The small chromatin fragments released by micrococcal nuclease from hepatoma tissue cultured cell nuclei are strongly enriched in coding DNA sequences and are related to an actively transcribed single-stranded DNA fraction

It was shown with the use of specific probes that mild micrococcal nuclease digestion releases from chromatin actively-transcribed genes as small nucleosome oligomers. In the present work we demonstrate that most if not all of the active genes are accessible to the nuclease. It was found that the short released fragments are greatly enriched in transcribed DNA sequences, the most enriched being the dimers of nucleosomes since 35% of their DNA could be hybridized to cytoplasmic RNA. The results of cDNA-DNA hybridizations indicate that the monomers and dimers of nucleosomes contain most of the DNA sequences which encode poly(A⁺) RNAs, however larger released fragments include some transcribed sequences, while the nuclease-resistant chromatin is considerably impoverished in coding sites. These evidences and the finding that about 25% of the DNA from the dimers of nucleosomes are exclusively located in this class of fragments, tend to prove that the active chromatin regions are attacked in a non-random way by micrococcal nuclease. We have previously isolated, without using exogenous nuclease, an actively transcribed genomic fraction amounting to 1.5–2% of the total nuclear DNA, formed of single-stranded DNA. In the present study we show that all or nearly all the single-stranded DNA sequences could be reassociated with the DNA fragments present in the released monomers and dimers of nucleosomes. Our observations confirmed our previous finding that the greatest part of single-stranded DNA selectively originates from the coding strand of genomic DNA.     

Non-histone proteins of soluble nucleoproteins released from mouse myeloma nuclei by mild micrococcal nuclease digestion

Mono- and dinucleosomes preferentially cleaved from mouse myeloma chromatin by very mild micrococcal nuclease digestion at 0 degree C are soluble and are released from nuclei under near-physiological conditions in which normal nucleosomes containing Hl are insoluble. These nucleosomes are highly enriched in RNA, high-mobility-group proteins and a unique subset of other non-histone proteins. They are nearly devoid of histone Hl and contain DNA significantly less methylated than whole myeloma DNA, indicating that they comprise a subset of genomic sequences. Previously we have shown that this fraction is enriched in transcribed DNA sequences. Non-histone proteins that co-sedimented with readily solubilized nucleosomes included many of the most basic, low-to-moderate molecular weight chromosomal proteins. Many of these proteins were also preferentially acetylated in vivo. The residual, pelleted chromatin was highly enriched in high molecular weight proteins (greater than 60 000), and very depleted in medium molecular weight proteins. Readily solubilized nucleoproteins sedimenting like mononucleosomes were partly resolved by electrophoresis, under non-denaturing conditions, into several subfractions differing significantly in non-histone protein contents. Methods described here should be useful for identifying and isolating non-histone proteins bound to nucleosomes and other chromatin regions that are structurally and functionally unique.     

Presence of non-histone proteins in nucleosomes

It has been established that nucleosomes are made of histones and DNA fragments. The purpose of this work to establish whether some non-histone proteins are also present in these chromatin subunits. We have found that nucleosome preparations contain phosphorylated non-histone proteins and protein kinases by sucrose gradient analysis. In order to establish whether these proteins are actually bound to nucleosomes or if they represent unbound or aggregated proteins, the following experiments were performed. (a) Free non-histone proteins and proteins released from chromatin by DNase overdigestion were analyzed by sucrose gradient centrifugation. No phosphoproteins but some phosvitin kinase activity was found in the part of the gradient which contained the nucleosomes. It could be assumed that part of the phosphoproteins are bound to nucleosomes. (b) A digestion of nucleosomes with DNase I suppressed the phosvitin kinase activity in the 11-S region of the gradient. (c) High ionic strength, which extracted non-histone proteins, suppressed the phosvitin kinase activity in the nucleosome region. Part of phosvitin kinase and of nuclear phosphoproteins are therefore bound to nucleosomes and are released by nuclease digestion and by high ionic strength.     

Disruption of the typical chromatin structure in a 2500 base-pair region at the 5' end of the actively transcribed ovalbumin gene.

