Levels of granular organization of chromatin fibres

Higher Order Structures in Chromosomes

Chromosomes are units of the genom in eukaryotes containing a specific fraction of the DNA characteristic for the species. This DNA forms the backbone of the chromosome and usually is represented by a single DNA double helix stretching from one end of the chromosome to the other. Relative to the size of most nuclei the length of the DNA is considerable. In humans for instance the haploid set of DNA is about 1 m long and in certain amphibia can measure many meters. The analysis of chromosome structure is mainly concerned with the various levels of folding or coiling by which this DNA is compacted in a regular way into chromosomes of interphase and mitotic stages.

The electron microscope has played an important role in the discovery of chromosome organization. The 20 nm fiber was first described in 1956 as a unit of interphase chromatin (Ris, 1956). Later the 10 nm fiber was recognized as the component of chromatin dispersed in the presence of chelating agents for biochemical studies (Ris, 1961).

The detailed 3D multi-loop aggregate/rosette chromatin architecture and functional dynamic organization of the human and mouse genomes

BACKGROUND

The dynamic three-dimensional chromatin architecture of genomes and its co-evolutionary connection to its function-the storage, expression, and replication of genetic information-is still one of the central issues in biology. Here, we describe the much debated 3D architecture of the human and mouse genomes from the nucleosomal to the megabase pair level by a novel approach combining selective high-throughput high-resolution chromosomal interaction capture (T2C), polymer simulations, and scaling analysis of the 3D architecture and the DNA sequence.

RESULTS

The genome is compacted into a chromatin quasi-fibre with ~5 ± 1 nucleosomes/11 nm, folded into stable ~30-100 kbp loops forming stable loop aggregates/rosettes connected by similar sized linkers. Minor but significant variations in the architecture are seen between cell types and functional states. The architecture and the DNA sequence show very similar fine-structured multi-scaling behaviour confirming their co-evolution and the above.

CONCLUSIONS

This architecture, its dynamics, and accessibility, balance stability and flexibility ensuring genome integrity and variation enabling gene expression/regulation by self-organization of (in)active units already in proximity. Our results agree with the heuristics of the field and allow "architectural sequencing" at a genome mechanics level to understand the inseparable systems genomic properties.

Magnesium chloride and polyamine can differentiate mouse embryonic stem cells into trophectoderm or endoderm

Magnesium chloride and polyamines stabilize DNA and chromatin. Furthermore, they can induce nucleosome aggregation and chromatin condensation in vitro. To determine the effects of elevating the cation concentrations in the nucleus of a living cell, we microinjected various concentrations of mono-, di- and polyvalent cation solutions into the nuclei of mouse embryonic stem (ES) cells and traced their fates. Here, we show that an elevation of either MgCl₂, spermidine or spermine concentration in the nucleus exerts a significant effect on mouse ES cells, and can differentiate a certain population of the cells into trophectoderm, a lineage that mouse ES cells do not normally generate, or endoderm. It is hypothesized that the cell differentiation was most probably caused by the condensation of chromatin including the Oct3/4 locus, which was induced by the elevated concentrations of these cations.

Chromatin fibers: from classical descriptions to modern interpretation

The first description of intrachromosomal fibers was made by Baranetzky in 1880. Since that time, a plethora of fibrillar substructures have been described inside the mitotic chromosomes, and published data indicate that chromosomes may be formed as a result of the hierarchical folding of chromatin fibers. In this review, we examine the evolution and the current state of research on the morphological organization of mitotic chromosomes.

