Interactions between core histones and chromatin at physiological ionic strength

Addition of core histones to chromatin or chromatin core particles at physiological ionic strength results in soluble nucleohistone complexes when polyglutamic acid is included in the sample. The interaction between nucleosomes and added core histones is strong enough to inhibit nucleosome formation on a closed circular DNA in the same solution. Complexes consisting of core particles and core histones run as discrete nucleoprotein particles on polyacrylamide gels. Consistent with the electrophoretic properties of these particles, protein cross-linking with dimethyl suberimidate indicates that added core histones are bound as excess octamers. Histones in the excess octamers do not exchange with nucleosomal core histones at an ionic strength of 0.1 M and can be selectively removed from core particles by incubating the complexes in a solution containing sufficient DNA. Under conditions where added histones are confined to the surface of chromatin, the excess histones are mobile and can migrate onto a contiguous extension of naked DNA and form nucleosomes.     

Nucleosomal structure of two Drosophila melanogaster simple satellites

Nucleosomes have been fractionated on nondenaturing polyacrylamide gels, and nucleosome subtypes containing the Drosophila melanogaster specific protein D1 and ubiquitinated core histone H2A were identified by solubility in 0.1 M NaCl before nucleoprotein gel electrophoresis. Nucleosomes which contain DNA complementary to the 1.672 density simple satellite (sequence-AATAT-) bind protein D1, as demonstrated by two-dimensional hybridization mapping. This hybridization pattern allows the identification of D1 dinucleosomes, which, like D1 mononucleosomes, are reduced in mobility on the first dimension (nucleoprotein) gel by the addition of D1, an AT sequence-specific DNA-binding protein. The 1.705 density simple satellite (sequence-AAGAG-) is also found in nucleosomes, in a radically different subset from those of the -AATAT- DNA sequence. -AAGAG- nucleosomes do not contain D1 protein, but appear to be enriched in ubiquitinated core histone H2A. One-dimensional hybridization patterns suggest that -AAGAG- nucleosomal DNA is rapidly trimmed to a shorter DNA length than either bulk or -AATAT- nucleosomes.     

Parental adenovirus DNA accumulates in nucleosome-like structures in infected cells.

Micrococcal-nuclease digestion of adenovirus 2(ad 2) infected HeLa cell nuclei early after infection has been used to investigate the nucleoprotein nature of parental viral DNA. Viral DNA is more susceptible to nuclease digestion than cellular DNA. The pattern of digestion products changes as digestion proceeds from an indistinct pattern 1 hour post infection(pi) to a nucleosome-like pattern at 6 hours pi. The major differences between viral and cellular nucleoprotein products were i) a subnucleosome fraction from viral DNA and ii) the repeat size of DNA in viral nucleosomes was 165 base pairs and in cellular nucleosomes, 195 base pairs. Up to 50% viral DNA in nuclei 6 hours pi seems to be in nucleosome-like structures. Such patterns are not seen on digestion of partially-uncoated virus or isolated cores.     

The sites of deposition of newly synthesized histone.

The chromosomal fragments produced by nuclease digestion of freshly replicated chromatin migrate more rapidly relative to bulk chromatin when analyzed in nucleoprotein gels. The cause of the anomalous migration has been studied and the evidence indicates that rather than reflecting a shorter nucleosomal repeat in vivo that it may be a consequence of nucleosome sliding during the digestion itself. The distinct electrophoretic characteristics of nucleosomal material containing newly replicated DNA have enabled us to examine their histone composition by two dimensional electrophoresis. We find that nucleosomes containing new DNA also contain newly synthesized histones H3 and H4. In contrast more than 50% of newly synthesized H2A and H2B, and essentially all of new H1, are deposited at sites on the bulk chromatin distinct from that material containing newly replicated DNA. In addition we show that newly synthesized histones H3 and H4 are bound unusually weakly when they first become associated with the chromatin.     

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.     

Chromatin assembly in isolated mammalian nuclei.

Cellular DNA replication was stimulated in confluent monolayers of CV-1 monkey kidney cells following infection with SV40. Nuclei were isolated from CV-1 cells labeled with [3H]thymidine and then incubated in the presence of [alpha-32P]deoxyribonucleoside triphosphates under conditions that support DNA replication. To determine whether or not the cellular DNA synthesized in vitro was assembled into nucleosomes the DNA was digested in situ with either micrococcal nuclease or pancreatic DNase I, and the products were examined by electrophoretic and sedimentation analysis. The distribution of DNA fragment lengths on agarose gels following micrococcal nuclease digestion was more heterogeneous for newly replicated than for the bulk of the DNA. Nonetheless, the state of cellular DNA synthesized in vitro (32P-labeled) was found to be identical with that of the DNA in the bulk of the chromatin (3H-labeled) by the following criteria: (i) The extent of protection against digestion by micrococcal nuclease of DNase I. (ii) The size of the nucleosomes (180 base pairs) and core particles (145 base pairs). (iii) The number and sizes of DNA fragments produced by micrococcal nuclease in a limit digest. (iv) The sedimentation behavior on neutral sucrose gradients of nucleoprotein particles released by micrococcal nuclease. (v) The number and sizes of DNA fragments produced by DNase I digestion. These results demonstrate that cellular DNA replicated in isolated nuclei is organized into typical nucleosomes. Consequently, subcellular systems can be used to study the relationship between DNA replication and the assembly of chromatin under physiological conditions.     

