Photochemical cross-linking of histones to DNA nucleosomes.

Ultraviolet (UV)-induced cross-linking was utilized in order to identify histone-DNA interacting regions in the chromatin repeating unit. Fractionated mononucleosomes which contained 185 base pairs of DNA and a full complement of the histones, including histone H1, were irradiated with light of lambda greater than 290nm in the presence of a photosensitizer. Equimolar amounts of histones H2A and H2B were found, by two independent labeling experiments, to be cross-linked to the DNA. Based on previous finding that the UV irradiation specifically cross-links residues which are in close proximity, irrespective of the nature of the amino acid side chain or the nucleotide involved, our results indicate that the four core histones are not positioned equivalently with respect to the DNA. This arrangement allows histones H2A and H2B to preferentially cross-link to the DNA. A water soluble covalent complex of DNA and histones was isolated. This complex was partially resistant to mild nuclease digestion, it exhibited a CD spectrum similar to that of chromatin, and was found to contain histone H1. These results are compatible with a model which suggests that histone H1, though anchored to the linker, is bound to the DNA at additional sites. By doing so it spans the whole length of the nucleosome and clamps together the DNA fold around the histone core.     

Histone-DNA interactions within chromatin. Isolation of histones from DNA-histone adducts induced in nuclei by UV light.

We have developed a method by which to isolate histones that have been crosslinked to DNA following irradiation of calf thymus nuclei by UV light. The procedure involves separation of protein-DNA adducts from uncrosslinked protein by Sepharose 4B chromatography under dissociating conditions. Histones which are crosslinked to DNA are released by chemical hydrolysis of the DNA and identified by SDS gel electrophoresis. The results indicate that, of the histones, H1 and H3 become crosslinked to the DNA most readily under our irradiation conditions.     

DNA-protein interactions in nucleosomes and in chromatin. Structural studies of chromatin stabilized by ultraviolet-light induced crosslinking.

Crosslinking induced by ultraviolet light irradiation at 254 nm has been utilized to investigate the structure of chromatin and isolated nucleosomes. The results presented here imply that the four core histones, as well as histone H1, have reactive groups within a bond length of the DNA bases. In nucleosomes depleted of H1, all of the core histones react similarly with the DNA and form crosslinks. In chromatin, the rate of crosslinking of all histones to DNA is essentially similar. Comparison of mononucleosomes, dinucleosomes and whole chromatin shows that the rate of crosslinking increases significantly with increasing number of connected nucleosomes. These differences in the rate of crosslinking are interpreted in terms of interactions between neighbouring nucleosomes on the chromatin fiber, which are absent in an isolated mononucleosome.     

The type of interaction of histone H5 wo ith DNA changes significantly at various stages of chromatin condensation

Histones were covalently bound to DNA by dimethylsulfate-induced crosslinking and DNA-contacting peptides of histone H5, thus modified, were mapped by a combination of peptide cleavage reactions and peptide gel electrophoresis. In the nucleosome, the only strong crosslinking point is His-25 which resides near the ends of nucleosomal DNA. This contact point persists throughout different steps of chromatin condensation--decondensation. In decondensed chromatin, it is supplemented by the contact with DNA of the N-terminus of the histone H5 molecule. The high level of chromatin condensation existing in the nuclei or induced by bivalent cations results in a new and considerably stronger crosslinking point His-62, which is also characteristic for cooperative H5-DNA complexes. This structural change is observed only on oligonucleosomal chains containing no less than 3 contiguous nucleosomes, and is absent in isolated mono- or dinucleosomes. We propose that the formation of the 30-nm chromatin fibre, typical for the nuclei, is accomplished in part by the histone H5-linker DNA cooperative interactions, manifested by strong His-62--linker DNA contact.     