Extraction of histone H1 and decondensation of nuclear chromatin with various Mg-dependent organization levels under treatment with polyglutamic acid and distamycin

Chromatin in rat liver nuclei under conditions of low ionic strength (20-25 mM) and [Mg2+] from 2 to 5 mM has a condensed structure (100-200 nm globules) and gives the same CD signal (320-340 nm) at interaction with the antibiotic distamycin A (DM). Reducing [Mg2+] to 1 mM leads to chromatin decondensation to 30 nm structures and increases the CD signal. Poly-L-glutamic acid (PG) at weight ratio PG/DNA = 6 and in the presence of 5 mM Mg2+ extracts only about 1/8 of nuclear histone H1, preserving a condensed chromatin structure. Removal of about 1/4 of H1 at 3 mM Mg2+ leads to chromatin decondensation to 30 nm fibrils. Extraction of about half of histone H1 at [Mg2+] ≤ 2 mM results in chromatin refolding to nucleosome fibrils. PG-decondensation leads to a significant increase in the CD signal. The main H1 extraction occurs in 1-2 min, but at all Mg2+ concentrations the more slowly PG extracted fraction is found comprising 5-7% of nuclear H1. About 25% of leaving nuclear H1 can be extracted by PG in the presence of saturating DM concentration (molar DM/DNA = 0.1). H1 release depends significantly on the PG concentration. However, even at high weight ratio PG/DNA = 30 and DM/DNA = 0.1, about 5-10% of histone H1 remained in the nuclei. Decondensation of chromatin in the nucleus is not always proportional to the yield of extracted histone H1 and is weakened in the presence of positively charged DM or high concentrations of PG. Our results show that the interaction of DM with chromatin depends primarily on chromatin packaging, while PG extraction depends on [Mg2+] supporting this packaging.

Influence of chromatin structure, antibiotics, and endogenous histone methylation on phosphorylation of histones H1 and H3 in the presence of protein kinase A in rat liver nuclei in vitro

In vitro phosphorylation of histones H1 and H3 by cAMP-dependent protein kinase A and endogenous phosphokinases in the presence of [γ-³²P]ATP was studied in isolated rat liver nuclei with different variants of chromatin structural organization: condensed (diameter of fibrils 100-200 nm; N-1) and partly decondensed (diameter of fibrils ~30 nm; N-2). In the N-1 state histone, H1 is phosphorylated approximately twice as much than histone H3. Upon the decondensation of the chromatin in the N-2 state, 1.5-fold decrease of total phosphorylation of H1 is observed, while that of H3 does not change, although the endogenous phosphorylation of both histones is reduced by half. Changes in histone phosphorylation in the presence of low or high concentrations of distamycin and chromomycin differ for H1 and H3 in N-1 and N-2. It was found that distamycin (DM) stimulates the phosphorylation of tightly bound H1 fraction, which is not extractable by polyglutamic acid (PG), especially in N-1. Chromomycin (CM) increases the phosphorylation of both histones in PG extracts and in the nuclear pellets, particularly in N-2. At the same time, in N-1 one can detect phosphorylation of a tightly bound fraction of histones H1 whose N-termini are located on AT-rich sites that become inaccessible for protein kinase in the process of chromatin decondensation in N-2. At the same time, in N-2 the accessibility for protein kinase A of tightly bound H1 fractions, whose N-termini are located on GC-rich sites, increases dramatically. High concentrations of both CM and DM in N-1 and N-2 stimulated phosphorylation of the non-extractable by PG fraction of H1 whose N-termini are located on sites where AT ≈ GC. CM at high concentration stimulated 4-7 times the phosphorylation of a small fraction of H3, which is extracted by PG from both types of nuclei. We detected an effect of endogenous methylation of histones H1 and H3 in the nuclei on their subsequent phosphorylation depending on the chromatin structure, histone-chromatin binding strength, and concentration of DM.

Assessing environmental risks for established invasive weeds: Dalmatian (Linaria dalmatica) and yellow (L. vulgaris) toadflax in North America

Environmental risk assessments characterizing potential environmental impacts of exotic weeds are more abundant and comprehensive for potential or new invaders than for widespread and well-established species such as Dalmatian (Linaria dalmatica [L.] Mill.) and yellow (L. vulgaris Mill.) toadflax. Specific effects evaluated in our assessment of environmental risks posed by yellow and Dalmatian toadflax included competitive displacement of other plant species, reservoirs of plant disease, animal and insect use, animal toxicity, human toxicity and allergenicity, erosion, and wildfire. Effect and exposure uncertainties for potential impacts of toadflax on human and ecological receptors were rated. Using publicly available information we were able to characterize ecological and human health impacts associated with toadflax, and to identify specific data gaps contributing to a high uncertainty of risk. Evidence supporting perceived negative environmental impacts of invasive toadflax was scarce.

