Unfolding of nucleosome cores induced by chemical acetylation of histones

Relative accessibility of nucleosomal histones to acetic anhydride during acetylation has been studied as a function of concentration, pH and ionic strength of the solution using high-resolution gel-electrophoresis. It was shown that about 80% of lysine residues in nucleosomal histones and 100% of the same residues in histone complexes without DNA in 2 M NaCl are accessible to the modification, which is proved by the localization of the majority of lysine residues in nucleosomes near the surface of the histone octamer, by their participation in ionic interactions with DNA and, probably, in histone-histone contacts. Gel-electrophoretic experiments with nucleosomes and studies of the histone resistance to mild trypsinolysis indicated that neither nucleosomes themselves nor histone octamers are affected even though 50% of lysine residues in histones have been acetylated. The process of acetylation is accompanied by the growing tendency of histones to participate in mild trypsinolysis and by a gradual decline in electrophoretic mobility and in the value of the sedimentation constant. The circular dichroism spectra and the microscopic appearance of nucleosomes are also markedly changed. These results suggest that a gradual unfolding of nucleosomes occurs when 5 or more lysine residues in the nucleosomal histones have been acetylated.     

Tertiary structure of histones]

Optical absorption and fluorescence of histones F2a and F2b were studied. An increase in pH and ionic strength induced the structure change in these histones fractions. The hydrofobic sites are formed in protein molecules and this leads to an intensification of histone-histone interactions. The change in the histone tertiary structure is of importance for processes associated with regulation of gene activity in eukaryotic cells.     

Nitration of the tyrosine in histone F1 in salt solutions and in F1-polyanion complexes

The reaction of histone F1 with tetranitromethane was used to study the environment of the single tyrosine residue in the molecule. It was found that at a 10-fold molar excess of tetranitromethane over tyrosine approx. 40 min were needed to convert 85% of the tyrosine residues to nitrotyrosine. The rate and extent of nitration of F1 in dilute salt solutions was used as a reference against which the rate and extent of nitration under conditions known to affect the conformation of F1 was measured. In 1.0 M NaCl solutions the rate of nitration decreased, suggesting that the presence of salt may cause a conformational change in the tyrosine containing region of the histone. When the histone is complexed with polyanions such as DNA, RNA or poly-L-glutamic acid the accessibility of the tyrosine to nitration is markedly reduced. The results indicate that upon association with polyanions the non-cationic, tyrosine-containing, region in F1 undergoes a conformational change or alternatively, this tyrosine containing region is tightly associated with the polyanion.     

Peculiarities of the amino acid composition, spatial organization and interaction with DNA of histones H1 from calf thymus and carp spermatozoa

The amino acid composition of the H1-like histone isolated from carp spermatozoa (H1carp) is characterized by a high content of lysine (34.6%) and a low content of glycine (4.5%) as compared to that of its calf counterpart (H1calf). The Lys/Arg ratio is 21.6, which is much higher than that for the H1-like histones from other species spermatozoa (cf. echinodermata). It was shown that the fluorescence anisotropy and excitation spectra of histones H1carp and H1calf change synchronically. At the same time the final folding of the polypeptide chains of these histones within their ternary structure is different. These differences manifest themselves in a distinct quantum yield of both histones and different accessibility of the single tyrosine residue for fluorescence quenchers. In histone--DNA complexes the tyrosine fluorescence is quenched. An increase in the ionic strength gives rise to a formation of large-sized aggregates in a histone H1--DNA solution which contain structurally heterogenous histones H1 from different sources. Histone H1carp causes DNA aggregation at lower ionic strength values than its calf counterpart. The complexes are dissociated at 0.6 M NaCl.     

Reactivity of heterogeneous F1 histones with glutaraldehyde and formaldehyde

The rates of glutaraldehyde and formaldehyde fixation of F1 histones have been investigated using chromatin from rat pancreas, chicken erythrocyte, and human spleen. These chromatins differ in number, type and relative proportion of F1 species present. In all cases the rates of fixation by glutaraldehyde and formaldehyde of the F1 components is much faster than for the other histones. The rates of fixation of F1-type histones are similar in each case with the exception of one minor F1 histone from chicken which reacts slower than the rest of that F1 group. The results suggest that the interactions of all F1 type histones with DNA are similar.     

