Core nucleosomes by digestion of reconstructed histone-DNA complexes.

Reconstructed complexes of the inner histones (H2A, H2B, H3, H4) and a variety of DNAs were digested with micrococcal nuclease to yield very homogeneous populations of core nucleosomes (nu 1). Nucleosomes containing Micrococcus luteus DNA (72% G+C); chicken DNA (43% G+C), Clostridium perfringens DNA (29% G+C); or poly(A-dT.poly(dA-dT) have been examined by circular dichroism, thermaldetenaturation, electron microscopy, and DNAse I digestion. Circular dichroism spectra of all particles show a typically suppressed ellipticity at 260--280 nm and a prominent alpha-helix signal at 222 nm. All particles show biphasic melting except nu 1 (dA-dT), which show three prominent melting transitions at ionic strength less than or equal to 1 mM. DNAse I digestion of nu 1 (dA-dT) produces a ladder of DNA fragments fiffering in lengthy by one base residue. nu 1 (dA-dT) contain 146 base pairs of DNA and exhibit an average DNA helix pitch of 10.4-10.5 bases per turn. There appear to be two regions of different DNA pitch wihtin nu 1 (dA-dT). It is suggested that the two regions of DNA pitch might correspond to the two regions of the melting profiles.     

Binding of phosphorylated histone H1 to DNA.

A chromatin associated protein kinase was used to add 3 moles of phosphate to seryl side chains of 1 mole of histone H1. The DNA binding properties of this in vitro phosphorylated H1 were compared with those of unmodified H1. Considerably more radioactive superhelical DNA was retained on nitrocellulose filters at 20mM-40mM NaCl by phosphorylated H1 than by unmodified H1. However, zone velocity sedimentation analysis of histone-DNA complexes indicated that similar amounts of phosphorylated and unmodified H1 are bound to DNA. It is therefore concluded that phosphorylated H1 binds distributively to many or all DNA molecules available (depending on the histone/DNA ratio) while unmodified H1 binds cooperatively to a fraction of the DNA molecules in the reaction mixture.     

Structure of subnucleosomal particles. Tetrameric (H3/H4)2 146 base pair DNA and hexameric (H3/H4)2(H2A/H2B)1 146 base pair DNA complexes

The tetrameric (H3/H4)2 146 base pair (bp) DNA and hexameric (H3/H4)2(H2A/H2B)1 146 bp DNA subnucleosomal particles have been prepared by depletion of chicken erythrocyte core particles using 3 or 4 M urea, 250 mM sodium chloride, and a cation-exchange resin. The particles have been characterized by cross-linking and sedimentation equilibrium. The structures of the particles, particularly the tetrameric, have been studied by sedimentation velocity, low-angle neutron scattering, circular dichroism, optical melting, and nuclease digestion with DNase I, micrococcal nuclease, and exonuclease III. It is concluded that since the radius of gyration of the DNA in the tetramer particle and its maximum dimension are very close to those of the core particle, no expansion occurs on removal of all the H2A and H2B. Nuclease digestion results indicate that histones H3/H4 in the tetramer particle protect a total of 70 bp of DNA that are centrally located within the 146 bp. Within the 70 bp DNA length, the two terminal regions of 10 bp are, however, not strongly protected from digestion. The optical melting profile of both particles can be resolved into three components and is consistent with the model of histone protection of DNA proposed from nuclease digestion. The structure proposed for the tetrameric histone complex bound to DNA is that of a compact particle containing 1.75 superhelical turns of DNA, in which the H3 and H4 histone location is the same as found for the core particle in chromatin by histone/DNA cross-linking [Shick, V. V., Belyavsky, A. V., Bavykin, S. G., & Mirzabekov, A. D. (1980) J. Mol. Biol. 139, 491-517]. Optical melting of the hexamer particle shows that each (H2A/H2B)1 dimer of the core particle protects about 22 base pairs of DNA.     

Nucleosome mono, di, tri-, and tetramers from chicken embryo chromatin.

The fractionation of gram quantities of nuclease digested chromatin from chicken embryos into nucleosome mono-, di-, tri-, and tetramers is described in detail. Each of these nucleosomal species contains a fraction soluble in 0-1 M KC1 that decreases with increasing repeat number. Less histone H1 is associated with the nucleosome fractions soluble as compared to the respective fractions precipitated in 0.1 M KC1. Thermal denaturation profiles of the four nucleosomal species are monophasic. The same Tm of 78 degrees C has been determined for the KC1-soluble nucleosomes and for the KC1-insoluble monomer. The Tm of the KC1-insoluble oligomers is 79.8 degrees C. Multiphasic melting curves were recorded for nucleosomal material that was concentrated by lyophilisation or stored at 4 degrees C in 0.25 mM EDTA. Total nucleosome mono-, di-, tri-, and tetramers (consisting of both the fraction soluble and insoluble in 0.1 M KC1) have been analyzed concerning their sedimentation, diffusion, partial specific volume, and molecular weight and compared with the sedimentation and molecular weight data of KC1-soluble nucleosome mono- and tetramers.     

