Core Histone Octamer Research Articles

Preparative separation of nucleosome core particles containing defined-sequence DNA in multiple translational phases.

The nucleosome core particle is composed of an octamer of core histone proteins and about 146 bp of DNA. When reconstituted from purified histone octamer and defined-sequence, nucleosome positioning DNA fragments, the DNA will bind to the histone core in a number of translational phases with respect to the dyad symmetry axis of the histone octamer. Only one of these phases contains symmetrically bound DNA, and it is this species which is required for crystallization and X-ray diffraction studies. We have developed a technique for separating nucleosome core particles, containing defined-sequence 146 bp DNA, which differ only in translational phasing of the DNA with respect to the histone octamer core.

Transcription factor binding sites in the matrix attachment region (MAR) of the chicken alpha-globin gene.

Nuclear matrix is a nuclear protein-DNA superstructure believed to be the exclusive site of DNA replication, transcription, repair, and recombination. The attachment regions of chromatin loops to the nuclear matrix, called MARs, nest origins of replication, have transcriptional enhancer activity, and via their interaction with protein transcription factors may govern gene switch during development and tissue-specific gene expression. In this study the 967 bp MAR of the chicken alpha-globin gene is analyzed for the presence of hexanucleotides from a number (83 in total) of vertebrate protein transcription factors and core origins of replication. A total number of 760 hexanucleotides from factor sites or origins of replication were used for this search. We found that: (1) The occurrence of protein transcription factor binding sites overall on the MAR fragment as well as on the enhancer and promoter regions of other genes is only about 1.2-1.5 times higher than in random DNA, something consistent for all MAR and enhancer sequences examined. However, a high concentration (up to 2.7 times over random sequences) of hexanucleotide factor sites is observed on small stretches of the alpha-globin gene MAR. (2) Some regulatory protein binding sites are underrepresented whereas others are overrepresented, giving to an MAR a particular transcription factor flavor. (3) The DNA curvature map of the MAR sequence and the potential sites of positioned nucleosomes suggest the sites where a competition between core histone octamers and protein transcription factors for DNA might be found. This approach might provide a novel technique to diagnose for the regulatory or nonregulatory function of a stretch of DNA. Furthermore, MARs are proposed to constitute important regulatory elements of genes in addition to enhancers, promoters, silencers, locus control regions, and origins of replication. Additional parameters such as interaction of a transcription factor with other transcription factors fixed at vicinal sites, DNA methylation, intrinsic DNA curvature torsional strain, and nucleosome positioning might also determine the high-affinity binding of a transcription factor to its functional sites and its exclusion from or low affinity binding to other nonregulatory regions.

Nucleosome Positioning on Chicken and Human Globin Gene Promoters in Vitro: Novel Mapping Techniques

We have developed two new techniques to assess the positions adopted by core histone octamers when reconstituted onto DNA. These, together with a previously described technique, were applied to mapping binding sites on plasmid DNAs containing either the human ζ-globin or chicken β-globin gene promoters. Each of the approaches enabled the sites occupied by histone octamers to be measured at high resolution and, in qualitative terms, revealed the same pattern of multiple, overlapping sites. Monomer extension, one of the novel techniques, can be used to reveal binding sites over extensive stretches of a single reconstitute (≈ 1000 bp). We found the distribution of histone octamer binding sites to be largely independent of the conditions employed for reconstitution, the topology of the DNA substrate and prolonged incubation under various post-reconstitution conditions. These properties, and features of the binding site maps that we derived, suggest that histone octamer positioning on these DNAs is predominantly a characteristic of the DNA sequence itself and, by implication, that nucleosome—nucleosome interactions and the formation of nucleosome arrays are of minor influence. Some of the techniques provide quantitative information concerning the relative binding strengths of the core histone octamer for different positioning sequences. In this context, it is notable that the majority of potential binding sites compete very poorly for the histone octamer, demonstrating that under the conditions pertinent to our analysis, the range of binding strengths exhibited by the octamer for particular DNA sequences is extensive, and greater than that observed when competitive binding has been studied by methods that do not reflect precise positioning.

Topography of the histone octamer surface: repeating structural motifs utilized in the docking of nucleosomal DNA.

