Different mechanism for in vitro formation of nucleosome core particles

The interaction of different histone oligomers with nucleosomes has been investigated by using nondenaturing gel electrophoresis. In the presence of 0.2 M NaCl, the addition of the pairs H2A,H2B or H3,H4 or the four core histones to nucleosome core particles produces a decrease in the intensity of the core particle band and the appearance of aggregated material at the top of the gel, indicating that all these histone oligomers are able to associate with nucleosomes. Equivalent results were obtained by using oligonucleosome core particles. Additional electrophoretic results, together with second-dimension analysis of histone composition and fluorescence and solubility studies, indicate that H2A,H2B, H3,H4, and the four core histones can migrate spontaneously from the aggregated nucleosomes containing excess histones to free core DNA. In all cases the estimated yield of histone transfer is very high. Furthermore, the results obtained from electron microscopy, solubility, and supercoiling assays demonstrate the transfer of excess histones from oligonucleosomes to free circular DNA. However, the extent of solubilization obtained in this case is lower than that observed with core DNA as histone acceptor. Our results demonstrate that nucleosome core particles can be formed in 0.2 M NaCl by the following mechanisms: (1) transfer of excess core histones from oligonucleosomes of free DNA, (2) transfer to excess H2A,H2B and H3,H4 associated separately with oligonucleosomes to free DNA, (3) transfer to excess H2A,H2B initially associated with oligonucleosomes to DNA, followed by the reaction of the resulting DNA-(H2A,H2B) complex with oligonucleosomes containing excess H3,H4, and (4) a two-step transfer reaction similar to that indicated in (3), in which excess histones H3,H4 are transferred to DNA before the reaction with oligonucleosomes containing excess H2A,H2B. The possible biological implications of these spontaneous reactions are discussed in the context of the present knowledge of the nucleosome function.     

The mechanism of nucleosome assembly onto oligomers of the sea urchin 5 S DNA positioning sequence

We have used a model system composed of tandem repeats of Lytechinus variegatus 5 S rDNA (Simpson, R. T., Thoma, F., and Brubaker, J. M. (1985) Cell 42, 799-808) reconstituted into chromatin with chicken erythrocyte core histones to investigate the mechanism of chromatin assembly. Nucleosomes are assembled onto the DNA template by mixing histone octamers and DNA in 2 M NaCl followed by stepwise dialysis into very low ionic strength buffer over a 24-h period. By 1.0 M NaCl, a defined intermediate composed of arrays of H3.H4 tetramers has formed, as shown by analytical and preparative ultracentrifugation. Digestion with methidium propyl EDTA.Fe(II) indicates that these tetramers are spaced at 207 base pair intervals, i.e. one/repeat length of the DNA positioning sequence. In 0.8 M NaCl, some H2A.H2B has become associated with the H3.H4 tetramers and DNA. Surprisingly, under these conditions DNA is protected from methidium propyl EDTA.Fe(II) digestion almost as well as in the complete nucleosome, even though these structures are quite deficient in H2A.H2B. By 0.6 M NaCl, nucleosome assembly is complete, and the MPE digestion pattern is indistinguishable from that observed for oligonucleosomes at very low ionic strength. Below 0.6 M NaCl, the oligonucleosomes are involved in various salt-dependent conformational equilibria: at approximately 0.6 M, a 15% reduction in S20,w that mimics a conformational change observed previously with nucleosome core particles; at and above 0.1 M, folding into a more compact structure(s); at and above 0.1 M NaCl, a reaction involving varying amounts of dissociation of histone octamers from a small fraction of the DNA templates. In low ionic strength buffer (less than 1 mM NaCl), oligonucleosomes are present as fully loaded templates in the extended beads-on-a-string structure.     