Dynamic equilibrium in histone assembly: self-assembly of single histones and histone pairs.

The assembly of acid-extracted, purified F2a1, F3, F2a2, and F2b histones and their six possible pairwise combination into organized structures has been studied by: (1) sedimentation velocity, (2) sedimentation equilibrium, (3) electrophoresis in polyacrylamide gels containing sodium dodecyl sulfate after cross-linking the protein solution with dimethyl suberimidate, and (4) electron microscopy. Each of the purified histone fractions can renature and assemble into high molecular weight organized structures. This assembly is dependent on the ionic strength, protein concentration, and temperature of the solutions. The four histones studied assemble into structures of similar dimensions and shape. In each case the first structure observed is a bent rod with a diameter of 22 A. Conditions which favor assembly lead to formation of fibers with diameters of about 44 A. The conditions which lead to assembly into organized structures are similar for the arginine-rich histones, F2a1 and F3. Higher ionic strength is required for the assembly of the lysine-rich histones, F2a2 and F2b. Certain pairs of histones interact. Strong interactions among pairs of histones interfere with the self-assembly of single histones into large structures. Howver, increase in protein concentration or ionic stregth leads to formation of large molecular structures even in solutions of pairs of strongly interacting histones. These structures are similar to those obtained with single histones. The results suggest that aggregation and complexing of histones represent a reversible, ordered process of assembly. The various assembled forms are in a dynamic equilibrium. The final assembled form, which is similar in all cases, is dependent on the environmental conditions to which the histones are exposed. It is suggested that each of the assembled histone structures, regardless whether it is composed of a single histone or a pair of histones, can serve as a core around which the DNA can be wrapped.     

The self-association of chicken-erythrocyte histones.

The self-association of the separate histone fractions isolated from chicken erythrocytes has been studied in solution at a number of different pH values and ionic strengths. The apparent molecular weights of the histones were determined over a range of macromolecular concentrations using the techniques of osmotic pressure and sedimentation equilibrium. Histone F2c (H5) did not associate under any of the conditions investigated whereas the other histone fractions all appeared to undergo self-association forming dimers, dimers of dimers, etc. The degree of association increased with the pH and ionic strength of the medium. The tendency to aggregate increased in the order; histone F2c (H5) (non-aggregating), histone F2b (H2B), histone F2a2 (H2A), histone F3 (H3), histone F2a1 (H4) (highly aggregating). In the case of histone F2a2 (H2A) at pH 3.0 and ionic strength 0.1, the apparent weight-average molecular weight was determined at a number of macromolecular concentrations at five different temperatures. The self-association was analysed according to the method of Adams (published by Beckman Instruments Inc. in 1967) and shown to be a monomer-dimer-tetramer equilibrium. The association constants were evaluated at each of the temperatures studied and from their variation with temperature the values of the enthalpy and entropy of association were calculated. The intermolecular association was characterised by only a small change in enthalpy but a large, positive, change in entropy. This suggests that the association of histones at acid pH is due to hydrophobic interactions between the relatively uncharged segments of like polypeptide chains.     

Iodination of Xenopus laevis histone F2a1 in chromatin.

