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.     

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.     

ATP dependent histone phosphorylation and nucleosome assembly in a human cell free extract.

Physiologically spaced nucleosome formation in HeLa cell extracts is ATP dependent. ATP hydrolysis is required for chromatin assembly on both linear and covalently closed circular DNA. The link between the phosphorylation state of histones and nucleosome formation has been examined and we demonstrate that in the absence of histone phosphorylation no stable and regularly spaced nucleosomes are formed. Phosphorylated H3 stabilizes the nucleosome core; while phosphorylation of histone H2a is necessary to increase the linker length between nucleosomes from 0 to approximately 45 bp. Histone H1 alone, whether phosphorylated or unphosphorylated, does not increase the nucleosome repeat length in the absence of core histone phosphorylation. Phosphorylations of H1 and H3 correlate with condensation of chromatin. Maximum ATP hydrolysis which is necessary to increase the periodicity of nucleosomes from approximately 150 to approximately 185 bp, not only inhibits H1 and H3 phosphorylation but facilitates their dephosphorylation.     

Histones and nucleosomes in Archaea and Eukarya: a comparative analysis

Archaeal histones from mesophilic, thermophilic, and hyperthermophilic members of the Euryarchaeota have primary sequences, the histone fold, tertiary structures, and dimer formation in common with the eukaryal nucleosome core histones H2A, H2B, H3, and H4. Archaeal histones form nucleoprotein complexes in vitro and in vivo, designated archaeal nucleosomes, that contain histone tetramers and protect approximately 60 base pairs of DNA from nuclease digestion. Based on the sequence and structural homologies and experimental data reviewed here, archaeal nucleosomes appear similar, and may be homologous in evolutionary terms and function, to the structure at the center of the eukaryal nucleosome formed by the histone (H3+H4)₂ tetramer. Received: January 22, 1998 / Accepted: February 16, 1998     

Multistep chromatin assembly on supercoiled plasmid DNA by nucleosome assembly protein-1 and ATP-utilizing chromatin assembly and remodeling factor

We examine in vitro nucleosome assembly by nucleosome assembly protein-1 (NAP-1) and ATP-utilizing chromatin assembly and remodeling factor (ACF). In contrast to previous studies that used relaxed, circular plasmids as templates, we have found that negatively supercoiled templates reveal the distinct roles of NAP-1 and ACF in histone deposition and the formation of an ordered nucleosomal array. NAP-1 can efficiently deposit histones onto supercoiled plasmids. Furthermore, NAP-1 exhibits a greater affinity for histones H2A-H2B than does naked DNA, but in the presence of H3-H4, H2A-H2B are transferred from NAP-1 to the plasmid templates. These observations underscore the importance of a high affinity between H2A-H2B and NAP-1 for ordered transfer of core histones onto DNA. In addition, recombinant ACF composed of imitation switch and Acf1 can extend closely packed nucleosomes, which suggests that recombinant ACF can mobilize nucleosomes. In the assembly reaction with a supercoiled template, ACF need not be added simultaneously with NAP-1. Regularly spaced nucleosomes are generated even when recombinant ACF is added after core histones are transferred completely onto the DNA. Atomic force microscopy, however, suggests that NAP-1 alone fails to accomplish the formation of fine nucleosomal core particles, which are only formed in the presence of ACF. These results suggest a model for the ordered deposition of histones and the arrangement of nucleosomes during chromatin assembly in vivo.     

Purification and initial characterization of a protein which facilitates assembly of nucleosome-like structure from mammalian cells

A protein, which facilitates assembly of a nucleosome-like structure in vitro, was previously partially purified from mouse FM3A cells [Ishimi, Y. et al. (1983) J. Biochem. (Tokyo) 94, 735-744]. The protein has been purified to approximately 80% from FM3A cells by using histone-Sepharose column chromatography. It sedimented at 4.6 S and had a molecular mass of 53kDa. A preincubation of core histones with the 53-kDa peptide before DNA addition was necessary for the nucleosome assembly. The 53-kDa peptide bound to core histones and formed a 12-S complex. This complex contained stoichiometrical amounts of the 53-kDa peptide and core histones, and the core histones in this complex were composed of equal amounts of H2A, H2B, H3 and H4 histones. The nucleosomes were assembled by adding pBR322 DNA to the 12-S complex. When mononucleosome DNA and core histones were mixed in the presence of the 53-kDa peptide, formation of a 10.5-S complex was observed. The complex contained DNA and core histones in equal amounts, while no 53-kDa peptide was detected in the complex. From above results it is suggested that the 53-kDa peptide facilitates nucleosome assembly by mediating formation of histone octamer and transferring it to DNA. Rat antibody against the 53-kDa peptide did not bind to nucleoplasmin from Xenopus eggs. The relationship between the 53-kDa peptide and nucleoplasmin is discussed.     