Influence of distamycin, chromomycin, and UV-irradiation on extraction of histone H1 from rat liver nuclei by polyglutamic acid

Rat liver nucleus histone H1 was fractionated by polyglutamic acid (PG) in the presence of distamycin A (DM) or chromomycin A(3) (CM). In the absence of the antibiotics, PG extracts from the nuclei about half of the nuclear H1. DM or CM added to the nuclei in saturating concentrations weakens the binding potential of most of H1. Titration of nuclei with DM shows that the number of binding sites for DM in the nuclei is less than in isolated DNA by only 20-25%, and this difference disappears after treatment of nuclei with PG. The lower CD value of DM complexes with nuclei compared to that of DM complexes with free DNA is evidence of a change in the DM-DNA binding mode in nuclear chromatin. About 25% of total histone H1 is sensitive only to DM and ~5% is sensitive only to CM. Half of the DM-sensitive H1 fraction seems to have a different binding mode in condensed compared relaxed chromatin. A small part of H1 (~3%) remains tightly bound to the nuclear chromatin independent of the presence of the antibiotics. Subfraction H1A is more DM-sensitive and H1B is more CM-sensitive. UV irradiation of nuclei results in dose-dependent cross-linking of up to 50% of total H1, which is neither acid-extractable nor recovered during SDS electrophoresis. PG with DM extracts only about 3% of H1 from UV-stabilized chromatin. DM treatment of the nuclei before UV irradiation results in extraction of the whole DM-sensitive H1 fraction (~25%), which in this case is not stabilized in the nucleus. A hypothesis on possible roles of the found H1 fractions in chromatin structural organization is discussed.

Structural-functional model of the mitotic chromosome

In the present review the structural role of noncoding DNA, mechanisms of differential staining of mitotic chromosomes, and structural organization of different levels of DNA compactization are discussed. A structural-functional model of the mitotic chromosome is proposed based on the principle of discreteness of structural levels of DNA compactization.

Functional and structural units in the chromomere

Electron microscopic observations demonstrate the existence of several DNA packing levels in the chromomere. A linear DNA molecule forms a big (chromomere) loop anchored to the chromosomal scaffold. The loop forms a set of smaller loops in the rosette pattern. Packing of the DNA by the histone octamer particles results in nucleosomes and nucleomeres. To establish the possible correspondence between the structural units of a chromomere and the genetical units (genes, exons, introns) in it, we compared the lengths of the units. Statistical analysis of the 315 sequenced genes indicate that the average gene size corresponds to the average length of a rosette loop. It means that a chromomere contains one or more genes. Assuming that exon-intron boundaries cannot bind nucleosomes we constructed DNA-packing models of the 88 genes. They demonstrate that the first (in 77.8 per cent of the genes) and the last (in 52.7 per cent) exons of the genes are too short to bind nucleosomes. Many genes contain long (nucleosome binding) pieces of DNA. Long packed pieces are introns in vertebrates; they are exons in invertebrates and plants. The average size gene contains two nucleomeres.

Ultrastructure of somatic and meiotic nucleoids

In this review emphasis is placed on the contribution of transmission electron microscopy to the analysis of spread chromosomes and nucleoids. Support is advanced for the DNA loop and rosette organization of meiotic and metaphase chromosomes and nucleoids. Extensive discussion is given to the biochemical treatments used for producing nucleoids and the effect of divalent cations and chelating agents on chromatin compactization (supercoiling). Detailed studies on nucleoids from hepatocytes are presented, with emphasis on the significance of DNA attachment to the internal nuclear matrix and to the nuclear lamina. It is firmly predicted that from the increasing knowledge of the structural organization of eukaryotic chromatin and the genome, a greater understanding of the functional roles of the various intranuclear structures will ultimately follow.

