Physical studies of chromatin. The recombination of histones with DNA

Efficient intracellular gene delivery using the formulation composed of poly (L-glutamic acid) grafted polyethylenimine and histone

PURPOSE

Inefficient endosomal escape and poor nuclear import are thought to contribute to low gene transfer efficiency of polycations. To overcome these drawbacks, we prepared multiple gene delivery formulations including low cytotoxic polycation, histone containing NLSs and chloroquine as the endosomolytic agent.

METHODS

Comb-shaped poly (L-glutamic acid) grafted low-molecular-weight polyethylenimine (PLGE) copolymer was synthesized by aminolysis of poly-γ-benzyl-L-glutamate using low-molecular-weight polyethylenimine (800 Da). The formation of DNA/histone/PLGE terplex was observed by atomic force microscope and gel retardation assay. The particle size and zeta potential of DNA complexes with varying content of histone were also measured to confirm the terplex formation. Cytotoxicity of vectors was assayed by MTT. Multiple gene delivery formulations were optimized to their best transfection efficiency that was monitored by fluorescence microscope and flow cytometry. In vivo gene delivery of the optimal formulation was evaluated by the GFP-expression levels in drosophila melanogaster.

RESULTS

The DNA/histone/PLGE terplex was successfully formed. The PLGE and histone together condensed DNA into small, discrete particles (less than 200 nm in diameter) in isotonic solution. Cytotoxicity of PLGE and histone were much lower than that of PEI 25 K. Either histone or chloroquine contributed to enhancing the levels of transfection activity of PLGE polymer. However, chloroquine and histone did not show a synergistic effect on the improvement of transfection efficiency. The optimal formulation was the DNA/histone/PLGE terplex at the N/P ratio of 15 and histone/ DNA weight ratio of 0.8. Compared with Lipofectamine 2000 and PEI 25 K, the optimal formulation showed significantly increased levels of GFP-expression both in vitro and in vivo.

CONCLUSION

This formulation provided a versatile approach for preparing high efficiency of the polycation-based gene vectors. It also reinforced the finding of earlier studies that nuclear import and endosomal escape were rate-limiting steps for nonviral gene delivery.

Conformations and flexibilities of histones and high mobility group (HMG) proteins in chromatin structure and function

The packaging of the enormous lengths of eukaryotic DNA into the different conformational states of chromosomes is controlled very largely by an equal total mass of the histones, H1, H2A, H2B, H3 and H4. Histone sequences, sequence conservations, postsynthetic chemical modifications and studies of histone conformations and interactions show clearly that histones are multi-domain proteins. The N-terminal domains of all histones and the C-terminal domains of H1, H2A and H2B are flexible random coils, while the C-terminal regions of H3 and H4 and the central regions of H1, H2A and H2B are structured. Histones H3 and H4 are essential for nucleosome structure and interact with DNA to give the nucleus of the nucleosome structure, which is completed by interactions of the conserved structured regions of (H2A, H2B) dimers and H1. The flexible domains of all the histones are very basic and contain all the sites of reversible chemical modifications: acetylation of lysines in the core histones and phosphorylation of serines and threonines in histone H1. Strict correlations have been observed (i) between acetylation and DNA processing and (ii) between H1 phosphorylation and chromosome condensation. In addition to histone acetylation, active chromatin is also associated with high mobility group (HMG) proteins 14 and 17. These proteins are completely flexible under all solution conditions and their native structures must be imposed by their binding sites in active chromatin. The function of flexibility in these chromosomal proteins is not understood but is probably related to the enormous lengths of DNA which have to be controlled in the structures and function of chromosomes.