We examined the chromatin organizations of approximately 3 kb of DNA in the 5'-end flanking region of the ovalbumin gene in chicken erythrocyte and oviduct cell nuclei. With specific DNA probes and an indirect end-labeling technique, we analysed the pattern of the DNA fragments obtained after micrococcal nuclease digestion and generated comparative maps of the nuclease cuts. This region of the chicken genome displays a "typical" chromatin arrangement in erythrocyte nuclei, with nucleosomes apparently positioned at random. In contrast, in oviduct nuclei, the same region has an "altered" chromatin structure, and lacks a typical nucleosomal array. The existence of specifically positioned proteins and of alterations in the DNA secondary structure in this region of the oviduct chromatin is suggested by comparison of the nuclease cleavage maps which reveals specific changes: disappearance of nuclease cuts present in "naked" and erythrocyte chromatin DNAs, and appearance of new cuts absent from these DNAs.     

Structural transition in inactive Balbiani ring chromatin of Chironomus during micrococcus nuclease digestion

We have analysed by micrococcus nuclease digestion the chromatin structure of genes in the Balbiani ring (BR) regions of a Chironomus cell line. Gel electrophoresis of the DNA fragments reveals a repeating structure which consists of two repeat sizes, a long repeat seen in the large fragments and a small repeat seen in the small fragments. The two repeats hardly overlap, except in a narrow transition zone which is at a different fragment size in the BR 2.2 and the BR 2.1 gene. The sizes of the large repeats fit the repeat of the underlying DNA sequence. The short repeats are between 170 and 180 bp, and after H1 depletion the short repeat in the BR 2.2 gene is 160 bp. Our most favoured interpretation of these data is that in intact chromatin the nucleosomes in the BR genes are phased with respect to the repeating DNA sequence, whereas micrococcus nuclease digestion leads to loss of a nucleosome-positioning constraint and hence to rearrangement of the nucleosomes. Our results imply a possible artefact of nuclease digestion of chromatin, which has to be taken into account in mapping nucleosome positions.     

Fractionation of nucleosomes by salt elution from micrococcal nuclease- digested nuclei

The solubilization of nucleosomes and histone H1 with increasing concentrations of NaCl has been investigated in rat liver nuclei that had been digested with micrococcal nuclease under conditions that did not substantially alter morphological properties with respect to differences in the extent of chromatin condensation. The pattern of nucleosome and H1 solubilization was gradual and noncoordinate and at least three different types of nucleosome packing interactions could be distinguished from the pattern. A class of nucleosomes containing 13-- 17% of the DNA and comprising the chromatin structures most available for micrococcal nuclease attack was eluted by 0.2 M NaCl. This fraction was solubilized with an acid-soluble protein of apparent molecular weight of 20,000 daltons and no histone H1. It differed from the nucleosomes released at higher NaCl concentrations in content of nonhistone chromosomal proteins. 40--60% of the nucleosomes were released by 0.3 M NaCl with 30% of the total nuclear histone H1 bound. The remaining nucleosomes and H1 were solublized by 0.4 M or 0.6 M NaCl. H1 was not nucleosome bound at these ionic strengths, and these fractions contained, respectively, 1.5 and 1.8 times more H1 per nucleosome than the population released by 0.3 M NaCl. These fractions contained the DNA least available for micrococcal nuclease attach. The strikingly different macromolecular composition, availability for nuclease digestion, and strength of the packing interactions of the nucleosomes released by 0.2 M NaCl suggest that this population is involved in a special function.     

Nascent DNA in nucleosome like structures from chromatin

We have used chromatin sensitivity to cleavage by micrococcal nuclease as a probe for differences between chromatin containing nascent DNA and that containing bulk DNA. Micrococcal nuclease digested the nascent DNA in chromatin of swimming blastulae of sea urchins more rapidly to acid-soluble nucleotides than the DNA of bulk chromatin. A part of the nascent DNA occurred in micrococcal nuclease-resistant structures which were either different from, or temporary modifications of, the bulk nucleosomes. This was inferred from the size differences between bulk and nascent DNA fragments in 10% polyacrylamide gels after micrococcal nuclease digestion of nuclei from a mixture of ¹⁴C-thymidine long- and ³H-thymidine pulse-labeled embryos. Bulk monomer and dimer DNA fragments contained about 170 and 410 base pairs (bp), respectively, when 18% of the bulk DNA had been rendered acid-soluble. At this level of digestion, “nascent monomer DNA” fragments of about 150 bp as well as 305 bp “large nascent DNA fragments” were observed. Increasing levels of digestion indicated that the large nascent DNA fragment was derived from a chromatin structure which was more resistant to micrococcal nuclease cleavage than bulk dimer chromatin subunits. Peaks of ³H-thymidine-labeled DNA fragments from embryos which had been pulse-labeled and then chased or labeled for several minutes overlapped those of ¹⁴C-thymidine long-labeled monomer, dimer and trimer fragments. This indicated that the chromatin organization at or near the replication fork which had temporarily changed during replication had returned to the organization of its nonreplicating state.     