Nucleosomal organization of a part of chromatin in mollusc sperm nuclei with a mixed basic protein composition

The structural organization of mature sperm chromatin from three representatives of the Mytilidae family has been studied. The acid-soluble proteins in these species nuclei are primarily sperm-specific (approximately 80%) with the remainder being core histones. Previously, we have shown that the mature sperm nuclei of these molluscs are compact, dense structures formed by interaction of the spermspecific proteins with DNA (1). Here we show that: a) although the histones are minor chromatin protein fraction, they still organize a part (20-25%) of the total DNA into nucleosomes; b) one of the sperm-specific proteins, different from somatic H1 or H5 histones participates in the formation of the beaded structures.

Differences of supranucleosomal organization in different kinds of chromatin: cell type-specific globular subunits containing different numbers of nucleosomes

Fractions of homogeneously-sized supranucleosomal particles can be obtained in high yield and purity from various types of cells by brief micrococcal nuclease digestion (10 or 20 s) of condensed chromatin in 100 mM NaCl followed by sucrose gradient centrifugation and agarose gel electrophoresis. These chromatin particles, which contain only DNA and histones, differed according to cell type. Sea urchin spermatozoa (Paracentrotus lividus) gave rise to heavy particles (ca. 260 S) with a mean diameter (48 nm). These resembled the unit chromatin fibrils fixed in situ, which contain an average of 48 nucleosomes, as determined both by electron microscopy after unraveling in low salt buffer and gel electrophoresis. In contrast, higher order particles from chicken erythrocyte chromatin were smaller (105 S; 36-nm diam) and contained approximately 20 nucleosomes. The smallest type of supranucleosomal particle was obtained from chicken and rat liver (39 S; 32-nm diam; eight nucleosomes). Oligomeric chains of such granular particles could be recognized in regions of higher sucrose density, indicating that distinct supranucleosomal particles of globular shape are not an artifact of exposure to low salt concentrations but can be obtained at near-physiological ionic strength. The demonstration of different particle sizes in chromatin from different types of nuclei is contrary to the view that such granular particles are produced by artificial breakdown into "detached turns" from a uniform and general solenoid structure of approximately six nucleosomes per turn. Our observations indicate that the higher order packing of the nucleosomal chain can differ greatly in different types of nuclei and the supranucleosomal organization of chromatin differs between cell types and is related to the specific state of cell differentiation.

Biochemical and ultrastructural study of the sperm chromatin from Mytilus galloprovincialis

Protein composition and ultrastructure of the mature spermatozoa of the mussel Mytilus galloprovincialis were studied upon gradual decondensation of the nuclei with increasing NaCl concentration. Three types of protein were found, associated with the sperm DNA: (1) the sperm-specific proteins S1, S2 and S3 (80% of the acid-soluble proteins); (2) the four core histones (20%); (3) three non-histone proteins tightly bound to DNA (about 4 micrograms protein per 100 micrograms DNA). The sperm-specific protein S3 was the first to dissociate at about 0.5 M NaCl and electron micrographs of spread nuclei indicated its participation in the final compaction of the nucleus. Hypotonically treated sperm nuclei revealed the presence of 21-25 nm large granules irregularly scattered along some of the DNA fibers. These granules correspond to the 'superbeads' of histone-containing chromatins. The tightly bound non-histone proteins were represented by a triplet in the range 60-80 kD. They formed 30-60 nm large annular bodies holding DNA fibers and resisting high salt-detergent treatment.

