Involvement of the globular domain of histone H1 in the higher order structures of chromatin

We have attacked H1-containing soluble chromatin by α-chymotrypsin under conditions where chromatin adopts different structures.Soluble rat liver chromatin fragments depleted of non-histone components were digested with α-chymotrypsin in NaCl concentrations between 0 mm and 500 mm. at pH 7, or at pH 10, or at pH 7 in the presence of 4 m-urea. α-Chymotrypsin cleaves purified rat liver histone H1 at a specific initial site (CT) located in the globular domain and produces an N-terminal half (CT-N) which contains most of the globular domain and the N-terminal tail, and a C-terminal half (CT-C) which contains the C-terminal tail and a small part of the globular domain. Since in sodium dodecyl sulfate/polyacrylamide-gel electrophoresis CT-C migrates between the core histones and H1, cleavage of chromatin-bound H1 by α-chymotrypsin can be easily monitored.The CT-C fragment was detected under conditions where chromatin fibers were unfolded or distorted: (1) under conditions of H1 dissociation at 400 mm and 500 mm-NaCl (pH 7 and 10); (2) at very low ionic strength where chromatin is unfolded into a filament with well-separated nucleosomes; (3) at pH 10 independent of the ionic strength where chromatin never assumes higher order structures; (4) in the presence of 4 m-urea (pH 7), again independent of the ionic strength. However, hardly any CT-C fragment was detected under conditions where fibers are observed in the electron microscope at pH 7 between 20 mm and 300 mm-NaCl. Under these conditions H1 is degraded by α-chymotrypsin into unstable fragments with a molecular weight higher than that of CT-C. Thus, the data show that there are at least two different modes of interaction of H1 in chromatin which correlate with the physical state of the chromatin.Since the condensation of chromatin into structurally organized fibers upon raising the ionic strength starts by internucleosomal contacts in the fiber axis (zig-zag-shaped fiber), where H1 appears to be localized, it is likely that in chromatin fibers the preferential cleavage site for α-chymotrypsin is protected because of H1-H1 contacts. The data suggest that the globular part of H1 is involved in these contacts close to the fiber axis. They appear to be hydrophobic and to be essential for the structural organization of the chromatin fibers. Based on the present and earlier observations we propose a model for H1 in which the globular domains eventually together with the N-terminal tails form a backbone in the fiber axis, and the nucleosomes are mainly attached to this polymer by the C-terminal tails.     

Reconstitution of chromatin higher-order structure from histone H5 and depleted chromatin

Reconstitution of the 30 nm filament of chromatin from pure histone H5 and chromatin depleted of H1 and H5 has been studied using small-angle neutron-scattering. We find that depleted, or stripped, chromatin is saturated by H5 at the same stoichiometry as that of linker histone in native chromatin. The structure and condensation behavior of fully reconstituted chromatin is indistinguishable from that of native chromatin. Both native and reconstituted chromatin condense continuously as a function of salt concentration, to reach a limiting structure that has a mass per unit length of 6.4 nucleosomes per 11 nm. Stripped chromatin at all ionic strengths appears to be a 10 nm filament, or a random coil of nucleosomes. In contrast, both native and reconstituted chromatin have a quite different structure, showing that H5 imposes a spatial correlation between neighboring nucleosomes even at low ionic strength. Our data also suggest that five to seven contiguous nucleosomes must have H5 bound in order to be able to form a higher-order structure.     

Involvement of histone H1 in the organization of the nucleosome and of the salt-dependent superstructures of chromatin

