The role of the central globular domain of histone H5 in chromatin structure

Histone H5 contains three tyrosines in the central, apolar region of the molecule. All three tyrosines can be spin labeled at low ionic strength. When the central globular domain is folded at high ionic strength, only one tyrosine becomes accessible to the imidazole spin label. Spin labeling the buried tyrosines prevents the folding of the globular structure, which, in turn, affects the proper binding of the H5 molecule to stripped chromatin. Chromatin complexes reconstituted from such an extensively modified H5 molecule show a weaker protection of the 168 base pair chromatosome during nuclease digestion. However, when only the surface tyrosine of the H5 molecule is labeled, such a molecule can still bind correctly to stripped chromatin, yielding a complex very similar to that of native chromatin. Our data supports the idea that not just the presence of the linker histone H5, but the presence of an intact H5 molecule with a folded, globular central domain in essential in the recognition of its specific binding sites on the nucleosomes. Our data also show that during the chromatin condensation process, the tumbling environment of the spin label attached to the surface tyrosine in the H5 molecule is not greatly hindered but remains partially mobile. This suggests that either the labeled domain of the H5 molecule is not directly involved in the condensation process or the formation of the higher-order chromatin structure does not result is a more viscous or tighter environment around the spin label. The folded globular domain of H5 molecule serves in stabilizing the nucleosome structure, as well as the higher-order chromatin structure.     

Spin-label study of histone H1-DNA interaction. Involvement of the central part of the molecule in reconstituted chromatin

As shown in a previous paper [J. J. Lawrence et al. (1980) Eur. J. Biochem. 107, 263-269], covalent spin labeling of basis residues in histone H1 allows the study of the interaction of this protein with DNA. Using a step gradient dialysis procedure to reconstitute chromatin from labeled H1 and stripped chromatin, it is shown that the process of interaction of the lysine residues and DNA is the same whether histone H1 is bound to linear purified DNA or to H1-depleted chromatin. In contrast, spin labeling of the unique tyrosine of histone H1 located in the globular part of the molecule shows that this part is more involved in the interaction with chromatin than it is with linear DNA (as judged from the lengthening of the rotational correlation time). These data are interpreted as reflecting different roles for the N and C termini of the molecule of H1 and the central globular part. A model, based on these observations together with examination of the primary structures of histones H1, is proposed which accounts for the H1 involvement in the chromatosome structure.     

Accessibility of the globular domain of histones H1 and H5 to antibodies upon folding of chromatin

Antibodies to the globular domain of histones H1 and H5 were purified by affinity chromatography and used to study the accessibility of this region of H1 and H5 in folded and unfolded rat liver and hen erythrocyte chromatin respectively. The different conformations of the chromatin filament were induced by varying the ionic strength from 1 mM to 80 mM NaCl and maintained by fixation with glutaraldehyde. Treatment with glutaraldehyde at a given salt concentration affected neither the orientation of nucleosomes relative to the fiber axis nor the compactness of chromatin. Solid-phase immunoassay and inhibition experiments showed no binding of the antibody against the globular domain of H1 to chromatin at the entire range of salt concentrations, while the antibody to the whole H1 molecule reacted with chromatin at low salt. On the other hand, the antibody to the globular region of H5 reacted with hen erythrocyte chromatin independently of the extent of chromatin condensation. These results indicate that the antigenic determinants of the globular domain of H5 are accessible to the antibody both in folded and unfolded chromatin, while those of the same region of H1 are masked, probably by interaction with DNA or proteins.     

Study by the spin-label method of relaxation properties of protein kinase, its subunits and the catalytic subunit--histone H1 complex

Using the spin label method, the rotational relaxation in solution of adenosine 3',5'-monophosphate-dependent protein kinase and its subunits as well as the complexes of the enzyme with the substrate, histone H1, was studied. The rotational correlation time of the spin labeled macromolecules was measured on the basis of the quantitative estimation of the label mobility in relation to the protein globule. The holoenzyme molecule was found to be a rigid sphere. Whereas the complex of the globular catalytic subunit of the enzyme with a specific protein substrate, the spin labeled histone H1, appeared a flexible formation. The relaxation properties of the histone H1 molecule selectively labeled by the spin label in its globular part were investigated.     