Magnesium binding and conformational change of DNA in chromatin

The structure of chromatin in the presence of Mg2+ ions was examined by circular dichroism and equilibrium dialysis. Circular dichroism (CD) shows that above 260 nm the intensity of the spectrum of DNA in nucleoproteins decreases as the Mg2+ concentration increases. This change is an intrinsic characteristic of DNA since it is also observed in protein-free DNA and has been attributed to a change in the winding angle of base pairs around the DNA axis. Some structural elements of the DNA in the nucleosome core, therefore, are as movable as those of protein-free DNA. The basic organization of H1-depleted chromatin, 146 base pairs (bp) of DNA wound around core histones and a residual 49 bp in the linker region in the repeating unit, is maintained both in the presence and in the absence of Mg2+ ions, as shown by the fact that the CD spectrum of H1-depleted chromatin has the same type of linear combination between the spectrum of protein-free DNA and that of the nucleosome core in 0.2 mM MgCl2-10 mM triethanolamine (pH 7.8) as it has in 1 mM ethylenediaminetetraacetic acid-10 mM tris(hydroxymethyl) aminomethane (pH 7.8). The ellipticity of chromatin shows a smaller decrease relative to the other nucleoproteins and protein-free DNA upon the addition of Mg2+ ions. Therefore, some structural elements of chromatin are apparently somewhat protected against the conformational change induced by these ions. The spectrum of chromatin becomes almost indistinguishable from that of H1-depleted chromatin in 0.2 mM MgCl2.(ABSTRACT TRUNCATED AT 250 WORDS)

Eukaryotic genome: model considerations

The paper presents a new model of chromosome structure based on the assumption that multiple circular subunits of DNA exist. The essential difference with previously described models is the circular DNA unit forms a central chromosome axis. Chromosome configurations during various phases of the cell cycle depend on the various conformations of this central integrating unit. The described model can be generalized for all haploid set of eukaryotic nucleus. Some aspects of the chromosome structure and their functions have been discussed.

Nucleomeric organization of chromatin

In the nuclei fixed in situ, as well as in nuclei in low-ionic-strength solutions containing magnesium ions, chromatin is represented by globular nucleomeric fibrils 20-25 nm in diameter. Staphylococcal or endogenous nucleases cleave chromatin fibrils to nucleomers and multinucleomers. On removal of firmly bound magnesium, the nucleomers unfold into chains of four, six or eight nucleosomes. Mild staphylococcal nuclease digestion of nuclear chromatin releases mononucleomers, dinucleomers and trinucleomers that sediment in the sucrose density gradient in the presence of EDTA as 37-S, 47-S and 55-S particles, respectively. The mononucleomers in the sucrose density gradient with MgCl2 sediment as 45-S particles. The determination of the length of staphylococcal-nuclease-digested DNAs contained in the chromatin fragments showed that a nucleomer is composed of 8, and a dimer and trimer of 14-16 and 21-24 nucleosomes, respectively. When deprived of Mg2+ ions, the monomers lose their compactness (45 S) and become loose particles (37 S). This transition is completely reversible if nucleomers contain histone H1. Removal of this histone or dialysis of the nucleomer against EDTA at low ionic strength results in the complete unfolding of the nucleomer into a chain of nucleosomes. A structural model of a nucleomer fibril is suggested where the helicity of the nucleosome chain in a nucleomer (two turns of four nucleosomes each) is periodically discontinued. Such an organization of chromatin apparently provides additional hindrances for site-specific recognition of DNA in chromatin but permits local changes (within a single nucleomer) in chromatin when a hindrance is abolished.

Ultrastructural organization of yeast chromatin

The ultrastructural organization of yeast chromatin was examined in Miller spread preparations of samples prepared from spheroplasts or isolated nuclei of Saccharomyces cerevisiae. Micrographs from preparations dispersed in 1 mM Tris (pH 7.2) illustrate that the basic chromatin fiber in yeast exists in two ultrastructurally distinct conformations. The majority (up to 95%) of the chromatin displays a beaded nucleosomal organization, although adjacent nucleosomes are separated by internucleosomal linkers of variable lengths. Ribonucleoprotein (RNP) fibrils are only occasionally associated with chromatin displaying the conformation. The remaining 5-10% of the chromatin appears to be devoid of discrete nucleosomes and has a smooth contour with a fiber diameter of 30-40 A. Transcriptional units, including putative ribosomal precursor RNA genes, defined by the presence of nascent RNP fibrils are restricted to chromatin displaying this smooth morphology. Chromatin released from nuclei in the presence of 5 mM Mg++ displays higher-order chromatin fibers, 200-300 A in diameter, these fibers appear to be arranged in a manner than reflects the two forms of the basic chromatin fiber.

