Mode of reconstitution of chicken erythrocyte and reticulocyte chromatin

The mode of reconstitution of chicken erythrocyte and reticulocyte chromatin has been investigated. Chromatin was dissociated in 2 M NaCl, 5 M urea, and 0.01 M potassium phosphate (pH 7.2) and was dialyzed against various NaCl concentrations in 5 M urea and 0.01 M potassium phosphate (pH 7.2). Histone reassociation to DNA occurs with the binding of histone H5 at 0.5 M NaCl in 5 M urea, followed by histone H1 at 0.4 M NaCl in 5 M urea. All the classes of histones are reassociated with DNA at 0.2 M NaCl in 5 M urea and binding of all classes of histones is complete in 0.1 M NaCl and 5 M urea. Nonhistone proteins reassociate with DNA before and at the same time that histones reassociate with DNA. Binding of nonhistone proteins to DNA appears to be complete in 5 M urea and 0.01 M potassium phosphate (pH 7.2). There is also found in both erythrocyte and reticulocyte chromatin a nonhistone protein present in relatively high concentrations, which remains associated with DNA in 2 M NaCl and 5 M urea. This tightly bound protein appears as one major band when chromatographed on sodium dodecyl sulfate-polyacrylamide gels, with a molecular weight of 95 000. This protein is soluble in phenol and sodium dodecyl sulfate but is insoluble in 5 M urea or 4 M guanidine hydrochloride. A fraction of reticulocyte nonhistone proteins was found to bind to DNA-cellulose in 5 M urea. The majority of these proteins elute at 0.15 M NaCl in 5 M urea but a significant fraction elutes at NaCl concentrations at which the bulk of the histones do not bind to DNA. The proteins that bind to free DNA have low molecular weights and do not show species speciificity. Approximatley 50% of the reticulocyte nonhistone protein does not bind to a DNA-cellulose column in 5 M urea and may require histones for complete reassociation.     

Histone redistribution and conformational effect on chromatin induced by formaldehyde

Histone redistributions between endogenous DNA in calf thymus chromatin and exogenous DNA from Clostridium perfringens (69% A + T) or from Micrococcus luteus (30% A + T) induced by 0.6 M NaCl or by 2% formaldehyde were studied by thermal denaturation. The observed redistribution occurred on histone Hl when the exogenous DNA was (A + T)-richer than the DNA in chromatin, and when the mixture was exposed to 0.6 M NaCl or formaldehyde. When a (G + C)-richer DNA was added as the acceptor for histones, no substantial transfer of histones from chromatin DNA to exogenous DNA was found. Thus the activation energy of histone dissociation from chromatin DNA seems to be substantially lowered by 0.6 M NaCl or formaldehyde such that histones (mostly histone Hl) can be dissociated and bind the (A + T)-richer DNA and form a more stable complex. It is suggested that the formaldehyde effect on histones may be due to the loss of positive charges on lysine and arginin residues (probably more on lysine than on arginine) in histones after their rapid reaction with formaldehyde. Formaldehyde treatment of chromatin also distorts the DNA conformation, as revealed by circular dichroism (CD) studies. This structural effect occurs mainly on those base pairs bound by histones other than Hl, or within the chromatin subunit. Histone redistribution is treated as a thermodynamic phenomenon of histone binding to DNA. The validity of using formaldehyde to study chromatin structure is discussed.     

Interactions between arginine-rich histones and deoxyribonucleic acids. II. Circular dichroism