ADP-ribosylation of pancreatic histone H1 and of other histones

Incubation of pancreatic nuclei with high NAD concentrations resulted in increased ADP-ribosylation of histone H1. Interaction of [3H]ADP-ribosylated histone H1 with chromatin was significantly different from unmodified histone H1. The presence of a protein which is eluted at a lower salt concentration and which is ADP-ribosylated was also noticed. Pancreatic histones were isolated by column chromatography and their degree of ADP-ribosylation evaluated both by gel electrophoresis and by chromatography: histone H1 was the main acceptor while the core histones H3, H2B, and H2A were lightly labelled. Histones H1 and H1(0) have a differential binding to pancreatic chromatin and histone H1(0) is not ADP-ribosylated.     

Protein-protein and protein-DNA interactions in calf thymus nuclear matrix using cross-linking by ultraviolet irradiation

Nuclear matrices from calf thymus contained 30-50 protein species with one prominent band at 70 kilodaltons tentatively identified by its isoelectric point, apparent molecular weight, charge modification, and abundance as bovine lamin. The amount of DNA present in the matrix fraction was strongly dependent on the extent of digestion of the nuclei by micrococcal nuclease. The size of the DNA was higher than two kilobase pairs, although the chromatin DNA had been digested down to short oligonucleosomes. The lamin band was preferentially dissociated from isolated matrices during repeated treatment by 2 M NaCl or 5 M urea. Irradiation of calf thymus nuclear matrices at 313 nm induced protein-protein and protein-DNA cross-linking, as well as double-strand breaking of DNA, presumably at unprotected, protein-free regions. Lamin protein was more dramatically affected than other protein species by ultraviolet (UV) irradiation. In situ DNA hydrolysis, after the separation of the cross-linked matrix components on polyacrylamide-sodium dodecyl sulfate gels, followed by two-dimensional electrophoresis, showed lamin to be the major protein that was cross-linked to the DNA. Lamin molecules were also cross-linked by UV light to each other to form lamin homo-oligomers. A discrete size DNA fragment of approximately 450 base pairs is protected by lamin homo-oligomers from breakdown during UV irradiation. It is proposed that the direct contact between lamin and DNA found in this study is responsible for anchoring chromatin loops (domains) to a stable, immobile matrix structure.     

Isolation and characterisation of a 167 bp core particle isolated from stripped chicken erythrocyte chromatin

We have digested chicken erythrocyte soluble chromatin, both unstripped and stripped of histones H1 and H5 with either 0.6 M NaCl or DNA-cellulose, with micrococcal nuclease (MNase). Digestion of unstripped chromatin to monomeric particles initially paused at 188 bp DNA; continued digestion resulted in another pause at 177 before the 167 bp chromatosome and 146 bp core particle were obtained. Digestion of stripped chromatin to monomeric particles paused transiently at 177 bp; continued digestion resulted in marked pauses at 167 and 156 before the 146 bp core particle was obtained. These results suggested that 167 bp DNA representing two complete turns are bound to the histone octamer. Histone H1/H5 binds an additional two helical turns of DNA, thereby protecting up to 188 bp DNA against nuclease digestion. Monomeric particles containing 167 bp DNA were isolated from stripped chromatin and found by DNase I digestion to be a homogeneous population with a 10 bp DNA extension to either end relative to the 146 bp core particle. Thermal denaturation and circular dichroism spectroscopy showed stronger histone-DNA interactions and increased DNA winding as the length of DNA attached to the core histone octamer was decreased. Thermal denaturation also showed three classes of histone-DNA interaction: the core particle containing 167 bp DNA had tight binding of ten helical turns of DNA, intermediate binding of two helical turns and looser binding of four helical turns.     

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.     