Use of RNA polymerase as an enzymatic probe of nucleosomal structure.

Nucleosomes prepared from human placental nuclei and Escherichia coli DNA-dependent RNA polymerase (nucleoside triphosphate: RNA nucleotidyl transferase EC.2.7.7.6) form stable initiation complexes. This property is utilized as a probe of nucleosome structure. RNA polymerase initiation has been studied on purified nucleosomes, nucleosome cores, and nucleosomal DNA. The affinity of E. coli RNA polymerase for both nucleosome cores and monomers was 5-6 fold less than found for nucleosomal DNA. No difference in apparent initiation Km was found between cores and mononucleosomes. This suggests that initiation does not preferentially occur on the DNA tails of nucleosomes. Once initiated and allowed to form nascent RNA, these complexes are very stable to ionic strength changes. Under conditions in which free enzyme is inactivated with rifampicin, the enzyme in the complex retains activity as demonstrated by its ability to transcribe and reinitiate on both nucleosomes and free DNA. These complexes can be well resolved from free nucleosomes on preparative polyacrylamide gels and both can be eluted from gels for analysis of proteins and DNA sequence complexity. Studies using (125I) labelled nucleosomes show that histones are retained in the initiation complex, and are not dissociated by the enzyme during initiation.     

Nucleosome geometry and internucleosomal interactions control the chromatin fiber conformation

Based on model structures with atomic resolution, a coarse-grained model for the nucleosome geometry was implemented. The dependence of the chromatin fiber conformation on the spatial orientation of nucleosomes and the path and length of the linker DNA was systematically explored by Monte Carlo simulations. Two fiber types were analyzed in detail that represent nucleosome chains without and with linker histones, respectively: two-start helices with crossed-linker DNA (CL conformation) and interdigitated one-start helices (ID conformation) with different nucleosome tilt angles. The CL conformation was derived from a tetranucleosome crystal structure that was extended into a fiber. At thermal equilibrium, the fiber shape persisted but relaxed into a structure with a somewhat lower linear mass density of 3.1 ± 0.1 nucleosomes/11 nm fiber. Stable ID fibers required local nucleosome tilt angles between 40° and 60°. For these configurations, much higher mass densities of up to 7.9 ± 0.2 nucleosomes/11 nm fiber were obtained. A model is proposed, in which the transition between a CL and ID fiber is mediated by relatively small changes of the local nucleosome geometry. These were found to be in very good agreement with changes induced by linker histone H1 binding as predicted from the high resolution model structures.     

Random location and absence of movement of the nucleosomes on SV 40 nucleoprotein complex isolated from infected cells.

SV 40 nucleoprotein complexes (NPC) containing viral DNA and cellular histones were extracted from nuclei of permissive cells and treated with either EcoR1 or BamI endonucleases. The fraction of SV 40 linear NPC, monitored by electron microscopy, reached a plateau value of about 15–20% after one hour and no further change occurred during further incubation for 2 hours. Free viral DNA added to the incubation mixture was totally cleaved. During the incubations of NPC and DNA, no redistribution of histones occurred, all the complexe still contained on average 21 nucleosomes and no nucleosomes were generated on the naked viral DNA. Our results suggest a random location and absence of movement of the nucleosomes in vitro on SV 40 nucleoprotein complex isolated from infected cells.     

Comparison of nuclease digestion of polyoma virus nucleoprotein complex and mouse chromatin.

We digested polyoma virus nucleoprotein complex, isolated from disrupted virions, with micrococcal nuclease and DNase I. The results were compared with digestions of chromatin from mouse nuclei. The nucleosome "core" structures were similar, but the spacing of the nucleosomes in the isolated polymoma nucleoprotein complexes was irregular, whereas in mouse chromatin it was regular. The average nucleosome repeat length in each case was 190 to 200 base pairs. This figure suggests that, unless there are substantial stretches of free DNA, the polyoma nucleoprotein complex contains about 26 nucleosomes. The commonly used method of preparing the nucleoprotein complex by disruption of virions at pH 10.2 may lead to significant damage to the structure. Such damage may be more clearly revealed by the susceptibility of the DNA to nuclease digestion than by the usual criteria of sedimentation velocity and buoyant density.     

