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.     

H3 phosphorylation-dependent structural changes in chromatin. Implications for the role of very lysine-rich histones

Contrary to native H1/H5-containing chromatin where phosphorylation induces local structural changes affecting chromatin condensation, in stripped fibers phosphorylation of the totality of H3 molecules does not affect significantly chromatin conformation and DNA-protein interactions. Modification of H3 causes only a slight increase of flexibility of nucleosomal chains, despite important changes in histone topography revealed by immunochemical reactivity studies. We suggest that phosphorylation may only induce into the system the potential for dynamic change by modulating histone-histone interactions within and between nucleosomes, probably as a result of conformational change in the H3 protein. The signal for structural change would come from one or other factors (very lysine-rich histones, non-histones) that influence internucleosomal interactions at very specific locations in the chromatin, probably through protein-protein contacts. So, phosphorylation may modify a direct interaction between the N-terminal basic tail of H3 and very lysine-rich histones.     

Yeast high mobility group protein HMO1 stabilizes chromatin and is evicted during repair of DNA double strand breaks

DNA is packaged into condensed chromatin fibers by association with histones and architectural proteins such as high mobility group (HMGB) proteins. However, this DNA packaging reduces accessibility of enzymes that act on DNA, such as proteins that process DNA after double strand breaks (DSBs). Chromatin remodeling overcomes this barrier. We show here that the Saccharomyces cerevisiae HMGB protein HMO1 stabilizes chromatin as evidenced by faster chromatin remodeling in its absence. HMO1 was evicted along with core histones during repair of DSBs, and chromatin remodeling events such as histone H2A phosphorylation and H3 eviction were faster in absence of HMO1. The facilitated chromatin remodeling in turn correlated with more efficient DNA resection and recruitment of repair proteins; for example, inward translocation of the DNA-end-binding protein Ku was faster in absence of HMO1. This chromatin stabilization requires the lysine-rich C-terminal extension of HMO1 as truncation of the HMO1 C-terminal tail phenocopies hmo1 deletion. Since this is reminiscent of the need for the basic C-terminal domain of mammalian histone H1 in chromatin compaction, we speculate that HMO1 promotes chromatin stability by DNA bending and compaction imposed by its lysine-rich domain and that it must be evicted along with core histones for efficient DSB repair.     

Analysis of chromatin reconstitutiion.

The ability of high molecular weight chicken erythrocyte chromatin to spontaneously self-assemble into native-like material, after dissociation by high ionic strength and reassociation by salt gradient dialysis, was critically examined. The native conformational state of the reassembled nucleoprotein complex was regenerated to the extent reflected by circular dichroism spectra and thermally induced helix--coil transition of the nucleoprotein DNA. However, internucleosomal packing of approximately 205 base pairs of DNA per repeating unit, as probed by digestion with micrococcal nuclease, was not regenerated upon reassembly and was replaced by a packing of approximately 160 base pairs per repeating unit. Thus, high molecular weight chromatin containing only lysine-rich histones (H1 and H5) and core histones (H2A, H2B, H3, and H4) is not a true self-assembling system in vitro using the salt gradient dialysis system used herein. Circular dichroism and thermal denaturation studies on core chromatin (lysine-rich histones removed) showed that core histones alone are not capable of reassembling high molecular weight DNA into native-like core particles at low temperature (4 degree C). Reassembly at 21 degree C restored the circular dichroism but not the thermal denaturation properties to those characteristic of undissociated core chromatin. Nonetheless, micrococcal nuclease digestions of both reassembled core chromatin products were identical with undissociated native core chromatin. Ressembly in the presence of the complete complement of histones, followed by removal of the lysine-rich histones, did regenerate the thermal denaturation properties of undissociated native core particles. These results indicated multiple functions of the lysine-rich histones in the in vitro assembly of high molecular weight chromatin.     

Evidence of altered histone interactions, as investigated by removal of histones, in chromatin isolated from rat liver nuclei by a conventional method.

It is shown that the release of the slightly lysine-rich histones f2a2 and f2b by 0.4 M ammonium sulfate from conventionally isolated chromatin is diminished in comparison to the lysed nuclei. The change in extractability is further demonstrated by the application of ethidium bromide. At a molar input ratio of 0.09 (moles ethidium bromide/moles nucleotide) and 0.4 M ammonium sulfate the slightly lysine-rich histones are released from the chromatin to 70 - 80% if the lysed nuclei are used. At 0.1 M ammonium sulfate ethidium bromide effected also a release of 50 % of histone f1. Comparable effects could not be observed with chromatin prepared in a conventional way but instead a tendency towards loss of histone f3 in the presence of ethidium bromide was observed.     