The reaction of calf thymus and Xenopus laevis histones with radioactive iodine has been studied under various conditions that affect chromatin structure. All histones from both species contain at least one tyrosine residue and, in a denaturing solvent, all the the histones react with iodine. Histone F2a1 has been studied in detail. Calf thymus F2a1 is known to contain four tyrosyls and all four react with iodine. In high voltage paper electrophoresis, the tyrosine-containing peptides from calf co-migrate with those from Xenopus F2a1, suggesting that the amino acid sequence is strongly conserved between these two species. Therefore, the published calf thymus F2a1 sequence has been used to order the Xenopus F2a1 peptides within the molecules. When gently isolated native chromatin is iodinated in a low ionic strength medium 60% of the radioactivity in F2a1 is in tyrosyl 88, 30% in tyrosyl 51, and tyrosyl 72 and 98 have almost no radioactivity. Reagents which remove the protein from the DNA (2 M NaCl) or partially disrupt protein tertiary structure (5 M urea) increase the reactivity of each of the four tyrosyls five- to tenfold, suggesting that all four are protected about equally by the overall folding of the chromatin. Isolated F2a1 iodinated in the presence of 10 M urea shows uniform labeling in each of the four peptides, suggesting that tyrosyl 72 and 98 are afforded some protection solely by protein-protein interactions. The stepwise removal of histones in increasing NaCl concentrations differentially increases the availability of each F2a1 tyrosyl. The preferential exposure of tyrosyl 88 coincides with the removal of the majority of F1 histones at 0.5 M NaCl while the gradual and stepwise increase in reactivity of tyrosyl 51, 72, and 98 correlates with the gradual removal of histones other than F1. Radioactive iodination of chromatin has been shown to be a sensitive probe for detecting changes in the association state (or conformation) of histone F2a1.     

Comparison between histones FV and F2a2 of chicken erythrocyte. II. Interaction with homologous DNA.

The conformation and stability of artificial complexes between chicken erythrocyte DNA and homologous histones FV and F2a2 was studied by circular dichroism (CD) and thermal denaturation followed by both absorbance and CD measurements. The complexes are made after a stepwise potassium fluoride gradient dialysis without urea and studied at low ionic strength (10-minus 3 M). 1) No structural changes of the DNA can be detected up to r equals 0.2 with FV and r equals 0.6 for F2a2. With FV at higher values of r the CD spectrum is altered, indicating the organization of DNA and histones in some kind of aggregate. 2) The conformation of histone molecules inside the complexes is not related to the ionic strength of the medium but to an effective ionic environment close to 0.1 M. This ionic strength would also correspond to the melting temperature of histone-covered DNA. 3) From the analysis of the absorbance melting profile the length of DNA covered with an histone molecule can be estimated. A good agreement is found between the negative charge of this piece of DNA and the net positive charge of the histone. 4) Since the CD transition at 227 nm occurs before the second absorbance transition at 280 nm, the DNA is stabilized no longer by native histone but partially or fully denatured histones. The helical regions of the histone molecule are not involved in the binding process, which appears to be almost purely coulombian and most likely related to some structural fit between the pattern of negative charges in the DNA helix and that of positive charges along the peptide chain.     

Differences in the mode of iodination of H2a variants in chromatin

Modification of H2a variants with radioactive iodine was used to study under different ionic conditions the accessibility of their tyrosine residues in chromatin, in monosomes and when free in solution. The modification of tyrosine 57 in the hydrophobic part of H2a was found responsible for the appearance of new fractions with a reduced electrophoretic mobility in the presence of Trition X 100, detected only by autoradiography (radioactive "ghosts"). At low ionic strength a very small number of molecules were iodinated in chromatin, the modification affecting only their hydrophobic region. At moderate ionic strength the tyrosine residues near the N-terminal region of the molecule were predominantly modified. In chromatin the accessibility of the tyrosine residues of H2a1 was much greater than that of H2a2, a difference not observed with free histones.     

A pH-dependent interaction between histones H2A and H2B involving secondary and tertiary folding.

It has been shown by high-resolution proton magnetic resonance (PMR) spectroscopy and circular dichroism (CD) that an H2A/H2B histone complex exists after salt extraction of these histones from chromatin and that this complex can be fully renatured from both urea-denatured acid-extracted and from urea-denatured salt-extracted histones. The histone complex is shown to involve specific secondary and tertiary structure. Formation of this complex is observed to be critically dependent on pH, occurring at and above pH 5. It cannot be induced below pH 5 by increase in ionic strength. From CD spectra the H2A/H2B complex is shown to contain about 37% alpha helix but no beta structure, the latter being confirmed by infrared spectroscopy in the 6-mum region. The PMR spectra show that the structured region includes most of the aromatic residues of both histones, at least two histidine residues of H2B and probably histidines 31 and 82 of histone H2A. The secondary structure of histones H2A and H2B is predicted using the Chou and Fasman procedure and comparisons are made between the predictions for histones of different species. These results in conjunction with the experimental evidence lead to the conclusion that at least residues 31-95 of H2A and residues 37-114 of H2B, i.e. the more apolar regions of the molecules, are involved in the tertiary structure of the H2A/H2B complex.     