Supercoiled induced transition to the Z-DNA conformation affects the ability of a d(CG/GC)12 sequence to be organized into nucleosome-cores

Nucleosome-cores were reconstituted by the salt-dialysis method onto closed circular pDHg16 DNA which contains a d(CG/GC)12 sequence. Alternating d(CG/GC)n sequences form left-handed Z-DNA readily when contained in negatively supercoiled DNA. We have investigated the ability of the d(CG/GC)12 sequence to be organized into nucleosome-cores when stabilized as Z-DNA through negative supercoiling. We have found that nucleosome assembly at the d(CG/GC)12 insert is prevented when the sequence is stable in the Z-conformation but it is not affected at all when the sequence adopts the right-handed B-form.

DNA topology in a chromatin model system

The synthetic copolypeptide (Lys33, Leu67)100-Orn20, modeled on some general features of the histone sequences, has been found to supercoil the DNA double helix, wrapping it into a micelle, as a result of cohesive interactions between the polypeptide hydrophobic moieties. X-ray low-angle diffraction of complexes between the polypeptide and DNA is characterized by maxima at 50, 32, and 23 A, reminiscent of the chromatin pattern. The existence of a nucleosome-like structure along the DNA is suggested by gel electrophoresis analysis of DNA fragments after micrococcal nuclease digestion, showing the presence of a fragment of about 100 basepairs (bp) long. Topological experiments on the complexes with supercoiled as well as relaxed circular DNA by two-dimensional gel electrophoresis show the presence of left-handed superhelical turns. The results are in agreement with an intrinsic propensity of B-DNA to writhe into left-handed supercoils.

Laser Raman spectra of calf thymus chromatin and its constituents

Extensive Raman measurements have been made on calf thymus chromatin, core chromatin, the (H3,H4)/DNA complex, and isolated DNA. The results indicate that the alpha-helical content of the nucleosomal histones gradually increases as they form the heterocomplexes that lead to the formation of the octameric nucleosome core. The secondary structure of the latter is not modified as it binds to DNA. The spectra indicate that the DNA essentially retains its B conformation in nucleosomes, although slight changes probably occur in the ribose-phosphate backbone. No specific interactions between the nucleosomal histones and DNA can be established from the spectra, but histone H1 possibly interacts selectively with the thymine bases.

Folding of single-stranded DNA on the histone octamer

A complex between the single-stranded DNA of the bacteriophage M13 and the histone octamer was analyzed by electron microscopy, low-angle X-ray diffraction and nuclease analysis. The morphology and the diffraction pattern of the complex strongly resemble those of the nucleosome. These results, as well as the finding of a protected DNA fragment about 100 nucleotides long following single-stranded DNA specific nuclease digestion, indicate that 'a nucleosome-like' complex can be formed between single-stranded DNA and the histone octamer. Competition experiments suggest that under physiological conditions the histone octamer is transferred from single- to double-stranded DNA.

Contribution of histones H2A and H2B to the folding of nucleosomal DNA

We have studied the structural properties of nucleosomal particles deficient in histones H2A and H2B produced by modification of histone amino groups with dimethylmaleic anhydride [Jordano, J., Montero, F., & Palacián, E. (1984) Biochemistry (preceding paper in this issue)]. Digestion with DNase I of residual particles containing only 15% of the original H2A . H2B complement produces only discrete DNA fragments no longer than 70 nucleotides. As compared with the original nucleosomes, thermal denaturation of the residual particles shows a decrease from 140 to about 90 in the number of nucleotide base pairs per particle that melt at the highest temperature transition as well as a drop in the temperature of this transition. Circular dichroism spectra of the residual particles give ellipticity values around 275 nm, much higher than those corresponding to the control nucleosomes, which appears to indicate a loss in the compact DNA tertiary structure. When regeneration of the modified amino groups of the residual particles takes place in the presence of the complementary fraction containing histones H2A and H2B, but not in its absence, nucleosomal particles with the structural properties of the original nucleosomes are reconstituted. Therefore, the structural change observed in the residual particles can be assigned to the lack of histones H2A and H2B and not to the modified amino groups of the histones present in the residual particles. The results are consistent with the stabilization by histones H2A and H2B of a DNA length of 50-70 base pairs per nucleosome.