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 Å and an average diameter of 320 Å 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.     

Duplicated nucleosome repeat generated in the erythrocyte chromatin by DNAse I. The role of lysine-rich histones

Dinucleosome periodicity of DNA fragmentation produced by DNAse I in nuclei of pigeon and trout erythrocytes differing in the content of histones H1 and H5 has been investigated. In spite of differences in the content of histone H5 (H1 to H5 ratio is approximately equal to 0.5 and 2 in pigeon and trout erythrocytes respectively) the double-nucleosome repeat was revealed clearly in pigeon and trout erythrocyte nuclei. To elucidate the role of lysine-rich histones we carried out the selective extraction of histone H1 from erythrocyte nuclei by a solution containing 0.3-0.35 M NaCl (pH 3.0) or cleavage of histones H1 and H5 by mild trypsinization in the presence of Mg2+ ions. It was shown that lysine-rich histones play a principal role in formation and maintenance of the so-called dinucleosomal chromatin structure.     

Effect of extraction of histones and their reconstitution on [3H] actinomycin D binding to isolated nuclei of the root of Pinus silvestris.

The purpose of the study presented was to investigate the effect of the extraction of histones on the template activity of DNA, measured by the autoradiographically evaluated intensity of [3H]actinomycin D ([3H]AMD) binding. The study was carried out on nuclei isolated from the root meristem of Pinus silvestris. Histones were removed selectively from them and reconstituted in the nuclei deprived of these proteins. The greatest rise in radioactivity was found after the extraction of the arginine fraction and that of lysine-rich and moderately lysine-rich fractions removed together, whereas the extraction of the lysine-rich fraction does not cause such a considerable increase in radioactivity. The reconstitution of particular histone fractions induced a fall in radioactivity to the level of controls in all the cases examined. No [3H]AMD binding to the nucleolus was found. The extraction of lysine histones results in the decondensation of chromatin and their reconstitution in the formation of complexes of compact chromatin.     

DNA-protein binding in interphase chromosomes

The metachromatic dye, azure B, was analyzed by microspectrophotometry when bound to DNA fibers and DNA in nuclei with condensed and dispersed chromatin. The interaction of DNA and protein was inferred from the amount of metachromasy (increased β/α-peak) of azure B that resulted after specific removal of various protein fractions. Dye bound to DNA-histone fibers and frog liver nuclei fixed by freeze-methanol substitution shows orthochromatic, blue-green staining under specific staining conditions, while metachromasy (blue or purple color) results from staining DNA fibers without histone or tissue nuclei after protein removal. The dispersed chromatin of hepatocytes was compared to the condensed chromatin of erythrocytes to see whether there were differences in DNA-protein binding in "active" and "inactive" nuclei. Extraction of histones with 0.02 N HCl, acidified alcohol, perchloric acid, and trypsin digestion all resulted in increased dye binding. The amount of metachromasy varied, however; removal of "lysine-rich" histone (extractable with 0.02 N HCl) caused a blue color, and a purplish-red color (µ-peak absorption) resulted from prolonged trypsin digestion. In all cases, the condensed and the dispersed chromatin behaved in the same way, indicating the similarity of protein bound to DNA in condensed and dispersed chromatin. The results appear to indicate that "lysine-rich" histone is bound to adjacent anionic sites of a DNA molecule and that nonhistone protein is located between adjacent DNA molecules in both condensed and dispersed chromatin.     

Generation of a third-order folded structure for chromatin

A model for the initiation of the diffuse-condensed transition of chromatin induced by a change in the conformation of lysine-rich histones is proposed. Three levels of folded structures are discussed. The first-order folded structure refers to the structure of the repeat unit of chromatin, which is called the nucleosome. The nucleosome contains a nuclease resistant region in which 140 base pairs of DNA are wrapped around the surface of a histone aggregated of two copies each of the histones H2A, H2B, H3 and H4. This DNA-histone aggregate is called a core particle. The nuclease accessible region of the nucleosome is approximately 60 base pairs of DNA which link the core particle, hence the terminology “linker DNA.” The lysine-rich histones, (Hl, H5), which are more loosely bound than the core histones, are associated with the linker DNA. The second-order folded structure refers to the conformation of a polynucleosome. Based on neutron scattering and quasielastic light scattering studies the second-order folded structure is assumed to be an extended helix in solution with 5–7 nucleosome units per turn. The third-order folded structure is defined as that structure resulting from the first stage in the condensation process induced by a conformational change in the lysine-rich histones. Generation of the third-order folded structure in the proposed model is effected by an increased affinity of the lysine-rich histones for super-helical DNA in the core particles in adjacent turns of the second-order folded structure. Since the lysine-rich histones preferentially bind to A-T rich regions in DNA, the distribution of these regions would determine the third-order folded structure. The net effect of a non-random distribution of A-T rich regions as in the proposed model is the generation of a helix for the third-order folded structure. The assumption of a non-random distribution of A-T rich regions is indirectly supported by proflavine binding studies reported herein and by the existence of repetitive and non-repetitive DNA regions inferred from renaturation studies. One consequence of the proposed mechanism is that the majority of the A-T rich regions are in the interior of the third-order folded structure. Promoter sites of high A-T content would then be inaccessible to polymerases. The proposed model also suggests a role for spacer DNA in the genome. Higher order folded structures must also be present in the final state of condensed chromatin since the three orders of folded structures considered in this communication accounts for only 2% of that required in the diffuse-condensed transition.     