Observations on the structure of mechanically stretched chromatin fibrils

During the spreading of human chromosomes prepared from cultured human lymphocytes, the peripheral fibers attaching the chromosome to the support film are mechanically stretched. The stretching reveals structural elements of the fibers; some of these features have been described earlier, for extracted chromatin. The molecule of DNA is bared through stretching and binds labeled actinomycin D in consequence. One of the prominent features of stretched fibers is the irregularity of resulting structures. This paper further demonstrates the excellent resolution obtainable by electron impact evaporation of tungsten.

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.

Visualization of nucleosomes in thin sections by stereo electron microscopy

Nucleosomes (approximately diameter) were clearly visualized in thin sections (approximately 0.1 micrometer thick) of isolated chicken erythrocytes. The cells were lysed and fixed in low ionic strength buffers that maintained the chromatin as dispersed filaments and prevented the reformation of supranucleosomal structures. Stereo electron micrographs at high magnification demonstrate the stability of nucleosome structure in the dispersed chromatin state during fixation, dehydration, and embedding.

Aggregation of small oligonucleosomal chains into 300-A globular particles

Chicken erythrocyte oligonucleosomes (trimers to about 20-mers) are able to interact with each other through the very lysine-rich histones (H1 and H5) and form heterogeneous globular particles with a mean diameter of about 300 A. These particles assemble spontaneously during micrococcal nuclease digestion of chromatin in the presence of 30 mM NaCl and contain approximately 25 nucleosomes. They are sensitive to ionic strength and unfold at lower salt concentrations but can be reconstituted by restoring the initial salt concentration. Even at 30 mM NaCl, the particles remain dynamic structures, being in equilibrium with their oligonucleosomal components as revealed by the fact that particle stability depends on the concentration of oligonucleosomes.

Upon the observation of superbeads in chromatin

There exist some indications that nucleases recognize "superbeads" in chromatin. We show that a chromatin extract of rat liver which contains so-called "superbead"-peaks can be separated in a Mg++ soluble and a Mg++ insoluble fraction. The Mg++ insoluble fraction contains the full complement of histones and the expected DNA fragments, but has lost the characteristic peaks in sucrosegradient profiles. These discrete peaks are found in the Mg2+ soluble fraction of the chromatin extract. We give evidence that these peaks are RNP particles on the basis of their protein- and nucleic acid contents.

A repeating unit of higher order chromatin structure in chick red blood cell nuclei

The organization of nucleosomes in higher order chromatin structures has been studied by electron microscopy of chick red blood cell nuclei. Chromatin appears as a thick fiber with an average diameter of approximately 300 A when prepared for electron microscopy in buffers which approximate physiological ionic strength. Progressive steps of disassembly of the thick fiber into individual nucleosomes could be induced either by ionic strength reduction or by tRNA treatment (which removes histone H1 and some non-histone chromosomal proteins). When disassembly was induced by ionic strength reduction in the presence of Mg++ (or Ca++), the lengths of the intermediate disassembly products were found to be multiples of 330 A. The diameter of these structures was estimated to be 275 A. This intermediate in the disassembly process is not observed if thick fiber disassembly is induced by ionic strength reduction in the absence of divalent cations. To investigate whether the higher order structural unit is present in the thick fiber at physiological ionic strengths, tRNA treatment was used to induce thick fiber disassembly under physiological monovalent ionic conditions. In this case, either with or without divalent cations, a supranucleosomal unit was found with dimensions similar to those given above. This data provides evidence for a slightly oblong supranucleosomal structure (330 x 275 A) whick forms a repeating unit in the chromatin thick fiber.