The histone octamer core of the nucleosome is a protein superhelix of four spirally arrayed histone dimers. The cylindrical face of this superhelix is marked by intradimer and interdimer pseudodyad axes, which derive from the nature of the histone fold. The histone fold appears as the result of a tandem, parallel duplication of the "helix-strand-helix" motif. This motif, by its occurrence in the four dimers, gives rise to repetitive structural elements--i.e., the "parallel beta bridges" and the "paired ends of helix I" motifs. A preponderance of positive charges on the surface of the octamer appears as a left-handed spiral situated at the expected path of the DNA. We have matched a subset of DNA pseudodyads with the octamer pseudodyads and thus have built a model of the nucleosome. In it, the two DNA strands coincide with the path of the histone-positive charges, and the central 12 turns of the double helix contact the surface of the octamer at the repetitive structural motifs. The properties of these complementary contacts appear to explain the preference of histones for double-helical DNA and to suggest a possible basis for allosteric regulation of nucleosome function.

Preferential and asymmetric interaction of linker histones with 5S DNA in the nucleosome.

We establish that linker histones H1 and H5 bind preferentially to a Xenopus borealis somatic 5S RNA gene associated with an octamer of core histones rather than to naked 5S DNA. This preferential binding requires free linker DNA to either side of the nucleosome core. Incorporation of a single linker histone molecule into the nucleosome protects an additional 20 bp of linker DNA from micrococcal nuclease digestion. This additional DNA is asymmetrically distributed with respect to the nucleosome core. Incorporation of linker histones causes no change to the cleavage of DNA in the nucleosome by hydroxyl radical or DNase I.

Enhanced stability of histone octamers from plant nucleosomes: role of H2A and H2B histones.

Gel filtration and sedimentation studies have previously established that the vertebrate animal core histone octamer is in equilibrium with an (H3-H4)2 tetramer and an H2A-H2B dimer [Eickbush, T. H., & Moudrianakis, E. N. (1978) Biochemistry 17, 4955-4964; Godfrey, J. E., Eickbush, T. H., & Moudrianakis, E. N. (1980) Biochemistry 19, 1339-1346]. We have investigated the core histone octamer of wheat (Triticum aestivum L.) and have found it to be much more stable than its vertebrate animal counterpart. When vertebrate animal histone octamers are subjected to gel filtration in 2 M NaCl, a trailing peak of H2A-H2B dimer can be clearly resolved from the main octamer peak. When the plant octamer is subjected to the identical procedure, there is no trailing peak of H2A-H2B dimer, but rather a single peak containing the octamer. A sampling across the octamer peak from leading to trailing edge shows no change in the ratio of H2A-H2B to (H3-H4)2. Surprisingly, the plant octamer shows the same stability at 0.6 M NaCl, a salt concentration in which the vertebrate animal octamer dissociates into dimers and tetramers. Equilibrium sedimentation data indicate that the assembly potential of the wheat histones in 2 M NaCl is very high at all protein concentrations above 0.1 mg mL-1. In order to disrupt the forces stabilizing the plant histone octamer at high histone concentrations, the concentration of NaCl must be lowered to approximately 0.3 M.(ABSTRACT TRUNCATED AT 250 WORDS)

Associative behavior of the histone (H3-H4)2 tetramer: dependence on ionic environment

Mixtures of histones H3 and H4 were examined by analytical ultracentrifugation and circular dichroism to determine their association behavior and secondary structure content in high and low ionic strength solvents containing chloride, phosphate, or sulfate. H3 and H4 were also cross-linked by using DSP in order to directly trap any intermolecular interactions occurring in solution. While H3 and H4 can exist as an H3-H4 dimer under limited conditions, they behave as a stable (H3-H4)2 tetramer under most conditions, particularly those which are physiologically relevant. In chloride-containing solutions, the equilibrium between H3-H4 and (H3-H4)2 is responsive to changes in ionic strength and paralleled by large changes in alpha-helicity. In sulfate- and phosphate-containing solutions, the equilibrium is again governed by ionic strength, but there are no significant changes in secondary structure accompanying shifts in the equilibrium. Small oligomers can be formed in the presence of sulfate and phosphate and trapped by the cross-linking reagent; these oligomers are much smaller than those formed in chloride-containing solutions. However, addition of the H2A-H2B dimer into the system prevents aggregation of the (H3-H4)2 tetramer by acting as a "molecular cap" and thus regulating the assembly pathway toward the formation of tripartite octamers. The observed assembly of H3 and H4 into a stable, tetrameric complex supports the concept of the core histone octamer having a tripartite organization in solution rather than being organized as two heterotypic tetramers.