HISTONES OF GENETICALLY ACTIVE AND INACTIVE CHROMATIN

It has frequently been proposed that a variation in the relative content of lysine-rich, moderately lysine-rich, and arginine-rich histones might provide a mechanism by which specific portions of the genome may be genetically regulated. This possibility was investigated by comparing the electrophoretic pattern of these three fractions in cells differing markedly in their content of genetically active and genetically inactive chromatin. Three models were used: heterochromatin versus euchromatin; metaphase cells versus interphase cells, and mature lymphocytes versus phytohemagglutinin-stimulated lymphocytes. In no case was there a significant difference in the histone patterns of these contrasting models. It is concluded that, although histones may act as a generalized repressor and structural component of chromatin, factors other than a variation in histone pattern may be responsible for repression or derepression of specific segments of the genome.     

Histones from nucleated erythrocytes of the marine invertebrate Sipunculus nudus

Total and lysine-rich histones were extracted from purified sipunculid erythrocyte nuclei with 0.25 N HCl and 0.74 N perchloric acid, respectively. The histones were fractionated and purified by gel filtration and ion exchange chromatography. Sipunculid PCA extract shows three lysine-rich histones, one of which may be a fraction specific to erythrocytes. The histones H₃ and H₄ of this marine invertebrate are very similar to their vertebrate homologues. Whereas no fraction H_2B has been detected in our investigation, the fraction H_2A has an unusual chromatographic behaviour if compared to its vertebrate homologue. These features may be the reflection of a peculiar distribution of histones in the chromatin of sipunculid erythrocytes.     

The basis of chromatin fiber assembly within chromosomes studied by histone-DNA crosslinking followed by trypsin digestion

To determine the structural basis of chromatin assembly that leads to chromosome formation in mitosis, crosslinks were introduced by formaldehyde between contiguous components within chromosomes. Crosslinked stable products were then observed by electronmicroscopy after non-cross-linked portions were briefly digested by trypsin to unfold chromosomes. — When the DNA-histone crosslink was the primary product, trypsin readily unfolded the whole chromosome structure while preserving the 250 Å unit chromatin fiber intact; only a single unit fiber was tracked within the centromere region connecting the arms of each chromatid. When a histone polymer was formed by a prolonged formaldehyde crosslinking, trypsin digestion gave rise to chromatin fibers interacting with others at certain distances, and the typical chromosome structure remained unchanged. Regardless of the degree of crosslinking, there were neither thick supercoiled unit fibers nor proteinaceous cores. — These results suggest that the fiber connection may represent, to some extent, the interacting sites of folded chromatin fibers in situ within chromosomes, and also that the 250 Å unit fibers are the sole, highest structural basis in chromosomes. Since virtually no appreciable histone digestion took place in the crosslinked chromosomes, the observation that even after DNA-histone crosslinking the fiber interacting sites were accessible to trypsin preferentially over other portions, may be consistent with our recent results that the exposed, lysine-rich tails of histones represent such interacting sites.     

Chromatin-associated proteins of the developing sea urchin embryo. II. Acid-soluble proteins

Of the five well-characterized histories, only the slightly lysine-rich histories F2a and F2b are present in sea urchin embryos before the 16-cell stage. At the 16-cell stage, the arginine-rich (F3) and lysine-rich (Fla) histones appear and all the major histones are then present in the same relative proportions until the pluteus stage except for a second lysine-rich protein, Flb, which is first detected at 12 to 16 hours of development and increases to the pluteus stage. From 16 cells to pluteus at 70 hours, all the histones are labeled by a 30-minute incubation with radioactive lysine, with the exception of the lysine-rich histone Fla which does not incorporate label after 20 to 30 hours of development and Fib which is labeled only after 20 to 30 hours. Fla is conserved, however, to the pluteus stage.The total acid-soluble protein content of chromatin remains constant to 22 hours of development. During the period of 22 to 45 hours, there is a slight loss of protein followed by a rapid loss from 45 to 70 hours such that at 70 hours only 20% remains.     