Selective depletion and reconstitution of nucleosome core particles

A method for the complete and specific removal of histones H2A and H2B from nucleosome core particles is presented. Reconstitution of the separated products of depletion form a particle which has the same structure as native core particles as judged by a number of physical and biochemical criteria. The technique described also minimises the possibility of the formation of reconstituted core particles with different histone stoichiometries. These experiments are important as they demonstrate a procedure which can be extended to prepare core particles with selectively deuterated components while maintaining complete integrity of structure. When prepared, and studied by neutron scattering, selectively-deuterated core particles can give detailed information with respect to the relative positions and structure of the histone fractions within the core particle.

Salt-induced conformational transitions in chromatin. A flow linear dichroism study

The chromatin structure in solution has been studied by the flow linear dichroism method (LD) in a wide range of ionic strengths. It is found that increasing the ionic strength from 0.25 mM Na2EDTA, pH 7.0 to 100 mM NaCl leads to a strong reduction of the LD amplitude of chromatin and inversion of the LD sign from negative to positive at 2 mM NaCl. Chromatin exhibits a positive LD maximum value at 10-20 mM NaCl. These data enable us to conclude that in very low ionic strength (0.25 mM Na2EDTA) the nucleosome discs are oriented with their flat faces more or less parallel to the chromatin filament axis. Increasing ionic strength up to 20 mM NaCl leads to reorientation of the nucleosome discs and to formation of chromatin structures with nucleosome flat faces inclined to the fibril axis. A conformational transition of that kind is not revealed in H1-depleted chromatin. The condensation of the chromatin filaments with increasing concentration of NaCl from 20 mM to 100 mM slightly influences the orientation of the nucleosomes.

Interactions of the histone octamer with single-stranded DNA. Sedimentation analysis and low-angle X-ray diffraction

A complex between 140-160 nucleotide single-stranded DNA and the octamer of histones was formed and analyzed by electron microscopy and X-ray low angle diffraction. The morphology of the complex is very similar to that of the nucleosome; the diffraction pattern appears less defined than for chromatin showing broader maxima in the same positions. These results strongly suggest that this particle has a geometry very similar to that of the fundamental subunit of chromatin. The possibility of artifacts due to renaturation reaction promoted by histones is ruled out by the analysis of the complex with S1 nuclease and by the formation of a 'nucleosome like' particle using poly(dT) instead of DNA. Association of the histone octamer with either the 140-160 nucleotide single-stranded DNA or the 140-160 bp double-stranded DNA was evaluated at different histone/DNA input ratios. In both cases, the formation of the complex appears to be regulated by comparable association constants, and in both cases the trend of the complexation reaction in function of the temperature is almost the same. These results suggest that an alternative binding of the histone octamer to double-stranded or to single-stranded DNA requires low energy charge and may be involved in the processes of replication and transcription of the 'active chromatin'.

Histone-dependent reconstitution and nucleosomal localization of a nonhistone chromosomal protein: the H2A-specific protease

We have described earlier a chromatin-bound protease with unique specificity for histone H2A [Eickbush, T. H., Watson, D. K., & Moudrianakis, E. N. (1976) Cell (Cambridge, Mass.) 9, 785--792]. In the present study, we explore the nature of interactions that form and stabilize the enzyme-chromatin system by using the activity of the protease to monitor its binding to DNA and DNA-histone complexes. During salt extraction of chromatin, the protease is released at an ionic strength between that required for the extraction of the slightly lysine-rich histones (H2A and H2B) and the arginine-rich histones (H3 and H4). The reassociation of this nonhistone protein to DNA has an absolute requirement for the H3--H4 tetramer and is only enhanced by the H2A--H2B dimer in the presence of the tetramer. We believe that the binding of the enzyme onto DNA requires some histone-elicited compaction of the helix. We have also examined the distribution of this enzyme within the chromatin fiber by isolating pools of monomer nucleosomes from micrococcal nuclease digests of 0.6 M NaCl extracted chromatin and from reconstituted DNA-protein complexes. The H2A-protease is found with these monomer nucleosome pools, and no activity can be detected in the low molecular weight products released during the digestion. Thus, by virtue of its extraction characteristics from chromatin and its association with isolated nucleosomes, this nonhistone protein exhibits properties hitherto assigned only to the inner histones.

