Conformational changes of the chromatin subunit

Effect of chromatin structure on quantitative ultrasound parameters

High-frequency ultrasound (~20 MHz) techniques were investigated using in vitro and ex vivo models to determine whether alterations in chromatin structure are responsible for ultrasound backscatter changes in biological samples. Acute myeloid leukemia (AML) cells and their isolated nuclei were exposed to various chromatin altering treatments. These included 10 different ionic environments, DNA cleaving and unfolding agents, as well as DNA condensing agents. Raw radiofrequency (RF) data was used to generate quantitative ultrasound parameters from spectral and form factor analyses. Chromatin structure was evaluated using electron microscopy. Results indicated that trends in quantitative ultrasound parameters mirrored trends in biophysical chromatin structure parameters. In general, higher ordered states of chromatin compaction resulted in increases to ultrasound paramaters of midband fit, spectral intercept, and estimated scatterer concentration, while samples with decondensed forms of chromatin followed an opposite trend. Experiments with isolated nuclei demonstrated that chromatin changes alone were sufficient to account for these observations. Experiments with ex vivo samples indicated similar effects of chromatin structure changes. The results obtained in this research provide a mechanistic explanation for ultrasound investigations studying scattering from cells and tissues undergoing biological processes affecting chromatin.

Complexes of semiflexible polyelectrolytes and charged spheres as models for salt-modulated nucleosomal structures

We investigate the complexation behavior between a semiflexible charged polymer and an oppositely charged sphere with parameters appropriate for the DNA-histone system. We determine the ground state of a simple free energy expression (which includes electrostatic interactions on a linear level) numerically and use symmetry arguments to divide the obtained DNA configuration into broad classes, thereby obtaining global phase diagrams. We pay specific attention to the effects of salt concentration, DNA length variation, DNA charge renormalization, and externally applied force on the obtained complex structures.

Alteration of nucleosome structure as a mechanism of transcriptional regulation

The nucleosome, which is the primary building block of chromatin, is not a static structure: It can adopt alternative conformations. Changes in solution conditions or changes in histone acetylation state cause nucleosomes and nucleosomal arrays to behave with altered biophysical properties. Distinct subpopulations of nucleosomes isolated from cells have chromatographic properties and nuclease sensitivity different from those of bulk nucleosomes. Recently, proteins that were initially identified as necessary for transcriptional regulation have been shown to alter nucleosomal structure. These proteins are found in three types of multiprotein complexes that can acetylate nucleosomes, deacetylate nucleosomes, or alter nucleosome structure in an ATP-dependent manner. The direct modification of nucleosome structure by these complexes is likely to play a central role in appropriate regulation of eukaryotic genes.

Structural states of the nucleosome

The nucleosome is the fundamental component of the eukaryotic chromosome, participating in the packaging of DNA and in the regulation of gene expression. Its numerous interactions imply a structural dynamism. Previous biophysical studies under limited sets of conditions have not been able to reconcile structural differences and transitions observed. We have determined a series of nucleosome conformations over a >10,000-fold range in salt concentration using a combination of biochemical methods, spectroscopic electron microscopy, and three-dimensional reconstruction techniques for randomly oriented single particles. This study indicates several ionic strength-dependent nucleosome conformations and also reconciles the differences between currently existing divergent models for the nucleosome. At low ionic environments, the particle appears highly elongated, becoming more compact and prolate ellipsoidal as ionic strength is increased to 10 mm NaCl. At 30 mM NaCl, the particle exhibits a spheroidal conformation. As ionic strength is increased to 150 mM NaCl, the nucleosome conformation changes and becomes oblate. Above 450 mM NaCl, the structure becomes highly elongated again. The result of this study is a unifying concept in which the three-dimensional structure of the nucleosome is inferred to be dynamic in response to ionic interactions and in accord with biochemical and genetic studies.

