Folding mechanism of the (H3-H4)2 histone tetramer of the core nucleosome

To further understand oligomeric protein assembly, the folding and unfolding kinetics of the H3-H4 histone tetramer have been examined. The tetramer is the central protein component of the core nucleosome, which is the basic unit of DNA compaction into chromatin in the eukaryotic nucleus. This report provides the first kinetic folding studies of a protein containing the histone fold dimerization motif, a motif observed in several protein-DNA complexes. Previous equilibrium unfolding studies have demonstrated that, under physiological conditions, there is a dynamic equilibrium between the H3-H4 dimer and tetramer species. This equilibrium is shifted predominantly toward the tetramer in the presence of the organic osmolyte trimethylamine-N-oxide (TMAO). Stopped-flow methods, monitoring intrinsic tyrosine fluorescence and far-UV circular dichroism, have been used to measure folding and unfolding kinetics as a function of guanidinium hydrochloride (GdnHCl) and monomer concentrations, in 0 and 1 M TMAO. The assignment of the kinetic phases was aided by the study of an obligate H3-H4 dimer, using the H3 mutant, C110E, which destabilizes the H3-H3' hydrophobic four-helix bundle tetramer interface. The proposed kinetic folding mechanism of the H3-H4 system is a sequential process. Unfolded H3 and H4 monomers associate in a burst phase reaction to form a dimeric intermediate that undergoes a further, first-order folding process to form the native dimer in the rate-limiting step of the folding pathway. H3-H4 dimers then rapidly associate with a rate constant of > or =10(7) M(-1)sec(-1) to establish a dynamic equilibrium between the fully assembled tetramer and folded H3-H4 dimers.     

Analysis of the dynamic equilibrium of histone oligomers in a solution. The nature of forces stabilizing the (H2A-H2B-H3-H4)2 octamer structure

Dynamic equilibrium analysis of the (H2A-H2B-H3-H4)2 histone octamer with lower oligomers was performed in 2 M NaCl. Calculated data on the relative content of histone oligomers upon changing protein concentration in solution are given. The red shift of lambda max for histone tyrosine fluorescence spectra is shown to be due to hydrogen bond formation by tyrosyl OH-groups. Analysis of free energy changes of histone oligomers upon association (delta G = -17,37 +/- 0,14 kcal/mole) as well as the effect of urea on histone octamer dissociation made it possible to conclude that virtually all tyrosyls in octamer form hydrogen bonds. Intermolecular hydrogen bonds formed by tyrosyls contribute substantially to octamer stabilization. The (H2A-H2B) dimer positive cooperativity in association with the (H3-H4)2 tetramer was found. This cooperativity is caused by interaction between association sites with a two order increase in an apparent constant of dimers with tetramer association. The histone octamer was determined to be of asymmetric structure due to unequivolency of the two binding sites for the (H2A-H2B) dimers.     

Thermodynamic studies of the core histones: stability of the octamer subunits is not altered by removal of their terminal domains.

We have investigated the role of the labile terminal domains of the core histones on the stability of the subunits of the protein core of the nucleosome by studying the thermodynamic behavior of the products of limited trypsin digestion of these subunits. The thermal stabilities of the truncated H2A-H2B dimer and the truncated (H3-H4)/(H3-H4)(2) system were studied by high-sensitivity differential scanning calorimetry and circular dichroism spectroscopy. The thermal denaturation of the truncated H2A-H2B dimer at pH 6.0 and low ionic strength is centered at 47.3 degrees C. The corresponding enthalpy change is 35 kcal/mol of 11.5 kDa monomer unit, and the heat capacity change upon unfolding is 1.2 kcal/(K mol of 11.5 kDa monomer unit). At pH 4.5 and low ionic strength, the truncated (H3-H4)/(H3-H4)(2) system, like its full-length counterpart, is quantitatively dissociated into two truncated H3-H4 dimers. The thermal denaturation of the truncated H3-H4 dimer is characterized by the presence of a single calorimetric peak centered at 60 degrees C. The enthalpy change is 25 kcal/mol of 10 kDa monomer unit, and the change in heat capacity upon unfolding is 0.5 kcal/(K mol of 10 kDa monomer unit). The thermal stabilities of both types of truncated dimers exhibit salt and pH dependencies similar to those of the full-length proteins. Finally, like their full-length counterparts, both truncated core histone dimers undergo thermal denaturation as highly cooperative units, without the involvement of any significant population of melting intermediates. Therefore, removal of the histone "tails" does not generally affect the thermodynamic behavior of the subunits of the core histone complex, indicating that the more centrally located regions of the histone fold and the extra-fold structured elements are primarily responsible for their stability and responses to parameters of their chemical microenvironment.     