Histone structure and function

The past year has seen major advances in our understanding of histone and nucleosome structure and function. Direct DNA mapping and thermodynamic experiments have finally provided conclusive evidence that the histones impose an altered helical pitch on the DNA as it is wrapped on the surface of the core histone octamer. Further, it is now clear that lysine acetylation in the amino-terminal domains of histones H3 and H4 can alter the topology of the DNA in chromatin and probably influence its higher-order folding. Genetic experiments reported in the past year have provided a wealth of new information on histone structure and function, including the identification of the peptide domain of histone H4 that is necessary for permanent gene repression, the confirmation that nucleosome structure is critical for centromere function, and evidence that histone acetylation plays a significant role in chromosome dynamics.

The promoter and enhancer of the inactive chicken β-globin gene contains precisely positioned nucleosomes

Core histone octamers reconstituted in vitro onto DNA fragments containing the chicken beta-globin gene promoter are precisely positioned with respect to the underlying DNA sequence [1]. Here we show that this is also true of the chicken beta-globin gene enhancer. These nucleosome binding sites are also employed within transfected COS cell nuclei, where the chicken beta-globin gene is transcriptionally inactive. Similar results were found in vivo, where positioned nucleosomes were detected over the inactive beta-globin promoter in chicken brain cells and 5-day red blood cells, and over the inactive beta-globin enhancer in brain cells. In contrast, the promoter and enhancer regions were found to be nucleosome-free in 15-day erythrocytes where the beta-globin gene is active. We argue that these results suggest a role for positioned nucleosomes in the regulation of the transcription of the chicken beta-globin gene.

Spectropolarimetric analysis of the core histone octamer and its subunits

The secondary structure of the calf thymus core histone octamer, (H2A-H2B-H3-H4)2, and its two physiological subunits, the H2A-H2B dimer and (H3-H4)2 tetramer, was analyzed by ORD spectropolarimetry as a function of temperature and solvent ionic strength within the ranges of these experimental parameters where assembly of the core histone octamer exhibits pronounced sensitivity. While the secondary structure of the dimer is relatively stable from 0.1 to 2.0 M NaCl, the secondary structure of the tetramer exhibits complex changes over this range of NaCl concentrations. Both complexes exhibit only modest responses to temperature changes. ORD spectra of very high and very low concentrations of stoichiometric mixtures of the core histones revealed no evidence of changes in the ordered structure of the histones as a result of the octamer assembly process at NaCl concentrations above 0.67 M, nor were time-dependent changes detected in the secondary structure of tetramer dissolved in low ionic strength solvent. The secondary structure of the chicken erythrocyte octamer dissolved in high concentrations of ammonium sulfate, including those of our crystallization conditions, was found to be essentially unchanged from that in 2 M NaCl when examined by both ORD and CD spectropolarimetry. The two well-defined cleaved products of the H2A-H2B dimer, cH2A-H2B and cH2A-cH2B, exhibited reduced amounts of ordered structure; in the case of the doubly cleaved moiety cH2A-cH2B, the reductions were so pronounced as to suggest marked structural rearrangements.

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.

H2a-specific proteolysis as a unique probe in the analysis of the histone octamer.

We have utilized the H2a-specific protease as a unique probe to investigate the nature of the interactions between the protein subunits which form the core histone octamer. Upon incubation in high ionic strength media this protease, normally found tightly associated with isolated calf thymus chromatin, releases the 15 COOH-terminal amino acids of histone H2a by specifically cleaving the H2a polypeptide between Val114 and Leu115, yielding cleaved H2a (cH2a) and a free pentadecapeptide (Eickbush, T. H., Watson, D. K., and Moudrianakis, E. N. (1976) Cell 9, 785-792). We find that removal of this pentadecapeptide results in a marked dissociation of the octamer into its H2a:H2b dimer and H3:H4 tetramer subunits. Reconstitution experiments indicate that cH2a is capable of forming a dimer with H2b, but this cH2a:H2b dimer has a substantially lower affinity for the H3:H4 tetramer than native H2a:H2b dimer. Kinetic studies of H2a cleavage in high ionic strength solutions demonstrate that H2a molecules in the octamer are relatively resistant to proteolytic attack compared to H2a molecules in the dimer. The extent of this resistance, in response to various experimental parameters, is directly correlated to the strength of interaction between the H2a:H2b dimer and H3:H4 tetramer subunits. These reconstitution and kinetic experiments suggest that the histone domains proximal to the H2a cleavage site have an important function in maintaining the association of the histone octamer subunits.