Chromatin structure. Further evidence against the existence of a beaded subunit for the 30-nm fiber

The size distribution of chromatin fragments released by micrococcal nuclease digestion of liver chromatin at various ionic strengths was examined. Below 20 mM ionic strength, gradient profiles with a peak centered at 6 nucleosomes are generated, whereas between 20 and 50 mM the peak is always centered on 12 nucleosomes, and above 50 mM ionic strength the 30-nm fiber becomes less accessible to the nuclease and there is a corresponding increase in the size distribution of fragments in the gradients. However, extensive digestions always give profiles with a peak of 12 nucleosomes as nuclease-resistant dodecamers accumulate. All of these observations are consistent with the winding of the 10-nm polynucleosome chain into a helical coil commencing at about 20 mM ionic strength. The helical turns are stabilized by histone H1 interactions between 20 and 50 mM ionic strength producing stable dodecamers. Above 50 mM ionic strength the coil condenses longitudinally and the profiles are consistent with a random attack of this fiber by the nuclease. Consequently it is not necessary to invoke the existence of a subunit bead to explain the profiles. We further define the conditions at which specific structural transitions take place and provide methodology for the preparation of chromatin at various levels of condensation.     

Remodeling of sperm chromatin after fertilization involves nucleosomes formed by sperm histones H2A and H2B and two CS histone variants

The composition of nucleosomes at an intermediate stage of male pronucleus formation was determined in sea urchins. Nucleosomes were isolated from zygotes harvested 10 min post-insemination, whole nucleoprotein particles were obtained from nucleus by nuclease digestion, and nucleosomes were subsequently purified by a sucrose gradient fractionation. The nucleosomes derived from male pronucleus were separated from those derived from female pronucleus by immunoadsorption to antibodies against sperm specific histones (anti-SpH) covalently bound to Sepharose 4B (anti-SpH-Sepharose). The immunoadsorbed nucleosomes were eluted, and the histones were analyzed by Western blots. Sperm histones (SpH) or alternatively, the histones from unfertilized eggs (CS histone variants), were identified with antibodies directed against each set of histones. It was found that these nucleosomes are organized by a core formed by sperm histones H2A and H2B combined with two major CS histone variants. Such a hybrid histone core interacts with DNA fragments of approximately 100 bp. It was also found that these atypical nucleosome cores are subsequently organized in a chromatin fiber that exhibits periodic nuclease hypersensitive sites determined by DNA fragments of 500 bp of DNA. It was found that these nucleoprotein particles were organized primarily by the hybrid nucleosomes described above. We postulate that this unique chromatin organization defines an intermediate stage of male chromatin remodeling after fertilization.     

Accessibility of the ribosomal genes to micrococcal nuclease in Physarum polycephalum.

In Physarum polycephalum most genes coding for ribosomal RNA are not integrated in chromosomes, but are located in many copies in the nucleolus as plasmid-like palindromic DNA molecules. To find out whether coding sequences of rDNA are organized in a chromatin-like structure similar to that of bulk chromatin, nuclei were treated with micrococcal nuclease and DNA fragments were isolated. From bulk chromatin multimers of a basic unit of 170-180 base pairs were obtained. Nuclease fragmented DNA hybridized with labelled 19-S + 26-S rRNA was found to give the same saturation value as did unfragmented control DNA. No preferential degradation of ribosomal genes to acid soluble products was observed. A more detailed analysis of the nuclease degradation products was carried out with fragments separated by preparative gel electrophoresis. DNA eluted from the gels was hybridized in solution with labelled 19-S + 26-S rRNA. The coding sequences of rRNA were found to be degraded to approximately nucleosome size slightly more quickly than was the DNA of bulk chromatin. However, the distribution of the rDNA fragments on the gels did not coincide with the distribution of the fragments derived from bulk chromatin nucleosomes and their oligomers. The amount of rDNA in the interband regions was about intermediate between that found in the two adjacent bands. These results lead to the conclusion that the ribosomal genes, most of which are presumably active during rapid growth, are protected by proteins, probably histones. However, the ribosomal genes are present in a structure differing in some way from that of bulk chromatin.     