Triiodothyronine nuclear receptor. Role of histones and DNA in hormone binding

The triiodothyronine (T3) nuclear receptor was previously shown to lose rapidly its high affinity hormone-binding property after a partial purification from the nuclear extract. It was then found that histones + DNA added to the incubation medium with labeled T3 could restore, at least in part, the high affinity T3 binding. We now demonstrate that DNA alone increases the high affinity T3 binding site concentration moderately, and only at low ionic strength where it can bind to the receptor. Total histones and all histone fractions studied (total core histones, F2a, H2B, H3, H4, H1) specifically increase, at low concentrations, the level of T3 binding; but higher concentrations of some individualized histones, particularly arginine-rich histones, have an inhibitory effect. DNA, or several other polynucleotides, in the presence of histones increase the stimulating histone effect and reverse the inhibitory effect into a true activation. Histones increase the number of T3 binding sites but decrease the affinity for T3; addition of DNA restores the high affinity for T3 and stabilizes the T3-receptor complexes. Thus, some of the histone molecules could play a role in the maintenance of the T3 binding site, but multiple interactions between histones or with DNA seem necessary to impair the negative effect exerted by other parts of the histone molecules. Whether these positive and negative effects of histones on the T3 binding site are of biological relevance in the regulation of T3 binding to its receptor remains to be determined.     

The nature of interactions responsible for the differences in the affinities of histones for DNA

Electrophoretic studies on the sequential binding of histones to DNA and to polyphosphate in low ionic strength solution have shown that the affinities of histones for both the polyanions decreases in the same order: H4 ～ H3 > H2A > H2B>H1. This permits to suggest that hydrophobic DNA-histone interactions do not determine the relative affinity of histones for DNA. Non-ionic interactions within and between histone molecules participate in determining the histone affinity for DNA affecting electrostatic DNA-histone interactions.     

Studies on the role and mode of operation of the very-lysine-rich histones in eukaryote chromatin. The conformation of phi1 histones from marine invertebrate sperm.

Proton magnetic resonance, circular dichroism and infrared spectroscopy are used to investigate the secondary and tertiary structure of three very lysine-rich histones from marine invertebrate sperm. At high ionic strength both Arbacia lixula and Holothuria tubulosa histone phi 1 are observed to contain 25-30% alpha-helix, no beta-structure and to form specific folded structures. Both phi 1 proton magnetic resonance spectra have perturbed methyl resonances at chemical shifts close to those observed for calf thymus H1, suggesting analogies in tertiary structure. Mytilus edulis histone phi 1 however, shows no spectroscopic evidence of secondary and tertiary structure on salt addition.     

Interactions of H1 and H5 histones with polynucleotides of B- and Z-DNA conformations

Interactions of chicken H1 and H5 histones with poly(dA-dT), poly(dG-dC), and the Z-DNA structure brominated poly(dG-dC) were measured by a nitrocellulose filter binding assay and circular dichroism. At low protein:DNA ratios, both H1 and H5 bound more Z-DNA than B-DNA, and binding of Z-DNA was less sensitive to interference by an increase in ionic strength (to 600 mM NaCl). H5 histone bound a higher percentage of all three polynucleotides than did H1 and caused more profound CD spectral changes as well. For spectral studies, histones and DNA were mixed in 2.0 M NaCl and dialyzed stepwise to low ionic strength. Prepared in this way or by direct mixing in 150 mM NaCl, complexes made with right-handed poly(dG-dC) showed a deeply negative psi spectrum (deeper with H5 than with H1). Complexes of histone and Br-poly(dG-dC) showed a reduction in the characteristic Z-DNA spectral features, with H5 again having a greater effect. Complexes of poly(dA-dT) and H5, prepared by mixing them at a protein:DNA ratio of 0.5, displayed a distinctive spectrum that was not achieved with H1 even at higher protein:DNA ratios. It included a new negative band at 287 nm and a large positive band at 255 nm, giving the appearance of an inverted spectrum relative to spectra of various forms of B-DNA. These findings may reflect an ability of the different lysine-rich histones to cause varying conformational changes in the condensation of chromatin in DNA regions of highly biased base sequence.     