A major nucleolar protein, nucleolin, induces chromatin decondensation by binding to histone H1.

Using circular dichroism to probe the extent of DNA condensation in chromatin, we have demonstrated that a major nucleolar protein, nucleolin can decondense chromatin. By means of various binding assays we show that nucleolin has a strong affinity for histone H1 and that the phosphorylated N-terminal domain, rich in lengthy stretches of acidic amino acids, is responsible for this ionic interaction. Additional experiments clearly demonstrate that nucleolin is unable to act as a nucleosome core assembly or disassembly factor and hence has little affinity for the core histone octamer. We propose that this nucleolar protein induces chromatin decondensation by binding to histone H1, and that nucleolin can therefore be regarded as a protein of the high-mobility-group type.

Structural changes of nucleosomal particles and isolated core-histone octamers induced by chemical modification of lysine residues.

Treatment of nucleosomal particles and isolated core-histone octamers with dimethylmaleic anhydride, but not with acetic anhydride, is accompanied by a biphasic release of the two H2A.H2B dimers, the first dimer being more easily released than the second. With both kinds of particles, 50% of histones H2A and H2B are released for modification of approximately 35% of the histone amino groups. The similar behavior of nucleosomal particles and isolated core-histone octamers is consistent with the same structure of the histone octamer in the nucleosomal particle and in the free octamer in 2 M NaCl. The described release of H2A.H2B dimers allows the preparation of nucleosomal particles deficient in one H2A.H2B dimer and of the histone hexamers H2A.H2B.(H3.H4)2. For more extensive modifications, both reagents, acetic and dimethylmaleic anhydrides, cause the dissociation of nucleosomal particles with liberation of double-stranded DNA, which suggests that lysine amino groups are involved in the binding of histones to DNA. The modified nucleosomal particles are more sensitive to ionic strength than those untreated, and the presence of salt (NaCl) increases the extent of DNA release. The histones corresponding to the liberated DNA, except H2A and H2B released with dimethylmaleic anhydride, are apparently bound to the DNA-containing particles as extra histones.

Nonrandom assembly of chromatin during hydroxyurea inhibition of DNA synthesis.

Incubation of MSB-1 chicken lymphoblastoid cells with hydroxyurea leads to a rapid 25-fold decrease in the incorporation of [3H]thymidine into DNA and a 5-fold decrease [3H]lysine into the nucleosome core histones. I have investigated whether the distortion in the normal proportion of histone-DNA synthesis results in alterations in the nucleosome assembly process and find that neither the stoichiometry of new histone synthesis nor the deposition is appreciably changed during hydroxyurea incubation. Protein cross-linking and micrococcal nuclease digestion show that the histones synthesized during hydroxyurea treatment form octamer structures and are assembled into typical nucleosome particles. Minor nucleosome subpopulations are found which exhibit altered sensitivity to nuclease digestion and which are depleted in new histones H3 and H4. When MSB-1 cells incubated in hydroxyurea are pulsed briefly with density-labeled amino acids and [3H]lysine, the radiolabeled core histone octamers formed are as dense as individual monomer histones. These results suggest that the newly synthesized histone octamers are uniformly dense and do not contain mixtures of new and old histones. Thus, histones synthesized during hydroxyurea incubation are deposited nonrandomly and do not exchange with preexisting histones.

The Condensation of Chromatin and Histone Hl-Depleted Chromatin By Spermine

At low ionic strength, spermine induces aggregation of native and H1-depleted chromatin at spermine/phosphate (Sp/P) ratios of 0.15 and 0.3, respectively. Physico-chemical methods (electric dichroism, circular dichroism and thermal denaturation) show that spermine, at Sp/P less than 0.15, does not appreciably alter the conformation of native chromatin and interacts unspecifically with all parts of chromatin DNA (linker as well as regions slightly or tightly bound to histones). In chromatin, the role of spermine could be more important in the stabilization of higher-order structure than in the condensation of the 30 nm solenoid. The addition of spermine to H1-depleted chromatin revealed two important features: (i) spermine can partially mimic the role of histone H1 in the condensation of chromatin; (ii) the core histone octamer does not appear to play any role in the aggregation process by spermine as DNA and H1-depleted chromatin aggregate at the same Sp/P ratio.

Neuronal nuclei and glial nuclei from mammalian cerebral cortex. Nucleosome repeat lengths, DNA contents and H1 contents.