Circular dichroism (CD) was used to investigate the conformations of arginine-rich histones, H3 (III or f3) and H4 (IV or f2a1), and DNA in the complexes prepared by four different methods: (A) NaCl gradient dialysis with urea; (B) NaCl gradient dialysis without urea; (C) direct mixing in 2.5 x 10(-4) M EDTA, pH 8.0; and (D) direct mixing in 0.01 M sodium phosphate, pH 7.0. Using the CD spectrum of native chromatin as a criterion to judge the closeness of a complex to its native state, it was observed that a complex made by direct mixing at low ionic strength (methods C and D) is better than the ones made by NaCl gradient dialysis with or without urea (methods A and B). It is explained as a result of lack of ordered secondary structures in histones due to the presence of urea in method A or due to nonspecific aggregation in NaCl without urea (method B). Compared with all the earlier reports in literature on the CD of histone-DNA complexes, the CD spectra of arginine-rich histone-DNA complexes prepared by methods C and D are closest to that of native chromatin both in shape and in amplitude. These results imply (a) that arginine-rich histones play an important role in maintaining the conformation of chromatin and (b) that the binding of these two histones to DNA prepared by methods C and D are close to that in native chromatin. Noticeable variation in conformation of free and bound histone and histone-bound DNA has also been observed in histone H3 with one or two cysteine residues, and in reduced or oxidized state even when the complexes were prepared and examined in the same condition. CD spectra of arginine-rich histones in 0.01 M phosphates, pH 7.0, indicate the presence of alpha-helix which could be responsible for a favorable binding of the less basic regions of these histones to DNA under this condition as demonstrated by thermal denaturation (Yu, S. .S, Li H. J., and Shih, T. Y. (1976), Bio-chemistry, the preceding paper in this issue). To preserve or generate alpha-helical structures in histones seems to be a critical step in reconstituting good histone-DNA complexes.     

Conformational states of chromatin nu bodies induced by urea

Monomer chromatin nu bodies (nu1) from chicken erythrocyte nuclei were exposed to 0-10 M urea plus 0.2 mM EDTA (PH 7). Alterations in nu1 conformation were examined using hydrodynamic methods (i.e., S, eta, and (formula: see text)), thermal denaturation, circular dichroism, reactivity of histone thiol groups to N-ethyl maleimide, and electron microscopy. The two domains of a nu body (i.e., the DNA-rich shell and the protein-rich core) aeared to respond differently to the destabilizing effects of increasing urea; DNA conformation and stability exhibited noncooperative changes; the core protein structure revealed cooperative destabilization between 4 and 7 M urea. Companion studies on the conformation of the inner histone "heterotypic tetramer" also revealed cooperative destabilization with increasing urea concentration.     

Histone neighbors in nuclei and extended chromatin

Histone neighbors in compact and extended chromatin have been investigated by cross-linking histones in nuclei and in nucleohistone extended with 6 M urea, using the bifunctional reversible reagent methyl-4-mercaptobutyrimidate (MMB). Similar histone dimers are found in both conformational states of chromatin. The dimers most frequently found are H2b-H2a, H2b-H3 and H3-H2a; dimers found less frequently are H3-H4, H3-H3 and H2b-H4. More H3-H3 is found in nuclei than in extended chromatin. H1 is found predominantly as poly-H1, although it can be cross-linked to H2b or H3. After reaction with MMB, native compact chromatin is no longer extendable in 6 M urea, which shows that the reagent is capable of linking together histones holding the chromatin in a compact conformation. Thus the histone propinquity in extended chromatin mimics and intimate histone associations in compact chromatin.     

In vitro binding of H1 histone subtypes to nucleosomal organized mouse mammary tumor virus long terminal repeat promotor

The binding of all known linker histones, named H1a through H1e, including H1(0) and H1t, to a model chromatin complex based on a DNA fragment containing the mouse mammary tumor virus long terminal repeat promotor was systematically studied. As for the histone subtype H1b, we found a dissociation constant of 8-16 nM to a single mononucleosome (210 base pairs), whereas the binding constant of all other subtypes varied between 2 and 4 nM. Most of the H1 histones, namely H1a, H1c, H1d/e, and H1(0), completely aggregate polynucleosomes (1.3 kilobase pairs, 6 nucleosomes) at 270-360 nM, corresponding to a molar ratio of six to eight H1 molecules per reconstituted nucleosome. To form aggregates with the histones H1t and H1b, however, greater amounts of protein were required. Furthermore, our results show that specific types of in vivo phosphorylation of the linker histone tails influence both the binding to mononucleosomes and the aggregation of polynucleosomes. S phase-specific phosphorylation with one to three phosphate groups at specific sites in the C terminus influences neither the binding to a mononucleosome nor the aggregation of polynucleosomes. In contrast, highly phosphorylated H1 histones with four to five phosphate groups in the C and N termini reveal a very high binding affinity to a mononucleosome but a low chromatin aggregation capability. These findings suggest that specific S phase or mitotic phosphorylation sites act independently and have distinct functional roles.     