The conformation of histone H5. Isolation and characterisation of the globular segment

Treatment of chicken erythrocyte histone H5 with trypsin in a high-ionic-strength medium results in very rapid initial digestion and the formation of a 'limiting' resistant product peptide. Under these solution conditions the H5 molecule is maximally folded by spectroscopic criteria and it is concluded that the resistant peptide, GH5, represents a globular folded region of the molecule whilst the rapidly digested parts are disordered. The peptide GH5 is shown to comprise the sequence 22-100. In support of this conclusion it is shown that whilst intact histone H5 is hydrodynamically far from being a compact globular shape, peptide GH5 is approximately spherical by hydrodynamic and scattering criteria. Further more, peptide GH5 retains all the alpha-helical structure of intact H5 (circular dichroism) and appears to also maintain all the tertiary structure (nuclear magnetic resonance). It follows that in solution at high ionic strength, histone H5 consists of three domains: an N-terminal disordered region 1-21, a compact globular central domain 22-100 and a long disordered C-terminal chain 101-185. Structural parallels are drawn with the three-domain structure of the histone H1 molecule.     

The globular domain of histone H5 is internally located in the 30 nm chromatin fiber: an immunochemical study.

The location of the globular domain of histone H5 relative to the axis of the 30 nm chromatin fiber was investigated by following the accessibility of this region of the molecule in chicken erythrocyte chromatin to specific antibodies as a function of chromatin structure. Antibodies to the globular domain of H5 as well as their Fab fragments were found to react with chromatin at ionic strengths ranging from 1-80 mM NaCl, the reaction gradually decreasing upon increase of salt concentration. If, however, Fab fragments were conjugated to ferritin, no reaction of the complex with chromatin was observed at salt concentrations higher than 20 mM. The accessibility of the globular part of H5 in unfolded chromatin to the Fab-ferritin complex was also demonstrated with trypsin-digested chromatin. The experiments were carried out by both solid-phase immunoassay and inhibition experiments. The data obtained are consistent with a structure in which the globular domain of H5 is internally located in the 30 nm chromatin fiber.     

Mapping the interaction surface of linker histone H1(0) with the nucleosome of native chromatin in vivo

H1 linker histones stabilize the nucleosome, limit nucleosome mobility and facilitate the condensation of metazoan chromatin. Here, we have combined systematic mutagenesis, measurement of in vivo binding by photobleaching microscopy, and structural modeling to determine the binding geometry of the globular domain of the H1(0) linker histone variant within the nucleosome in unperturbed, native chromatin in vivo. We demonstrate the existence of two distinct DNA-binding sites within the globular domain that are formed by spatial clustering of multiple residues. The globular domain is positioned via interaction of one binding site with the major groove near the nucleosome dyad. The second site interacts with linker DNA adjacent to the nucleosome core. Multiple residues bind cooperatively to form a highly specific chromatosome structure that provides a mechanism by which individual domains of linker histones interact to facilitate chromatin condensation.     

Histone H1 and chromatin higher order structure. Does histone H1 exhibit specific self-association?

1. Histones H1 and H5 in chromatin and in free solution can be cross-linked to higher multimers. Is this due to a specific protein/protein interaction? If so, this interaction might be the structural basis of the condensation of the chromosomal nucleofilament, known to be mediated by histones H1 and H5. 2. Since only the central domain of H1 and H5 exhibits tertiary folding and globular structure, this is the most likely site of specific interaction. 3. Formaldehyde has been used to test whether the central domains of histone H1 from calf thymus or from sea urchin sperm or histone H5 from chicken erythrocytes self-interact. 4. The cross-linking shown by each globular peptide was compared with that of its parent histone. 5. In all three cases the peptide cross-linked to a much lower extent than its intact parent histone and the observed cross-linked rates were roughly in proportion to the relative number of lysine residues parent histone and peptide. 6. It is concluded that there is no specific self-interaction between the globular domains of either H1 or H5 molecules in free solution. 7. This result suggests that specific H1/H1 protein/protein interactions are not the basic cause of chromatin condensation.     