Analysis of Histones Associated with Neuronal and Glial Nuclei Exhibiting Divergent DNA Repeat Lengths

Abstract: Total cerebral hemisphere nuclei purified from adult rabbit brain were subfractionated into neuronal and glial populations. Previous studies have shown that chromatin in neuronal nuclei is organized in an unusual nucleosome conformation compared with glial or kidney nuclei, i.e., a short DNA repeat length is present. We now analyze whether this difference in chromatin organization is associated with an alteration in the histone component of nucleosomes. Total histone isolated by acid/urea-protamine extraction of purified neuronal, glial, and kidney nuclei was analyzed by electrophoresis on SDS-polyacrylamide slab gels. Histone H1 that was selectively extracted from nuclei was also examined. Differences were not observed on SDS gels in the electrophoretic mobilities of histones associated with either the nucleosome core particle (histones H2A, H2B, H3, H4) or the nucleosome linker region (histone H1). Total histone and selectively extracted histone H1 were also analyzed on acid/urea slab gels that resolve histones on the basis of both molecular weight and charge differences. When analyzed in this system, differences with respect to electrophoretic mobility were not detected when comparing either selectively extracted histone H1 or total histone from neuronal and glial nuclei. Quantitative analyses were also performed and neuronal nuclei were found to contain less histone H1 per milligram DNA compared with glial or kidney nuclei. Neuronal nuclei also demonstrated a lower ratio of histone H1/core histone. These results suggest that the pronounced difference in chromatin organization in neuronal compared with glial nuclei, which is reflected by a short DNA repeat length in neurons, appears to be associated with quantitative differences in neuronal histone H1.     

Transferring DNA from electrophoretically resolved nucleosomes to diazobenzyloxymethyl cellulose: properties of nucleosomes along mouse satellite DNA.

Electrophoresis fractionates nucleosomes which possess different protein compositions. We report here a procedure for transferring the DNA components of electrophoretically resolved nucleosomes to diazobenzyloxymethyl cellulose (DBM-paper). Histones are first removed from nucleosome components by electrophoresis in the presence of cetyltrimethylammonium bromide (CTAB), leaving DNA fragments fixed within the original gel as the CTAB salts. The DNA is then converted to the sodium salt, denatured, and electrophoretically transferred to DBM-paper. The overall pattern of DNA on the resulting blot is visualized either by fluorography or by immunoautoradiography. This DNA pattern is then compared with autoradiograms obtained after hybridizing the same blot with specific 32P-labeled probes. Using mouse satellite DNA as a hybridization probe, we illustrate the above techniques and demonstrate that nucleosomes carrying satellite sequences are compositionally heterogeneous. The procedures described here should also be useful in the analysis of the nucleic acid components associated with other nucleoprotein complexes.     

Relaxation effects in the gel electrophoresis of DNA in intermittent fields

The electrophoretic mobility of restriction fragments of lambda DNA in agarose gels declines if the field is intermittent rather than continuous, with a greater effect on the longer fragments. The changes are compatible with the assumption of two exponential relaxation processes for field-dependent configurational changes, one when the field is turned on and another when it terminates. The length dependence at the extrapolated limit of mobility for short pulses with long intervals corresponds closely to the simple inverse proportionality to length expected from theoretical considerations when the molecular configuration is not affected by the electric field. Simple intermittent fields would allow separation of longer molecules than can ordinarily be resolved. The relaxation times for both the change in conformation imposed by the field and the return to field-free conformation vary as approximately the second power of the length of the molecule, independent of the salt concentration or field strength and varying only slightly with gel density. These relations are not in good agreement with properties expected from reputation theory, and they suggest that a different mechanism must be invoked for the electrophoretic migration of long DNA molecules at ordinary values of field strength.     

Chromatin-Like Structures in Polyoma Virus and Simian Virus 40 Lytic Cycle

Nucleoprotein complexes containing viral DNA and cellular histones were extracted from nuclei of permissive cells infected with polyoma virus or simian virus 40 (SV40) and examined by electron microscopy. Polyoma and SV40 nucleoprotein complexes are almost identical. They appear as relaxed circular molecules consisting of 20 to 21 globular particles interconnected by thin filaments. Their contour length in 0.02 M salt is 2.7 times shorter than that of viral DNA form I obtained after dissociation of the proteins in 1 M NaCl. The nucleosomes have an average diameter of 12.5 nm. Each nucleosome contains 175 to 205 DNA base pairs condensed fivefold in length. The nucleosomes are regularly spaced on the circular molecule. The internucleosomal filaments are made of naked DNA, and each filament contains about 55 base pairs. The partial sensitivity of the nucleoprotein complex to cleavage by EcoR1 endonuclease suggests that the nucleosomes are not formed at specific sites on the viral genome. Faster sedimenting nucleoprotein complexes containing replicative intermediates were studied. Isopycnic centrifugation in metrizamide gradients in the absence of aldehyde fixation showed that these molecules conserved the same DNA-to-protein ratio as the form I DNA-containing complexes.     