Study of conformational states and reversibility of histone complexes

The core histone complex (H3:H4:H2A:H2B)2 and products of dissociation, the H2A:H2B: dimer and the H3:H4 tetramer, were isolated from chicken erythrocyte chromatin by several literature methods as well as gel filtration on Bio-Gel A15m at various salt concentrations. The conformational and oligomeric characteristic of these histone complexes were compared to analogous histone complexes prepared by renaturation of individually acid-extracted histones by circular dichroism (CD) and analytical gel filtration chromatography. The salt-extracted core histone complex (independent of method of preparation), the purified dissociation products, the H2A:H2B dimer, and the H3:H4 tetramer in 2 M NaCl, 10 mM sodium phosphate, 0.25 mM EDTA and 0.1 mM DTT, pH 7.0, have conformation which are identical, by the criteria of similar CD spectra, with complexes prepared from acid-extracted histones, Likewise, the salt-extracted complexes may be cycled through solvents of low ionic strength (10 mM sodium phosphate, pH 7.0 or 50 mM NaOAc, pH 5.0) or 1 mM HCl and returned to 2.0 M NaCl, 10 mM sodium phosphate, 0.25 mM EDTA, and 0.1 mM DTT, pH 7.0, in a completely reversible manner. Thus it would appear that acid-denatured histones are capable of being fully renatured to yield native-like complexes.

Infrared spectroscopy and X-ray diffraction study of complexes of histones H3 and H4 in the condensed state

Infrared spectroscopy, deuterium exchange kinetics and X-ray diffraction experiments on H3-H4 complexes in the condensed state are described. Both salt- and acid-extracted material are shown to contain alpha-helix in an amount comparable to that found under dilute solution conditions. Support for an anisotropic model of these complexes is provided.

A low resolution structure for the histone core of the nucleosome

Image reconstruction to 22 A resolution of the histone octamer (H3)2(H4)2(H2A)2(H2B)2 shows it to have a 2-fold axis of symmetry, and the overall shape of the left-handed helical spool on which to wind about two turns of a flat superhelix of DNA in the nucleosome. From this structure and the results of various cross-linking studies, we have deduced the arrangement of the individual histones. We propose that the (H3)2(H4)2 tetramer forms a dislocated disk which defines the central turn of DNA, while the two H2A-H2B dimers lie one on each face, each associated with about one half a turn.

Composition of native and reconstituted chromatin particles: direct mass determination by scanning transmission electron microscopy

Chromatin particles reconstituted from 145-base-pair lengths of DNA and either the arginine-rich histones H3 and H4 only or all four nucleosomal core histones have been compared with native nucleosomes in terms of their ultrastructure and mass distribution, as determined by scanning transmission electron microscopy (STEM). The mass of the nucleosome derived from STEM analysis was very close to that calculated for its DNA and histone components. The reconstituted particles showed a broader mass distribution, but it was clear that the majority contained at least eight histone molecules. This was to be expected for structures reconstituted from all four core histones, but in the case of H3H4-DNA complexes clearly showed that an octamer rather than tetramer of these histones was required to fold nucleosomal DNA into a stable compact particle. The significance of the H3H4 octamer complex with respect to nucleosomal structure is discussed, and the evidence that nucleosomal DNA can accept even greater numbers of histones is considered.