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.     

Binding of linker histones to the core nucleosome

Binding of chicken erythrocyte linker histones H1/H5 to the core nucleosome has been studied. Histones H1/H5 bind very efficiently to the isolated core nucleosome in vitro. The binding of linker histones to the core nucleosome is associated with aggregation of the particles. Approximately one molecule of linker histone binds per core nucleosome in the aggregates, irrespective of the concentration of the linker histones and the salt used. Histone H5 shows greater binding affinity to the core nucleosome as compared to H1. The carboxyl-terminal fragment of the linker histones binds strongly to the core nucleosome while the binding of the central globular domain is weak. Each core nucleosome is capable of binding two molecules of carboxyl-terminal fragment of linker histone. The core nucleosome containing one molecule of carboxyl-terminal fragment of linker histone requires higher salt concentration for aggregation while the core nucleosome containing two molecules of carboxyl-terminal fragment of linker histone can self-associate even at lower salt concentrations. On the basis of these results we are proposing a novel mechanism for the condensation of chromatin by linker histones and other related phenomena.     

Monoclonal antibody with specificity to a conserved epitope in the C-terminal domain of histone H1 variants.

A monoclonal type M-immunoglobulin (IgM) was generated in mice against a nuclease-urea extract of HeLa metaphase chromosomes. This antibody stains metaphase chromosomes from a variety of mammalian cultured cell types by indirect immunofluorescence. Antibody 12C7 reacts by western transfer technique with histone H1 in all the cell lines tested. The antibody cross-reacts with H1, and H1(0) in human cells. Proteolytic digestions of H1 suggest that the epitope is localized in the carboxy-terminal domain of the histone H1 molecule. Digestion with trypsin demonstrates that the antibody 12C7 does not react with the globular domain of histone H1. The C-terminal domain of H1 subtypes therefore seems to have a conserved determinant which does exist in H1, H1(0), and probably in H5. This antibody has applications in studying the role of that domain of H1 in processes like chromosome condensation and variations in chromatin structure which influence gene expression.     

Studies on the role and mode of operation of the very-lysine-rich histone H1 (F1) in eukaryote chromatin. The properties of the N-terminal and C-terminal halves of histone H1.

Restricted chymotrypsin digestion of calf thymus H1 histone gives two fragments, residues 1--106 and 107--C-terminal. These were studied by proton magnetic resonance and circular dichroism. The N-terminal fragment exhibited some salt-induced structure in aqueous solution, but this did not parallel the globular structure of the intact H1 molecule. Comparison of circular dichroism results with helix predictions for this portion of the molecule suggests that the secondary structure may be the same in this fragment as it is in the corresponding region of the whole molecule. The C-terminal fragments show very little salt-induced structure. The N-terminal fragments binds to DNA very weakly, but the C-terminal fragment binds as strongly as the whole molecule. In the C-terminal fragment, about one quarter of the lysine residues are not bound to the DNA in water, but initial increase of salt concentration causes them to become bound. This increasing binding occurs under the same ionic conditions that cause chromatin condensation and condensation of H1 - DNA complexes, and it is suggested that there may be a connection between these phenomena.     

Association-dissociation of histone oligomers. A spin label study

The spin label method has been used to obtain information about conformational changes of histone oligomers taking advantage of the fact that at a low ionic strength and in the presence of other histones about 45% of cysteine residues of histone H3 react with the 3-maleimido-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl spin label. For the labeled complexes H3-H4 and H nu the degree of immobilization of the spin label is a function of the ionic strength. This variation is identical for both complexes within a long range of ionic strengths, including the interval of 0.8-2 M NaCl, under which conditions interactions are known to exist between the tetramer (H3)2 (H4)2 and the dimer (H2A) (H2B). This finding suggests a negligible influence of the dimer for modifying the cysteine residue environment of histone H3 on octamer formation. GuHCl treatment at high ionic strength of the labeled complexes gives rise to a non-lineal increase in the degree of mobility of the spin label. This increase, at low GuHCl concentration (0-0.5 M GuHCl), is interpreted as showing a lowering in rigidity for the Cys residue environment, without affecting the general stability of the tetramer (H3)2 (H4)2. At higher GuHCl concentration (2-3 M GuHCl) the increase in the spin label mobility is related to a dissociation of the complexes in single histones. Our results are consistent with the view that the overall structure of the tetramer, as well as its conformational changes during complex structuration or denaturation, are not strongly affected by the presence of the dimer (H2A) (H2B).     