The structure and dynamics of H1-depleted chromatin

The size of DNA involved in the interaction with a histone octamer in H1-depleted chromatin was re-examined. We compared the thermal untwisting of chromatin DNA and naked DNA using CD and electrophoretic topoisomer analysis, and found that DNA of 175 +/- 10 base pairs (bp) in length interacted with the histone core under physiological conditions. The decrease of ionic strength below 20 mM NaCl reduced this length down to 145 bp: apparently, an extra 30 bp DNA dissociated from the histone core to yield well-known 145-bp core particle. Histone cores partly dissociate within the temperature range of 25 to 40 degrees C. Quantitative analysis of histone thermal dissociation from DNA shows that the size of DNA protected against thermal untwisting would be significantly overestimated if this effect is neglected. The results presented in this paper also suggest that the dimers (H2A, H2B) act as a lock, which prevents transmission of conformational alterations from a linker to nucleosome core DNA. The histone core dissociation as well as (H2A, H2B) dimer displacement are discussed in the light of their possible participation in the eukaryotic genome activation.

Direct detection of linker DNA bending in defined-length oligomers of chromatin

Linker DNA, which connects between nucleosomes in chromatin, is short and, therefore, may be essentially straight and inflexible. We have carried out hydrodynamic and electron microscopic studies of dinucleosomes--fragments of chromatin containing just two nucleosomes--to test the ability of linker DNA to bend. We find that ionic conditions that stabilize the folding of long chromatin cause linker DNA in dinucleosomes to bend, bringing the two nucleosomes into contact. The results uphold a key prediction of the solenoid model of chromosome folding and suggest a mechanism by which proteins that are separated along the DNA can interact by direct contact.

In vitro replication through nucleosomes without histone displacement

A well-characterized set of proteins encoded by bacteriophage T4 replicates DNA in vitro and generates replication forks that can pass nucleosomes. The histone octamers remain associated with newly replicated DNA even in the presence of excess DNA competitor, and intact nucleosomes re-form on the two daughter DNA helices. It is concluded that nucleosomes are designed to open up transiently to allow the passage of a replication fork without histone displacement.

Histone hyperacetylation. Its effects on nucleosome core particle transitions

Effects of histone hyperacetylation on transitions of HeLa cell nucleosome core particles were studied. The transitions examined were induced by low salt concentrations, pH, temperature, and nondissociating high salt. Effects of salt dissociation were also examined. The low-salt transition was found to shift to higher ionic strength by approximately three fold for hyperacetylated particles, a change which may be due simply to the increased overall negative charge on the particles caused by acetylation of lysine residues. Some differences were also seen in the way in which core particles refold after exposure to very low salt (which induces a nonreversible change in the particles). Otherwise no significant effects of hyperacetylation were observed.

Reversibility of the low-salt transition of chromatin core particles

The low-salt transition of chromatin core particles is reversible if the monovalent cation concentration is kept above 0.2 mM. Exposure of the particles to salt concentrations below this value results in a nonreversible secondary transition. The nonreversible changes are relatively slow with a half-time of about 15 minutes. Once exposed to such low ionic strength, the particles then begin to refold with increasing salt in at least two steps over a much higher ionic strength range than is required for the usual low-salt transition. The refolding is very fast, with a half-time less than a minute. Small differences between particles which had or had not been exposed to very low salt persist even when the particles are returned to near physiological ionic strengths.