Modification of histone binding in calf thymus chromatin by protamine.

When calf thymus chromatin is incubated with protamine, the protein binds to DNA, forming a chromatin-protamine complex. The binding reaches a saturating level at the weight ratio of protamine to DNA of approximately 0.5. Although the saturated binding of protamine to DNA does not cause major displacement of histones from calf thymus chromatin, examination of the dissociation profiles by salt in combination with urea of protamine-treated chromatin shows that the histone-DNA interactions are markedly altered by such binding. The dissociation of histones from the chromatin-protamine complex requires less NaCl but the same concentration of urea as that for untreated chromatin, suggesting that the electorstatic interactions between the histones and DNA are decreased as a result of protamine binding. When protamine concentration is increased beyond that required for saturated binding to DNA during in vitro exposure of calf thymus chromatin to protamine, lysine-rich histone is completely displaced.     

Inhibition of mammary gland cyclic AMP-dependent protein kinase by arginine-rich histones.

The cyclic AMP-dependent protein kinase activity from lactating bovine mammary gland efficiently phosphorylates lysine-rich histones but not arginine-rich histones. It is shown that arginine-rich histones in fact inhibit phosphorylation of lysine-rich histones. Polyarginine and a range of low molecular weight cationic molecules are also inhibitors. Inhibition of histone H2b phosphorylation by histones H4 and H3 is competitive with respect to H2b. This inhibition behaviour may be tissue-specific since the protein kinase activity in crude extracts from lactating bovine mammary gland, although heterogeneous, may be completely inhibited (>95%) by arginine-rich histones and polyarginine.     

Order and disorder in 30 nm chromatin fibers.

The tendency of DNA to form fibers upon condensation with counterions is reviewed. It is shown that chromatin fibers may acquire a relatively constant diameter of about 30 nm simply as an optimal size achieved upon neutralization of DNA, without requiring a repetitive internal structure. Thus the size of chromatin fibers would not be determined by any specific spatial interaction between DNA and histones. The driving force for the formation of fibers in chromatin would be similar to that found in proteins when they acquire a compact globular shape.     

Ionic strength-dependent conformational transitions of chromatin. Circular dichroism and thermal denaturation studies

High-molecular-weight chicken erythrocyte chromatin was prepared by mild digestion of nuclei with micrococcal nuclease. Samples of chromatin containing both core (H3, H4, H2A, H2B) and lysine-rich (H1, H5) histone proteins (whole chromatin) or only core histone proteins (core chromatin) were examined by CD and thermal denaturation as a function of ionic strength between 0.75 and 7.0 × 10^?3M Na⁺. CD studies at 21°C revealed a conformational transition over this range of ionic strengths in core chromatin, which indicated a partial unfolding of a segment of the core particle DNA at the lowest ionic strength studied. This transition is prevented by the presence of the lysine-rich histones in whole chromatin. Thermal-denaturation profiles of both whole and core chromatins, recorded by hyperchromicity at 260 nm, reproducibly and systematically varied with the ionic strength of the medium. Both materials displayed three resolvable thermal transitions, which represented the total DNA hyperchromicity on denaturation. The fractions of the total DNA which melted in each of these transitions were extremely sensitive to ionic strength. These effects are considered to result from intra- and/or internucleosomal electrostatic repulsions in chromatin studied at very low ionic strengths. Comparison of the whole and core chromatin melting profiles indicated substantial stabilization of the core-particle DNA by binding sites between the H1/H5 histones and the 140-base-pair core particle.     

Chromatin structure as probed by nucleases and proteases: Evidence for the central role of hitones H3 and H4

We have examined the role played by each histone in forming the structure of the ν-body. When DNAase I, DNAase II, trypsin, and chymotrypsin attack chromatin, characteristic discrete DNA and protein digest fragments are produced. Using this restriction of accessibility as diagnostic for chromatin structure, we have examined complexes of DNA with virtually all possible combinations of histones. The results strongly support our previous conclusion (Camerini-Otero, Sollner-Webb, and Felsenfeld, 1976) that the arginine-rich histones are unique in their ability to create, with DNA, a structure with many features of native chromatin. Acting together, slightly lysine-rich histones then modify this complex into one very similar to native chromatin. An analysis of the rate constants of staphylococcal nuclease digestion also confirms that the complex of H3, H4, and DNA is crucial to the structure of the ν-body.