We have characterised the histone and DNA contents of neuronal and glial nuclei from ox cerebral cortex which have, respectively, repeat lengths of 162 base pairs and 201 base pairs. Although the neuronal population cannot be obtained completely free of glial nuclear contamination, the degree of contamination is easily determined by counting, and has been allowed for in all the methods used here. By diphenylamine assay and flow cytofluorometry we find that the DNA contents of both nuclear types are essentially equal, and equivalent to the diploid value, contrary to some reports. By quantification of the core histones in known numbers of nuclei with respect to an added external standard, we have shown that the ratio of core histone octamers in the two nuclear types, neuronal and glial, is the inverse of the ratio of repeat lengths. Thus the same proportion of DNA is associated with core histone octamers in the two nuclear types, most simply all of the DNA. By complete radiolabelling of the lysine side chains of the histones with methyl [1-3H]acetimidate we have determined the stoichiometry of H1 relative to the core histones. Neuronal nuclei have a low H1 content of 0.45 molecule H1/nucleosome on average; glial nuclei have the 'normal' 1 H1 molecule/nucleosome. In neuronal nuclei about half of the nucleosomes therefore probably lack H1. Whether there is any relation between the low H1 content and the short DNA repeat length of neuronal nuclei, on the one hand, and their high transcriptional capacity (at least when assayed in vitro), on the other, remains to be established.

Crystals of the octameric histone core of the nucleosome.

The undegraded core histone octamer has been crystallized in a form suitable for x-ray analysis. The hexagonal bipyramidal crystals reproducibly grow larger than 1.0 by 0.6 millimeter, X-ray reflections are observed from Bragg planes with spacings larger than 3.5 angstroms. The crystals have the symmetry of the space group P3l21 or its enantiomorph. There appears to be one histone octamer per asymmetric unit.

Conservative segregation of nucleosome core histones.

Density labelling studies have shown that nascent histones are not mixed with parental histones during the assembly of nucleosome cores. However, experiments in other laboratories, examining histone deposition with respect to newly synthesized DNA, have been interpreted as suggesting that a substantial proportion of core histones (greater than 15%) are randomized at each chromatin replication. The data presented here support our previous results in showing that conservatively assembled nucleosome core histone octamers are conservatively segregated over successive cell generations. It is also shown that the nucleosome cores assembled during 1-beta-D-arabinofuranosylcytosine inhibition of DNA synthesis are conservatively segregated for a minimum of five or six cell generations. These results suggest that the nonrandom assembly of nucleosome cores is not merely a coincidence of the mechanism of histone transport into the nucleus and that the conservative mode of nucleosome segregation is a fundamental feature of chromatin replication, one which is stable to modulations in chromatin packaging.

Role of histone tyrosines in nucleosome formation and histone-histone interaction.

We have studied the functional properties of iodinated histones. Isolated, denatured histones were iodinated at trace levels and then renatured together with carrier histones and high molecular weight DNA to form nucleohistone. Nucleosomes were prepared from the reconstitute using micrococcal nuclease, and the relative representations of the individual iodinated tyrosines of the histones in the reconstituted nucleosomes were determined. Our principal findings are 1) that denatured histones can be iodinated at any tyrosine without interfering in subsequent nucleosome reconstitution and 2) that the resulting reconstituted nucleosomes nevertheless possess histone cores of altered stability, being either more or less stable depending on the particular tyrosine which is iodinated. We show that tyrosines 37, 40, and 42 of H2B are protected from iodination in intact core particles, as expected since these tyrosines lie within the H2B-H2A binding site. Yet iodination of these tyrosines in denatured H2B does not interfere with nucleosome assembly. However, the histone cores isolated from these reconstituted nucleosomes are of diminished stability as assayed by Sephadex column chromatography in 2 M salt. In contrast, iodination of tyrosines 83 and 121 of H2B, as well as iodination of the tyrosines of H2A, increases the stability of the histone octamer core. Iodination of H4 tyrosine 72 is without effect on histone octamer stability. Tyrosine iodination constitutes a profound amino acid alteration in the context of the absolute evolutionary conservation of most histone tyrosines. For example, all H2Bs sequenced to date, from fungi to mammals, possess tyrosines at positions 37, 40, and 42. Our results suggest that the immutability of these tyrosines reflects some sophisticated function of the nucleosome histone core beyond the assembly and mere maintenance of a compact structure.