Internal architecture of the core nucleosome: fluorescence energy transfer studies at methionine-84 of histone H4

Chicken histone H4, labeled separately at Met-84 with N-[[(iodoacetyl)amino]ethyl]-5-naphthylamine-1-sulfonic acid and 5-(iodoacetamido)fluorescein, was reassociated with unlabeled histones H2A, H2B, and H3 and 146 base pairs of DNA to produce fluorescently labeled nucleosomes having physical characteristics virtually the same as those of native core particles. Four types of particles were prepared containing respectively unlabeled H4, dansylated H4, fluoresceinated H4, and a mixture of the two labeled H4 molecules. Quantitative singlet-singlet energy-transfer measurements were carried out to determine changes in the distance between the two Met-84 H4 sites within the same nucleosome following conformational transitions which we have reported earlier. In the ionic strength range 0.1-100 mM NaCl, the distance between these sites is less than 2 nm except at 1 mM. Between 100 and 600 mM monovalent salt the distance separating the donor and acceptor fluors at Met-84 H4 increases to 3.8 nm. The conformational change centered around 200 mM NaCl is cooperative. Our results and those of others indicate that there is little unfolding of the histone octamer, at least around Met-84 H4, in the entire ionic strength range studied. A mechanism involving the rotation of the globular portion of H4 is proposed to account for this transition which occurs at physiological ionic strengths.

The effect of preincubation of HeLa cell nuclei with ATP on the degradation of mononucleosomal DNA by micrococcal nuclease

HeLa cell nuclei with DNA labeled with [3H] thymidine have been preincubated under varying conditions and then incubated with micrococcal nuclease. Aliquots, removed at increasing times, were analyzed for mononucleosomal size DNA and for acid-soluble DNA, the ratios were plotted and a slope was determined. Preincubation with ATP and a regenerating system increased the slope 2 fold. Optimum ATP concentrations were above 0.25 mM. The ATP effect was reversed by novobiocin. No inhibition of the ATP effect was observed with nalidixic acid, coumermycin, oxolinic acid, VM-26, aphidicolin, or 3 amino-benzamide. NAD or cAMP or cGMP had no effect with or without ATP. Other nucleoside triphosphates could substitute to varying degrees for ATP as could ATP analogues. Nuclei from log phase cells showed no ATP effect, but log phase cells, partially depleted of ATP by incubation with deoxyglucose, showed the effect. The effect was lost in nuclei on long-term storage. No evidence was found for differential degradation of core histones, histone H-1 or DNA, and there was no evidence of nucleosome sliding.

The effect of histone H1 on the compaction of oligonucleosomes. A quasielastic light scattering study

The structural properties of H1-depleted oligonucleosomes are investigated by the use of quasielastic laser light scattering, thermal denaturation and circular dichroism and compared to those of H1-containing oligomers. To obtain information on the role of histone H1 in compaction of nucleosomes, translational diffusion coefficients (D) are determined for mono-to octanucleosomes over a range of ionic strength. The linear dependences of D on the number of nucleosomes show that the conformation of stripped oligomers is very extended and does not change drastically with increasing the ionic strength while the rigidness of the chain decreases due to the folding of linker DNA. The results prove that the salt-induced condensation is much smaller for H1-depleted than for H1-containing oligomers and that histone H1 is necessary for the formation of a supercoiled structure of oligonucleosomes, already present at low ionic strength.

Effects of pH on the stability of chromatin core particles

Chromatin core particles near physiological ionic strength undergo a reversible transition induced by changes in pH near neutrality. While sedimentation studies indicate no significant effect on size or shape, changes in tyrosine fluorescence anisotropy and in circular dichroism suggest a somewhat looser structure at high pH. Further support of this suggestion is given by high salt dissociation experiments; at pH 8 core particles begin to show changes at lower salt concentration than at pH 6. The pH transition appears unaffected by the presence of Mg2+ but can be blocked by crosslinking of the histones. A possible relationship is suggested between this transition and increases in intracellular pH which correlate with enhancement in several aspects of cellular activity including DNA replication.

