Different repeat lengths in rat satellite I DNA containing chromatin and bulk chromatin

Nucleosome distribution and linker DNA: connecting nuclear function to dynamic chromatin structure

Genetic information in eukaryotes is managed by strategic hierarchical organization of chromatin structure. Primary chromatin structure describes an unfolded nucleosomal array, often referred to as "beads on a string". Chromatin is compacted by the nonlinear rearrangement of nucleosomes to form stable secondary chromatin structures. Chromatin conformational transitions between primary and secondary structures are mediated by both nucleosome-stacking interactions and the intervening linker DNA. Chromatin model system studies find that the topography of secondary structures is sensitive to the spacing of nucleosomes within an array. Understanding the relationship between nucleosome spacing and higher order chromatin structure will likely yield important insights into the dynamic nature of secondary chromatin structure as it occurs in vivo. Genome-wide nucleosome mapping studies find the distance between nucleosomes varies, and regions of uniformly spaced nucleosomes are often interrupted by regions of nonuniform spacing. This type of organization is found at a subset of actively transcribed genes in which a nucleosome-depleted region near the transcription start site is directly adjacent to uniformly spaced nucleosomes in the coding region. Here, we evaluate secondary chromatin structure and discuss the structural and functional implications of variable nucleosome distributions in different organisms and at gene regulatory junctions.

Nucleosome positioning and periodicity of satellite DNA in the liver of aging rats. Nucleosome positioning and periodicity of satellite DNA

The positioning of nucleosomes has been analysed by comparing the pattern of cutting sites of a probing reagent on chromatin and naked DNA. For this purpose, high molecular weight DNA and nuclei from the liver of young (18 +/- 2 weeks) and old (100 +/- 5 weeks) Wistar male rats were digested with micrococcal nuclease (MNase) and hybridized with 32P-labelled rat satellite DNA probe. A comparison of the ladder generated by MNase with chromatin and nuclei indicates long range organization of the satellite chromatin fiber with distinct non-random positioning of nucleosomes. However, the positioning of nucleosomes on satellite DNA does not vary with age. For studying the periodicity and subunit structure of satellite DNA, high molecular weight DNA from the liver of young and old rats were digested with different restriction enzymes. Surprisingly, no noteworthy age-related change is visible in the periodicity and subunit structural organization of the satellite DNA. These results suggest that the nucleosome positioning and the periodicity of liver satellite DNA do not vary with age.

Nucleosomal organization of the rat liver satellite DNA-containing chromatin during aging

Nucleosomal organization of the satellite DNA-containing chromatin of the liver of young (18 +/- 2 weeks) and old (100 +/- 5 weeks) rats was examined by nucleases and satellite I DNA probe. The satellite DNA-containing chromatin exhibits lower accessibility to endogenous endonucleases in old rats. The nucleosomal repeat length of this chromatin as investigated from digestion with endogenous endonucleases and MNase differs remarkably from bulk chromatin, though it does not alter with age. However, age-dependent loss of satellite DNA is apparent from hybridization results. Furthermore, DNase I analysis of the satellite DNA-containing chromatin at nucleosomal level reveals a relatively loose organization in young rats than old ones. It also shows an altered 10 bp periodicity as compared to bulk chromatin in both ages. These findings establish organizational differences between rat liver bulk and satellite DNA-containing chromatin. They further show that repeat length and altered 10 bp periodicity are similar in young and old, but accessibility to nucleases declines with age.

Nucleosomal organization of telomere-specific chromatin in rat

Rat liver interphase chromosomes have telomeres 20-100 kb in length. Micrococcal nuclease digestion of nuclei cleaves telomeres with a uniform 157 bp periodicity, producing soluble particles that sediment in sucrose gradients exactly like oligonucleosomes. The monomeric telomere particles comigrate with nucleosome core particles on nucleoprotein and DNA gels but do not bind H1. DNAase I cleaves telomere nucleoprotein into a series of bands spaced by about 10.4 bp and with the same intensity distribution as bands from bulk nucleosomes. Removal of H1 from chromatin alters the sedimentation properties of telomeres in parallel with bulk chromatin. Thus, telomeres of mammals are constructed of closely spaced nucleosomes, in contrast with the telomeres of lower eukaryotes, which show no evidence of nucleosomal structure.

Antibodies to defined histone epitopes reveal variations in chromatin conformation and underacetylation of centric heterochromatin in human metaphase chromosomes

Unfixed metaphase chromosome preparations from human lymphocyte cultures were immunofluorescently labelled using antibodies to defined histone epitopes. Both mouse monoclonal antibody HBC-7, raised against the N-terminal region of H2B, and rabbit serum R5/12, which recognizes H4 acetylated at Lys-12, gave non-uniform labelling patterns, whereas control antibodies against total histone fractions H4 and H1 produced homogeneous fluorescence. HBC-7 bound approximately uniformly to the bulk of the chromosomes, but the major heterochromatic domains of chromosomes 1, 9, 15, 16 and the Y showed significantly brighter fluorescence. Serum R5/12 indicated an overall reduction in acetylation of H4 in metaphase chromosomes compared with interphase nuclei, although some specific chromosomal locations had considerably elevated acetylation levels. Acetylation levels in the major heterochromatic domains appeared extremely low. To investigate further the differences noted in heterochromatin labelling, metaphases from cultures grown in the presence of various agents known to induce undercondensation of the major heterochromatic domains were similarly immunolabelled. Decondensed heterochromatin no longer exhibited higher than normal immunofluorescence levels with HBC-7. The higher resolution afforded by "stretching" the centromeric heterochromatin of chromosomes 1, 9 and 16 confirmed the low level of H4 acetylation in these domains. We consider the implications of these observations in relation to chromatin conformation and activity.