Nucleosome Interaction Surface of Linker Histone H1c Is Distinct from That of H10

The fully organized structure of the eukaryotic nucleosome remains unsolved, in part due to limited information regarding the binding site of the H1 or linker histone. The central globular domain of H1 is believed to interact with the nucleosome core at or near the dyad and to bind at least two strands of DNA. We utilized site-directed mutagenesis and in vivo photobleaching to identify residues that contribute to the binding of the globular domain of the somatic H1 subtype H1c to the nucleosome. As was previously observed for the H1⁰ subtype, the binding residues for H1c are clustered on the surface of one face of the domain. Despite considerable structural conservation between the globular domains of these two subtypes, the locations of the binding sites identified for H1c are distinct from those of H1⁰. We suggest that the globular domains of these two linker histone subtypes will bind to the nucleosome with distinct orientations that may contribute to higher order chromatin structure heterogeneity or to differences in dynamic interactions with other DNA or chromatin-binding proteins.     

Chromatin on a membrane: accessibility of histone H5 for antibodies in the supernucleosomal structure

Histone H5 accessibility for the antibodies in chromatin was studied. Chromatin was immobilised on the nitrocellulose membrane in conditions which provide different levels of its compactization. Antiserum specific to the globular domain of histone H5 was used. It was shown, that for establishing real protection of histone H5 in the supernucleosomal structure it is necessary to use long fibers of chromatin. Their linking to the membrane must occur by a minimum quantity of points. It was established, that histone H5 is 5 times more accessive in the preparations of dispersed chromatin (low ionic strength) then in chromatin with the supernucleosomal organization (physiological ionic strength). We suppose that the small level of accessibility of histone H5 for the antibodies in the compact chromatin can be explained by some disruptions in the supernucleosomal organization. On the contrary, the long equable solenoid of nucleosomes provides complete protection of histone H5. In accordance with the results obtained, the model of ordered packaging of nucleosomes in the solenoid is discussed. In this model the point of entrance and exit of DNA on the nucleosomes, fixed by globular region of histone H5, is localized inside the solenoid.     

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.     

Roles of H1 domains in determining higher order chromatin structure and H1 location

Peptides derived from calf thymus H1 and rat liver H1, comprising only the globular and COOH-terminal domains of the intact molecule and therefore lacking NH2-terminal domains, have been shown by reconstitution to be as effective as the complete H1 molecule in inducing higher-order-chromatin structure. As the globular domain of H1 alone cannot induce chromatin folding, our results demonstrate that this function is primarily controlled by the COOH-terminal domain of the molecule. Surprisingly, these peptides do not locate correctly with respect to the nucleosome. This is demonstrated by their failure to confer upon reconstitutes the ability to protect DNA fragments of chromatosome length when digested with micrococcal nuclease. The precise placement of the H1 molecule (globular domain) with respect to the nucleosome is shown to be influenced by the "tail" domains of both H1 and the core histones.     

Site-directed mutagenesis studies on the binding of the globular domain of linker histone H5 to the nucleosome.

The globular domain of the linker histone H5 has been expressed in Escherichia coli. The purified peptide is functional as it permits chromatosome protection during micrococcal nuclease digestion of chromatin reconstituted with the peptide, indicating that it binds correctly at the dyad axis of the nucleosomal core particle. The globular domain residue lysine 64 is highly conserved within the linker histone family, and site-directed mutagenesis has been used to assess the importance of this residue in the binding of the globular domain of linker histone H5 to the nucleosome. Recombinant peptides mutated at lysine 64 are unable to elicit chromatosome protection to the same degree as the wild-type peptide, and since they appear to be fully folded, these observations confirm a major role for this residue in determining the effective interaction between the globular domain of histone H5 and the nucleosome.