Primary organization of nucleosomes. Interaction of non-histone high mobility group proteins 14 and 17 with nucleosomes, as revealed by DNA-protein crosslinking and immunoaffinity isolation

The binding sites for histones and high mobility group proteins (HMG) 14 and 17 have been located on DNA in the nucleosomal cores and H1/H5-containing nucleosomes. The nucleosomes were specifically associated with two molecules of the non-histone proteins HMG 14 and/or HMG 17 when followed by DNA-protein crosslinking and immunoaffinity isolation of the crosslinked HMG-DNA complexes. HMGs 14 and 17 were shown to be crosslinked in a similar manner to each core DNA strand at four sites: to both 3' and 5' DNA ends and also at distances of about 25 and 125 nucleotides from the 5' termini of the DNA. These sites are designated as HMG(143), (0), (25) and (125). The site HMG(125) is located at the place where no significant histone-DNA crosslinking was observed. The HMG(125) and HMG(25) sites lie opposite one another on the complementary DNA strands across the minor DNA groove and are placed, similarly to histones, on the inner side of the DNA superhelix in the nucleosome. The crosslinking of HMG 17 to the 3' ends of the DNA is much weaker than that of HMG 14. These data indicate that each of two molecules of HMG 14 and/or HMG 17 is bound to the double-stranded core DNA at two discrete sites: to the 3' and 5' ends of the DNA and at a distance of 20 to 25 base-pairs from each DNA terminus inside the nucleosome on a histone-free DNA region. Binding of HMG 14 or 17 does not induce any detectable rearrangement of histones on DNA and both HMGs seem to choose the same sites for attachment in nucleosomal cores and H1/H5-containing nucleosomes.     

Unique positioning of reconstituted nucleosomes occurs in one region of simian virus 40 DNA

A direct end label method was used to study the positioning of nucleosome arrays on several long (greater than 2200 base pairs) SV40 DNA fragments reconstituted in vitro with core histones. Comparison of micrococcal nuclease cutting sites in reconstituted and naked DNA fragments revealed substantial differences in one DNA region. When sufficient core histones were annealed with the DNA to form closely spaced nucleosomes over most of the molecule, a uniquely positioned array of four nucleosomes could be assigned, by strict criteria, to a 610-base pair portion of the SV40 "late region," with a precision of about +/- 20 base pairs. In some other DNA regions, a number of alternative nucleosome positions were indicated. The uniquely positioned four-nucleosome array spanned the same 610 nucleotides on two different DNA fragments that possessed different ends. Removal of a DNA region that had contained a terminal nucleosome of the array, by truncation of the fragment before reconstitution, did not affect the positioning of the other three nucleosomes. As the core histone to DNA ratio was lowered, evidence for specific positioning of nucleosomes diminished, except within the region where the four uniquely positioned nucleosomes formed. This region, however, does not appear to have a higher affinity for core histones than other regions of the DNA.     

NAP1-Assisted Nucleosome Assembly on DNA Measured in Real Time by Single-Molecule Magnetic Tweezers

While many proteins are involved in the assembly and (re)positioning of nucleosomes, the dynamics of protein-assisted nucleosome formation are not well understood. We study NAP1 (nucleosome assembly protein 1) assisted nucleosome formation at the single-molecule level using magnetic tweezers. This method allows to apply a well-defined stretching force and supercoiling density to a single DNA molecule, and to study in real time the change in linking number, stiffness and length of the DNA during nucleosome formation. We observe a decrease in end-to-end length when NAP1 and core histones (CH) are added to the dsDNA. We characterize the formation of complete nucleosomes by measuring the change in linking number of DNA, which is induced by the NAP1-assisted nucleosome assembly, and which does not occur for non-nucleosomal bound histones H3 and H4. By rotating the magnets, the supercoils formed upon nucleosome assembly are removed and the number of assembled nucleosomes can be counted. We find that the compaction of DNA at low force is about 56 nm per assembled nucleosome. The number of compaction steps and associated change in linking number indicate that NAP1-assisted nucleosome assembly is a two-step process.     

Structural dynamics of nucleosome core particle: comparison with nucleosomes containing histone variants

The present study provides insights on the dominant mechanisms of motions of the nucleosome core particle and the changes in its functional dynamics in response to histone variants. Comparative analysis of the global dynamics of nucleosomes with native and variant H2A histones, using normal mode analysis revealed that the dynamics of the nucleosome is highly symmetric, and its interaction with the nucleosomal DNA plays a vital role in its regulation. The collective dynamics of nucleosomes are predicted to be dominated by two types of large-scale motions: (1) a global stretching-compression of nucleosome along the dyad axis by which the nucleosome undergoes a breathing motion with a massive distortion of nucleosomal DNA, modulated by histone-DNA interactions; and (2) the flipping (or bending) of both the sides of the nucleosome in an out-of-plane fashion with respect to the dyad axis, originated by the highly dynamic N-termini of H3 and (H2A.Z-H2B) dimer in agreement with the experimentally observed perturbed dynamics of the particular N-terminus under physiological conditions. In general, the nucleosomes with variant histones exhibit higher mobilities and weaker correlations between internal motions compared to the nucleosome containing ordinary histones. The differences are more pronounced at the L1 and L2 loops of the respective monomers H2B and H2A, and at the N-termini of the monomers H3 and H4, all of which closely interact with the wrapping DNA.     

