Assembly of oligonucleosomes into a limit series of multimeric higher-order chromatin structures

Chicken erythrocyte chromatin, obtained after fragmentation with micrococcal nuclease, appears to remain folded in a stable distribution of supranucleosomal structures in buffers containing 80 mM NaCl. These supranucleosomal particles are composed of on average 25 nucleosomes. However, the integrity of the linker DNA within these particles is not required. The supranucleosomal particles have been interpreted by others as superbeads cut out of a preexisting granular nominal 30-nm chromatin fibre. We show that the same distribution of supranucleosomal structures (even those containing internal DNA scissions) can be reconstituted from unfolded nuclear chromatin extracts as present in 10 mM or 600 mM NaCl. Moreover, fractions of oligonucleosomes with mean lengths between 6 and 15 nucleosomes reassemble or aggregate into a limit series of multimeric species. The existence of an assembly barrier could be inferred as we were unable to observe a stable and soluble assembly product containing more than about 25 nucleosomes. We propose an alternative explanation for the generation and observation of a constant distribution of supranucleosomal structures in nuclear extracts, based on the assembly or aggregation property of oligonucleosomes and on the existence of an assembly barrier.     

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 Å 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 Å. The diameter of these structures was estimated to be 275 Å. 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 × 275 Å) which forms a repeating unit in the chromatin thick fiber.     

Periodicity of DNA folding in higher order chromatin structures.

Each level of DNA folding in cells corresponds to a distinct chromatin structure. The basic chromatin units, nucleosomes, are arranged into solenoids which form chromatin loops. To characterize better the loop organization of chromatin we have assumed that the accessibility of DNA inside these structures is lower than on the outside and examined the size distribution of high mol. wt DNA fragments obtained from cells and isolated nuclei after digestion with endogenous nuclease or topoisomerase II. The largest discrete fragments obtained contain 300 kbp of DNA. Their further degradation proceeds through another discrete size step of 50 kbp. This suggests that chromatin loops contain approximately 50 kbp of DNA and that they are grouped into hexameric rosettes at the next higher level of chromatin structure. Based upon these observations a model by which the 30 nm chromatin fibre can be folded up into compact metaphase chromosomes is also described.     

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.     

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.     

The role of H2B histones from the sea urchin sperm in the formation of supranucleosome structures

The structural role of histone H2B from sea urchin sperm (H2Bsp) has been examined in experiments on reconstitution of chromatin from DNA and core histones taken in three variants: (1) four core histones from sea urchin sperm; (2) four core histones from calf thymus; (3) (H3, H4, H2A) from calf thymus and H2Bsp. It is shown that H2Bsp when present in reconstituted chromatin induces its aggregation. Fidelity of the reconstitution of nucleosomes has been tested using DNase I probe, one- and two-dimensional electrophoresis and electron microscopy. The reconstitutes that contain H2Bsp appear under electron microscope mainly as regular closely spaced large granules, about 450 A in diameter, which are very similar to the granules found in "native" sea urchin sperm chromatin. The reconstitutes formed by four core histones from calf thymus appear as randomly arranged particles, about 100 A in diameter. We conclude that histone H2Bsp participates in interactions between nucleosomes and is involved in the formation of the condensed supranucleosomal structure in sea urchin sperm chromatin.     

Chromatin-Like Structures in Polyoma Virus and Simian Virus 40 Lytic Cycle

Nucleoprotein complexes containing viral DNA and cellular histones were extracted from nuclei of permissive cells infected with polyoma virus or simian virus 40 (SV40) and examined by electron microscopy. Polyoma and SV40 nucleoprotein complexes are almost identical. They appear as relaxed circular molecules consisting of 20 to 21 globular particles interconnected by thin filaments. Their contour length in 0.02 M salt is 2.7 times shorter than that of viral DNA form I obtained after dissociation of the proteins in 1 M NaCl. The nucleosomes have an average diameter of 12.5 nm. Each nucleosome contains 175 to 205 DNA base pairs condensed fivefold in length. The nucleosomes are regularly spaced on the circular molecule. The internucleosomal filaments are made of naked DNA, and each filament contains about 55 base pairs. The partial sensitivity of the nucleoprotein complex to cleavage by EcoR1 endonuclease suggests that the nucleosomes are not formed at specific sites on the viral genome. Faster sedimenting nucleoprotein complexes containing replicative intermediates were studied. Isopycnic centrifugation in metrizamide gradients in the absence of aldehyde fixation showed that these molecules conserved the same DNA-to-protein ratio as the form I DNA-containing complexes.     