Controls of Nucleosome Positioning in the Human Genome

Nucleosomes are important for gene regulation because their arrangement on the genome can control which proteins bind to DNA. Currently, few human nucleosomes are thought to be consistently positioned across cells; however, this has been difficult to assess due to the limited resolution of existing data. We performed paired-end sequencing of micrococcal nuclease-digested chromatin (MNase–seq) from seven lymphoblastoid cell lines and mapped over 3.6 billion MNase–seq fragments to the human genome to create the highest-resolution map of nucleosome occupancy to date in a human cell type. In contrast to previous results, we find that most nucleosomes have more consistent positioning than expected by chance and a substantial fraction (8.7%) of nucleosomes have moderate to strong positioning. In aggregate, nucleosome sequences have 10 bp periodic patterns in dinucleotide frequency and DNase I sensitivity; and, across cells, nucleosomes frequently have translational offsets that are multiples of 10 bp. We estimate that almost half of the genome contains regularly spaced arrays of nucleosomes, which are enriched in active chromatin domains. Single nucleotide polymorphisms that reduce DNase I sensitivity can disrupt the phasing of nucleosome arrays, which indicates that they often result from positioning against a barrier formed by other proteins. However, nucleosome arrays can also be created by DNA sequence alone. The most striking example is an array of over 400 nucleosomes on chromosome 12 that is created by tandem repetition of sequences with strong positioning properties. In summary, a large fraction of nucleosomes are consistently positioned—in some regions because they adopt favored sequence positions, and in other regions because they are forced into specific arrangements by chromatin remodeling or DNA binding proteins.     

Restriction endonuclease cleavage of satellite DNA in intact bovine nuclei

We have analyzed the efficiency with which specific nucleotide sequences within nucleosomes are recognized and cleaved by DNA restriction endonucleases. A system amenable to this sort of analysis is the cleavage of the bovine genome with the restriction endonuclease EcoRI. Bovine satellite I comprises 7% of the genome and is tandemly repetitious with an EcoRI site at 1400 base pair (bp) intervals within this sequence. The ease with which this restriction fragment can be measured permits an analysis of the accessibility of this sequence when organized in a nucleosomal array.Initial studies indicated that satellite I sequences are organized in a nucleosomal structure in a manner analogous to that observed for total genomic DNA. We then examined the accessibility of the EcoRI cleavage sites in satellite to endonucleolytic cleavage in intact nuclei. We find that whereas virtually all the satellite I sequences from naked DNA are cleaved into discrete 1400 bp fragments, only 33% of the satellite I DNA is liberated as this fragment from intact nuclei. These data indicate that 57% of the EcoRI sites in nuclei are accessible to cleavage and that cleavage can occur within the core of at least half the nucleosomal subunits. Analysis of the products of digestion suggests a random distribution of nucleosomes about the EcoRI sites of satellite I DNA.Finally, the observation that satellite sequences can be cleaved from nuclei to 1400 bp length fragments with their associated proteins provides a method for the isolation of specific sequences as chromatin. Using sucrose gradient velocity centrifugation, we have isolated a 70% pure fraction of satellite I chromatin. Nuclease digestion of this chromatin fraction reveals the presence of nucleosomal subunits and indicates that specific sequences can be isolated in this manner without gross disorganization of their subunit structure.     

Accessibility of some regions of DNA in chromatin (chicken erythrocytes) to single strand-specific nucleases.