We describe the results of a systematic study, using electron microscopy, of the effects of ionic strength on the morphology of chromatin and of H1-depleted chromatin. With increasing ionic strength, chromatin folds up progressively from a filament of nucleosomes at approximately 1 mM monovalent salt through some intermediate higher- order helical structures (Thoma, F., and T. Koller, 1977, Cell 12:101- 107) with a fairly constant pitch but increasing numbers of nucleosomes per turn, until finally at 60 mM (or else in approximately 0.3 mM Mg++) a thick fiber of 250 A diameter is formed, corresponding to a structurally well-organized but not perfectly regular superhelix or solenoid of pitch approximately 110 A as described by Finch and Klug (1976, Proc. Natl. Acad. Sci. U.S.A. 73:1897-1901). The numbers of nucleosomes per turn of the helical structures agree well with those which can be calculated from the light-scattering data of Campbell et al. (1978, Nucleic Acids Res. 5:1571-1580). H1-depleted chromatin also condenses with increasing ionic strength but not so densely as chromatin and not into a definite structure with a well-defined fiber direction. At very low ionic strengths, nucleosomes are present in chromatin but not in H1-depleted chromatin which has the form of an unravelled filament. At somewhat higher ionic strengths (greater than 5 mM triethanolamine chloride), nucleosomes are visible in both types of specimen but the fine details are different. In chromatin containing H1, the DNA enters and leaves the nucleosome on the same side but in chromatin depleted of H1 the entrance and exit points are much more random and more or less on opposite sides of the nucleosome. We conclude that H1 stabilizes the nucleosome and is located in the region of the exit and entry points of the DNA. This result is correlated with biochemical and x-ray crystallographic results on the internal structure of the nucleosome core to give a picture of a nucleosome in which H1 is bound to the unique region on a complete two-turn, 166 base pair particle (Fig. 15). In the formation of higher-order structures, these regions on neighboring nucleosomes come closer together so that an H1 polymer may be formed in the center of the superhelical structures.     

Distinct effects of histone H1 and non-histone chromosomal proteins on the structure of nucleosomes and the chromatin fibre in solution

In this study we attempt to differentiate between the effects of the non-histone chromosomal proteins and histone H1 on the structure of the nucleosomes and the chromatin fibre in solution. The properties of chromatin preparations with different histone H1 and non-histone protein compositions were compared using circular dichroism and flow linear dichroism and the following conclusions were drawn. When histone H1 is absent the non-histone proteins partially prevent the unfolding of the nucleosomes at low ionic strength. The complete blocking of this unfolding, however, is accomplished only in the presence of histone H1. The non-histone proteins do not affect the orientation of the nucleosomes along the fibre axis. Only histone H1 can maintain the positive anisotropy of the chromatin fibre.     

Accessibility and structural role of histone domains in chromatin. biophysical and immunochemical studies of progressive digestion with immobilized proteases

The accessibility and role of histone regions in chromatin fibres were investigated using limited proteolysis with enzymes covalently bound to collagen membranes. The changes in chromatin conformation and condensation monitored by various biophysical methods, were correlated to the degradation of the histone proteins revealed by antibodies specific for histones and histone peptides. Upon digestion with trypsin and subtilisin, chromatin undergoes successive structural transitions. The cleavage of the C-terminal domains of H1, H2A and H2B, and of the N-terminal tail of H3 led to a decondensation of chromatin fibres, indicated by increases in electric birefringence and orientational relaxation times. It corresponds to a 15% increase in linear dimensions. The degradation of the other terminal regions of histones H3, H2A and H2B resulted in the appearance of hinge points between nucleosomes without alteration of the overall orientation of polynucleosome chains. Despite the loss of all the basic domains of H1, H3, H2A and H2B, no significant change in DNA-protein interactions occurred, suggesting that most of these protease-accessible regions interact weakly, if at all, with DNA in chromatin. Further proteolysis led to H4 degradation and other additional cleavages of H1, H2B and H3. This caused the relaxation of no more than 8% of the total DNA but resulted in changes in the ability of chromatin to condense at high ionic strength. More extensive digestion resulted in a total unravelling of nucleosomal chains which acquired properties similar to those of H1-depleted chromatin, although the globular part of H1 was still present. The data suggest that histone-histone interactions between H1 and core histone domains play a central role in stabilizing the chromatin fibres, and cuts in H3, H2A and H2B as well as H1, seem necessary for chromatin expansion. On the contrary, H4 might be involved in the stabilization of nucleosomes only.     