Repeating oligonucleosomal units. A new element of chromatin structure

Supranucleosomal chromatin structure has been analysed by the use of histone H1 polymers crosslinked in nuclei and extended chromatin with bifunctional reagents methyl-4-mercaptobutyrimidate (MMB) and dimethyl suberimidate dihydrochloride. Almost pure H1 homopolymers were obtained in milligram amounts and examined for the distribution in molecular weights. The H1 homopolymer molecules both from nuclei and chromatin have been found to be integer multiples of an elementary structure (called "clisone") consisting of 12 histone H1 molecules. This finding strongly suggests that nucleosomal chains of chromatin are not uniform but rather organized as repeating oligonucleosomal units each consisting of 12 nucleosomes. Correlation between oligonucleosomal structures in nuclei and chromatin implies that a linearized nucleosomal chain retains the information on chromatin superstructure. The relation of the disclosed 12-nucleosome units to superbeads (nucleomeres) and other structures is discussed.

Chromatin freeze fracture electron microscopy: a comparative study of core particles, chromatin, metaphase chromosomes, and nuclei

Chromatin gels, metaphase chromosomes, and intact nuclei were studied by freeze fracturing followed by electron microscopy. The results complement and extend those obtained by classical electron microscopy techniques as they are obtained without fixation or dehydration. The freeze fracturing technique permits a determination of the hydrated diameters of nucleosomes in chromatin and in nuclei to be 13 nm by comparing to simultaneously studied test objects. Nucleosomes in chromatin fibers are closely spaced but are discrete particles in all conditions studied. In the presence of divalent ions, most chromatin in solution, chromosomes, and nuclei is organized into fibers whose thickness is larger than 40 nm. The images are not at all compatible with a super bead organization of the nucleofilament. Freeze fractures of intact nuclei provides information on the distribution of chromatin in a hydrated unfixed state. The images suggest that most of the chromatin is localized in large domains in contact with the inner nuclear membrane.

Native and reconstituted chromosome fiber fragments

The structure of hen erythrocyte chromatin fibers was studied with the electron microscope. Chromatin fiber fragments with a length of about 5,000 A and an average diameter of 320 A are composed of 13 globular subunits (superbeads) which contain different numbers of nucleosomes. Their number average corresponds to 17 nucleosomes. - The interaction of lysine-rich histones with nucleosome chains was investigated by reconstitution experiments and was found to be semi-cooperative.

Mitosis in milk secreting epithelial cells of mammary gland: an ultrastructural study

In all stages of lactation mitotic configurations were observed in mammary gland epithelial cells of rats. An electron microscopic study is presented which shows that ultrastructure of such mitotic stages is normal and that mitotic cells contain typical products of milk secreting cells such as casein micelle-containing vesicles and milk fat droplets. Such secretory products can even be observed in the immediate vicinity of the chromosomes and microtubules of the spindle apparatus. The endoplasmic reticulum of mitotic cells appeared altered in that it did not show typical cisternal stacks characteristic of interphase cells. While the numbers of such mitotic cells were very low, especially from the second week of lactation on (always less than 0.1% of the milk secreting epithelial cells encountered), the observations clearly demonstrate that differentiation for milk secretory activity and cells division are not mutually exclusive. We conclude that postpartum growth of mammary gland epithelium and replacement of epithelial cells lost during desquamation into the milk liquids can occur by division of existing differentiated milk secreting cells and does not require mitotic activity of non-lactating 'stem cells' which are not observed in lactating alveoli.

Higher order structure of simian virus 40 chromatin

Simian virus 40 nucleoprotein complexes undergo an ionic strength-dependent structural transition. At moderate ionic strength they contain histone H1 as well as the nucleosomal histones and have a compact conformation with globular subunits 190 angstroms in diameter. At high ionic strength histone H1 is released, and the structure unfolds into chains with an average of 24 nucleosomes. The extended viral chromatin converts to the compact form by the addition of histone H1. Transcriptionally active simian virus 40 chromatin undergoes the same structural transitions. The higher order structure of viral chromatin may be analogous to the compact state of cellular chromatin fibers observed at physiological ionic strength.