Physical structure of gene-sized chromatin from the protozoan Oxytricha

Oxytricha nova is a hypotrichous ciliate containing a transcriptionally active macronucleus and a transcriptionally inactive micronucleus. Two-dimensional gel electrophoresis shows that macronuclei contain a normal complement of inner histones. However, despite extensive efforts, no classical H1-like protein has been detected. Micrococcal nuclease digestion indicates a nucleosome repeat length of approximately 220 bp for macronuclear chromatin. Thermal denaturation profiles of macronuclear chromatin in 0.2 mM EDTA display four transitions at about 46, 57, 64, and 79 degrees C. The lowest of these shifts to higher temperature as the ionic strength is raised to 3-5 mM Na phosphate. These results are consistent with the absence of H1 and a nucleosome repeat of 220-230 bp. Circular dichroism (CD) results agree with these findings. By contrast, micronuclear chromatin displays a much smaller premelt and a more suppressed DNA CD signal at 285 nm, consistent with a micronuclear chromatin repeat of 165-185 bp as determined by micrococcal nuclease digestion.

Neutron-scattering studies of accurately reconstituted nucleosome core particles and the effect of ionic strength on core particle structure

Chicken erythrocyte nucleosome core particles can be dissociated quantitatively into histones (H3, H4)2 bound to 146 base pairs of DNA, and 2(H2A, H2B). Reconstitution of core particles from the two components produces an 85% yield of particles which neutron scattering studies show to be accurate stoichiometrically and indistinguishable from native core particles: the radii of gyration of the shape, the protein components and the DNA components of the particles are 4.02 nm, 3.3 nm and 4.95 nm respectively. The largest distance and most probable distance which can be drawn in the particles are 11.5 nm and 4.3 nm respectively. The molecular weight of the particles is identical to that of control 'native' core particles. All of these values, within limits of error, are the same as known values for 'native' core particles. These experiments confirm the essential role of histones H3 and H4 in the initial organisation of core-particle structure, make possible the manufacture of perfectly pure and homogeneous core-particle preparations and allow the 100% incorporation of labelled or modified histones. Neutron scattering studies of core particles at high contrast (in D2O and H2O) have been carried out over a range of ionic strengths and pH. No change in structure is detected down to pH 5.5 in 20 mM NaCl or down to ionic strength 2.0 mM at pH 7.

Nucleosomal particles open as the histone core becomes hyperacetylated

Lymphoblastoid cells grown in the presence of the deacetylase inhibitor butyrate were used to isolate nucleosomal particles in a hyperacetylated state. During a non-denaturing gel electrophoresis these particles revealed a heterogeneity which is only in part due to the presence of nonhistone proteins. Monomers that are free from histone H1 and high-mobility-group (HMG) proteins 14 and 17 yield a subfractionation according to the degree of core histone acetylation beyond a limiting value of 10 acetyl groups/particle. It is shown that hyperacetylation provides particles with low mobilities and a considerable conformational freedom in contrast to HMG protein 14 which locks them in a conformation that has a similar electrophoretic behaviour but is more defined.

The structure of partly decondensed metaphase chromosomes

The technique of freeze-drying was applied to examine the submicroscopic organisation of metaphase chromosomes from Chinese hamster after removal of bivalent cations with EDTA and removal of histone HI with 0,6 M NaCl. Treated chromosomes increased in size, and nucleosomal filaments appeared at the periphery of the chromosomes. Removal of bivalent cations is accompanied with the appearance of regularly organized structures of the "beads-on-a-string" type. The regular organization of the fibers is damaged as soon as histone H1 is removed. After decondensation in a 0.6 M NaCl solution the metaphase chromosomes were treated with staphylococcal nuclease in situ on EM grids nd the residual structures analysed using electron microscopy. Nucleohistone fibers wer visible at the periphery of the chromosomes at the beginning of digestion. After complete elimination of the nucleohistone fibers in the course of digestion the remaining proteinaceous material was represented by aggregates of irregular shape and of varying size. These were either concentrated along the central axis of the chromatids or, at the final step of digestion, scattered evenly over the entire area that had been occupied by the chromosome. Presumably, in the chromosome prior to digestion, the material did not form an integral protein structure similar to a scaffold in dehistonised and spread chromosomes. An alternative interpretation for the fragmentation of protein material in the chromosome considers possible degradation of the protein scaffold in the course of digestion.