Histone octamer instability under single molecule experiment conditions

We have studied the sample concentration-dependent and external stress-dependent stability of native and reconstituted nucleosomal arrays. Whereas upon stretching a single chromatin fiber in a solution of very low chromatin concentration the statistical distribution of DNA length released upon nucleosome unfolding shows only one population centered around approximately 25 nm, in nucleosome stabilizing conditions a second population with average length of approximately 50 nm was observed. Using radioactively labeled histone H3 and H2B, we demonstrate that upon lowering the chromatin concentration to very low values, first the linker histones are released, followed by the H2A-H2B dimer, whereas the H3-H4 tetramer remains stably attached to DNA even at the lowest concentration studied. The nucleosomal arrays reconstituted on a 5 S rDNA tandem repeat exhibited similar behavior. This suggests that the 25-nm disruption length is a consequence of the histone H2A-H2B dimer dissociation from the histone octamer. In nucleosome stabilizing conditions, a full approximately 145 bp is constrained in the nucleosome. Our data demonstrate that the nucleosome stability and histone octamer integrity can be severely degraded in experiments where the sample concentration is low.     

The nature of forces stabilizing nucleosome structure. Dissociation of histone octamers from DNA

We have used the measurements of the histone fluorescence parameters to study the influence of the ionic strength on histone-DNA and histone-histone interactions in reconstructed nucleosomes. The ionic strength increase lead to the two-stage nucleosome dissociation. The dimer H2A-H2B dissociates at the first stage and the tetramer (H3-H4)2 at the second one. The dimer H2A-H2B dissociation from nucleosome is a two-stage process also. The ionic bonds between (H2A-H2B) histone dimer and DNA break at first and then the dissociation of dimer from histone tetramer (H3-H4)2 occurs. According to the proposed model the dissociation accompanying a nucleosome "swelling" and an increase of DNA curvature radius. It was shown that the energy of electrostatic interactions between histone dimer and DNA is sufficiently less than the energy of dimer-tetramer interaction. We propose that the nucleosome DNA ends interact with the dimer and tetramer simultaneously. The calculated number (approximately 30 divided by 40) of ionic bonds between DNA and histone octamer globular part practically coincides with the number of exposed cationic groups on the surface of octamer globular head. On this basis we have assumed that the spatial distribution of these groups is precisely determined, which explains the high evolutionary conservatism of the histone primary structure.     

Yeast CAF-1 assembles histone (H3-H4)2 tetramers prior to DNA deposition

Following acetylation, newly synthesized H3-H4 is directly transferred from the histone chaperone anti-silencing factor 1 (Asf1) to chromatin assembly factor 1 (CAF-1), another histone chaperone that is critical for the deposition of H3-H4 onto replicating DNA. However, it is unknown how CAF-1 binds and delivers H3-H4 to the DNA. Here, we show that CAF-1 binds recombinant H3-H4 with 10- to 20-fold higher affinity than H2A-H2B in vitro, and H3K56Ac increases the binding affinity of CAF-1 toward H3-H4 2-fold. These results provide a quantitative thermodynamic explanation for the specific H3-H4 histone chaperone activity of CAF-1. Surprisingly, H3-H4 exists as a dimer rather than as a canonical tetramer at mid-to-low nanomolar concentrations. A single CAF-1 molecule binds a cross-linked (H3-H4)₂ tetramer, or two H3-H4 dimers that contain mutations at the (H3-H4)₂ tetramerization interface. These results suggest that CAF-1 binds to two H3-H4 dimers in a manner that promotes formation of a (H3-H4)₂ tetramer. Consistent with this idea, we confirm that CAF-1 synchronously binds two H3-H4 dimers derived from two different histone genes in vivo. Together, the data illustrate a clear mechanism for CAF-1-associated H3-H4 chaperone activity in the context of de novo nucleosome (re)assembly following DNA replication.     

