Gene-specific differences in the supranucleosomal organization of rat liver chromatin

Rat liver chromatin was separated into a solubilized portion and insoluble nuclear material, and the solubilized portion was fractionated by sucrose gradient sedimentation. The chromatin encompassing three transcribed genes (albumin, tryptophan oxygenase, and alpha-fetoprotein), which are expressed at very different levels, partitions preferentially with insoluble nuclear material and possesses a disrupted nucleosome structure. On the contrary, the chromatin encompassing three inactive genes fractionates into the solubilized chromatin portion and exhibits a canonical nucleosome repeat structure. By sucrose gradient sedimentation, all size classes of inactive chromatin particles are found to contain internal cleavages in the linker region between nucleosomes; they are probably held together by histone H1 and mono- and divalent cations. When the chromatin encompassing two flanking sequences of the tyrosine aminotransferase gene is studied, the 0.35-kilobase upstream-located chromatin exhibits features of active genes, while the 2.55-kilobase upstream-located chromatin partitions preferentially with solubilized chromatin and sediments in internally cleaved particles.     

Characteristics of the structural state of DNA in chromatin with short linker

Various fragments of pigeon brain neuron chromatin with very short linker DNA have been studied by circular dichroism (CD). The DNA structure in core particles of the brain and thymus chromatins is very similar. Linker DNA and a part of core DNA in the mononucleosomes of brain chromatin is extended. This conclusion follows from increasing CD amplitude of the brain mononucleosomes as compared with the corresponding value for thymus mononucleosomes. The internucleosome interactions stabilized the compactness of core DNA in the brain oligonucleosomes. The whole linker DNA of the brain chromatin unlike thymus chromatin is extended at low ionic strength. This fact can explain the brain chromatin ability to form a compact structure with increasing ionic strength.     

The higher order repeat structure of chromatin is built up of globular particles containing eight nucleosomes

Mild nuclease digestion of rat liver chromatin generates particles with sedimentation coefficients of about 33S, 60S, and 90S (in 50 mM NaCl). The kinetics of appearance and disappearance of these particles with progressive digestion suggest that they are produced by cleavage from a higher order repeat structure, the 33S particle representing the monomer. At an intermediate stage of digestion, about 75 % of the nuclear chromatin can be recovered as monomers to trimers of this higher order structure. Sedimentation profiles indicate that monomer particles containing 7–8 nucleosomes occur at the highest frequency. The DNA fragments in monomers have a size corresponding to hepta- and octanucleosomes, and those in dimers have a size corresponding to chains of sixteen nucleosomes. The higher order repeat structure is only stable between 30 and 200 mM NaCl; the particles unfold below 30 and above 200 mM NaCl. When examined by electron microscopy, monomers and dimers appear as compact globular structures. Relaxation by lowering the salt concentration results in the appearance of polynucleosomes with a chain length of eight beads in the monomer and sixteen in the dimer particle. These results indicate that the unit particle of the higher order repeat structure of rat liver chromatin contains eight nucleosomes.     

Monoazido analog of ethidium as a chromatin probe: Binding to DNA

Two photoaffinity analogs of ethidium, 8-azido-3-amino, and 3-azido-8-amino-5-ethyl-6-phenylphenanthridinium chloride, have been used to probe the structure of mammalian chromatin and its interactions with the ethidium moiety. The monoazido analogs were established as suitable probes by comparing their interactions with chromatin and pure DNA prepared from chromatin to those of the parent ethidium bromide. Scatchard analysis of the binding data determined from spectrophotometric titrations showed that the analogs interacted with both nucleic acids in a manner similar to the parent compound. The effect of chromatin proteins on the interaction of the ethidium moiety with intact chromatin was investigated directly. By exposing the noncovalent complex to visible light, the monoazido analog was attached covalently in its interaction sites within chromatin, and the amount of drug bound covalently to DNA was determined for both protein-free DNA and chromatin. Using saturating concentrations of drug, DNA within intact chromatin was found to be associated with only half as much drug as DNA extracted from its protein prior to drug exposure. The distribution of drug bound within chromatin was determined following the attachment of the monoazido analog (by photoactivation) to chromatin that had undergone limited nuclease digestion. Several distinct populations isolated by size fractionation and quantitative measurements revealed that (1) both the core particles and the spacer-containing particles contained bound drug, reflecting high-affinity binding sites; and (2) chromatin particles containing 150 DNA base pairs (putatively nucleosome core structures) contained less total bound drug at high drug concentrations than those particles having intact spacer DNA.     