The binding sites for large and small high-mobility-group (HMG) proteins. Studies on HMG-nucleosome interactions in vitro

Studies in vitro of binding high-mobility-group (HMG) proteins to nucleosomal particles that differ in their DNA contents reflect several aspects pertinent to their function in vivo. Two molecules of HMG 14 or 17 are accommodated by particles with 140 or 180 base pairs of DNA whereas HMG 1 or 2 are only bound by the larger specimens irrespective of the presence of HMG 14/17. It is concluded that one molecule of HMG 1 or 2 binds to the 40 base pairs of linker DNA whereas the HMG 14 or 17 molecules associate with the nucleosomal core. At physiological ionic strength, HMG 14 binding is cooperative, probably by triggering a conformational change in the nucleosomal particle. The phenomenon has been studied by two independent techniques. Besides the common gel-electrophoretic system, a centrifugation assay is described, which permits the derivation of a Hill coefficient nH = 1.3 and dissociation constants in the range of 30-90 nM at 0.15 M NaCl, pH 6.8.

Eukaryotic ternary transcription complexes. I. The release of ternary transcription complexes of RNA polymerases I and II by the endogenous nucleases of rat liver nuclei

Autodigestion of rat liver nuclei in magnesium-containing buffers leads to the release of about 80% of DNA-dependent RNA polymerases I and II, together with 4 to 8% of the DNA. The RNA polymerases are at least partially DNA bound as judged by the effect on in vitro transcription of (1) Actinomycin D, (2) preirradiation of the enzymes in the presence of 8-methoxypsoralen and (3) heparin. The released DNA migrates as ladders of nicked nucleosome-size fragments on electrophoresis. On sucrose gradients, most RNA polymerase activity sediments as two peaks: one slightly smaller than the 11S mononucleosome and the other with the dinucleosome. The released material can act as a source of ternary transcription complexes for further structural studies.

Effects of pH on low-salt transition of chromatin core particles

The low-salt transition of chicken erythrocyte core particles containing uniform 145 base pair DNA was studied as a function of pH and of salt concentration. Intrinsic tyrosine fluorescence was used to follow the changes. Potassium salts of the anions C1-, H2PO4-, and SO4(2-) were indistinguishable in their ability to affect the transition. Divalent cations (Mg2+, Mn2+, Ca2+) were effective at 36-fold lower total concentration than monovalent cations (Li+, Na+, K+, Tris+), but no significant differences were observed within the two classes of cations. These results indicate that cation binding to the core particle is involved in the transition. At pH 9 the transition was broadened and shifted to higher monovalent cation concentration as compared to that at pH 6. At both pHs the fluorescence changes could be resolved into two steps by numerical least-squares analysis. On the basis of what is known about histone--histone interactions, a two-step mechanism is suggested, involving changes in the interactions between dimers of histones 2a and 2b with a tetramer of histones 3 and 4. The pH-induced changes appear to be correlated with a structural transition, which was detected as a function of pH at near physiological ionic strength (0.1 M). This structural change was accompanied by a small decrease in the tyrosine fluorescence anisotropy. An apparent pKa value near 7 is indicated, suggesting that the structural changes involved may be of physiological significance.

Modulation of nucleosome structure by histone subtypes in sea urchin embryos

Switches of the types of histones synthesized and incorporated into chromatin occur during sea urchin embryogenesis. In an attempt to define the possible effects of these variant histones on chromatin structure, I have isolated and characterized nucleosome core particles from Strongylocentrotus purpuratus blastula (nearly 100% early histones) and pluteus (75% late histones). Both particles contain 146-base-pair lengths of DNA wrapped around an octamer of H2A, H2B, H3, and H4. Although sharing these similarities with the canonical core particle, the nucleosome structures have certain features that differ from those of typical adult tissues. Both the reversible and the irreversible conformational transitions occurring on heating core particles are destabilized in the embryonic particles vs. "typical" core particles. The blastula core particle unfolds more easily than pluteus (or other) nucleosomes under the stress of low ionic strength. The rate of DNase I digestion of pluteus core particles is about half that of particles from blastula; certain cutting sites differ in their susceptibility between the two embryonic particles and between these two and the canonical core particle. The data demonstrate that the variant histones synthesized during early embryogenesis have demonstrable effects on chromatin structure, even at this basic level.