Presence of non-histone proteins in nucleosomes

It has been established that nucleosomes are made of histones and DNA fragments. The purpose of this work to establish whether some non-histone proteins are also present in these chromatin subunits. We have found that nucleosome preparations contain phosphorylated non-histone proteins and protein kinases by sucrose gradient analysis. In order to establish whether these proteins are actually bound to nucleosomes or if they represent unbound or aggregated proteins, the following experiments were performed. (a) Free non-histone proteins and proteins released from chromatin by DNase overdigestion were analyzed by sucrose gradient centrifugation. No phosphoproteins but some phosvitin kinase activity was found in the part of the gradient which contained the nucleosomes. It could be assumed that part of the phosphoproteins are bound to nucleosomes. (b) A digestion of nucleosomes with DNase I suppressed the phosvitin kinase activity in the 11-S region of the gradient. (c) High ionic strength, which extracted non-histone proteins, suppressed the phosvitin kinase activity in the nucleosome region. Part of phosvitin kinase and of nuclear phosphoproteins are therefore bound to nucleosomes and are released by nuclease digestion and by high ionic strength.     

Effect of non-histone proteins on thermal transition of chromatin and of DNA.

The effect of chromatin non-histone protein on DNA and chromatin stability is investigated by differential thermal denaturation method. 1) Chromatin (rat liver) yields a multiphasic melting profile. The major part of the melting curve of this chromatin is situated at temperatures higher than pure DNA, with a distinct contribution due to nucleosomes melting. A minor part melts at temperatures lower than DNA which may be assigned to chromatin non-histone protein-DNA complex which destabilized DNA structure. 2) Heparin which extracts histones lowers the melting profile of chromatin and one observes also a contribution with a Tm lower that of pure DNA. In contrast, extraction on non-histone proteins by urea supresses the low Tm peak. 3) Reconstitution of chromatin non-histone protein-DNA complexes confirms the existence of a fraction of chromatin non-histone protein which lowers the melting temperature when compared to pure DNA. It is concluded that chromatin non-histone proteins contain different fractions of proteins which are causing stabilizing and destabilizing effect on DNA structure.     

The superstructure of chromatin and its condensation mechanism

Synchroton radiation X-ray scattering experiments have been performed on chicken erythrocyte chromatin fibres over a wide range of ionic conditions and on various states of the fibres (i.e. "native" in solution, in gels and in whole nuclei; chromatin depleted of the H1 (H5) histones and chromatin with bound ethidium bromide). A correlation between the results obtained with the various chromatin preparations provides evidence for a model according to which at low ionic strength the chromatin fibre already possesses a helical superstructure, with a diameter comparable to that of condensed chromatin, held together by the H1(H5) histone. The most significant structural modification undergone upon an increase of the ionic strength is a reduction of the helix pitch, this leads to condensation in a manner similar to the folding of an accordion. The details of this process depend on whether monovalent or divalent cations are used to raise the ionic strength, the latter producing a much higher degree of condensation. Measurements of the relative increase of the mass per unit length indicate that the most condensed state is a helical structure with a pitch around 3.0-4.0 nm. In this paper we give a detailed presentation of the experimental evidence obtained from static and time-resolved scattering experiments, which led to this model.     

Exchange of histone H1 between segments of chromatin

We have asked whether histone H1 is tightly bound in chromatin at relatively low ionic strength (below physiological) or whether it can exchange between binding sites. We have studied this question in chromatin fragments generated by digestion with micrococcal nuclease, by mixing two fragments of known H1 content and different length (either a fragment radioactively labelled in all its histones with an unlabelled fragment, or two labelled fragments, only one of which contains H1) and then separating them again by centrifugation in sucrose gradients in order tom reexamine their H1 contents.At very low ionic strength (5 mm-Tris · HCl (pH 7.1), 1 mm-Na₂EDTA, 0.5 mm-phenylmethylsulphonyl fluoride) there was very little (less than 5 to 10%) exchange of H1. In contrast, the presence of 70 mm-NaCl in the buffer caused rapid and complete equilibration of H1 between sites in less (possibly much less) than about one hour. At 30 mm added NaCl, the result was intermediate between those at 0 mm and 70 mm added NaCl, partial exchange occurring with a half-time of one to two hours. The results were essentially the same whether or not both fragments contained H1. We infer from these results that at physiological ionic strength (~150 mm) there will be rapid and complete equilibration of H1 between sites in chromatin. We do not know whether the exchange of particular H1 subtypes is restricted to a particular class of binding site.     

