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.     

Effects of DNA and urea on the specificity for H1 histone of the neutral protease B partially-purified from rat liver chromatin

A neutral protease, named protease B in the previous report (Tsurugi, K. & Ogata, K. (1982) J. Biochem. 92, 1369-1381), was partially purified from rat liver chromatin by gel filtration through Sepharose 6B followed by DE-Sephadex column chromatography. The proteolytic activity on total histones of the partially-purified protease B was increased about two fold by addition of DNA and again increased by further addition of 2 M urea. Analysis of the hydrolysed products showed that out of five species of histones, only H1 was degraded in the presence of an amount of DNA equivalent to the amount of histones, whereas core histones were also degraded in the absence or presence of one-tenth amount of DNA. Urea accelerated the selective degradation of H1 histone because H1 histone was preferentially degraded in the presence of even a low amount of DNA. In contrast, core histones became resistant to the protease B in the presence of DNA and/or urea. Heat-denatured DNA stimulated the degradation of H1 histone even in the absence of urea to almost the same extent that native DNA did in the presence of urea. Thus, protease B efficiently degrades H1 histone when its association with DNA is destabilized by either addition of urea or pretreatment of DNA with heat.     

Folding of DNA by histones which lack their NH2-terminal regions

HeLa chromatin core particles were digested with trypsin to excise the NH2-terminal histone regions. The resulting nucleoprotein complexes were dissociated in 2.5 M NaCl; the DNA and polypeptides were then allowed to reassemble by lowering the NaCl concentration. Eighty per cent of the DNA reassociated with the polypeptides. The reassembled nucleoprotein complexes sediment at 9.7 S, have a molecular elipticity at 280 nm of 3000 degrees cm2/dmol of PO4, and contain DNase I-susceptible sites at 10 nucleotide intervals. The pattern of products generated by cross-linking the polypeptides with dimethylsuberimidate is very similar to the pattern generated by cross-linking native core particles. The results indicate that histones which lack their HN2-terminal regions retain both the features necessary for correct protein-protein interactions and the ability to fold DNA into a nucleoprotein complex resembling the chromatin core particle.     

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.     

Studies on histone oligomers. V. Reconstitution of chromatin from purified DNA and acid-extracted histones

DNA-histone complexes were reconstituted from DNA and acid-extracted core histones and the products were characterized by micrococcal nuclease digestion to examine whether proper nucleosome structure had been reconstituted. No nucleosome structure was produced starting from the mixture of acid-extracted histones and purified DNA in 2 M NaCl-5 M urea, while the reassociation of chromatin by the same procedures was successful. This was due to the inappropriate conformation of acid-extracted histones, which was preserved in 2 M NaCl even in the presence of 5 M urea. If acid-extracted histones were reannealed from the completely denatured state, such as in 5 M urea, 6 M guanidine hydrochloride or 0.6 M NaCl-5 M urea, reconstitution of nucleosome structure was always successful.     

Structure of nucleosomes and organization of internucleosomal DNA in chromatin

We have compared the mononucleosomal pattern produced by micrococcal nuclease digestion of condensed and unfolded chromatin and chromatin in nuclei from various sources with the repeat length varying from 165 to 240 base-pairs (bp). Upon digestion of isolated H1-containing chromatin of every tested type in a low ionic strength solution (unfolded chromatin), a standard series of mononucleosomes (MN) was formed: the core particle, MN145, and H1-containing, MN165, MN175, MN185, MN195, MN205 and MN215 (the indexes give an approximate length of the nucleosomal DNA that differs in these particles by an integral number of 10 bp). In addition to the pattern of unfolded chromatin, digestion of whole nuclei or condensed chromatin (high ionic strength of Ca2+) gave rise to nuclei-specific, H1-lacking MN155. Digestion of H1-lacking chromatin produced only MN145, MN155 and MN165 particles, indicating that the histone octamer can organize up to 165 bp of nucleosomal DNA. Although digestion of isolated sea urchin sperm chromatin (repeat length of about 240 bp) at a low ionic strength gave a typical "unfolded chromatin pattern", digests of spermal nuclei contained primarily MN145, MN155, MN235 and MN245 particles. A linear arrangement of histones along DNA (primary organization) of the core particle was found to be preserved in the mononucleosomes, with the spacer DNA length from 10 to 90 bp on one (in MN155) or both sides of core DNA being a multiple of about 10 bp. In MN235, the core particle occupies preferentially a central position with the length of the spacer DNA on both sides of the core DNA being usually about 30 + 60 or 40 + 50 bp. Histone H1 is localized at the ends of these particles, i.e. close to the centre of the spacer DNA. The finding that globular part of histones H3 and sea urchin sperm H2B can covalently bind to spacer DNA suggests their involvement in the organization of chromatin superstructure. Our data indicate that decondensation of chromatin is accompanied by rearrangement of histone H1 on the spacer DNA sites adjacent to the core particle and thus support a solenoid model for the chromatin superstructure in nuclei in which the core DNA together with the spacer DNA form a continuous superhelix.     