Conformation of chromatin oligomers. A new argument for a change with the hexanucleosome

Quasielastic laser light scattering measurements have been made on chromatin oligomers to obtain information on the transition in their electrooptical properties, previously observed for the hexameric structures [Marion, C. and Roux, B. (1978) Nucleic Acids Res. 5, 4431-4449]. Translational diffusion coefficients were determined for mononucleosomes to octanucleosomes containing histone H1 over a range of ionic strength. At high ionic strength, oligomers show a linear dependence of the logarithm of diffusion coefficient upon the logarithm of number of nucleosomes. At low ionic strength a change occurs between hexamer and heptamer. Our results agree well with the recent sedimentation data of Osipova et al. [Eur. J. Biochem. (1980) 113, 183-188] and of Butler and Thomas [J. Mol. Biol. (1980) 140, 505-529] showing a change in stability with hexamer. Various models for the arrangements of nucleosomes in the superstructure of chromatin are discussed. All calculations clearly indicate a conformational change with the hexanucleosome and the results suggest that, at low ionic strength, the chromatin adopts a loosely helical structure of 28-nm diameter and 22-nm pitch. These results are also consistent with a discontinuity every sixth nucleosome, corresponding to a turn of the helix. This discontinuity may explain the recent electric dichroism data of Lee et al. [Biochemistry (1981) 20, 1438-1445]. The hexanucleosome structure which we have previously suggested, with the faces of nucleosomes arranged radially to the helical axis has been recently confirmed by Mc Ghee et al. [Cell (1980) 22, 87-96]. With an increase of ionic strength, the helix becomes more regular and compact with a slightly reduced outer diameter and a decreased pitch, the dimensions resembling those proposed for solenoid models.

Differing accessibility in chromatin of the antigenic sites of regions 1-58 and 63-125 of histone H2B

Experiments with antibodies induced by separated fragments 1-58 and 63-125 of H2B histone indicated that the 1-58 portion of the molecule is much more accessible in chromatin than is the 63-125 region. In immunoabsorption and immunoelectron microscopic assays with bovine and chicken chromatins, anti-1-58 antibodies reacted with sheared or unsheared chromatin both at low ionic strength (1 mM Tris-HCl) and in 0.14 M NaCl. Anti-63-125 antibodies were bound only weakly by chromatin at low ionic strength and not at all in 0.14 M NaCl. Antibodies to whole H2B showed intermediate reactivity with chromatin in both assays. In tests of immunofluorescence with unfixed calf liver nuclei in suspension, anti-1-58 caused nucleolar as well as nucleoplasmic fluorescence, whereas anti-63-125 did not lead to detectable fluorescence; anti-H2B showed intermediate staining intensity. In control experiments, anti-H1 antibody was bound by chromatin at low ionic strength but not in 0.14 M NaCl; anti-H3 antibody was bound poorly under either condition.