Fractionation of native and reconstituted chromatin by digesting with deoxyribonuclease ii

Native and reconstituted chromatin from Ehrlich ascites tumor cells were fractionated into template-active and inactive fractions by the DNAase II/Mg2+-solubility method of Gottesfeld et al. (Gottesfeld, J.M., Garrard, W.T., Bagi, G., Wilson, R.F. and Bonner, J. (1974) Proc. Natl. Acad. Sci. U.S.A. 71, 2193-2197). The Mg2+-soluble (template-active) fractions were compared in respect to sedimentation behavior in sucrose gradients and the relative content of specific transcribed (ribosomal) and non-transcribed (satellite) DNA sequences. It was found that the Mg2+-soluble fraction of the native chromatin was enriched in ribosomal DNA while almost completely devoid of satellite DNA; the nucleoprotein monomer of this fraction sedimented in sucrose gradient at 14 S. Similar-results were obtained if chromatin was fractionated in the presence of 3 M urea. With reconstituted chromatin, however, neither the sedimentation profile, nor the relative content of ribosomal and satellite DNA sequences were recovered, thus indicating that reconstitution did not yield nucleoprotein structurally similar to native chromatin.

Reversible dissociation of linker histone from chromatin with preservation of internucleosomal repeat

Procedures are described for the dissociation of histones H1 and H5 from chicken reticulocyte chromatin without disruption of the native core histone-DNA complex. The comparative properties of native and depleted chromatin with respect to sedimentation, thermal denaturation, and sensitivity to nuclease digestion have been studied. The changes in these properties resulting from removal of the linker histones are fully reversed when histone H5 is added back to the depleted chromatin.

Chromatin substructure: an electron microscopic study of thin-sectioned chromatin subjected to sequential protein extraction and water swelling procedures

Electron microscopic observations and measurements were made on thin-sectioned chromatin fibers and fibrils obtained from nuclei of mature chicken erythrocytes. The nuclei were isolated in low ionic strength gum arabic and octanol then extracted sequentially with (1) 0.14 M NaCl, (2) 0.25 N HCl, (3) buffer saturated phenol, (4) hot 5% SDS and 0.14 M 2-mercaptoethanol and, (5) 0.4 N NaOH. The amount of nuclear protein removed at each of the first four extraction steps was 1, 86, 3 and 11% of the total, respectively. Each extract was characterized by electrophoretic profiles. At each extraction the chromatin was fixed by adding large quantities of a mixture of equal volumes of sodium cacodylate buffered 8% (w/v) glutaraldehyde (pH 6.8) and 2% OsO4 (w/v), directly into (1) an aliquot of the chromatin in extraction fluid, and (2) an aliquot of the chromatin after water washing and swelling. Three size classes of chromatin structure were seen in thin sections prepared for high resolution transmission electron microscopy and stained with uranyl acetate and lead citrate. A thick fiber of about 25 + nm diameter was the predominant large fiber seen in freshly isolated nuclei or in nuclei after salt extraction. This 25 + nm fiber has a substructure consisting of 3.2-5.2 nm diameter fibrils. After water swelling of such freshly isolated or salt extracted nuclei a fiber of about 10 nm diameter was the predominant large fiber instead of the 25 nm diameter fiber. The HCl extraction step which is known to remove histones, caused the disappearance of both the 25 nm and the 10 nm fibers. High magnification (600,000 x) micrographs of the chromatin at all procedural steps, except the last NaOH step, reveal the fibril to be omnipresent. This fibril tends to decrease somewhat in diameter during the protein extraction steps to a 2.5 nm diameter fibril after the hot SDS extraction. A fibril of 2.5 nm diameter is expected of naked double helical DNA stained with a positive stain. The NaOH, which is known to denature DNA, completely destroyed the remaining fibril. We inerpret our results to indicate that the larger chromatin fiber seen in micrographs of thin-sectioned chromatin has a fibrillar substructure which probably represents a double coil of native DNA which may have a thin protein coating of its own. The latter fibril may in turn be wrapped around a hydrophobic histone domain, perhaps reflected in the 10 nm diameter fiber which is seen upon swelling of the chromatin. This 10 nm diameter fiber is thought to be further packaged by folding into the 25 + nm diameter chromatin fiber most frequently reported in thin sections of eukaryotic cell nuclei in situ.