The integrity of the histone-DNA complex in chromatin fibres is not necessary for the maintenance of the shape of mitotic chromosomes

In this study we addressed the question of whether scaffold structures produced from purified mitotic chromosomes are an artefact of dehistonization, and whether the integrity of the chromatin fibres is necessary for the maintenance of the well-known shape of mitotic chromosomes. Purified mitotic chromosomes from Friend erythroleukemia cells were treated either with increasing NaCl concentrations up to 500 mM, or with 6 M urea in the presence or absence of 10 mM 2-mercaptoethanol. The main criterion for the intactness of the overall chromosome shape as seen by electron microscopy was the characteristic X-or U-like appearance with clearly discernable chromatid axes. Histone H1 is known to be essential for the integrity of chromatin fibres. Its removal in sucrose gradients containing 500 mM NaCl did not lead to loss of the overall chromosome shape. However, treatment of chromosomes in sucrose gradients containing 10 mM 2-mercaptoethanol and 6 M urea led to loss of the structure probably due to dissociation (or denaturation) of shape-determining (scaffolding) components. Under these conditions most of the histones remained bound to the chromosomes, and the fibres in this chromatin material, after removal of excess urea and 2-mercaptoethanol, still showed condensation of the nucleosome filaments into the characteristic fibre structures upon increasing ionic strength. Our observations are compatible with the model that specific non-histone components, independently of histone-DNA interactions, organize or stabilize the structure of metaphase chromosomes.     

Chromatin structure. Further evidence against the existence of a beaded subunit for the 30-nm fiber

The size distribution of chromatin fragments released by micrococcal nuclease digestion of liver chromatin at various ionic strengths was examined. Below 20 mM ionic strength, gradient profiles with a peak centered at 6 nucleosomes are generated, whereas between 20 and 50 mM the peak is always centered on 12 nucleosomes, and above 50 mM ionic strength the 30-nm fiber becomes less accessible to the nuclease and there is a corresponding increase in the size distribution of fragments in the gradients. However, extensive digestions always give profiles with a peak of 12 nucleosomes as nuclease-resistant dodecamers accumulate. All of these observations are consistent with the winding of the 10-nm polynucleosome chain into a helical coil commencing at about 20 mM ionic strength. The helical turns are stabilized by histone H1 interactions between 20 and 50 mM ionic strength producing stable dodecamers. Above 50 mM ionic strength the coil condenses longitudinally and the profiles are consistent with a random attack of this fiber by the nuclease. Consequently it is not necessary to invoke the existence of a subunit bead to explain the profiles. We further define the conditions at which specific structural transitions take place and provide methodology for the preparation of chromatin at various levels of condensation.     

Characterization of lamina-bound chromatin in the nuclear shell isolated from HeLa cells

The structure and the polypeptide composition of the nuclear shell isolated from interphase HeLa cells have been investigated and compared to those of the intranuclear material. The isolated nuclear shell contains chromatin superstructures (28-32 nm thick fibres) made of tightly packed nucleosomes that resist low ionic strength conditions and that are associated with the three nuclear lamins. Chromatin in the nuclear shell exhibits very simple chemical composition. Especially, non-histone proteins are lacking. The results presented here rule out the possibility that the nuclear shell results from contamination of lamina by intranuclear elements. They suggest that the lamins are directly involved in the specific properties and in the organization of chromatin in the nuclear shell.     

Accessibility and Structural Role of Histone Domains in Chromatin. Biophysical and Immunochemical Studies of Progressive Digestion with Immobilized Proteases

Abstract

The accessibility and role of histone regions in chromatin fibres were investigated using limited proteolysis with enzymes covalently bound to collagen membranes. The changes in chromatin conformation and condensation monitored by various biophysical methods, were correlated to the degradation of the histone proteins revealed by antibodies specific for histones and histone peptides.