Stability of the primary organization of nucleosome core particles upon some conformational transitions

The sequential arrangement of histones along DNA in nucleosome core particles was determined between 0.5 and 600 mM salt and from 0 to 8 M urea. These concentrations of salt and urea up to 6 M had no significant effect on the linear order of histones along DNA but 8 M urea caused the rearrangement of histones. Conformational changes in cores have been identified within these ranges of conditions by several laboratories 8-21. Also, abrupt structural changes in the cores, apparently their unfolding, were found by gel electrophoresis to occur at urea concentration, between 4 and 5 M. 600 mM salt and 6 M urea were shown to relax the binding of histones to DNA in cores but do not however release histones or some part of their molecules from DNA. It appears therefore that nucleosomal cores can undergo some conformational transitions and unfolding whereas their primary organization remains essentially unaffected. These results are consistent with a model of the core particles in which the histone octamer forms something like a helical "rim" along the superhelical DNA and histone-histone interactions beyond the "rim" are rather weak in comparison with those within the "rim".

The role of histone H1 in compaction of nucleosomes. Sedimentation behaviour of oligonucleosomes in solution

The dependence of sedimentation coefficients of oligonucleosomes on the number of nucleosomes in the chain in solutions of different ionic strength has been studied for oligonucleosomes both containing and lacking histone H1. The analysis of these dependencies has shown that oligonucleosomes with H1 at low concentration (I = 0.01 mol/l) may be described by the model of a short cylinder with an average length of the chain per nucleosome l0 = 11 nm where the neighbouring nucleosomes are in close contact. Oligonucleosomes without H1 at I = 0.01 mol/l can be described by the model of a worm-like chain with l0 = 27 nm. This suggests that when H1 is removed the linker DNA unfolds completely. In 0.15 M NaCl the oligonucleosome chain without H1 folds up to a compact configuration typical of oligonucleosomes with H1 at I = 0.01 mol/l. Thus, the linker DNA, with charges being screened, may fold due to interactions with core histones. Oligonucleosomes with H1 in 0.15 M NaCl form a supercoiled structure, whose stable conformation is accounted for by cooperative interactions of no less than five nucleosomes.

The roles of H1, the histone core and DNA length in the unfolding of nucleosomes at low ionic strength

Calf thymus nucleosomes exhibit two different and independent hydrodynamic responses to diminishing salt concentration. One change is gradual over the range 40 to 0.2 mM Na+ and is accompanied by decreases in contact-site cross-linking efficiency. The other change is abrupt, being centered between 1 and 2 mM Na+. We found only one abrupt change in sedimentation rate for particles ranging in DNA content fom 144 to 230 base pairs. This response to decreasing ionic strength is similar for particles of both 169 and 230 base pairs. Core particles (144 base pairs) exhibit a somewhat diminished response. The abrupt change is blocked by formaldehyde or dimethylsuberimidate cross-linking. The blockage by dimethylsuberimidate demonstrates that the abrupt conformational change requires the participation of the core histones. H1 completely blocks the abrupt but not the gradual conformational change. Thus H1 uncouples the different responses to low ionic strength and exerts an important constraint on the conformational states available to the nucleosome core.

Conformation of nucleosome core particles and chromatin in high salt concentration

The conformation of nucleosome core particles and chromatin under different ionic strength conditions has been studied by electron microscopic, hydrodynamic, and spectroscopic techniques. In the range of ionic strength used (6--600 mM), all four core histones were bound to the DNA. The sedimentation coefficient of the core particle decreases from 11.3 in 6 mM NaCl to 9.4 in 600 mM NaCl, and an alteration of the circular dichroic spectrum was observed when the ionic strength was increased. Direct evidence for the alteration of the chromatin structure in high salt was obtained by electron microscopy where a very extended conformation of the nucleosome was observed. The protein cross-linking agent dimethylsuberimidate was used to study the histone--histone proximities in the core particles; our experiments reveal that the same histones are in contact in the extended particles and in the compact native particles.

Salt induced transitions of chromatin core particles studied by tyrosine fluorescence anisotropy

Chromatin core particles containing 146 base pairs of DNA have been found to undergo a single defined transition below 10 mM ionic strength as studied by both sedimentation velocity and tyrosine fluorescence anisotropy. A method is described for the preparation of such core particles from chicken erythrocytes with greater than 50% yield.