DNAase hydrolysis of chromatin DNA in intact sea urchin sperm cells. Effect of the ionic strength on the digestion parameters

Chromatin DNA in intact functional Sphaerechinus granularis sperm cells has been digested with micrococcal nuclease at three different ionic strength conditions. The results show a highly-flexible chromatin organization similar to that found in sperm heads. The rate of digestion, the limit value of acid-soluble material and the fragmentation pattern show that the sensitivity of nucleosome and internucleosome DNA regions to nuclease hydrolysis depends on a delicate balance of polar and non polar interactions. At low ionic strength, both nucleosome and internucleosome regions are rapidly and completely hydrolysed at the same time and a transient subunit fragment of 120 b.p. average length is formed. At high ionic strength, internucleosome regions are preferentially hydrolysed; there is a limit digest value and a stable subunit fragment of 140 b.p. average length is formed. A supernucleosome organization in the high ionic strength environment of the sperm cells is suggested by the transient preferential formation of heptamers of nucleosome DNA fragments.

Two modes of aggregation of artificial H1-DNA complexes depending on the rate of decrease of ionic strength

The properties of H1-DNA artificial complexes, formed at different rates of decrease of NaCl concentration from 0.9 to 0.15 M, were investigated. It was found that two distinct processes, both depending on the rate of the concentration decrease, lead to the formation of aggregates differing in: the ability to form sediments, the distribution of sedimentation constants, the initial turbidity and its changes during trypsin and DNAase I digestion, and the H1/DNA ratio in the sediments. The accessibility of DNA in the complexes to DNAase I and the properties of nonaccessible DNA fragments led us to the conclusion that, at the H1/DNA ratio equal 0.2, the H1 molecules are clustered along the DNA chain independently of the rate of complex formation.

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.

An octamer of histones H3 and H4 forms a compact complex with DNA of nucleosome size

Equimolar mixtures of histones H3 and H4 have been reconstituted onto DNA of nucleosome core size. Two distinct complexes are formed in a relative abundance that depends on the starting ratio of H3 + H4 to DNA. One of these complexes contains two H3-H4 dimers for each DNA molecule, and has a sedimentation coefficient of 7.5S. The other complex contains an octamer consisting of four H3-H4 dimers, and has a sedimentation coefficient of 10.4S. On the basis of these measurements, we conclude that the octamer complex (but not the tetramer complex) is a fully folded, compact structure resembling the nucleosome.

The histone core complex: an octamer assembled by two sets of protein-protein interactions

A protein complex, extracted from calf thymus chromatin with 2 M NaCl, pH 7.5, containing approximately equal molar ratios of histones H2A, H2B, H3, and H4, has been characterized in this study. Gel filtration, sedimentation velocity, and sedimentation equilibrium experiments demonstrate that this complex, known as the core complex, has a molecular weight near that expected for a histone octamer (108 000 for a unit containing two each of the four inner histones) and far exceeding that of a histone tetramer (54 400). This finding suggests that the histone octamer, postulated to be the fundamental histone unit in chromatin, is stable in 2 M NaCl, pH 7.5, in the absence of DNA or chemical cross-linking reagents. In the second part of this study, we demonstrate that the bonds maintaining the octameric complex in 2 M NaCl are weak and distinctly different from the forces stabilizing the H2A-H2B dimer or H3-H4 tetramer. The octamer is dissociated into two H2A-H2B dimers and one H3-H4 tetramer by (i) increasing temperature; (ii) decreasing NaCl concentration; (iii) adding low concentrations of urea or guanidine hydrochloride; and (iv) lowering the pH below 7 or raising it above 10. These findings indicate that the octamer is assembled by two sets-of protein-protein interactions. The first set involves mostly hydrophobic interactions and yields the H2A-H2B dimer and the H3-H4 tetramer subunits. The second set involves the weak association of one H3-H4 tetramer with two H2A-H2B dimers to form an octamer. We suggest that these weak interactions might be derived predominantly from histidine-lysine or histidine-tyrosine hydrogen bonds between the dimer and tetramer subunits.