Histones H2A and H2B are neighbors along DNA in chromatin: characterization of subnucleosomal particles containing H2A+H2B.

Two specific slow sedimenting nucleoprotein particles containing equimolar amounts of histones H2A and H2B and 38 or 49 base pair (bp) lengths of DNA have been isolated by centrifugation on sucrose gradients. The 3.4S particles containing 38 bp DNA and H2A+H2B thermally denature at 61 degrees, considerably higher than Proteinase K treated particles (44 degrees), but lower than 11S nucleosomes (76 degrees). Treatment with Proteinase K increases the circular dichroism of 3.4S particles at 280 nm by 63% and decreases the sedimentation coefficient to 2.1S. These results indicate that H2A and H2B are proximate along DNA in nucleosomes and alone can alter the optical activity and perhaps conformation of local regions of DNA.     

Isolation of a chromatin fraction from calf endometrium highly enriched in estradiol binding sites.

The intranuclear distribution of [3H]-estradiol binding sites was studied in highly purified nuclei isolated from calf endometrial tissue pre-incubated with the labeled hormone. The major part (approximately 85%) of the receptor bound estradiol was found associated with the extranucleolar chromatin; only a negligible amount of [3H]-estradiol (approximately 8%) sedimented with the nucleolar fraction. [3H]-estradiol labeled chromatin was then fragmented by sonication and fractionated by sucrose density gradient sedimentation under different conditions of centrifugation. The vast majority of the [3H]-estradiol was invariably found to be associated with a fast sedimenting fraction which contained only 5 to 10% of the nuclear DNA. The concentration of estradiol receptors (per weight of DNA) in this fraction was 25- to 50-fold higher than that found in the slow sedimenting major chromatin component. Chemical analysis showed this fraction to have a high protein/DNA ratio but no phospholipids were detected.     

Association of nucleosome core particle DNA with different histone oligomers. Transfer of histones between DNA-(H2A,H2B) and DNA-(H3,H4) complexes

In non-denaturing low ionic strength gels, the titration of core DNA with H2A,H2B produces five well-defined bands. Quantitative densitometry and cross-linking experiments indicate that these bands are due to the successive binding of H2A,H2B dimers to core DNA. Only two bands are obtained with DNA-(H3,H4) samples. The slower of these bands is broad and presumably corresponds to two complexes containing one and two H3,H4 tetramers, respectively. In gels of higher ionic strength, DNA-(H2A,H2B) samples produce an ill-defined band, suggesting that the lifetime of the complexes containing H2A,H2B is relatively short. However, the low intensity of the free DNA band observed in these gels indicates that most of the DNA is associated with H2A,H2B. In agreement with this, our results obtained using different techniques (sedimentation, cross-linking, trypsin and nuclease digestions, and thermal denaturation) demonstrate that the association of H2A,H2B with core DNA occurs in free solution in both the absence and presence of NaCl (0.1 to 0.2 M). The low mobilities of DNA-(H2A,H2B) complexes, together with sedimentation and DNase I digestion results, indicate that the DNA in these complexes is not folded into the compact structure found in the core particle. Furthermore, non-denaturing gels have been used to study the dynamic properties of DNA-(H2A,H2B) and DNA-(H3,H4) complexes in 0.2 M-NaCl. Our results show that: (1) H2A,H2B and H3,H4 can associate, respectively, with DNA-(H3,H4) and DNA-(H2A,H2B) to produce complexes containing the four core histones; (2) DNA-(H2A,H2B) and DNA-(H3,H4) are able to transfer histones to free core DNA; (3) an exchange of histone pairs takes place between DNA-(H2A,H2B) and DNA-(H3,H4) and produces complexes with the same histone composition as that of the normal nucleosome core particle; and (4) although both histone pairs can exchange, histones H2A,H2B show a higher tendency than H3,H4 to migrate from one incomplete core particle to another. The complexes produced in these reactions have the same compact structure as reconstituted core particles containing the four core histones. Our kinetic results are consistent with a reaction mechanism in which the transfer of histones involves direct contacts between the reacting complexes. The possible participation of these spontaneous reactions on the mechanism of nucleosome assembly is discussed.     