Internucleosome interaction: detection of dinucleosome fragmentation of chromatin by micrococcal nuclease. Analysis of the products of cleavage of chromatin from rat liver nuclei and L cells by micrococcal nuclease

In murine L-cell nuclei micrococcal nuclease causes chromatin fragmentation with predominant liberation of dinucleosomes. Analysis of dynamics of rat liver nuclear chromatin cleavage by micrococcal nuclease revealed that the "dinucleosomal" mode of fragmentation is due to the pretreatment of nuclei with the non-ionic detergent Triton X-100 in the course of the isolation procedure. The set of particles detected in nuclease hydrolysates of nuclear chromatin pretreated with Triton X-100 and those isolated by the standard procedure was shown to be significantly different. In Triton X-100 treated nuclei the dichromatosome is the main hydrolysate component under various experimental conditions of nuclease hydrolysis and the sole component under "mild" conditions, whereas sucrose-treated nuclei contain three types of dinucleosomes. In Triton-treated nuclei prolongation of hydrolysis results in the liberation of the chromatosome which is absent in chromatin hydrolysates of sucrose-treated nuclei. Hydrolysis of Triton-treated nuclear chromatin by micrococcal nuclease is unaccompanied by the liberation (up to the stage of "deep" hydrolysis) of the core particle, the major component of the "sucrose" nuclear hydrolysate under the conditions used. The sharp differences in the accessibility of various types of dinucleosomes observed during pretreatment of nuclei with Triton X-100 are interpreted in terms of the localization of histone H1. The non-random type of the histone H1 molecule orientation along the nucleosome fibril is postulated.     

Modulation of action of wheat seedling endonucleases WEN1 and WEN2 by histones

Wheat core histones and various subfractions of histone H1 modulate differently the action of endonucleases WEN1 and WEN2 from wheat seedlings. The character of this modulation depends on the nature of the histone and the methylation status of the substrate DNA. The modulation of enzyme action occurs at different stages of processive DNA hydrolysis and is accompanied by changes in the site specificity of the enzyme action. It seems that endonuclease WEN1 prefers to bind with protein-free DNA stretches in histone H1-DNA complex. The endonuclease WEN1 does not compete with histone H1/6 for DNA binding sites, but it does compete with histone H1/1, probably for binding with methylated sites of DNA. Unlike histone H1, the core histone H2b binds with endonuclease WEN1 and significantly increases its action. This is associated with changes in the site specificity of the enzyme action that is manifested by a significant increase in the amount of low molecular weight oligonucleotides and mononucleotides produced as a result of hydrolysis of DNA fragments with 120–140-bp length. The WEN2 endonuclease binds with histone-DNA complexes only through histones. The action of WEN2 is increased or decreased depending on the nature of the histone. Histone H1/1 stimulated the exonuclease activity of WEN2. It is supposed that endonucleases WEN1 and WEN2, in addition to the catalytic domain, should have a regulatory domain that is involved in binding of histones. As histone H1 is mainly located in the linker chromatin areas, it is suggested that WEN2 should attack DNA just in the chromatin linker zones. As differentiated from WEN2, DNA hydrolysis with endonuclease WEN1 is increased in the presence of core histones and, in particular, of H2b. Endonuclease WEN1 initially attacks different DNA sites in chromatin than WEN2. Endonuclease WEN2 activity can be increased or diminished depending on presence of histone H1 subfractions. It seems that just different fractions of the histone H1 are responsible for regulation of the stepwise DNA degradation by endonuclease WEN2 during apoptosis. Modulation of the action of the endonucleases by histones can play a significant role in the epigenetic regulation of various genetic processes and functional activity of genes.     

Structural organization of the meiotic prophase chromatin in the rat testis

Pachytene nuclei were isolated from rat testes by the unit gravity sedimentation technique and contained histone variants H1a, H1t, TH2A, TH2B, and X2 in addition to the somatic histones H1bde, H1c, H2A, H2B, H3, and H4. The basic organization of the pachytene chromatin namely the nucleosome repeat length and the accessibility to micrococcal nuclease, was similar to that of rat liver interphase chromatin. However, when digested by DNase I, the susceptibility of pachytene chromatin was 25% more than liver chromatin under identical conditions. Nucleosome core particles were isolated from both liver and pachytene nuclei and were characterized for their DNA length and integrity of the nucleoprotein on low ionic strength nucleoprotein gels. While liver core particles contained all the somatic histones H2A, H2B, H3, and H4, in the pachytene core particles, histone variants TH2A, X2, and TH2B had replaced nearly 60% of the respective somatic histones. A comparison of the circular dichroism spectra obtained for pachytene and liver core particles indicated that the pachytene core particles were less compact than the liver core particles. Studies on the thermal denaturation properties of the two types of core particles revealed that the fraction of the pachytene core DNA melting at the premelting temperature region of 55-60 degrees C was significantly higher than that of the liver core DNA.     