High-resolution proton-magnetic-resonance studies of chromatin core particles

The binding of histones in chromatin core particles and in core particles depleted of histones H2A and H2B has been studied by high-resolution proton nuclear magnetic resonance (NMR) at 270 MHZ. At low ionic strengths it is shown that histones H3 and H4 are bound in the core particle. Further, whereas the apolar regions of H2A and H2B are also bound to the core particle, the basic N-terminal and C-terminal regions are more mobile and give rise to sharp resonances in the NMR spectrum of the core particle. Between 0.3 and 0.6 M NaCl there is further release of basic regions of histones H3 and H4 from the complex. The dissociation of the core particle between 0.6 and 2.0 M NaCl is accompanied by the release of the structured apolar regions of the histones as evidenced by the appearance of a complex aromatic spectrum and perturbed upfield ring-current-shifted methyl resonances. Arginine residues are implicated in the binding between histones and DNA and 69% of these residues are found in the apolar regions of the histones. The interactions between histones and DNA in the core particle thus involves H3 and H4 and the apolar regions of H2A and H2B. It is suggested that these basic regions of H2A and H2B have binding sites outside the core particle.

Photochemical cross-linking of histones to DNA nucleosomes

Ultraviolet (UV)-induced cross-linking was utilized in order to identify histone-DNA interacting regions in the chromatin repeating unit. Fractionated mononucleosomes which contained 185 base pairs of DNA and a full complement of the histones, including histone H1, were irradiated with light of lambda greater than 290nm in the presence of a photosensitizer. Equimolar amounts of histones H2A and H2B were found, by two independent labeling experiments, to be cross-linked to the DNA. Based on previous finding that the UV irradiation specifically cross-links residues which are in close proximity, irrespective of the nature of the amino acid side chain or the nucleotide involved, our results indicate that the four core histones are not positioned equivalently with respect to the DNA. This arrangement allows histones H2A and H2B to preferentially cross-link to the DNA. A water soluble covalent complex of DNA and histones was isolated. This complex was partially resistant to mild nuclease digestion, it exhibited a CD spectrum similar to that of chromatin, and was found to contain histone H1. These results are compatible with a model which suggests that histone H1, though anchored to the linker, is bound to the DNA at additional sites. By doing so it spans the whole length of the nucleosome and clamps together the DNA fold around the histone core.

Protein kinase in HeLA nucleosomes: a reevaluation of the interactions of histomes with the ends of core particle DNA

HeLa chromatin core particles contain a protein kinase which transfers phosphate from ATP to both nonhistone proteins and histones. The enzyme preferentially modifies H3 among the histones; about 7% of the H3 molecules in the nucleoprotein are modified at saturation. Activity of this kinase likely contributed to earlier results using crosslinking methodology to study which histones interact with the ends of core particle DNA. When the kinase is largely removed by sedimentation of core particles through sucrose gradients containing 0.45 M NaCl, crosslinking of the 5'-terminal label on DNA is observed only to histone H3. The overall efficiency of the crosslinking reaction is about 15%. The origin of the 5'-terminal 32P previously assigned as crosslinked to H4 is not explained by the current experiments.