The effect of various conditions of chromatin isolation on the nucleosomal structure of the isolated chromatin

Chromatin from calf thymus isolated under hypotonic conditions in the presence of various agents was investigated by methods of electron microscopy prior to and after EDTA treatment. It is shown that the presence of chelating agents and, especially, the application of considerable mechanical forces in the course of isolation may cause damage to the nucleosomal structure of the chromatin. Moreover, sufficiently great mechanical forces are liable to destroy the structure of the chromatin nucleosomal fibres even when they are packed in structures of a higher order of organization of the chromatin.

Subunit structure of Eutherian sperm chromatin

The beta-mercaptoethanol induced decondensation of spermatozoon cell nuclei from several Eutherian species has been followed from the intact spermatazoon cell to the solubilized linear unit sperm chromosomal fiber using fluorescence and electron microscopy. Data from nuclease digestion studies in conjunction with electron microscopic evidence indicate that the gross structure of the unit Eutherian sperm chromosomal fiber consists of DNA folded around sperm specific histone multimers spaced regularly along the fiber generating a linear array of sperm nucleosomes connected by short stretches of uncomplexed DNA. The sperm nucleosomes, 80 A in diameter are separated by 20 A filaments of DNA. This structure is remarkably similar to the structure of somatic chromatin although the protein components of the two chromosomes are markedly different. It seems likely that chromosomal fibers, similar to those described herein, may be present in the male pronucleus following fertilization.

Structural transition in chromatin induced by ions in solution

Structural transition in chromatin was measured as a function of counter ions in solution (NaCl or MgCl(2)) and of histones bound on the DNA. The addition of counter ions to aqueous solutions of chromatin, partially dehistonized chromatin, and DNA caused a drastic reduction in viscosity and a significant increase in sedimentation coefficient. Transitions occurred primarily at about 2 x 10(-3) M NaCl and 1 x 10(-5) M MgCl(2) and are interpreted as a change in structure of chromatin induced by tight binding of cations (Na(+) or Mg(++)) to DNA, either free or bound by histones, and is an intrinsic property of DNA rather than of the type of histone bound. At a given ionic condition, removal of histone H1 from chromatin had only a minor effect on the hydrodynamic properties of chromatin while removal of other histones caused a drastic change in these properties. An increase in the sedimentation coefficient of DNA was observed also for protamine. DNA complexes wherein the bound protein contains only unordered coil rather than the alpha-helices found in histones.

Influence of histone H1 on chromatin structure

Removal of histone H1 produces a transition in the structure of chromatin fibers as observed by electron microscopy. Chromatin containing all histone proteins appears as fibers with a diameter of about 250 A. The nucleosomes within these fibers are closely packed. If histone H1 is selectively removed with 50-100 mM NaCl in 50 mM sodium phosphate buffer (pH 7.0) in the presence of the ion-exchange resin AG 50 W - X2, chromatin appears as "beads-on-a-string" with the nucleosomes separated from each other by distances of about 150-200 A. If chromatin is treated in the presence of the resin with NaCl at concentrations of 650 mM or more, the structural organization of the chromatin is decreased, yielding fibers of irregular appearance.

The chromosome fiber: evidence for an ordered superstructure of nucleosomes

Chromosome fibers isolated from lymphocyte nuclei and prepared for electron microscopy by techniques designed to preserve their native structure have a distinctly knobby appearance, suggesting that DNA and protein are not distributed evenly along the fiber axis. Individual knobs (superbeads) are arranged in tandem and have an average diameter of about 200 A. Mild nuclease digestion of isolated nuclei releases apparent monomer superbeads that are composed of nucleohistone particles with the properties of nucleosomes. The kinetics of digestion indicate that the superbead is a discrete structural unit containing, on the average, about eight nucleosomes.