Rearrangement of nucleosomal components by modification of histone amino groups. Structural role of lysine residues

Modification of nucleosomal particles from chicken erythrocytes with the reagents for protein amino groups acetic and dimethylmaleic anhydrides causes a rearrangement of nucleosomal components. Treatment with both reagents is accompanied by liberation of free DNA and formation of residual particles with anomalous histone composition. The residual particles obtained with acetic anhydride contain an excess of histones corresponding to the free DNA produced. In contrast, dimethylmaleic anhydride causes release of histones H1, H5, H2A and H2B and formation of residual particles deficient in these histones but containing an excess of H3 and H4 corresponding to the liberated DNA. Regeneration of the modified amino groups of nucleosomal preparations treated with dimethylmaleic anhydride is accompanied by reconstitution of nucleosomal particles with the sedimentation coefficient and composition of core histones of the original nucleosomes. This reconstitution does not occur when the released fraction containing histones H2A and H2B and free DNA is separated from the residual particles. The studied disassembly of nucleosomal particles obtained by specifically blocking lysine-DNA interactions with these reagents appears to indicate that lysine residues are essential for the binding of DNA to histones with formation of nucleosomal particles.     

Physical properties of inner histone-DNA complexes.

Chicken-erythrocyte inner histone tetramer has been complexed with several natural and synthetic DNA duplexes by salt-gradient dialysis at various protein/DNA ratios. The resulting complexes, in low-ionic-strength buffer, have been examined by electron microscopy, circular dichroism, and thermal denaturation. Electron microscopy reveals nucleosomes (nu bodies) randomly arranged along DNA fibers, including poly(dA-dT)-poly(dA-dT), poly(dI-dC)-poly(dI-dC), but not poly(dA)-poly(dT). Circular dichroism studies showed prominent histone alpha-helix and "suppression" of nucleic acid ellipticity (lambda less than 240 nm). Thermal denaturation experiments revealed Tm behavior comparable to that of H1- (or H5-) depleted chromatin. Tm III and Tm IV increased linearly with G + C%(natural DNAs), but were virtually independent of the histone/DNA ratio; therefore, the melting of nucleosomes along a DNA chain is insensitive to adjacent "spacer" DNA lengths. This suggests that Tm III and Tm IV arise from the melting of different domains of DNA associated with the core nu body.     

Isolation and characterization of chromatin subfractions from rat liver

Rat-liver chromatin was digested with micrococcal nuclease at low ionic strength in the presence of a low concentration of CaCl2. The nuclease digest was successfully separated into three fractions, P1, P2, and P3, by gel filtration on a column of Sepharose 2B. P1 fraction was shown to be a mixture of long fragments of partially digested chromatin by the sedimentation profile or by electrophoresis of DNA. P2 fraction contained four histones H2A, H2B, H3, and H4 in almost equal amounts, together with nonhistone protein of low molecular weight. The DNA was composed of three or four fragments less than 300 base pairs long. From the Kav value of the P2 fraction, the average size was estimated to be about 240 base pairs. On analytical ultracentrifugation, this fraction exhibited a monophasic boundary and a sedimentation value of 13.7S. P3 fraction contained nonhistone proteins which showed a molecular weight larger than that of H1 histone. The size of DNA was estimated to be less than 50 base pairs from the Kav value. Based on these results, the P2 fraction was concluded to consist of nucleosome monomer enriched in nonhistone proteins. The P3 fraction is presumably the nuclease-sensitive or internucleosome portion, which contains small amounts of nonhistone proteins.     

DNA crosslinks,single-strand breaks and effects on bacteriophage T4 survival from tritium decay of [2-3H]adenine, [8-3H]adenine and [8-3H]guanine

Escherichia coli and bacteriophage T4 DNA containing [2-³H]adenine accumulated crosslinks between the complementary strands. For T4 DNA stored in frozen solution there were 0.41 to 0.54 crosslinks formed per tritium decay. The crosslinks were demonstrated both by an increased DNA sedimentation rate in alkaline sucrose gradients and by an increasing amount of DNA that renatured quickly after denaturation by heat or alkali. Single-strand breaks were also formed with an efficiency of 0.08 to 0.50 breaks per tritium decay. DNA containing both [8-³H]adenine and [8-³H]guanine showed no crosslinking but did undergo single-strand breaks at a rate of 0.08 per tritium decay. T4 bacteriophage containing [2-³H]adenine lost plaque-forming ability when stored at 4 °C, with 0.34 lethal hits per tritium decay, whereas the same phage labeled with a mixture of [8-³H]adenine and [8-³H]guanine sustained only 0.12 lethal hits per tritium decay. The loss of plaque-forming ability in the latter case is probably due to a radiation effect from the emitted beta particle; the high lethal efficiency for tritium decay at 2-adenine is probably caused either by crosslinks between complementary strands or from some undetected lesion produced in the DNA.     