Chromatin superstructure-dependent crosslinking with DNA of the histone H5 residues Thr1, His25 and His62

The points of histone H5 interactions with DNA within nucleosomes and chromatin at different levels of compaction are delineated by identification of H5 amino acid residues that can be covalently bound to DNA. Three major crosslinkable points of H5 are His25, His62 (both within the globular part of the molecule), and N-terminal Thr1. His25 interacts with the terminal regions of nucleosomal DNA; His62 appears to bind more distal segments of the linker DNA. The His25-DNA crosslink predominates in the isolated mononucleosomes and persists throughout the chromatin condensation states studied, from extended oligonucleosomal chains to nuclei. His62 is the strongest crosslinking site in nuclei; in oligonucleosomes, the predominance of the His62-DNA crosslink requires the number of nucleosomes in the chain to be above some critical value. The Thr1-DNA crosslink is generated only in decondensed poly- or oligonucleosomes, but not in mononucleosomes. Thus, underlying the higher-order folding transitions of the nucleosomal chain is the restructuring of H5-DNA interactions.     

Assembly of oligonucleosomes into a limit series of multimeric higher-order chromatin structures

Chicken erythrocyte chromatin, obtained after fragmentation with micrococcal nuclease, appears to remain folded in a stable distribution of supranucleosomal structures in buffers containing 80 mM NaCl. These supranucleosomal particles are composed of on average 25 nucleosomes. However, the integrity of the linker DNA within these particles is not required. The supranucleosomal particles have been interpreted by others as superbeads cut out of a preexisting granular nominal 30-nm chromatin fibre. We show that the same distribution of supranucleosomal structures (even those containing internal DNA scissions) can be reconstituted from unfolded nuclear chromatin extracts as present in 10 mM or 600 mM NaCl. Moreover, fractions of oligonucleosomes with mean lengths between 6 and 15 nucleosomes reassemble or aggregate into a limit series of multimeric species. The existence of an assembly barrier could be inferred as we were unable to observe a stable and soluble assembly product containing more than about 25 nucleosomes. We propose an alternative explanation for the generation and observation of a constant distribution of supranucleosomal structures in nuclear extracts, based on the assembly or aggregation property of oligonucleosomes and on the existence of an assembly barrier.     

Structural transformations of oligonucleosomes from pigeon erythrocyte chromatin

The methods of velocity sedimentation and circular dichroism have been used to investigate structural rearrangements of pigeon erythrocyte oligonucleosomes isolated after digestion with micrococcal nuclease (oligonucleosomes-M) or pancreatic DNase I (oligonucleosomes-D), in the wide range of ionic strength (mu from 0.005 to 0.5). The electrophoretic analysis of DNA isolated from the oligonucleosomes has revealed internal cuts in the DNA chain of oligonucleosomes-D. In spite of this fact the conformational parameters of DNA in both types of oligonucleosomes are practically indistinguishable, and their optical and hydrodynamic properties vary in a similar way with increasing ionic strength of the solution. The specificity of DNase I action results in the ability of oligonucleosomes-D to form homogeneous associates at mu = 0.065, which seems to be due to the existence of elongated intact ends of linker DNA in oligonucleosomes-D. It has been shown that the integrity of oligonucleosomes-D in a wide range of ionic strength is maintained by histones H1 and H5, because after their dissociation the sedimentation coefficient sharply decreases. The results obtained reveal the multifunctional role of lysine-rich histones and intact linker in the processes of compaction and association of oligonucleosomes.     

Structural properties of barley nucleosomes

The structural properties of barley oligonucleosomes are investigated and compared to those of rat liver oligomers. Extraction of barley chromatin was performed using mild nuclease digestion of isolated nuclei leading to a low ionic strength soluble fraction. Oligonucleosomes were fractionated on sucrose gradients and characterized for DNA and histone content. Physico-chemical studies (sedimentation, circular dichroism and electric birefringence) showed that barley oligonucleosomes exhibit properties very close to those of the H1-depleted rat liver counterparts. Moreover, in situ, barley linker DNA was more sensitive to micrococcal nuclease digestion than that of rat liver. These results suggest that barley oligonucleosomes show a less compact structure than their rat liver counterparts and appear to be in contradiction with the very condensed organization of barley chromatin previously suggested.     

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.     

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.     