Remodeling of sperm chromatin after fertilization involves nucleosomes formed by sperm histones H2A and H2B and two CS histone variants

The composition of nucleosomes at an intermediate stage of male pronucleus formation was determined in sea urchins. Nucleosomes were isolated from zygotes harvested 10 min post-insemination, whole nucleoprotein particles were obtained from nucleus by nuclease digestion, and nucleosomes were subsequently purified by a sucrose gradient fractionation. The nucleosomes derived from male pronucleus were separated from those derived from female pronucleus by immunoadsorption to antibodies against sperm specific histones (anti-SpH) covalently bound to Sepharose 4B (anti-SpH-Sepharose). The immunoadsorbed nucleosomes were eluted, and the histones were analyzed by Western blots. Sperm histones (SpH) or alternatively, the histones from unfertilized eggs (CS histone variants), were identified with antibodies directed against each set of histones. It was found that these nucleosomes are organized by a core formed by sperm histones H2A and H2B combined with two major CS histone variants. Such a hybrid histone core interacts with DNA fragments of approximately 100 bp. It was also found that these atypical nucleosome cores are subsequently organized in a chromatin fiber that exhibits periodic nuclease hypersensitive sites determined by DNA fragments of 500 bp of DNA. It was found that these nucleoprotein particles were organized primarily by the hybrid nucleosomes described above. We postulate that this unique chromatin organization defines an intermediate stage of male chromatin remodeling after fertilization.     

The fate of parental nucleosomes during SV40 DNA replication.

The fate of parental nucleosomes during the replication of chromatin templates was studied using a modification of the cell-free SV40 DNA replication system. Plasmid DNA molecules containing the SV40 origin were assembled into chromatin with purified core histones and fractionated assembly factors derived from HeLa cells. When these templates were replicated in vitro, the resulting progeny retained a nucleosomal organization. To determine whether the nucleosomes associated with the progeny molecules resulted from displacement of parental histones during replication followed by reassembly, the replication reactions were performed in the presence of control templates. It was observed that the progeny genomes resulting from the replication of chromatin templates retained a nucleosomal structure, whereas the progeny of the control DNA molecules were not assembled into chromatin. Additional experiments, involving direct addition of histones to the replication reaction mixtures, confirmed that the control templates were not sequestered in some form which made them unavailable for nucleosome assembly. Thus, our data demonstrate that parental nucleosomes remain associated with the replicating molecules and are transferred to the progeny molecules without displacement into solution. We propose a simple model in which nucleosomes ahead of the fork are transferred intact to the newly synthesized daughter duplexes.     

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.     

Nucleosome assembly in vitro: separate histone transfer and synergistic interaction of native histone complexes purified from nuclei of Xenopus laevis oocytes.

High speed supernatants of Xenopus laevis oocyte nuclei efficiently assemble DNA into nucleosomes in vitro under physiological salt conditions. The assembly activity cofractionates with two histone complexes composed of the acidic protein N1/N2 in complex with histones H3 and H4, and nucleoplasmin in complex with histones H2B and H2A. Both histone complexes have been purified and their nucleosome assembly activities have been analysed separately and in combination. While the histones from the N1/N2 complexes are efficiently transferred to DNA and induce supercoils into relaxed circular plasmid DNA, the nucleoplasmin complexes show no supercoil induction, but can also transfer their histones to DNA. In combination, the complexes act synergistically in supercoil induction thereby increasing the velocity and the number of supercoils induced. Electron microscopic analysis of the reaction products shows fully packaged nucleoprotein structures with the typical nucleosomal appearance resulting in a compaction ratio of 2.8 under low ionic strength conditions. The high mobility group protein HMG-1, which is also present in the soluble nuclear homogenate from X. laevis oocytes, is not required for nucleosome core assembly. Fractionation experiments show that the synergistic effect in the supercoiling reaction can be exerted by histones H3 and H4 bound to DNA and the nucleoplasmin complexes alone. This indicates that it is not the synchronous action of both complexes which is required for nucleosome assembly, but that their cooperative action can be resolved into two steps: deposition of H3 and H4 from the N1/N2 complexes onto the DNA and completion of nucleosome core formation by addition of H2B and H2A from the nucleoplasmin complexes.