The presence of RNA in a double helix inhibits its interaction with histone protein

The binding of core histones (H2A, H2B, H3, H4) to a circular plasmid DNA and to a circular DNA-RNA hybrid molecule of similar size has been compared. Circular hybrid molecules were formed from single stranded fd DNA by synthesis of the complimentary strand with ribonucleotides using wheat germ RNA polymerase II. Upon reconstitution of plasmid DNA circles with histone, the sedimentation profiles of the DNA remained sharp by increased several fold in rate. Material from the peak fractions of these sedimentations appeared to be condensed circular loops of nucleosomes when examined by electron microscopy (EM), and the mass ratio of DNA to histone (at the histone concentrations which produced the fastest sedimentations) was typical of native chromatin. In contrast, the sedimentation behavior of DNA-RNA hybrid circles after addition of histone remained unchanged except for a minor fraction which exhibited a broad and faster sedimentation rate. Examination by EM revealed that most of the molecules appeared identical to protein free hybrid circles while the minor, faster sedimenting fraction appeared to be two or more circles bound together by protein aggregates. Finally, a linear molecule consisting of about 3000 base pairs of duplex DNA covalently joined on both ends to 1500 base pairs of RNA-DNA hybrid helix was constructed. Reconstitution of this molecule with core histone showed nucleosome formation only on the central DNA duplex region. Isopycnic banding of fixed hybrid-histone mixtures showed that little or no histone had bound to the bulk of the full hybrid molecules. We suggest that the presence of RNA in a nucleic acid duplex inhibits the condensation of the duplex into a nucleosomal structure by histone.     

Metabolic Fate of [3H]1-β-d-Arabinofuranosyl-5-[(E)-2-bromovinyl]uracil in Herpes Simplex Virus Type 1-Infected Cells

The metabolic fate of 1-β-d -arabinofuranosyl-5-[(E)-2-bromovinyl]uracil (BV-araU) in herpes simplex virus type 1-infected cells was studied using tritium-labeled BV-araU. [³H]BV-araU was selectively taken-up by infected cells. Approximately 10% of the total uptake of [³H]BV-araU was recovered from the acid-insoluble fraction at any time post-infection. Both cellular uptake of [³H]BV-araU and its incorporation into the acid-insoluble fraction increased with increasing incubation time through 8 hr post-infection. Uptake of [³H]BV-araU and its incorporation into the acid-insoluble fraction also increased proportionally to the duration of exposure to [³H]BV-araU. An alkaline sucrose gradient sedimentation analysis revealed that the radioactive DNA obtained from cells pulse-labeled with [³H]BV-araU were small DNA fragments which remained at the top following a chasing period in isotope-free medium, whereas that pulse-labeled with [³H]thymidine was chased to a fraction of high molecular weight DNA. Nuclease P₁ digestion reduced 99% of the [³H]BV-araU-labeled DNA extracted from infected cells to a low molecular weight. Following digestion of [³H]BV-araU-labeled DNA with micrococcal nuclease and spleen exonuclease, all of the radioactivity was recovered as [³H]BV-araU 3′-monophosphate. Thus, BV-araU strongly inhibits the elongation of viral DNA strands as demonstrated by the alkaline sucrose gradient sedimentation analysis, whereas at least a portion of the [³H]BV-araU is incorporated inside viral DNA strands in infected cells.     

Use of ethidium bromide fluorescence enhancement to detect duplex DNA and DNA bacteriophages during zone sedimentation in sucrose gradients: molecular weight of DNA as a function of sedimentation rate

Duplex DNA molecules and DNA bacteriophages have been sedimented through 5--25% sucrose gradients containing ethidium bromide. The location of DNA within the gradients has been determined by illuminating gradients with ultraviolet light and observing the ethidium bromide fluorescence enhancement induced by the DNA. The relative sedimentation rates of linear, duplex DNAs from bacteriophages T4, T5, T7 and an 8.3% T7 deletion mutant have been determined. The distances sedimented by DNA have been corrected, when necessary, for a progressive decrease in sedimentation rate that occurs after the DNA has traversed 40% of the sucrose gradient. The corrected distances sedimented by two DNA molecules, r1' and r2', are related to the DNA molecular weights, m1 and m2, by the equation: r1'/r2' = (m1/m2)0.38 when 0.025--0.70 microgram of each type of DNA is sedimented. Intact bacteriophages were also sedimented in ethidium bromide--sucrose gradients and detected by fluorescence enhancement.     

