Histone acetylation reduces H1-mediated nucleosome interactions during chromatin assembly

During chromatin replication and nucleosome assembly, newly synthesized histone H4 is acetylated before it is deposited onto DNA, then deacetylated as assembly proceeds. In a previous study (Perry and Annunziato, Nucleic Acids Res. 17, 4275 [1989]) it was shown that when replication occurs in the presence of sodium butyrate (thereby inhibiting histone deacetylation), nascent chromatin fails to mature fully and instead remains preferentially sensitive to DNaseI, more soluble in magnesium, and depleted of histone H1 (relative to mature chromatin). In the following report the relationships between chromatin replication, histone acetylation, and H1-mediated nucleosome aggregation were further investigated. Chromatin was replicated in the presence or absence of sodium butyrate; isolated nucleosomes were stripped of linker histone, reconstituted with H1, and treated to produce Mg(2+)-soluble and Mg(2+)-insoluble chromatin fractions. Following the removal of H1, all solubility differences between chromatin replicated in sodium butyrate for 30 min (bu-chromatin) and control chromatin were lost. Reconstitution with H1 completely restored the preferential Mg(2+)-solubility of bu-chromatin, demonstrating that a reduced capacity for aggregation/condensation is an inherent feature of acetylated nascent nucleosomes; however, titration with excess H1 caused the solubility differences to be lost again. Moreover, when the core histone N-terminal "tails" (the sites of acetylation) were removed by trypsinization prior to reconstitution, H1 was unable to reestablish the altered solubility of chromatin replicated in butyrate. Thus, the core histone "tails," and the acetylation thereof, not only modulate H1-mediated nucleosome interactions in vitro, but also strongly influence the ability of H1 to differentiate between new and old nucleosomes. The data suggest a possible mechanism for the control of H1 deposition and/or chromatin folding during nucleosome assembly.     

Histone H1 depletion in mammals alters global chromatin structure but causes specific changes in gene regulation

Linker histone H1 plays an important role in chromatin folding in vitro. To study the role of H1 in vivo, mouse embryonic stem cells null for three H1 genes were derived and were found to have 50% of the normal level of H1. H1 depletion caused dramatic chromatin structure changes, including decreased global nucleosome spacing, reduced local chromatin compaction, and decreases in certain core histone modifications. Surprisingly, however, microarray analysis revealed that expression of only a small number of genes is affected. Many of the affected genes are imprinted or are on the X chromosome and are therefore normally regulated by DNA methylation. Although global DNA methylation is not changed, methylation of specific CpGs within the regulatory regions of some of the H1 regulated genes is reduced. These results indicate that linker histones can participate in epigenetic regulation of gene expression by contributing to the maintenance or establishment of specific DNA methylation patterns.     

HMG proteins 14 and 17 become cross-linked to the globular domain of histone H3 near the nucleosome core particle dyad.

HMG proteins were derivatized with the photoactivatable cross-linker N-succinimidyl 3-((4-azidophenyl)dithio)propionate and then allowed to associate with nucleosome core particles. Following photolysis, peptide mapping of the principal dimeric adducts was carried out. Cross-linking occurred primarily from a central location in the HMGs to a central location in H3. The positions of these cross-links, considered along with other data from the literature, show that HMG proteins 14 and 17 make important contacts to H3 near the front face of the nucleosome. This raises the possibility that HMGs 14 and 17 participate in the reported conformational transition which exposes the H3 sulfhydryls of active nucleosomes.     

Histone tails and the H3 alphaN helix regulate nucleosome mobility and stability

Nucleosomes fulfill the apparently conflicting roles of compacting DNA within eukaryotic genomes while permitting access to regulatory factors. Central to this is their ability to stably associate with DNA while retaining the ability to undergo rearrangements that increase access to the underlying DNA. Here, we have studied different aspects of nucleosome dynamics including nucleosome sliding, histone dimer exchange, and DNA wrapping within nucleosomes. We find that alterations to histone proteins, especially the histone tails and vicinity of the histone H3 alphaN helix, can affect these processes differently, suggesting that they are mechanistically distinct. This raises the possibility that modifications to histone proteins may provide a means of fine-tuning specific aspects of the dynamic properties of nucleosomes to the context in which they are located.     

Ectopic histone H3S10 phosphorylation causes chromatin structure remodeling in Drosophila

Histones are subject to numerous post-translational modifications that correlate with the state of higher-order chromatin structure and gene expression. However, it is not clear whether changes in these epigenetic marks are causative regulatory factors in chromatin structure changes or whether they play a mainly reinforcing or maintenance role. In Drosophila phosphorylation of histone H3S10 in euchromatic chromatin regions by the JIL-1 tandem kinase has been implicated in counteracting heterochromatization and gene silencing. Here we show, using a LacI-tethering system, that JIL-1 mediated ectopic histone H3S10 phosphorylation is sufficient to induce a change in higher-order chromatin structure from a condensed heterochromatin-like state to a more open euchromatic state. This effect was absent when a ;kinase dead' LacI-JIL-1 construct without histone H3S10 phosphorylation activity was expressed. Instead, the 'kinase dead' construct had a dominant-negative effect, leading to a disruption of chromatin structure that was associated with a global repression of histone H3S10 phosphorylation levels. These findings provide direct evidence that the epigenetic histone tail modification of H3S10 phosphorylation at interphase can function as a causative regulator of higher-order chromatin structure in Drosophila in vivo.     