Effects of estrogen on gene expression in the chick oviduct. Isolation and fractionation of chromatin non-histone proteins

Non-histones isolated from hen oviduct chromatin have been fractionated by a variety of methods. Chromatin was dissociated in 2 M NaC1, 5 M Urea, 0.1% beta-mercaptoethanol and 0.01 M Tris - HC1, pH 8.3, and the DNA removed by ultracentrifugation. After desalting by gel filtration the chromatin proteins were separated into three distinct fractions by stepwise elution with 0.10 M NaC1, 0.25 M Na C1 and 15% guanidine - HC1 from Bio-Rex 70 columns. Fractions I and II contain only non-histones and Fraction III contains histones plus a small amount of non-histones. Further fractionation of the non-histones was achieved by ammonium sulfate precipitation and DEAE-cellulose chromatography for Fraction I and phosphocellulose chromatography and gel filtration on Bio-Gel A-15 m for Fraction II. The histone and non-histones present in Fraction III were separated by gel filtration on Bio-Gel A-0.5 m. All fractionation methods have been used preparatively with reasonable recoveries of protein (greater than or equal to 60%). The fractions have been characterized by acrylamide gel electrophoresis. The integrity of the histones was maintained during the fractionation procedure indicating that proteolytic degradation was unlikely to have occurred. There was no selective loss of chromatin proteins during the ultracentrifugation and desalting steps and the non-histones were separated into distinct fractions with enrichment of some species not apparent prior to fractionation of the chromatin proteins.     

Physicochemical properties of calcium phosphate coatings produced by pulsed laser deposition at different water vapour pressures

Conformational peculiarities of DNA complexes with histones of the H1 family have been studied by the method of circular dichroism (CD). The H1 histones were isolated from spermatozoa of the sea urchin Strongylocentrotus intermedius, starfish Aphelasterias japonica, and bivalve mollusc Chlamis islandicus and also from the rat thymus. It is shown that these sperm-specific histones do not compact DNA in low ionic strength solution. At physiologic conditions H1 from the sea urchin and starfish sperms compact DNA more intensively than other histones. The H1 from rat thymus has a minimum ability to compact DNA. This histone does not change the structure of DNA double helix. It was supposed that it could be associated with interactions of this histone with DNA in the major groove of its helix. At the same time sperm-specific H1 can interact with DNA not only in the major groove but also in the minor groove, and this induces changes in DNA structure. This DNA-protein interaction is specific for the sperm chromatin and may support the supercompact organization of the sperm chromatin.     

Histone synthesis in Trypanosoma cruzi

Trypanosoma cruzi is an ancient, parasitic eukaryote which does not undergo chromatin condensation during cell division. This behavior may be explained if one considers the strong amino acid sequence divergence of Trypanosoma histones compared to higher eukaryotes. In the latter organisms histone synthesis is coupled to DNA replication. Considering the nonconserved amino acid sequence of T. cruzi histones, as well as the absence of chromatin condensation in this organism, we have studied histone synthesis in relation to DNA replication in this parasite. We have found that core histones and a fraction of histone H1 are synthesized concomitantly to DNA replication. However, another fraction of histone H1 is constitutively synthesized.     

Association products and conformations of salt-dissociated and acid-extracted histones. A two-phase procedure for isolating salt-dissociated histones

We present an extremely rapid and efficient method for the separation of salt-dissociated histones from DNA in which the macromolecular components of chicken erythrocyte chromatin are partitioned in a two-phase system of the water-soluble, nonionic polymers, poly(ethylene glycol) and dextran. We have compared the association products and conformations of salt-dissociated histones purified with the two-phase procedure and histones that had been extracted with 0.4 M H2SO4. In the gel chromatography system of D. R. vander Westhuyzen and C. von Holt (1971), FEBS Lett. 14, 333-337] the association products of salt-dissociated and acid-extracted histones are indistinguishable. Furthermore, the circular dichroism spectra of histones prepared with the two methods are identical within experimental error. These results indicate that histones extracted, with sulfuric acid can adopt conformations at least very similar to those of salt-dissociated preperties of total erythrocyte histones are the same in 2 M NaCl as those of these histones bound to DNA in chromatin in 1 mM Tris-Cl (pH 7.5). This result and the studies of Weintraub et al. [Weintraub, H., Palter, K., and Van Lente, F. (1975), Cell 6, 68-110] on the patterns of tryptic digest products of histones strongly suggest that in 2 M NaCl the histones exist in conformations very similar to their conformations when bound to DNA. The concept of native histone conformations is discussed in light of our results.     