The susceptibility of the DNA in chromatin to single strand-specific nucleases was examined using nuclease P1, mung bean nuclease, and venom phosphodiesterase. A stage in the reaction exists where the size range of the solubilized products is similar for each of the three nucleases and is nearly independent of incubation time. During this stage, the chromatin fragments sediment in the range of 30 to 100 S and contain duplex DNA ranging from 1 to 10 million daltons. Starting with chromatin depleted of histones H1 and H5 similar fragments are generated. In both cases these nucleoprotein fragments are reduced to nucleosomes and their multimers by micrococcal nuclease. Thus, chromatin contains a limited number of DNA sites which are susceptible to single strand-specific nucleases. These sites occur at intervals of 8 to 80 nucleosomes and are distributed throughout the chromatin. Nucleosome monomers, dimers, or trimers were not observed at any stage of single strand-specific nuclease digestion of nuclei, H1- and H5-depleted chromatin, or micrococcal nuclease-generated oligonucleosomes. Each of the three nucleases converted mononucleosomes (approximately 160 base pairs) to nucleosome cores (approximately 140 base pairs) probably by exonucleolytic action that was facilitated by the prior removal of H1 and H5. The minichromosome of SV40 is highly resistant to digestion by nuclease P1.     

Localization of phosphoproteins and of protein kinases in chromatin from butyrate treated HTC cells

We have recently shown that phosphoproteins are associated with the chromatin regions accessible to micrococcal nuclease. We have also shown that butyrate treatment modifies the accessibility of chromatin to the nuclease. In this work we have studied the effect of butyrate on the localization of phosphoproteins in chromatin. We observed a strong similarity between the effect of butyrate on the release of DNA fragments and on the release of phosphoproteins by the nuclease, which indicates that in butyrate treated as in control cells the released fragments include phosphoproteins. Butyrate treatment increases strongly chromatin protein kinase specific activity and modifies its localization in the released fragments; it is therefore likely that it modifies its localization in chromatin.     

Nuclear reassemblyin vitro is independent of nucleosome/chromatin assembly

It was show11 that nuclear reassembly was induced by small pieces of DNA fragments in cell-free extracts ofXenopus. In an attempt to learn the relationship between the nuclear reassembly and nucleosome/chromatin assembly, limited amounts of CM-Cellulose are used to eliminate the capacity of the egg extract S-150 to assemble chromatin. while the forming of nucleosomes is checked with DNA supercoiling by plasmid DNA pBR322 incubated in the extract, and further analysed by micrococcal nuclease digestion. This depleted extract is then used to induce nuclear reassembly around demembraned sperms with membrane vesicles. It is found that CM-Cellulose depletes histones H2A and H2B efficiently and blocks the assembly of nucleosomes, the demembraned sperms are yet reconstituted into nuclei in the treated S-150, although the chromatin in reassembled nuclei does not produce protected DNA fragments when digested with micrococcal nuclease. It suggests that in the cell-free system ofXenopus, DNA can be formed into nuclei without assembly of nucleosomes or chromatin.     

Nucleosome positioning as a critical determinant for the DNA cleavage sites of mammalian DNA topoisomerase II in reconstituted simian virus 40 chromatin.

We have assessed the ability of nucleosomes to influence the formation of mammalian topoisomerase II-DNA complexes by mapping the sites of cleavage induced by four unrelated topoisomerase II inhibitors in naked versus nucleosome-reconstituted SV40 DNA. DNA fragments were reconstituted with histone octamers from HeLa cells by the histone exchange method. Nucleosome positions were determined by comparing micrococcal nuclease cleavage patterns of nucleosome-reconstituted and naked DNA. Three types of DNA regions were defined: 1) regions with fixed nucleosome positioning; 2) regions lacking regular nucleosome phasing; and 3) a region around the replication origin (from position 5100 to 600) with no detectable nucleosomes. Topoisomerase II cleavage sites were suppressed in nucleosomes and persisted or were enhanced in linker DNA and in the nucleosome-free region around the replication origin. Incubation of reconstituted chromatin with topoisomerase II protected nucleosome-free regions from micrococcal nuclease cleavage without changing the overall micrococcal nuclease cleavage pattern. Thus, the present results indicate that topoisomerase II binds preferentially to nucleosome-free DNA and that the presence of nucleosomes at preferred DNA sequences influences drug-induced DNA breaks by topoisomerase II inhibitors.