Fragmentation of chromatin with 125I radioactive disintegrations.

The DNA in Chinese hamster cells was labeled first for 3 h with [3H]TdR and then for 3 h with [125I]UdR. Chromatin was extracted, frozen, and stored at -30 degrees C until 1.0 X 10(17) and 1.25 X 10(17) disintegrations/g of labeled DNA occurred for 125I and 3H respectively. Velocity sedimentation of chromatin (DNA with associated chromosomal proteins) in neutral sucrose gradients indicated that the localized energy from the 125I disintegrations, which gave about 1 double-strand break/disintegration plus an additional 1.3 single strand breaks, selectively fragmented the [125I] chromatin into pieces smaller than the [3H] chromatin. In other words, 125I disintegrations caused much more localized damage in the chromatin labeled with 125I than in the chromatin labeled with 3H, and fragments induced in DNA by 125I disintegrations were not held together by the associated chromosomal proteins. Use of this 125I technique for studying chromosomal proteins associated with different regions in the cellular DNA is discussed. For these studies, the number of disintegrations required for fragmenting DNA molecules of different sizes is illustrated.     

The assembly of an H2A2,H2B2,H3,H4 hexamer onto DNA under conditions of physiological ionic strength

A novel nucleohistone particle is generated in high yield when a complex of DNA with the four core histones formed under conditions that are close to physiological (0.15 M NaCl, pH 8) is treated with micrococcal nuclease. The particle was found to contain 102 base pairs of DNA in association with six molecules of histones in the ratio 2H2A:2H2B:1H3:1H4 after relatively brief nuclease treatment. Prolonged nuclease digestion resulted in a reduction in the DNA length to a sharply defined 92-base pair fragment that was resistant to further degradation. Apparently normal nucleosome core particles containing two molecules each of the four core histones in association with 145 base pairs of DNA and a particle containing one molecule each of histones H2A and H2B in association with approximately 40 base pairs of DNA were also generated during nuclease treatment of the histone-DNA complexes formed under physiological ionic strength conditions. Kinetic studies have shown that the hexamer particle is not a subnucleosomal fragment produced by the degradation of nucleosome core particles. Furthermore, the hexamer particle was not found among the products of nuclease digestion when histones and DNA were previously assembled in 0.6 M NaCl. The high sedimentation coefficient of the hexameric complex (8 S) suggests that the DNA component of the particle has a folded conformation.     

Different mechanism for in vitro formation of nucleosome core particles

The interaction of different histone oligomers with nucleosomes has been investigated by using nondenaturing gel electrophoresis. In the presence of 0.2 M NaCl, the addition of the pairs H2A,H2B or H3,H4 or the four core histones to nucleosome core particles produces a decrease in the intensity of the core particle band and the appearance of aggregated material at the top of the gel, indicating that all these histone oligomers are able to associate with nucleosomes. Equivalent results were obtained by using oligonucleosome core particles. Additional electrophoretic results, together with second-dimension analysis of histone composition and fluorescence and solubility studies, indicate that H2A,H2B, H3,H4, and the four core histones can migrate spontaneously from the aggregated nucleosomes containing excess histones to free core DNA. In all cases the estimated yield of histone transfer is very high. Furthermore, the results obtained from electron microscopy, solubility, and supercoiling assays demonstrate the transfer of excess histones from oligonucleosomes to free circular DNA. However, the extent of solubilization obtained in this case is lower than that observed with core DNA as histone acceptor. Our results demonstrate that nucleosome core particles can be formed in 0.2 M NaCl by the following mechanisms: (1) transfer of excess core histones from oligonucleosomes of free DNA, (2) transfer to excess H2A,H2B and H3,H4 associated separately with oligonucleosomes to free DNA, (3) transfer to excess H2A,H2B initially associated with oligonucleosomes to DNA, followed by the reaction of the resulting DNA-(H2A,H2B) complex with oligonucleosomes containing excess H3,H4, and (4) a two-step transfer reaction similar to that indicated in (3), in which excess histones H3,H4 are transferred to DNA before the reaction with oligonucleosomes containing excess H2A,H2B. The possible biological implications of these spontaneous reactions are discussed in the context of the present knowledge of the nucleosome function.