Identification of interacting amino acids at the histone 2A--2B binding site.

Histones 2A and 2B of calf thymus were cross-linked within intact nuclei by UV irradiation. This procedure induces the formation of covalent cross-links between noncovalently interacting residues in the histones of native chromatin. Tryptic peptide and partial sequence analysis of the cross-linked product has shown that the covalent linkage is between tyrosine-37, -40, or -42 (we have not yet determined which) of H2B and proline-26 of H2A. We conclude that these residues constitute part of the hydrophobic H2A--H2B binding domain within the nucleosomes of native chromatin.     

Intra- and inter-nucleosomal protein-DNA interactions of the core histone tail domains in a model system

The core histone tail domains are key regulators of eukaryotic chromatin structure and function and alterations in the tail-directed folding of chromatin fibers and higher order structures are the probable outcome of much of the post-translational modifications occurring in these domains. The functions of the tail domains are likely to involve complex intra- and inter-nucleosomal histone-DNA interactions, yet little is known about either the structures or interactions of these domains. Here we introduce a method for examining inter-nucleosome interactions of the tail domains in a model dinucleosome and determine the propensity of each of the four N-terminal tail domains to mediate such interactions in this system. Using a strong nucleosome "positioning" sequence, we reconstituted a nucleosome containing a single histone site specifically modified with a photoinducible cross-linker within the histone tail domain, and a second nucleosome containing a radiolabeled DNA template. These two nucleosomes were then ligated together and cross-linking induced by brief UV irradiation under various solution conditions. After cross-linking, the two templates were again separated so that cross-linking representing inter-nucleosomal histone-DNA interactions could be unambiguously distinguished from intra-nucleosomal cross-links. Our results show that the N-terminal tails of H2A and H2B, but not of H3 and H4, make internucleosomal histone-DNA interactions within the dinucleosome. The relative extent of intra- to inter-nucleosome interactions was not strongly dependent on ionic strength. Additionally, we find that binding of a linker histone to the dinucleosome increased the association of the H3 and H4 tails with the linker DNA region.     

Role of individual histone tyrosines in the formation of the nucleosome complex.

We have determined the accessibility of histone tyrosine residues to react with p-nitrobenzenesulfonyl fluoride (NBSF) in intact nuclei, salt-dissociated nucleosomes, isolated histone complexes, and individual core histones. Of the 15 core histone tyrosine residues, 13 are inaccessible in native nucleosomes; only Tyr121 near the C-terminus of H2B is fully accessible, and Tyr54 of H3 is partially accessible under near-physiological conditions. When H1 and the basic N-terminal tails of the core histones are dissociated from the DNA by treating nuclei with 0.4 and 0.8 M NaCl, the two tyrosines which are adjacent to the basic regions of H2B and H3 become accessible as well. This indicates that these tyrosine residues may be involved in histone-DNA interactions, either directly or indirectly. When the H2A-H2B dimers are dissociated from the chromatin by raising the NaCl concentration to 1.2 M, three to four tyrosines located in the structured regions of H2B and H4 are exposed, suggesting that these tyrosine residues may be located at the dimer-tetramer interface. Dissociating all the histones from the DNA at an even higher ionic strength as a mixture of dimers, tetramers, and octamers does not change the pattern of Tyr exposure, but reduces the reactivity of the tyrosines at the dimer-tetramer interface as would be expected from the reassociation of H2A-H2B dimers and H3-H4 tetramers.(ABSTRACT TRUNCATED AT 250 WORDS)