Scatter analysis of discrete-sized chromatin fragments favours a cylindrical organization

Fragments of chromatin containing 23 +/- 2.5 nucleosomes have been fractionated after light nuclease treatment of chicken erythrocyte nuclei. Low-angle scattering measures the total z-average radius of gyration of the already well-defined particles and the shape of scatter curves can be compared with three-dimensional analysis as opposed to cross-section analysis of long chromatin fragments. The data show that the particles are not spherical, have no detectable hole in the center of the structure and are best represented by a solid rod-like shape such as that generated by a coil of nucleosomes with the centre perhaps filled with linker DNA and histone H1/H5. 23 nucleosome fragments, where the DNA is partially fragmented, have near-identical scatter curves to the above-defined intact particles, indicating the primary importance of histone proteins in maintaining the integrity of the chromatin higher-order structure. Neutron scattering shows the radii of gyration to be contrast-independent, which fits in with the model calculations for solenoids. Particles with fragmented DNA and the intact particles, therefore, behave as sections of a solenoidal higher-order structure and possibly are observed as "superbeads' only during the folding and unfolding pathways of nucleosome multimers.     

Heterogeneous packing of the Escherichia coli chromosome and its decompaction in in vitro experiments

The chromatin organization of E. coli cells, taken on various growth stages of the culture (active, stationary, grown with heightened density), displays different characters when examined by the Miller method. In the active phase of growth, the cell chromatin is released as threads and loops of DNA, threads of nucleosome-like particles and granules 25-38 nm in size. The chromatin from cells in the stationary phase of growth, grown in heightened density conditions, contains not only granules of average size 30 and 100 nm, but also larger conglomerates consisting of several 100 nm particles. The chromatin decompaction of cells grown under heightened density, in conditions of weak alkali medium and low salt buffer, was in general of two types: creation of diffusion cloud with no clear-cut outlines, and spherical structure of 1.5-2 microns in diameter with electron dense centre. In one chromosome both the types of chromatin decompaction can be found at the same time with regions of compact chromatin, which undoubtedly shows different functional activity of some regions of the chromosome.     

Chromatin structure visualization by immunoelectron microscopy

Antibodies elicited in rabbits by chromatin and by purified histone H2B have been used to study the structure of chromatin by immunoelectron microscopy. Chromatin spread on grids reveals a structure of closely packed spherical particles with an average diameter of 104 Å, arranged either in clusters or in linear arrays of beads, some of which have a supercoil-like arrangement. No DNA strings connecting the beads could be observed. Upon antibody binding, the diameter of the particles increases up to 300 Å. This size is compatible with a model where one layer of gamma globulin molecules 110 Å long encircles a sphere of chromatin 100 Å in diameter. The presence of rabbit gamma globulins on the enlarged beads has been verified by the addition of ferritin-labeled goat anti-rabbit gamma globulins. Anti-chromatin sera which react with nonhistone proteins but not with free histones or DNA react with more than 95% of the beads; this suggests that most of the beads contain nonhistone proteins. Since the number of nonhistone proteins is large, it is improbable that each sphere contains a full complement of these proteins. We therefore suggest that the various chromatin spheres contain different types of nonhistone proteins. About 90% of the chromatin spheres reacted with antibodies to histone H2B, suggesting that most of the chromatin beads contain this type of histone.     

Laser-induced crosslinking of histones to DNA in chromatin and core particles: implications in studying histone-DNA interactions.

UV laser irradiation has been used to covalently crosslink histones to DNA in nuclei, chromatin and core particles and the presence of the different histone species in the covalently linked material was detected immunochemically. When nuclei were irradiated and then trypsinized to cleave the N- and C- terminal histone tails, no histones have been found covalently linked to DNA. This finding shows that UV laser-induced crosslinking of histones to DNA is accomplished via the non-structured domains only. This unexpected way of crosslinking operated in chromatin, H1-depleted chromatin and core particles, i.e. independently of the chromatin structure. The efficiency of crosslinking, however, showed such a dependence: whilst the yield of crosslinks was similar in total and H1-depleted chromatin, in core particles the efficiency was 3-4 times lower for H2A, H2B and H4 and 10-12 times lower for H3. The decreased crosslinking efficiency, especially dramatic in the case of H3, is attributed to a reduced number of binding sites, and, respectively, is considered as a direct evidence for interaction of nonstructured tails of core histones with linker DNA.     