A comparison of the interactions of proflavine with DNA and with deoxyribonucleohistone using circular dichroism spectroscopy

Complexes of proflavine with DNA and deoxyribonucleohistone from calf thymus show different optical activity in the visible and the ultraviolet. Although the visible CD spectra of both complexes arise from interactions of dye molecules, the variation in the optical activity with the amount of dye bound suggests that a lesser conformational mobility exists in DNH. This is confirmed by the ultraviolet CD spectra of the complexes, and it is suggested that the conformation of DNA within nucleohistone is altered by separation of the base pairs by a greater extent than occurs in DNA in free solution. Even if the protein is unequally distributed along the DNA, the conformation of all of the DNA is altered by its incorporation into the nucleoprotein complex, since no evidence could be detected to show that DNA in a “free” conformation existed.     

Intracellular DNA of the parvovirus minute virus of mice is organized in a minichromosome structure.

Minute virus of mice (MVM) nucleoprotein complexes were leached from infected cell nuclei in the presence of a hypotonic buffer. Detailed biochemical analyses performed on the extracted complexes revealed nucleoprotein complexes sedimenting together with virions at 110S and defective particles sedimenting at 50S. In contrast to the virions, the nucleoprotein complexes were found to be sensitive to treatment with DNase, Sarkosyl, and heparin. They were found to be composed of replicative forms of MVM DNA and cellular histones. After extensive micrococcal nuclease digestion performed on purified nucleoprotein complexes, a viral nucleosomes core containing a DNA segment of about 140 base pairs in length was identified. These complexes when visualized by electron microscopy revealed the existence of beaded structures (minichromosomes) having 26 and 52 beads per monomer and dimer molecules, respectively. We suggest that the organization of the intracellular viral DNA in a minichromosome structure is an essential step in the virus growth cycle.     

Limitations of the poly(glutamic acid) reconstitution method in the reassembly of mono- and dinucleosomes

Reconstitution of mononucleosomes and dinucleosomes at physiological ionic strength by means of poly(glutamic acid) is not efficient at physiological histone octamer:DNA ratios, unlike that with the salt dialysis method. The shorter the DNA is, the less transfer of octamers from poly(glutamic acid) to DNA occurs. By increasing the octamer:DNA ratio it is possible to involve all the DNA in the assembly, but for DNA longer than core particle length, nucleoprotein particles containing extra histones are concomitantly generated. Except for core particle and chromatosome lengths of DNA reassembled at 0.6:1 or 1:1 octamer:DNA ratio (and thus with low yield), reconstituted nucleoprotein particles proved to be different from native nucleosomes by their insolubility upon isolation. In the aggregates, DNA ends seemed to be sufficiently loose to allow exonuclease III digestion up to a certain limit. This resulted in patterns that for some cloned DNA fragments could give the impression, without knowledge of the above, of resulting from a unique octamer position. In view of the small range of length of DNA and the low yield of faithful reconstitution, the assembly method using poly(glutamic acid) is only of limited use in mono- or dinucleosome reconstitution experiments, at least in our hands.     

Changing Chromatin Fiber Conformation by Nucleosome Repositioning

Chromatin conformation is dynamic and heterogeneous with respect to nucleosome positions, which can be changed by chromatin remodeling complexes in the cell. These molecular machines hydrolyze ATP to translocate or evict nucleosomes, and establish loci with regularly and more irregularly spaced nucleosomes as well as nucleosome-depleted regions. The impact of nucleosome repositioning on the three-dimensional chromatin structure is only poorly understood. Here, we address this issue by using a coarse-grained computer model of arrays of 101 nucleosomes considering several chromatin fiber models with and without linker histones, respectively. We investigated the folding of the chain in dependence of the position of the central nucleosome by changing the length of the adjacent linker DNA in basepair steps. We found in our simulations that these translocations had a strong effect on the shape and properties of chromatin fibers: i), Fiber curvature and flexibility at the center were largely increased and long-range contacts between distant nucleosomes on the chain were promoted. ii), The highest destabilization of the fiber conformation occurred for a nucleosome shifted by two basepairs from regular spacing, whereas effects of linker DNA changes of ∼10 bp in phase with the helical twist of DNA were minimal. iii), A fiber conformation can stabilize a regular spacing of nucleosomes inasmuch as favorable stacking interactions between nucleosomes are facilitated. This can oppose nucleosome translocations and increase the energetic costs for chromatin remodeling. Our computational modeling framework makes it possible to describe the conformational heterogeneity of chromatin in terms of nucleosome positions, and thus advances theoretical models toward a better understanding of how genome compaction and access are regulated within the cell.