The number of charge-charge interactions stabilizing the ends of nucleosome DNA

It has been shown by others that the melting of DNA in the nucleosome core particle is biphasic (ref. 1) and that the initial denaturation phase is due to melting of the DNA termini (refs. 1 & 2). We analyze the salt dependence of the melting temperature of this first transition and estimate that only 15% of the phosphates of the DNA termini are involved in intimate charge-charge interactions with histones. (The simplest model yields approximately 9%, whereas a calculated overestimate yields approximately 21% neutralization.) This is a surprisingly small number of interactions but we suggest that it may nonetheless be representative of all the core particle DNA.

Effect of DNA length on the nucleosome low salt transition

The effect of DNA length on the low salt unfolding transition of nucleosomes has been studied by the use of fluorescently labeled histones. Nucleosomes were formed by the reconstitution of bulk DNA fragments averaging 173 and 250 base pairs in length. These nucleosomes exhibited a conformational change in a transition centered at about 7 mM ionic strength, very different from that observed for the standard 145 bp nucleosomes (1-3mM). In addition, the conformational change of the 173 and 250 bp nucleosomes involves twice as many ions as that of the 145 bp nucleosomes.

Nucleosomes structure and its dynamic transitions

The discovery of nucleosomes as a basic repeating unit of the chromatin structure organizing the major part of eukaryotic DNA greatly catalyzes the expansion of our knowledge on chromatin. Several lines of experimental evidence have led to the formulation of the nucleosome conception: the observation of chains of globular particles in electron micrographs of chromatin (Olins & Olins, 1974); the demonstration that DNA is released as a set of discrete sizes upon digestion of chromatin with endogenous nucleases (Hewish & Burgoyne, 1973); the isolation of discrete nucleoprotein particles upon digestion of chromatin with micrococcal nuclease (Rill & Van Holde, 1973).

Singlet-singlet energy transfer studies of the internal organization of nucleosomes

We report the measurement of two specific protein to DNA distances in several conformational states of core nucleosomes by singlet-singlet energy transfer. A distance of 50-53 A separates each DNA terminus from cysteine-110 of chicken erythrocyte histone H3 in the native nucleosome. This cysteine residue must therefore be located very near the center of the nucleosome. The H3-DNA distance remained nearly constant in several unfolded forms of the core particles, as found in very low salt, in 0.6 M NaCl, and in high urea. Furthermore, it was shown that each DNA end lies within 32 A of cysteine-73 of Arbacia lixula sperm histone H4 in both the compact and the low-salt unfolded forms of the nucleosome. Because of the invariance of the two measured distances in the various conformational states of the nucleosome, we conclude that the cysteine-containing C-terminal segments of histones H3 and H4 maintain a very strong and close association with the terminal positions of the 146 base pair nucleosomal DNA. This binding may provide the primary interactions necessary for the folding of DNA into nucleosomes and for protection of 146 base pair nucleosomes from further nuclease digestion.

Salt-induced structural changes in nucleosomes

Ehrlich ascites tumor (EAT) nucleosomes treated with increasing NaCl concentrations were analyzed by sucrose density gradient centrifugation. Two events were found to take place in the course of the salt treatment: a) increasing amounts of nucleosomes dissociated into free DNA and protein in the interval 0.6M-1.5M NaCl, and b) the sedimentation coefficient of the nucleosomes decreased from 11S to 8S in the interval 0.6M - 1M NaCl. This decrease was not caused by loss of protein and was fully reversible upon slow and gradual lowering of the ionic strength. This shows that before dissociation of the protein core from DNA, nucleosomes undergo a structural transition. The electron microscopic observations revealed that it consisted in detachment of the ends of nucleosomal DNA from the protein core. It is suggested that an arginine-rich domain in the protein core exists, which holds more tightly the central part of the nucleosomal DNA, while its ends are relatively loosely bound to lysine-rish domains.