Mitosis-specific histone H3 phosphorylation in vitro in nucleosome structures

A mechanism of mitosis-specific enhancement of histone H3 phosphorylation was analyzed in vitro in terms of nucleosome structure. The incorporation of [32P]phosphate into DNA-bound H3 was approximately 5-7 times higher than in DNA-free H3 using the catalytic subunit of cAMP-dependent protein kinase. The two major N-terminal serine sites, including the mitosis-specific site (Ser10) and Ser28, were extensively phosphorylated in the DNA-bound forms. These phosphorylation patterns were identical to those of nucleosomal H3. In contrast, the H3 in DNA-free octamers was very slightly phosphorylated. The major site of H3 phosphorylation in DNA-free H3 was Thr118 in the C-terminus. Results indicate that DNA-binding is essential for the high level of mitosis-specific H3 phosphorylation, and that the nucleosome structure promotes H3 N-terminal phosphorylation in vitro. It also suggests the possibility that H1 prevents H3 phosphorylation during interphase of the cell cycle.     

H2A.Z alters the nucleosome surface to promote HP1alpha-mediated chromatin fiber folding

Controlling the degree of higher order chromatin folding is a key element in partitioning the metazoan genome into functionally distinct chromosomal domains. However, the mechanism of this fundamental process is poorly understood. Our recent studies suggested that the essential histone variant H2A.Z and the silencing protein HP1alpha may function together to establish a specialized conformation at constitutive heterochromatic domains. We demonstrate here that HP1alpha is a unique chromatin binding protein. It prefers to bind to condensed higher order chromatin structures and alters the chromatin-folding pathway in a novel way to locally compact individual chromatin fibers without crosslinking them. Strikingly, both of these features are enhanced by an altered nucleosomal surface created by H2A.Z (the acidic patch). This shows that the surface of the nucleosome can regulate the formation of distinct higher order chromatin structures mediated by an architectural chromatin binding protein.     

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.     

Histone variant H2ABbd confers lower stability to the nucleosome

The histone H2ABbd is a novel histone variant of H2A with a totally unknown function. We have investigated the behaviour of the H2ABbd nucleosomes. Nucleosomes were reconstituted with recombinant histone H2ABbd and changes in their conformations at different salt concentrations were studied by analytical centrifugation. The data are in agreement with H2ABbd being less tightly bound compared with conventional H2A in the nucleosome. In addition, stable cell lines expressing either green fluorescent protein (GFP)-H2A or GFP-H2ABbd were established and the mobility of both fusions was measured by fluorescence recovery after photobleaching. We show that GFP-H2ABbd exchanges much more rapidly than GFP-H2A within the nucleosome. The reported data are compatible with a lower stability of the variant H2ABbd nucleosome compared with the conventional H2A particle.     

Histone H1-DNA interactions and their relation to chromatin structure and function

The belief that histone H1 interacts primarily with DNA in chromatin and much less with the protein component has led to numerous studies of artificial H1-DNA complexes. This review summarizes and discusses the data on different aspects of the interaction between the linker histone and naked DNA, including cooperativity of binding, preference for supercoiled DNA, selectivity with respect to base composition and nucleotide sequence, and effect of H1 binding on the conformation of the underlying DNA. The nature of the interaction, the structure of the complexes, and the role histone H1 exerts in chromatin are also discussed.     

Higher-order structure of nucleosome oligomers from short-repeat chromatin

Sedimentation measurements and electron microscopy at a series of ionic strengths suggest that chromatin from neurons of the cerebral cortex is able to form condensed structures in vitro that are probably several turns of a solenoid with about six nucleosomes per turn. Since neuronal chromatin has a short nucleosomal repeat (approximately 165 bp) allowing virtually no linker DNA between nucleosomes, and yet forms apparently 'normal' elements of solenoid, the packing of nucleosomes in the solenoid must be highly constrained. This permits only a limited number of possible models, and enables tentative suggestions to be made about the location of the linker DNA in the typical solenoid.     

Histone H1 can be removed selectively from chicken erythrocyte chromatin at near physiological conditions.

Histone H1 was depleted selectively from chicken erythrocyte polynucleosomes, without any detectable concomitant loss of H5 or core particle histones. The depletion is performed with ion exchange resin at low ionic strength (80 mM NaCl). The nucleosomes did not slide during the procedure. In contrast to the native chromatin, H1 depleted polynucleosomes are completely soluble in the 5--600 mM NaCl range.