Higher order chromatin structure determines double-nucleosome periodicity of DNA fragmentation

Double-nucleosome periodicity of DNA fragmentation with DNAse I in the nuclei of cells differing in size of the linker DNA length and lysine-rich histone composition was analyzed by means of nondenaturing agarose gel electrophoresis. DNAse I revealed this type of periodicity in rat thymus and CHO cell nuclei as well as in erythrocyte nuclei. It has been deduced that the so-called nucleodisome structure is also typical of cells possessing a usual DNA repeat length (200 bp or less) and lysine-rich histone H1. Two probably related events are important for establishing a clear double-nucleosome periodicity of DNA fragmentation: the replacement of H1 histone by a specific arginine-rich histone fraction (H5 histone in the case of erythrocyte) and the increase of the linker DNA length. The results are interpreted in terms of supranucleosomal organization of chromatin which may determine the dinucleosome periodicity of DNA fragmentation due to a specific packing of nucleosomes.     

Histone H1 compacts DNA under force and during chromatin assembly

Histone H1 binds to linker DNA between nucleosomes, but the dynamics and biological ramifications of this interaction remain poorly understood. We performed single-molecule experiments using magnetic tweezers to determine the effects of H1 on naked DNA in buffer or during chromatin assembly in Xenopus egg extracts. In buffer, nanomolar concentrations of H1 induce bending and looping of naked DNA at stretching forces below 0.6 pN, effects that can be reversed with 2.7-pN force or in 200 mM monovalent salt concentrations. Consecutive tens-of-nanometer bending events suggest that H1 binds to naked DNA in buffer at high stoichiometries. In egg extracts, single DNA molecules assemble into nucleosomes and undergo rapid compaction. Histone H1 at endogenous physiological concentrations increases the DNA compaction rate during chromatin assembly under 2-pN force and decreases it during disassembly under 5-pN force. In egg cytoplasm, histone H1 protects sperm nuclei undergoing genome-wide decondensation and chromatin assembly from becoming abnormally stretched or fragmented due to astral microtubule pulling forces. These results reveal functional ramifications of H1 binding to DNA at the single-molecule level and suggest an important physiological role for H1 in compacting DNA under force and during chromatin assembly.     

Assembly of newly replicated chromatin.

Mild staphylococcal nuclease digestions under isotonic conditions release fragments of a 200 Å diameter fiber from nuclei of Drosophila melanogaster tissue culture cells. These soluble fragments have high sedimentation coefficients (30–100S) and show tightly packed nucleosomes in the electron microscope. Under the same conditions, newly replicated chromatin is released as more slowly sedimenting fragments (14S). Within 20 min after DNA replication, the nascent chromatin gradually matures into compact supranucleosomal structures which are indistinguishable from bulk chromatin on the isokinetic sucrose gradients.We have used this fractionation technique to examine the question of the fate and assembly of the new histones. After short pulses with either ³⁵S-methionine or ³H-lysine, the radioactive histones do not co-sediment with the bulk chromatin but appear instead in the fractions where the newly replicated DNA is found. Furthermore, the various nascent histones appear in different fractions on the gradient: histones H3 and H4 in 10–15S structures, histones H2A and H2B in 15–50S structures and histone H1 in 30–100S structures. These results, together with the analysis of pulse and pulse-chase experiments of both nascent DNA and histones, strongly suggest that histones H3 and H4 are deposited first on the nascent DNA (during or slightly after the DNA is replicated), histones H2A and H2B are deposited next (2–10 min later) and histone H1 is deposited last (10–20 min after DNA replication). A high turnover 20,000 dalton protein is also associated with the newly replicated chromatin.     

Selective association between nucleosomes with identical DNA sequences

Self-assembly is the autonomous organization of constituents into higher order structures or assemblages and is a fundamental mechanism in biological systems. There has been an unfounded idea that self-assembly may be used in the sensing and pairing of homologous chromosomes or chromatin, including meiotic chromosome pairing, polytene chromosome formation in Diptera and transvection. Recent studies proved that double-stranded DNA molecules have a sequence-sensing property and can self-assemble, which may play a role in the above phenomena. However, to explain these processes in terms of self-assembly, it first must be proved that nucleosomes retain a DNA sequence-sensing property and can self-assemble. Here, using atomic force microscopy (AFM)-based analyses and a quantitative interaction assay, we show that nucleosomes with identical DNA sequences preferentially associate with each other in the presence of Mg²⁺ ions. Using Xenopus borealis 5S rDNA nucleosome-positioning sequence and 601 and 603 sequences, homomeric or heteromeric octa- or tetranucleosomes were reconstituted in vitro and induced to form weak intracondensates by MgCl₂. AFM clearly showed that DNA sequence-based selective association occurs between nucleosomes with identical DNA sequences. Selective association was also detected between mononucleosomes. We propose that nucleosome self-assembly and DNA self-assembly constitute the mechanism underlying sensing and pairing of homologous chromosomes or chromatin.