Antibody to poly(adenosine diphosphate-ribose) polymerase and its use in chromatin analysis

To facilitate investigations on the organization of poly (ADP-Rib) polymerase in chromatin, and to elucidate its biological function, polymerase purified from HeLa nuclei was used to elicit antibodies in mice. The anti-polymerase sera was found to be specific by multiple criteria. The association of polymerase with oligonucleosomes of differing chain size was determined by the specific binding of polymerase antibody (and as control, anti-histone H3) to nitrocellulose transfers of native electrophoretic gels of these particles. By this technique, polymerase appears to be associated with a select subclass of nucleosomes. Further resolution of the polymerase binding sites within nucleosome classes was achieved with the antibody by two-dimensional native polyacrylamide gel electrophoresis and nitrocellulose transfer.     

Localization of testis-variant histones in rat testis chromatin.

Nucleosome core particles and oligonucleosomes were isolated by digesting rat testis nuclei with micrococcal nuclease to 20% acid-solubility, followed by fractionation of the digest on a Bio-Gel A-5m column. The core particles thus isolated were characterized on the basis of their DNA length of 151 +/- 5 base-pairs and sedimentation coefficient of 11.4S. Analysis of the acid-soluble proteins of the core particles indicated that histones TH2B and X2 are constituents of the core particles, in addition to the somatic histones H2A, H2B, H3 and H4. The acid-soluble proteins of the oligonucleosomes comprised all the histones, including both the somatic (H1, H2A, H2B, H3, H4 and X2) and the testis-specific ones (TH1 and TH2B). It was also observed that histones TH1 and H1 are absent from the core particles and were readily extracted from the chromatin by 0.6 M-NaCl, which indicated that both of them are bound to the linker DNA.     

Mouse Dnmt3a preferentially methylates linker DNA and is inhibited by histone H1

In mammals, DNA methylation is crucial for embryonic development and germ cell differentiation. The DNA methylation patterns are created by de novo-type DNA methyltransferases (Dnmts) 3a and 3b. Dnmt3a is crucial for global methylation, including that of imprinted genes in germ cells. In eukaryotic nuclei, genomic DNA is packaged into multinucleosomes with linker histone H1, which binds to core nucleosomes, simultaneously making contacts in the linker DNA that separates adjacent nucleosomes. In the present study, we prepared oligonucleosomes from HeLa nuclei with or without linker histone H1 and used them as a substrate for Dnmt3a. Removal of histone H1 enhanced the DNA methylation activity. Furthermore, Dnmt3a preferentially methylated the linker between the two nucleosome core regions of reconstituted dinucleosomes, and the binding of histone H1 inhibited the DNA methylation activity of Dnmt3a towards the linker DNA. Since an identical amount of histone H1 did not inhibit the activity towards naked DNA, the inhibitory effect of histone H1 was not on the Dnmt3a catalytic activity but on its preferential location in the linker DNA of the dinucleosomes. The central globular domain and C-terminal tail of the histone H1 molecule were indispensable for inhibition of the DNA methylation activity of Dnmt3a. We propose that the binding and release of histone H1 from the linker portion of chromatin may regulate the local DNA methylation of the genome by Dnmt3a, which is expressed ubiquitously in somatic cells in vivo.     

Co-operative binding of the globular domain of histone H5 to DNA.

The globular domain of histone H5 (GH5) was prepared by trypsin digestion of H5 that was extracted from chicken erythrocyte nuclei with NaCl. Electron microscopy, sucrose gradient centrifugation, native agarose gel electrophoresis and equilibrium density gradient ultracentrifugation show that GH5 binds co-operatively to double-stranded DNA. The electron microscopic images suggest that the GH5-DNA complexes are very similar in structure to co-operative complexes of intact histone H1 (or its variants) with double-stranded DNA, studied previously, which have been proposed to consist of two parallel DNA double helices sandwiching a polymer of the protein. For complexes with GH5 or with intact H1, naked DNA co-sediments with the protein-DNA complexes through sucrose gradients, and DNA also appears to protrude from the ends and sides of the complexes; measurements of the protein-DNA stoichiometry in fractionated samples may not reflect the stoichiometry in the complexes. An estimate of the stoichiometry obtained from the buoyant density of fixed GH5-DNA complexes in CsCl suggests that sufficient GH5 is present in the complexes for the GH5s to be in direct contact, as required by a simple molecular mechanism for the co-operative binding. Chemical crosslinking demonstrates that GH5s are in close proximity in the complexes. In the absence of DNA, GH5-GH5 interactions are weak or non-existent.