Linker histones stabilize the intrinsic salt-dependent folding of nucleosomal arrays: mechanistic ramifications for higher-order chromatin folding

Defined nucleosomal arrays reconstituted from core histone octamers and twelve 208 bp tandem repeats of Lytechinus 5S rDNA (208-12 nucleosomal arrays) possess the ability to form an unstable folded species in MgCl2 whose extent of compaction equals that of canonical higher-order 30 nm diameter chromatin structures [Schwarz, P. M., and Hansen, J. C. (1994) J. Biol. Chem. 269, 16284-16289]. To address the mechanistic functions of linker histones in chromatin condensation, purified histone H5 has been assembled with 208-12 nucleosomal arrays in 50 mM NaCl. Novel purification procedures subsequently were developed that yielded preparations of 208-12 chromatin model systems in which a majority of the sample contained both one histone octamer per 5S rDNA repeat and one molecule of histone H5 per histone octamer. The integrity of the purified 208-12 chromatin has been extensively characterized under low-salt conditions using analytical ultracentrifugation, quantitative agarose gel electrophoresis, electron cryomicroscopy, and nuclease digestion. Results indicate that histone H5 binding to 208-12 nucleosomal arrays constrains the entering and exiting linker DNA in a way that produces structures that are indistinguishable from native chicken erythrocyte chromatin. Folding experiments performed in NaC1 and MgC12 have shown that H5 binding markedly stabilizes both the intermediate and extensively folded states of nucleosomal arrays without fundamentally altering the intrinsic nucleosomal array folding pathway. These results provide new insight into the mechanism of chromatin folding by demonstrating for the first time that distinctly different macromolecular determinants are required for formation and stabilization of higher-order chromatin structures.     

Interaction of non-histone chromosomal proteins HMG1 and HMG2 with DNA

Interaction between non-histone protein HMG1 or HMG2 and DNA has been studied by using thermal denaturation and circular dichroism (CD) spectroscopy. We have made the following observations. 1. The binding of each of these two proteins to DNA stabilizes the latter, as shown by an increase in melting temperature of 20 degrees C (from 45 degrees C to about 65 degrees C). 2. There are 6.0 amino acids/nucleotide in HMG1-bound DNA and 5.0 in HMGI-bound DNA which suggests that each HMB1 moleculae would cover about 20 base pairs of DNA and each HMG2 molecule would cover about 25 base pairs. 3. The alpha-helical content of these two non-histone proteins in the complexes, estimated from the CD value at 220 nm, is about one third to one half that of total proteins in calf thymus chromatin. 4. DNA conformation is distorted only slightly by the binding of protein HMG1 or HMG2. 5. Neither the melting nor the CD properties of HMG1-DNA or HMG2-DNA complexes differ substantially whether they are prepared by NaCl-gradient dialysis in urea or by direct mixing of protein and DNA at 0.15 M NaCl, followed by dialysis against the same buffer i.e. 0.25 mM EDTA (pH 8.0).     

Changes in size and shape of chromatin particles after successive removal of histones

The preparations of whole chromatin, chromatin selectively depleted of histone f1, depleted of all lysine-rich histones (f1, f2b, f2a2), and DNA was studied by viscosimetric and light scattering methods. The obtained results were used for calculation of the dimensions and packing ratios of DNA for the preparations studied. The packing ratio in whole chromatin is 7.2 and is almost unaffected by selective removal of histone f1 (6.9), but decreases on successive removal of the remaining four histones, the decrease being dependent more on the quantity than the kind of the dissociated histones.     