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)     

NF-Y associates with H3-H4 tetramers and octamers by multiple mechanisms

NF-Y is a CCAAT-binding trimer with two histonic subunits, NF-YB and NF-YC, resembling H2A-H2B. We previously showed that the short conserved domains of NF-Y efficiently bind to the major histocompatibility complex class II Ea Y box in DNA nucleosomized with purified chicken histones. Using wild-type NF-Y and recombinant histones, we find that NF-Y associates with H3-H4 early during nucleosome assembly, under conditions in which binding to naked DNA is not observed. In such assays, the NF-YB-NF-YC dimer forms complexes with H3-H4, for whose formation the CCAAT box is not required. We investigated whether they represent octamer-like structures, using DNase I, micrococcal nuclease, and exonuclease III, and found a highly positioned nucleosome on Ea, whose boundaries were mapped; addition of NF-YB-NF-YC does not lead to the formation of octameric structures, but changes in the digestion patterns are observed. NF-YA can bind to such preformed DNA complexes in a CCAAT-dependent way. In the absence of DNA, NF-YB-NF-YC subunits bind to H3-H4, but not to H2A-H2B, through the NF-YB histone fold. These results indicate that (i) the NF-Y histone fold dimer can efficiently associate DNA during nucleosome formation; (ii) it has an intrinsic affinity for H3-H4 but does not form octamers; and (iii) the interactions between NF-YA, NF-YB-NF-YC, and H3-H4 or nucleosomes are not mutually exclusive. Thus, NF-Y can intervene at different steps during nucleosome formation, and this scenario might be paradigmatic for other histone fold proteins involved in gene regulation.     

Dynamics of Nucleosome Assembly and Effects of DNA Methylation

The nucleosome is the fundamental packing unit of the eukaryotic genome, and CpG methylation is an epigenetic modification associated with gene repression and silencing. We investigated nucleosome assembly mediated by histone chaperone Nap1 and the effects of CpG methylation based on three-color single molecule FRET measurements, which enabled direct monitoring of histone binding in the context of DNA wrapping. According to our observation, (H3-H4)₂ tetramer incorporation must precede H2A-H2B dimer binding, which is independent of DNA termini wrapping. Upon CpG methylation, (H3-H4)₂ tetramer incorporation and DNA termini wrapping are facilitated, whereas proper incorporation of H2A-H2B dimers is inhibited. We suggest that these changes are due to rigidified DNA and increased random binding of histones to DNA. According to the results, CpG methylation expedites nucleosome assembly in the presence of abundant DNA and histones, which may help facilitate gene packaging in chromatin. The results also indicate that the slowest steps in nucleosome assembly are DNA termini wrapping and tetramer positioning, both of which are affected heavily by changes in the physical properties of DNA.     

Isolation and physico-chemical properties of native histone complexes: dimer (H2-H2B), tetramer (H3-H4)2 and octamer (H3-H4-H2A-H2B)2

The paper is concerned with the isolation of the native histone complexes: dimer (H2A-H2B), tetramer (H3-H4)2 and octamer (H3-H4-H2A-H2B)2 from the calf thymus chromatin under soft conditions (hydroxyl apatite) fractionation with the subsequent gel filtration). Parameters of hydroxyl apatite saturation with chromatin are determined. The complexes obtained are free of DNA and nonhistone proteins. Absorption spectra parameters, quantum efficiencies and fluorescence spectra typical of the corresponding histone oligomers are established. Comparison of free tyrosine fluorescence spectra with histone tyrosyl ones revealed a long-wave shift in the latter.     