Upon digestion with trypsin and subtilisin, chromatin undergoes successive structural transitions. The cleavage of the C-terminal domains of Hl, H2A and H2B, and of the N-terminal tail of H3 led to a decondensation of chromatin fibres, indicated by increases in electric birefringence and orientational relaxation times. It corresponds to a 15% increase in linear dimensions. The degradation of the other terminal regions of histones H3, H2A and H2B resulted in the appearance of hinge points between nucleosomes without alteration of the overall orientation of polynucleosome chains. Despite the loss of all the basic domains of HI, H3, H2A and H2B, no significant change in DNA-protein interactions occurred, suggesting that most of these protease-accessible regions interact weakly, if at all, with DNA in chromatin. Further proteolysis led to H4 degradation and other additional cleavages of Hl, H2B and H3. This caused the relaxation of no more than 8% of the total DNA but resulted in changes in the ability of chromatin to condense at high ionic strength. More extensive digestion resulted in a total unravelling of nucleosomal chains which acquired properties similar to those of Hl- depleted chromatin, although the globular part of HI was still present.

The data suggest that histone-histone interactions between HI and core histone domains play a central role in stabilizing the chromatin fibres, and cuts in H3, H2A and H2B as well as HI, seem necessary for chromatin expansion. On the contrary, H4 might be involved in the stabilization of nucleosomes only.     

Changes in chromatin folding in solution

The formation of higher order structures by nucleosome oligomers of graded sizes with increasing ionic strength has been studied in solution, by measuring sedimentation coefficients. Nucleosome monomers and dimers show no effect of ionic strength at the concentrations used, while trimers to pentamers show a linear dependence of the logarithm of sedimentation coefficient upon the logarithm of ionic strength between 5 and 25 mm, but no dependence above 25 mm. Between pentamer and hexamer a change occurs and the linear relationship is observed up to ionic strength 125 mm with hexamer and above.The simple power-law dependence of the sedimentation coefficient upon the ionic strength (s ∝ Iⁿ) is observed up to nucleosome 30mers, but by 60mer a jump in the sedimentation coefficient occurs between ionic strengths 45 and 55 mm, with the power-law applying both above and below the jump. Removal of histone H1 and non-histone proteins lowers the overall sedimentation rate and abolishes the jump.Cross-linking large oligomers at ionic strength 65 mm stabilizes the structure in the conformation found above the jump, leading to a simple power-law dependence throughout the range of ionic strength for cross-linked material. Cleavage of the cross-links restores the jump, presumably by allowing the conformational transition that causes it. Large oligomers are indistinguishable in sedimentation behaviour whether extracted from nuclei at low ionic strength or at 65 mm and maintained in the presence of salt.We interpret these results, together with the detailed electron microscopic studies reported by Thoma et al. (1979) under similar salt conditions, as showing the histone H1-dependent formation of superstructures of nucleosomes in solution induced by increasing ionic strength. The unit of higher order structure probably contains five or six nucleosomes, leading to the change in stability with hexamer. Although this size corresponds to the lower limit of size suggested for “superbeads” (Renz et al., 1977), we see no evidence that multiples of six nucleosomes have any special significance as might be predicted if superbeads had any structural importance. Rather, our results are compatible with a continuous pattern of condensation, such as a helix of nucleosomes (see e.g. Finch & Klug, 1976). The jump in sedimentation observed between ionic strengths 45 and 55 mm, together with the effect of cross-linking, suggests the co-operative stabilization of this structure at higher ionic strengths. A plausible hypothesis is that the turns of the solenoid are not tightly bonded in the axial direction below 45 mm, but come apart due to the hydrodynamic shearing forces in the larger particles leading to less compact structures with slower sedimentation rates. Above 55 mm the axial bonding is strong enough to give a stable structure of dimensions compatible with the 30 nm structures observed in the cell nucleus.     

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.     