Changes of chromatin organization induced by phospholipids

Isolated nuclei represent a suitable model for studying the influence of exogenous phospholipids, normally found as minor chromatin components, on the nuclear structure, which, in turn, could be related to the observed modifications of DNA and RNA synthesis. The morphological modifications induced on chromatin RNP granules and nuclear matrix have been analyzed both with conventional thin sectioning and with an original method based on image analysis of freeze-fractured and replicated nuclear samples. The results obtained support the hypothesis that anionic phospholipids, by removing histone H1, induce a transition of the chromatin from solenoid to nucleosome conformation and favour the RNA polymerizing activity which results in an increased release of RNP particles, while neutral phospholipids, probably affecting the matrix structure, partly impare the RNP maturation and transport, with consequent increase of chromatin condensation.     

Contribution à l'étude de la structure de la chromatine: I - Etude physico-chimique de la stabilité de la chromatine

Physicochemical studies of calf thymus chromatin were performed on micromicellar suspensions by thermal denaturation. These diluted suspensions were obtained, by a controlled shearing method, from a compact gel chromatin. Sedimentation and free-flow electrophoresis determined the size distribution of these particles. The most important result is a new transition on the melting profiles corresponding to a sudden increase of solution turbidity. This chromatin solution transition occurs at a higher temperature than usual DNA transition. The degree of « turbidity transitiondiminishes with micelle size but disappears when they are very mildly degraded by DNAases and when F₁ histone fraction is removed.This transition is not only size dependent but also depends on the micellar structure. This phenomenon is interpreted as an excluded volume effect by contact between compact and native regions of nucleoprotein micelles and denatured coils of DNA. Our study tried to show that the degree of turbidity transition can be a criterion of chromatin native structure.     

Analysis of supra-nucleosome particles from unfertilized eggs of sea urchins

Two discrete supranucleosomal particles that differ in their electrophoretic migration on 1% agarose gels were isolated from unfertilized sea urchin eggs. Both particles contain the same complement of cleavage stage (CS) chromosomal proteins, which is identical to the complete set of basic proteins isolated directly from chromatin by extraction with 0.25 N HCl. DNA fragments between 210 and 1500 bp were found in both particles, and the basic unit of DNA repeat length determined by micrococcal nuclease digestion was 126 +/- 3 bp. The isolated nucleoparticles are electrophoretically stable over a wide range of DNA sizes (126-1500 bp) indicating that their structure is maintained by internal interactions among the CS chromosomal proteins, previously designated CS A through CS G. Based on these results we conclude that the CS chromosomal proteins are functionally equivalent to classical histones in their ability to direct higher ordered structures of chromatin.     

Hydrodynamic shearing by VirTis blending conserves nucleosome structure of rat liver chromatin

The effects of VirTis shearing on chromatin subunit structure were investigated by enzymatic digestion, thermal denaturation, and electron microscopy. While initial rates of micrococcal nuclease and DNase I digestion were greater postshearing, limit digest values were similar to those for unsheared chromatin. Fractionated chromatin digestion kinetics varied with sedimentation. Digestion of all chromatins produced monomer and dimer DNA fragment lengths, but only unsheared chromatins exhibited higher order nucleosome oligomer lengths. Mononucleosomes and core particles were resolved in digests of sheared and gradient fractions analyzed by electrophoresis. All chromatins exposed to DNase I showed discrete 10-base pair nicking patterns. The presence of nucleosomes was confirmed by electron microscopy. Electron microscopy and histone content of gradient fractions showed that nucleosome density along the chromatin axis increased in rapidly sedimenting fractions. Thermal denaturation detected no appreciable generation of protein-free DNA fragments as a result of shearing. The results indicate that VirTis blending conserves subunit structure with loss of less than 12–15% of nucleosome structure.     