The Hydrophobicity of the H3 Histone Fold differs from the Hydrophobicity of the other three Folds

The eukaryotic histone dimers, H3–H4 and H2A–H2B, are formed in the cytosol prior to being transported into the nucleus and assembled into the nucleosome. Residue side-chain distances from the interior of the histone dimers are obtained with an ellipsoidal spatial metric and structural information provided by X-ray analyses at atomic resolution of the nucleosome core particles. While the spatial hydrophobic moment profiles of the dimers are comparable with profiles obtained previously that characterize the hydrophobic core of single-chain, single-domain globular soluble proteins, correlation coefficients between the side-chain hydrophobicities and distances from the interior of the H3–H4 dimer and H2A–H2B dimer differ significantly. This difference is traced to the H3 histone fold, which segregates fewer hydrophobic residues within the protein interior than the three other folds. Examination of the correlation coefficient between residue hydrophobicity and side-chain distance from the dimer interior over local regions of the fold sequence shows that the region of reduced correlation is associated mainly with the residues at the carboxyl end of the H3 histone fold, the helical region of the fold involved in the H3–H3 binding of the (H3–H4)₂ tetramer of the nucleosome. Hydrophobic interactions apparently contribute to the binding of this fourfold helical bundle and this evolutionary requirement may trade off against the requirement for H3–H4 dimer stability. The present results provide a different view than previously proposed, albeit of similar origin, to account for the reduced stability of the H3–H4 dimer compared with the H2A–H2B dimer.Reviewing Editor: Dr. Martin Kreitman     

Structure of histone octamers in reconstituted polynucleosomes

The salt-dependent structural changes of the histone octamer in complex with high-molecular-weight DNA have been studied by fluorescent spectroscopy. Changes in both the spectra maximum position and anisotropy of the histone tyrosine fluorescence reveal structural transitions in nucleosome within the ranges of 0.5-3 mM and 20-30 mM NaCl. Comparison of the octamer fluorescent parameters in complex with DNA as well as in a free state permits to interpret the revealed structural transitions as a change in degree of contacts stability between (H2A-H2B) dimer and (H3-H4)2 tetramer. More pronounced conformational changes in histone octamer are observed under the conditions of polynucleosome fibers interaction within the range of physiological ionic strength (100-600 mM NaCl). As far as fluorescent parameters are concerned, the aforementioned changes are connected with entire destruction of (H2A-H2B) dimer specific contacts with (H3-H4)2 tetramer. The obtained results suggest the possibility of existence of different structural states of histone octamer in the chromatin composition including those which are quite dissimilar from the octamer structure in the 2M NaCl solution.     

Roles of the histone H2A-H2B dimers and the (H3-H4)(2) tetramer in nucleosome remodeling by the SWI-SNF complex

SWI-SNF is an ATP-dependent chromatin remodeling complex required for expression of a number of yeast genes. Previous studies have suggested that SWI-SNF action may remove or rearrange the histone H2A-H2B dimers or induce a novel alteration in the histone octamer. Here, we have directly tested these and other models by quantifying the remodeling activity of SWI-SNF on arrays of (H3-H4)(2) tetramers, on nucleosomal arrays reconstituted with disulfide-linked histone H3, and on arrays reconstituted with histone H3 derivatives site-specifically modified at residue 110 with the fluorescent probe acetylethylenediamine-(1,5)-naphthol sulfonate. We find that SWI-SNF can remodel (H3-H4)(2) tetramers, although tetramers are poor substrates for SWI-SNF remodeling compared with nucleosomal arrays. SWI-SNF can also remodel nucleosomal arrays that harbor disulfide-linked (H3-H4)(2) tetramers, indicating that SWI-SNF action does not involve an obligatory disruption of the tetramer. Finally, we find that although the fluorescence emission intensity of acetylethylenediamine-(1,5)-naphthol sulfonate-modified histone H3 is sensitive to octamer structure, SWI-SNF action does not alter fluorescence emission intensity. These data suggest that perturbation of the histone octamer is not a requirement or a consequence of ATP-dependent nucleosome remodeling by SWI-SNF.