Histones H1 and H5 interact preferentially with crossovers of double-helical DNA

The interaction of the linker histones H1 and H5 from chicken erythrocyte chromatin with pBR322 was studied as a function of the number of superhelical turns in circular plasmid molecules. Supercoiled plasmid DNA was relaxed with topoisomerase I so that a population with a narrow distribution of topoisomers, containing from zero to five superhelical turns, was obtained. None of the topoisomers contained alternative non-B-DNA structures. Histone-DNA complexes formed at either 25 or 100 mM NaCl final concentration and at histone-DNA molar ratios ranging from 10 to 150 were analyzed by agarose gel electrophoresis. The patterns of disappearance of individual topoisomer bands from the gel were interpreted as an indication of preference of the linker histones for crossovers of double-helical DNA. This preference was observed at both salt concentrations, being more pronounced under conditions of low ionic strength. Isolated H5 globular domain also caused selective disappearance of topoisomers from the gel, but it did so only at very high peptide-DNA molar ratios. The observed preference of the linker histones for crossovers of double-helical DNA is viewed as a part of the mechanism involved in the sealing of the two turns of DNA around the histone octamer.     

Ethidium bromide as a probe of conformational heterogeneity of DNA in chromatin. The role of histone H1

The accessibility and the tertiary structure of the DNA inside chromatin were studied by using ethidium bromide (EB) as a fluorescent probe. The exclusion model of binding was refined by introductina a parameter alpha (0less than alpha less than 1) which measures the accessibility of the DNA and by taking into account when necessary the existence of two sets of binding sites. We were thus able to fit predicted and experimental isotherms and then to describe completely EB binding to native or partially histone depleted chromatin under various conditions. Itn native chromatin 95% of the DNA (alpha = 0.95) appears to be accessible to EB but two sets of sites are present. The first one corresponds to alpha = 0.13 and is characterized by an affinity constant which is higher by two orders of magnitude than that relative to pure DNA. The second set corresponds to alpha = 0.82 and the corresponding binding constant is only three or four times lower than that of pure DNA. The sites with high affinity are still present after treatment with formaldehyde but disappear after removal of histon H1. By comparison with chromatin treated with deoxycholate of with artifical complexes between H1 and DNA, high affinity sites were found only when all of the histons are bound to DNA. An alpha value around 0.8 is still obtained in 1 M NaC1 treated chromatin, pointing to the fact that histones H3 and H4 are preventing 20% of the DNA to intercalate EB.     

The in situ labeling of histone H3 in chromatin by a fluorescent probe

A sulfhydryl-specific fluorescent probe, N-3-pyrene maleimide, has been shown to label with high efficiency the sulfhydryl groups of histone H3 in nonsheared chromatin. The probe labels chromatin preparations obtained by mild homogenization or nuclease treatment of rat liver and mouse thymocyte, but not chick erythrocyte nuclei. Mononucleosomes from all nuclear preparations are labeled by the probe. The reaction is inhibited by prior reaction of the chromatin with N-ethyl maleimide. The reaction kinetics show fast and slow components representing reactions with cysteinyl sulfhydryl groups and lysyl epsilon-amino groups, respectively. Dissociation of the chromatin by urea (6 M) or sodium dodecyl sulfate (SDS) increases the fluorescence intensity (2-3 fold) and is maximal at approx. 0.01-0.02% (w/v) SDS. Histones extracted from the labelled chromatin show that approx. 80-90% of the label is associated with the histone fraction and column chromatography of this fraction shows that the label is primarily associated with histone H3. Labelling of the isolated histone fractions shows significant labelling only of histone H3. The intrinsic fluorescence of tryptophan is quenched by the labelled histone H3, but not by iodide, suggesting that non-histone (tryptophan-containing) proteins lie in close proximity to the labelled histone H3 but are not immediately accessible to external solvent. The labelled chromatin exhibits fluorescence anistropy, the anistropy parameter being 0.19 +/- 0.003 for chromatin, 0.05 +/- 0.01 for mononucleosomes and 0.0 for isolated histone H3. This demonstrates the restriction placed on the label's mobility by the chromatin fiber. The formation of a superhelix at 60-100 mM NaCl has been monitored with the probe. An increase in fluorescence intensity at 80 mM NaCl is observed with intact chromatin (but not H-1 depleted chromatin) followed by dissociation of the octamer in 1.50-2.0 M salt accompanied by a large increase in labelling.