Mobile histone tails in nucleosomes. Assignments of mobile segments and investigations of their role in chromatin folding

The 13C NMR spectrum of isolated nucleosome core particles contains many sharp resonances, including resonances of alpha- and beta-carbons, indicating that certain terminal segments of histones rich in basic residues are highly mobile (Hilliard, R. R., Jr., Smith, R. M., and Rill, R. L. (1986) J. Biol. Chem. 261, 5992-5998). Specific histone termini can be removed sequentially from nucleosome core particles by mild treatment with alpha-chymotrypsin or chymotrypsin plus trypsin (Rosenberg, N. L., Smith. R. M., and Rill, R. L. (1986) J. Biol. Chem. 261, 12375-12383). Comparisons of the 13C NMR spectra of native and several partially proteolyzed core particles indicated that a minimum of residues 1-20 of H3 and 1-11 and 118-128 of H2a are contained in mobile segments of native cores. H4 did not appear to contribute to the resonances from mobile histone segments, but a possible contribution of H2b residues 1-16 could not be ruled out. The 13C NMR spectra of oligonucleosomes containing and lacking lysine-rich histones (H1, H5) were similar to each other and to that of native nucleosome cores both when the oligonucleosomes were in an extended conformation at low ionic strength and when they were in a more compact conformation at higher ionic strength. This similarity suggests that histones H1 and H5 must be largely immobilized upon chromatin binding and that the segments of core histones that are mobile in isolated nucleosome cores are not strongly bound to adjacent linker regions in intact chromatin, and are not immobilized by compaction to the degree achieved in 50 mM phosphate buffer.     

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.     

DNA wrapping in nucleosomes. The linking number problem re-examined.

Chromatin was assembled in vitro from relaxed closed circular DNA (SV40) and core histones at histone to DNA ratios of 0.2 to 0.3 (g/g) and incubated with topoisomerase I to relax supercoils in DNA regions not constrained by protein. Addition of histones H1 + H5 to the chromatin at an ionic strength of 0.1 M, in the presence of the solubilizing agent, polyglutamic acid, and topoisomerase I, increased the magnitude of the DNA linking number change, relative to protein-free DNA. No change in the linking number distribution occurred for relaxed protein-free DNA under these conditions. Control experiments indicated that the increase in the absolute value of the DNA linking number change in the chromatin could not be attributed to an increase in the number of nucleosomes per DNA molecule. These data suggest a solution to the linking number problem associated with models of chromatin structure.     

Isolation and characterization of the nuclear matrix in Friend erythroleukemia cells: chromatin and hnRNA interactions with the nuclear matrix.

Nuclear matrices from undifferentiated and differentiated Friend erythroleukemia cells have been obtained by a method which removes DNA in a physiological buffer. These matrices preserved the characteristic topographical distribution of condensed and diffuse "chromatin" regions, as do nuclei in situ or isolated nuclei. Histone H1 was released from the nuclear matrix of undifferentiated cells by 0.3 M KCl; inner core histones were released by 1 M KCl. Nuclear matrix from differentiated cells did not maintain H1, and histone cores were fully released in 0.7 M KCl. KCl removed the core histones as an octameric structure with no evidence of preferential release of any single histone. Electron microscopy of KCl-treated matrix revealed no condensed regions but rather a network of fibrils in the whole DNA-depleted nuclei. When nuclear matrices from both types of cell were exposed to conditions of very low ionic strength, inner core histones and condensed regions remained. These observations support the contention that inner core histones are bound to matrix through natural ionic bonds or saline-labile elements, and that these interactions are implicated in chromatin condensation. hnRNA remained undegraded and tenaciously associated to the matrix fibrils, and was released only by chemical means which, by breaking hydrophobic and hydrogen bonds, produced matrix lysis. Very few nonhistone proteins were released upon complete digestion of DNA from either type of nuclei. The remaining nonhistone proteins represent a large number of species of which the majority may be matrix components. The molecular architecture in both condensed and diffuse regions of interphase nuclei appears to be constructed of two distinct kinds of fibers; the thicker chromatin fibers are interwoven with the thinner matrix fibers. The latter are formed by a heteropolymer of many different proteins.     