Structure of chromatin containing extensively acetylated H3 and H4

I have grown HeLa cells in 5 mM sodium n-butyrate leading to extensive in vivo histone acetylation, and have characterized the structure of chromatin containing the modified histones. Nuclear DNA in butyrate-treated cells is digested 5-10 fold more rapidly by DNAase I than the DNA of control cells. Staphylococcal nuclease degrades the two nuclear samples to acid-soluble material with identical rates; this nuclease, however, does excise nucleosomes with extensively acetylated histones from the nucleoprotein chain preferentially. The physical properties of unsheared chromatin and isolated core particles from control and butyrate-treated cells are closely similar, as are the rates of digestion of core particles from the two cell preparations by DNAase I. Determination of the relative susceptibilities of cleavage sites for DNAase I demonstrates that the site 60 bases from the ends of the DNA resistant in control cells, becomes susceptible to the nuclease in core particles containing acetylated histones. Similarly, the 5' terminal phosphate at the end of DNA in core prticles is removed by staphylococcal nuclease 2-3 fold faster in particles containing acetylated histones than in particles from control cells.

Closely spaced nucleosome cores in reconstituted histone.DNA complexes and histone-H1-depleted chromatin

It has been demonstrated by digestion studies with micrococcal nuclease that reconstitution of complexes from DNA and a mixture of the four small calf thymus histones H2A, H2B, H3, and H4 leads to subunits closely spaced in a 137 +/- 7-nucleotide-pair register. Subunits isolated from the reconstituted complex contain nearly equimolar amounts of the four histones and sediment at 11.6S. On DNase I digestion both the reconstituted complex and the separated subunits gave rise to series of single-stranded DNA fragments with a 10-nucleotide periodicity. This indicates that the reconstitution leads to subunits very similar to nucleosome cores. Nucleosome cores closely spaced in a 140-nucleotide-pair register were also obtained upon removal of histone H1 from chromatin by dissociation with 0.63 M NaCl and subsequent ultracentrifugation. In reconstitution experiments with all five histones (including histone H1) our procedure did not lead to tandemly arranged nucleosomes containing about 200 nucleotide pairs of DNA. In the presence of EDTA, DNase II cleaved calf thymus nuclei and chromatin at about 200-nucleotide-pair intervals whereas in the presence of Mg2+ cleavage at intervals of approximately half this size was observed. The change in the nature of the cleavage pattern, however, was no longer found after removal of histone H1 from chromatin. This indicates that H1 influences the accessibility of DNase II cleavage sites in chromatin. This finding is discussed with respect to the influence of histone H1 on chromatin superstructure.

Reconstitution of chromatin: assembly of the nucleosome

The order of reassociation of the four histones H2a, H2b, H3 and H4 to the DNA during the reconstitution of chromatin was determined. At each step of the reconstitution the DNA and associated histones were separated from the free histones by centrifugation in a glycerol gradient. The unbound and reassociated histones were analysed by gel electrophoresis and the histone-DNA complexes characterized by circular dichroism and electron microscopy. We show that H3 and H4 bind first to the DNA between 1.2 M NaCl and 0.85 M NaCl and impose a nucleosome like structure; in a second step histones H2a and H2b are placed around this kernel to complete the nucleosome.

Chromatin

The approximate shape of the chromatin subunit called the nucleosome is now known, but its internal architecture is not well understood. Recent studies reveal details of the organisation of DNA within the nucleosome, and show that the arginine-rich histones are essential to DNA folding. Nucleosomes or structures related to them seem to be present at points of DNA replication and transcription; interactions within and between nucleosomes are likely to play a critical part in these processes.

Inhibitory effect of histone on the peroxidase activity of the Hp/Hb complex

The human leukocyte nuclear histones can bind to haptoglobin (Hp), and thus interfere with subsequent binding of Hb. The Hp/Hb complex possesses peroxidase activity, but a Hp/histone complex does not. The inhibitory effect of histone molecules depends directly on the Hp and Hb, as well as the histone concentrations. The biological significance of the complex Hp/Hb as a measure of intravascular hemolysis and the interference of histones in this assay is briefly discussed.