Fragmentation of chromatin by endogenous nucleases, accumulation of the subnucleosomal fragments with high electrophoretic mobility]

Digestion of chromatin by endogenous nucleases to nucleosomes (140-160 base pairs of DNA) is accompanied by the accumulation of subnucleosomal DNP particles with high electrophoretic mobility (20-40 base pairs of DNA). All histones associate with the 140-160 base pairs fragment. The production of subnucleosomal DNP particles does not correlate with the degradation of histone H1 and the appearance of nucleosomes lacking histone H1. Degradation of the protein in this fragment is accompanied by the appearance of free DNA. The data obtained are in agreement with the hypothesis on the origin of subnucleosomes from the nucleosomal locus preferentially associated with the non-histone proteins and on the autonomy of these loci and of the loci associated with histone H1 in the nucleosome.     

Histone phosphorylation in native chromatin induces local structural changes as probed by electric birefringence

In order to understand how the phosphorylation of histones affects the chromatin structure, we used electron microscopy, sedimentation velocity, circular dichroism and electric birefringence to monitor the salt-induced filament reversible solenoid transition of phosphorylated and native chromatin. Phosphorylation in vitro of chicken erythrocyte chromatin by cyclic-AMP-dependent protein kinase from porcine heart led to the modification of the histones H3 and H5 only, which were modified at a level of one phosphate and about three phosphate groups per molecule, respectively. In contrast to circular dichroism and sedimentation studies, which tend to suggest that phosphorylation of H3 and H5 does not affect chromatin structure, electron microscopy reveals that phosphorylation causes a relaxation of structure at low ionic strength. Electric birefringence and relaxation time measurements clearly prove that local structural changes are induced in chromatin: we observe a decrease of the steady-state birefringence with the appearance of a negative contribution in the signal and a marked increase of the flexibility of fibres. The component with the negative birefringence presents very short relaxation times, like those exhibited by small DNA fragments or individual nucleosomes. Two possibilities are then suggested. First, the conformational change is consistent with what would be expected from the presence of DNA segments loosely associated with the core histone H3. That the length of such segments could correspond to about one to two base-pairs per nucleosome strongly suggests that phosphorylation induces changes affecting some specific H3-DNA interactions only. This result could corroborate previous observations indicating that the N-terminal region of H3, where the site of phosphorylation is located, plays a decisive role in maintaining the superstructure of chromatin. Second, phosphorylation could introduce hinge points between each nucleosome. In this case, the negative birefringence results from partial orientation of the swinging nucleosomes. A possible mode of action of phosphorylation might be to weaken structural restraints imposed by histone H3, thus facilitating further condensation of chromatin.     

Stability of nucleosomes in native and reconstituted chromatins.

The stability of nucleosomes of SV40 minichromosomes extracted from infected cells or reconstituted by association of SV40 DNA and the four histones H2A, H2B, H3 and H4 was studied as a function of the ionic strength. As a measure of the stability of the nucleosome, we followed the disappearance of the nucleosomes from the original chromatin and their appearance on a "competing" DNA. We show here that the DNA and the histone components of the nucleosomes do not apprecially dissociate below 800 mM NaCl. At 800 mM and above, the histone moiety of the nucleosomes can dissociate from the DNA and efficiently participate to the formation of nucleosomes on a "competing" DNA.     

Cytochemical properties of interphase chromatin condensed as a result of treatment with caffeine

Treatment of living cultured cells with caffeine (10 mg/ml, 2 h, 37 °C) brings about marked chromatin condensation which results in the appearance of small, distinct chromatin clumps in the majority of interphase nuclei. The changes taking place in the chromatin properties under the action of caffeine are rather similar to those observed in mitotic condensation (an increase in acridine orange and berberine binding and a sharp decrease in [³H]actinomycin D binding in situ; inhibition of [³H]uridine incorporation in vivo) and are reversible from the point of view of the criteria studied (nuclear morphology, ligand binding, [³H]uridine incorporation, culture viability). It is concluded that caffeine treatment can be regarded as a promising approach to the study of events occurring in chromatin condensation.