Triiodothyronine nuclear receptor: Role of histones and DNA in hormone binding

The triiodothyronine (T₃) nuclear receptor was previously shown to lose rapidly its high affinity hormone-binding property after a partial purification from the nuclear extract. It was then found that histones + DNA added to the incubation medium with labeled T₃ could restore, at least in part, the high affinity T₃ binding. We now demonstrate that DNA alone increases the high affinity T₃ binding site concentration moderately, and only at low ionic strength where it can bind to the receptor. Total histones and all histone fractions studied (total core histones, F2a, H2B, H3, H4, H1) specifically increase, at low concentrations, the level of T₃ binding; but higher concentrations of some individualized histones, particularly arginine-rich histones, have an inhibitory effect. DNA, or several other polynucleotides, in the presence of histones increase the stimulating histone effect and reverse the inhibitory effect into a true activation. Histones increase the number of T₃ binding sites but decrease the affinity for T₃; addition of DNA restores the high affinity for T₃ and stabilizes the T₃-receptor complexes. Thus, some of the histone molecules could play a role in the maintenance of the T₃ binding site, but multiple interactions between histones or with DNA seem necessary to impair the negative effect exerted by other parts of the histone molecules. Whether these positive and negative effects of histones on the T₃ binding site are of biological relevance in the regulation of T₃ binding to its receptor remains to be determined.     

Investigation of DNA complexes with histones F3 and F3+F2a2]

Characteristic viscosity, sedimentation constant and optical anisotropy were studied of the complexes formed between DNA and histone fractions F3 and F3+F2a2. The parameters mentioned continuously change with the increase of protein content within the complex. Analysis of experimental data shows that binding of a histone bads to a decrease of size and thermodynamic rigidity of the DNA molecule. On the basis of results obtained a model of F3 histone binding with DNA is suggested, amino acid sequence of this protein being taken into account. Comparison of behaviour of nucleohistones DNA+F3 and DNA+F1 studied previously testifies different way of binding of these histones to DNA.     

Comparison between histones FV and F2a2 of chicken erythrocyte. I. Structure, stability and conformation of the free proteins.

Purified chicken erythrocyte histones FV and F2a2 were studied by means of circular dichroism as a function of ionic strength and temperature. The percentage of alpha-helical regions was calculated by comparison with reference spectra obtained with four standard proteins of known tertiary structure. Maximal alpha-helical organization, reached in high ionic strength, was estimated to 14% and 23% for FV and F2a2 respectively. We have compared our experimental determinations of the secondary structure of F2a2 with predictions made from amino-acid sequence according to Fasman's rules. When instability induced by the presence of charged residues close together is taken into account, a good agreement is found between predicted and observed values. The thermal denaturation of FV is cooperative and, unlike F2a2, seems to obey a two-state transition. The classical Arrhenius plot is linear, which indicates that the heat capacity is the same in both the native and the denatured state. Such a behaviour is typical of an expanded configuration of FV even in the "native" state.     

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)     

Studies on the role and mode of operation of the very-lysine-rich histone H1 (F1) in eukaryote chromatin. Histone H1 in chromatin and in H1 - DNA complexes.

The nuclear magnetic resonance (NMR) spectrum of chromatin at ionic strengths below about 0.5 M may be attributed solely to its histone H1 component. The effect of various ions and urea on the complex has been investigated using NMR and confirm that the contraction of the complex on increase of ionic strength is largely due to electrostatic interactions. A detailed study of the H1 - DNA complex has also been undertaken. The behaviour of H1 in the two cases is virtually identical, implying that in chromatin the H1 is complexed with the DNA rather than with the other histones. Microcalorimetric measurements reveal that the binding of H1 to DNA is athermic or involves a heat of reaction which is very small indeed.