Urea denaturation of chromatin periodic structure.

Isolated chicken erythrocyte nuclei dispersed in urea solutions (0-5.0 M) have been examined in terms of their low-angle X-ray diffraction and electron microscopic properties. At high urea concentrations, the characteristic low-angle X-ray reflections of chromatin are absent, and the spheroid chromatin particles (v bodies) are markedly perturbed. This lability of chromatin periodic structure to high concentrations of urea is consistent with previous hydrodynamic and spectroscopic studies.     

Distribution of tissue-specific tightly bound non-histone proteins in the first level of repeating chromatin structures

Non-histone proteins, tightly bound to DNA, have been extracted from whole chromatin and core particles prepared from pig liver or kidney. We have investigated by bidimensional slab gel electrophoresis the distribution of this protein class in the first level of repeating structure of chromatin. Our results reveal that non-histone proteins tightly bound to DNA are a heterogeneous protein class. Some of them, particularly in the core particles, appear to be essentially the same in both tissues, though having differences in their isoelectric point, which may be attributed to postsynthetic modifications. We have calculated that this protein class is associated to only 10% of nucleosomes, these nucleosomes having, on the average, one protein molecule for each core DNA. The tissue-specific proteins have high molecular mass (ranging from 135 kDa to 70 kDa in liver, over 135 kDa in kidney) and, in kidney, a more basic isoelectric point. These proteins are mainly located outside the core particles; they could be situated in the spacer regions and/or be involved in determining higher levels of chromatin organization.     

Structural organization of rat hepatocyte chromatin as visualized in thin frozen sections selectively stained for DNA

We studied the structure of rat hepatocyte chromatin in situ using thin frozen sections selectively stained for DNA after aldehyde fixation. Our results indicate that intranucleolar chromatin is arranged into three different organization levels, confirming the observations on Epon-embedded chromatin. These are: completely extended DNA filaments, with a thickness of approximately 3 nm, clustered in loose, roundish agglomerates, very long fibers with a thickness ranging from 15 to 35 nm and compact chromatin clumps. Both the fibers and the chromatin clumps frequently appeared to be composed of nucleosome-like particles. In the extranucleolar chromatin, agglomerates of extended DNA filaments and long fibers were never visualized. In contrast to data from Epon-embedded chromatin, we noticed that in frozen sections neither the nucleolar nor the extranucleolar compact chromatin appear to be organized into discrete, 20 to 30 nm superordered fibers.     

Visualization of chromatin substructure: upsilon bodies

Spread chromatin fibers, from isolated eucaryotic nuclei, reveal linear arrays of spherical particles (upsilon bodies), about 70 A in diameter, connected by thin filaments about 15 A wide. These particles have been observed in freshly isolated nuclei from rat thymus, rat liver, and chicken erythrocytes. In addition, upsilon bodies can be visualized in preparations of isolated sheared chromatin, and in chromatin reconstructed from dissociating solvent conditions (i.e., high urea-NaCl concentration). As a criterion for perturbation of native chromatin structure low-angle X-ray diffraction patterns were obtained from nuclear pellets at different stages in the preparation of nuclei fro electron microscopy. These results suggest that the particulate (upsilon body) structures observed by electron microscopy may be closely related to the native configuration of chromatin.     

Aggregation of mono- and dinucleosomes into chromatin-like fibers

Three classes of chicken erythrocyte chromatin particles differing in their content of lysine-rich histones and/or spacer DNA have been studied in order to determine their ability to aggregate into complexes resembling those observed in native chromatin. The complexes have been obtained in the presence of MgCl₂ and NaCl and studied by electron microscopy. Mononucleosomes, containing spacer DNA and histones H1 and H5, give rise to thick (about 70 nm) ellipsoidal particles in the presence of 0.5 mM MgCl₂. These particles are disrupted by the addition of small amounts of NaCl (5–20 mM). On the other hand in 0.5 mM MgCl₂ dinucleosomes give rise to regular fibrous complexes of about 40 nm in diameter which are very similar to native chromatin fibers. These complexes are much more stable when NaCl is added. We conclude that for the stability of nucleosomal aggregates, similar to native chromatin fibers, a continuity of DNA structure is not required, but the presence of divalent cations, spacer DNA and lysine-rich histones is essential.