interphase CenH3 particles display a stable association of approximately 120 DNA base pairs. Purified centromeric nucleosomal arrays have typical “beads-on-a-string” appearance by electron microscopy but appear to resist condensation under physiological conditions. Atomic force microscopy reveals that native CenH3-containing nucleosomes are only half as high as canonical octameric nucleosomes are, confirming that the tetrameric structure detected by cross-linking comprises the entire interphase nucleosome particle. This demonstration of stable half-nucleosomes in vivo provides a possible basis for the instability of centromeric nucleosomes that are deposited in euchromatic regions, which might help maintain centromere identity.     

Higher order chromatin structure determines double-nucleosome periodicity of DNA fragmentation

Double-nucleosome periodicity of DNA fragmentation with DNAse I in the nuclei of cells differing in size of the linker DNA length and lysine-rich histone composition was analyzed by means of nondenaturing agarose gel electrophoresis. DNAse I revealed this type of periodicity in rat thymus and CHO cell nuclei as well as in erythrocyte nuclei. It has been deduced that the so-called nucleodisome structure is also typical of cells possessing a usual DNA repeat length (200 bp or less) and lysine-rich histone H1. Two probably related events are important for establishing a clear double-nucleosome periodicity of DNA fragmentation: the replacement of H1 histone by a specific arginine-rich histone fraction (H5 histone in the case of erythrocyte) and the increase of the linker DNA length. The results are interpreted in terms of supranucleosomal organization of chromatin which may determine the dinucleosome periodicity of DNA fragmentation due to a specific packing of nucleosomes.     

Effect of DNA length and H4 acetylation on the thermal stability of reconstituted nucleosome particles

To examine the factors involved with nucleosome stability, we reconstituted nonacetylated particles containing various lengths (192, 162, and 152 base pairs) of DNA onto the Lytechinus variegatus nucleosome positioning sequence in the absence of linker histone. We characterized the particles and examined their thermal stability. DNA of less than chromatosome length (168 base pairs) produces particles with altered denaturation profiles, possibly caused by histone rearrangement in those core-like particles. We also examined the effects of tetra-acetylation of histone H4 on the thermal stability of reconstituted nucleosome particles. Tetra-acetylation of H4 reduces the nucleosome thermal stability by 0.8 degrees C as compared with nonacetylated particles. This difference is close to values published comparing bulk nonacetylated nucleosomes and core particles to ones enriched for core histone acetylation, suggesting that H4 acetylation has a dominant effect on nucleosome particle energetics.     

Differential association of linker histones H1 and H5 with telomeric nucleosomes in chicken erythrocytes.

Rat liver telomeric DNA is organised into nucleosomes characterised by a shorter and more homogeneous average nucleosomal repeat than bulk chromatin as shown by Makarov et al. (1). The latter authors were unable to detect the association of any linker histone with the telomeric DNA. We have confirmed these observations but show that in sharp contrast chicken erythrocyte telomeric DNA is organised into nucleosomes whose spacing length and heterogeneity are indistinguishable from those of bulk chromatin. We further show that chicken erythrocyte telomeric chromatin contains chromatosomes which are preferentially associated with histone H1 relative to histone H5. This contrasts with bulk chromatin where histone H5 is the more abundant species. This observation strongly suggests that telomeric DNA condensed into nucleosome core particles has a higher affinity for H1 than H5. We discuss the origin of the discrimination of the lysine rich histones in terms of DNA sequence preferences, telomere nucleosome preferences and particular constraints of the higher order chromatin structure of telomeres.