Structural repeat units of Chinese hamster ovary chromatin. Evidence for variations in repeat unit DNA size in higher eukaryotes.

DNA lengths in the structural repeat units of Chinese hamster ovary (CHO) and chicken erythrocyte chromatin were compared by analyzing the sizes of DNA fragments produced after treatment of nuclei with staphylococcal nuclease. The repeat length of CHO chromatin (173 +- 4 BP) is about 20 base pairs (BP) smaller than that of chicken erythrocyte chromatin (194 +- 8 BP). Repeat lengths of rat liver and calf thymus chromatin were found to be about 10 BP shorter than that of chicken erythrocyte chromatin. Thus significant variations occur in repeat units of chromatin of higher eukaryotes. These variations occur in the lengths of "spacer" (or "internucleosomal") DNA segments, not in "core particle" (or "nucleosomal") DNA lengths. The concept of spacer regions and the possible influence of H1 histones is discussed.     

Role of individual histone tyrosines in the formation of the nucleosome complex.

We have determined the accessibility of histone tyrosine residues to react with p-nitrobenzenesulfonyl fluoride (NBSF) in intact nuclei, salt-dissociated nucleosomes, isolated histone complexes, and individual core histones. Of the 15 core histone tyrosine residues, 13 are inaccessible in native nucleosomes; only Tyr121 near the C-terminus of H2B is fully accessible, and Tyr54 of H3 is partially accessible under near-physiological conditions. When H1 and the basic N-terminal tails of the core histones are dissociated from the DNA by treating nuclei with 0.4 and 0.8 M NaCl, the two tyrosines which are adjacent to the basic regions of H2B and H3 become accessible as well. This indicates that these tyrosine residues may be involved in histone-DNA interactions, either directly or indirectly. When the H2A-H2B dimers are dissociated from the chromatin by raising the NaCl concentration to 1.2 M, three to four tyrosines located in the structured regions of H2B and H4 are exposed, suggesting that these tyrosine residues may be located at the dimer-tetramer interface. Dissociating all the histones from the DNA at an even higher ionic strength as a mixture of dimers, tetramers, and octamers does not change the pattern of Tyr exposure, but reduces the reactivity of the tyrosines at the dimer-tetramer interface as would be expected from the reassociation of H2A-H2B dimers and H3-H4 tetramers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Use of histone antibodies for studying chromatin topography and the phosphorylation of chromatin subunits

Polyclonal and monoclonal antibodies specific for histones as well as sera directed against synthetic peptides of histones were used to probe the topography of chromatin subunits. In native chromatin, the regions corresponding to residues 130-135 of H3 and 6-18 of H2B were found to be exposed and able to interact with antibodies whereas the regions 26-35 and 36-43 of H2B and 80-89 and 85-102 of H4 were not. In vitro phosphorylation of H3 and H5 in native chromatin or of H3 in H1/H5-depleted chromatin led to a marked drop in the binding of antibodies specific for residues 130-135 of H3 and 6-18 of H2B. Phosphorylation of H1/H5-depleted chromatin also altered the degree of exposure of certain H2A epitopes but it did not affect the surface accessibility of residues 1-11 of H2B.     

Histone H1 and chromatin interactions in human fibroblast nuclei after H1 depletion and reconstitution with H1 subfractions.

BACKGROUND: Linker histones constitute a family of lysine-rich proteins associated with nucleosome core particles and linker DNA in eukaryotic chromatin. In permeabilized cells, they can be extracted from nuclei by using salt concentration in the range of 0.3 to 0.7 M. Although other nuclear proteins are also extracted at 0.7 M salt, the remaining nucleus represents a template that is relatively intact. METHODS: A cytochemical method was used to study the affinity of reconstituted linker histones for chromatin in situ in cultured human fibroblasts. We also investigated their ability to condense chromatin by using DNA-specific osmium ammine staining for electron microscopy. RESULTS: Permeabilized and H1-depleted fibroblast nuclei were suitable for the study of linker histone-chromatin interactions after reconstitution with purified linker histone subfractions. Our results showed that exogenous linker histones bind to chromatin with lower affinity than the native ones. We detected no significant differences between the main H1 and H1 degrees histone fractions with respect to their affinity for chromatin or in their ability to condense chromatin. CONCLUSIONS: Linker histone interactions with chromatin are controlled also by mechanisms independent of linker histone subtype composition.     

Chromatin structure from the marine sponge Geodia cydonium

The histones isolated from the siliceous sponge Geodia cydonium have been separated using two electrophoretic techniques. A comparison of their mobilities with those of calf thymus and rat liver show that some Geodia histone species (H3, H1 and H1(0) exhibit electrophoretic variance. The results show, that as in other eukaryotic systems the sponge chromatin contains the core histones (H2A, H2B, H3 and H4) and the linker histone (H1). ADP-ribosylation of Geodia histones and separation of the individual histones by electrophoresis resulted in four histones being radiolabeled. Digestion of Geodia chromatin with endogenous endonuclease is shown to result in the formation of nucleosome particles containing approximately 200 base pairs of DNA. A major product of endogenous endonuclease digestion is a relatively stable 110 base pair intermediate. Incubation of chromatin with DNase II and separation of the products under denaturing conditions reveals 20 bands migrating at 10 base intervals.     

The specificity of human autoantibodies that react with both cell nuclei and plasma membranes: the nuclear antigen is present on core mononucleosomes.

We have examined the nature of the nuclear antigen recognized by certain natural human antibodies that react specifically with both cell nuclei and plasma membranes from many species. Partial purification of these antibodies, called X-ANA, is achieved by binding to and rapid elution from the surface of viable human leukocytes. Chicken erythrocyte chromatin was solubilized by digestion with staphylococcal nuclease and fractionated into a 0.15 M NaCl soluble fraction that consisted of core mononucleosomes lacking H1/H5, and a 0.15 M NaCl insoluble fraction composed of polynucleosomes with H1/H5 present. No proteins other than histones were detected. Native and reconstituted mononucleosomes displaced IgG of the leukocyte eluates from nuclei of frozen mouse kidney sections and from the walls of plastic tubes coated with polynucleosomes. The reconstituted core mononucleosomes were 4- 10-fold less efficient inhibitors than native mononucleosomes. Trypsin digested mononucleosomes, free high m.w. DNA, and free histones displayed no or very weak inhibitory activity. The data indicate that X-ANA recognize a complex consisting of the core histones H2A, H2B, H3, H4, and DNA of 140 to 200 base pairs in length.     

A chromatin core particle obtained by selective cleavage of histones by clostripain.

Rat liver chromatin core particles digested with clostripain yield a structurally well-defined nucleoprotein particle with an octameric core made up of fragmented histone species (designated H'2A, H'2B, H'3 and H'4, respectively) after selective loss of a sequence segment located in the N-terminal region of each core histone. Sequential Edman degradation and carboxypeptidase digestion unambiguously establish that histones H2A, H2B, H3 and H4 are selectively cleaved at the carboxyl side of Arg 11, Lys 20, Arg 26 and Arg 19 respectively and that the C-terminal sequences remain unaffected. Despite the loss of the highly basic N-terminal regions, including approximately 17% of the total amino acids, the characteristic structural organization of the nucleosome core particle appears to be fully retained in the proteolyzed core particle, as judged by physicochemical and biochemical evidence. Binding of spermidine to native and proteolyzed core particles shows that DNA accessibility differs markedly in both structures. As expected the proteolyzed particle, which has lost all the in vivo acetylation sites, is not enzymatically acetylated, in contrast to the native particle. However, proteolyzed histones act as substrates of the acetyltransferase in the absence of DNA, as a consequence of the occurrence of potential acetylation sites in the core histones thus rendered accessible. The possible role of the histone N-terminal regions on chromatin structure and function is discussed in the light of the present observations with the new core particle obtained by clostripain proteolysis.     

The condensation of chromatin and histone H1-depleted chromatin by spermine

At low ionic strength, spermine induces aggregation of native and H1-depleted chromatin at spermine/phosphate (Sp/P) ratios of 0.15 and 0.3, respectively. Physico-chemical methods (electric dichroism, circular dichroism and thermal denaturation) show that spermine, at Sp/P less than 0.15, does not appreciably alter the conformation of native chromatin and interacts unspecifically with all parts of chromatin DNA (linker as well as regions slightly or tightly bound to histones). In chromatin, the role of spermine could be more important in the stabilization of higher-order structure than in the condensation of the 30 nm solenoid. The addition of spermine to H1-depleted chromatin revealed two important features: (i) spermine can partially mimic the role of histone H1 in the condensation of chromatin; (ii) the core histone octamer does not appear to play any role in the aggregation process by spermine as DNA and H1-depleted chromatin aggregate at the same Sp/P ratio.