Structural organization of satellite I chromatin of calf liver

The organization of liver calf satellite DNA I chromatin has been studied. Precisely seven nucleosomes per DNA satellite repeat (1.4 kb) are shown to be present. Several strict positionings of the nucleosomes along the satellite DNA repeat have been described. One of these positionings, the major phase, was shown to be preferentially organized in clustered repeats. Most of the non-methylated CpG restriction sites were shown to be located in the linker DNAs of the satellite I nucleosomes, whilst, accordingly, methylated HpaII sites were found in the core satellite I DNA. The significance of these results is discussed.

Nucleosomes are positioned on mouse satellite DNA in multiple highly specific frames that are correlated with a diverged subrepeat of nine base-pairs

Nucleosome phasing on highly repetitive DNA was investigated using a novel strategy. Nucleosome cores were prepared from mouse liver nuclei with micrococcal nuclease, exonuclease III and nuclease S1. The core DNA population that contains satellite sequences was then purified from total core DNA by denaturation of the DNA, reassociation to a low Cot value and hydroxyapatite chromatography to separate the renatured satellite fraction. After end-labeling, the termini of the satellite core DNA fragments were mapped with an accuracy of +/- 1 base-pair relative to known restriction sites on the satellite DNA. Sixteen dominant nucleosome positions were detected. There is a striking correlation between these nucleosome frames and an internal highly diverged 9 base-pair subrepeat of the satellite DNA. The results are consistent with a sequence-dependent association of histone octamers with the satellite DNA. Our finding that histone octamers can interact with a given DNA in a number of different defined frames has important implications for the possible biological significance of nucleosome phasing.

Positioning of nucleosomes in satellite I-containing chromatin of rat liver

The location of nucleosomes on rat satellite I DNA has been investigated using a new approach. Nucleosome cores were prepared from rat liver nuclei with micrococcal nuclease, exonuclease III and nucleases S1. From the total population of core DNA fragments the satellite-containing fragments were isolated by molecular cloning and the complete sequence of 50 clones was determined. The location of nucleosomes along the satellite sequence was found to be non-random. Our results show that nucleosomes occupy a number of positions on satellite I DNA. About 35 to 50% of all nucleosomes are positioned in two corresponding major sites, the remainder in about 16 less preferred sites. The major nucleosome positions are apparently strictly defined with the precision of a single base-pair. These results were confirmed by other approaches, including restriction nuclease digestion experiments. There are good indications of a defined long-range organization of the satellite chromatin fiber in two or more oligonucleosomal arrays with distinct nucleosome configurations.

Nucleosome arrangement in green monkey alpha-satellite chromatin. Superimposition of non-random and apparently random patterns

We have studied the structure of tandemly repetitive alpha-satellite chromatin (alpha-chromatin) in African green monkey cells (CV-1 line), using restriction endonucleases and staphylococcal nuclease as probes. While more than 80% of the 172-base-pair (bp) alpha-DNA repeats have a HindIII site, less than 15% of the alpha-DNA repeats have an EcoRI site, and most of the latter alpha-repeats are highly clustered within the CV-1 genome. EcoRI and HindIII solubilize approximately 8% and 2% of the alpha-chromatin, respectively, under the conditions used. EcoRI is thus approximately 30 times more effective than HindIII in solubilizing alpha-chromatin, with relation to the respective cutting frequencies of HindIII and EcoRI on alpha-DNA. EcoRI and HindIII solubilize largely non-overlapping subsets of alpha-chromatin. The DNA size distributions of both EcoRI- and HindIII-solubilized alpha-chromatin particles peak at alpha-monomers. These DNA size distributions are established early in digestion and remain strikingly constant throughout the digestion with either EcoRI or HindIII. Approximately one in every four of both EcoRI- and HindIII-solubilized alpha-chromatin particles is an alpha-monomer. Two-dimensional (deoxyribonucleoprotein leads to DNA) electrophoretic analysis of the EcoRI-solubilized, sucrose gradient-fractionated alpha-oligonucleosomes shows that they do not contain "hidden" EcoRI cuts. Moreover, although the EcoRI-solubilized alpha-oligonucleosomes contain one EcoRI site in every 172-bp alpha-DNA repeat, they are completely resistant to redigestion with EcoRI. This striking difference between the EcoRI-accessible EcoRI sites flanking an EcoRI-solubilized alpha-oligonucleosome and completely EcoRI-resistant internal EcoRI sites in the same alpha-oligonucleosome indicates either that the flanking EcoRI sites occur within a modified chromatin structure or that an altered nucleosome arrangement in the vicinity of a flanking EcoRI site is responsible for its location in the nuclease-sensitive internucleosomal (linker) region. Analogous redigestions of the EcoRI-solubilized alpha-oligonucleosomes with either HindIII, MboII or HaeIII (both before and after selective removal of histone H1 by an exchange onto tRNA) produce a self-consistent pattern of restriction site accessibilities. Taken together, these data strongly suggest a preferred nucleosome arrangement within the EcoRI-solubilized subset of alpha-oligonucleosomes, with the centers of most of the nucleosomal cores being approximately 20 bp and approximately 50 bp away from the nearest EcoRI and HindIII sites, respectively, within the 172-bp alpha-DNA repeat. However, as noted above, the clearly preferred pattern of nucleosome arrangement within the EcoRI-solubilized alpha-oligonucleosomes is invariably violated at the ends of every such alpha-oligonucleosomal particle, suggesting at least a partially statistical origin of this apparently non-random nucleosome arrangement.(ABSTRACT TRUNCATED AT 400 WORDS)

Eight different highly specific nucleosome phases on alpha-satellite DNA in the African green monkey

The question of nucleosome phasing on African Green Monkey (AGM) alpha-satellite DNA has been addressed by employing a new approach. Nucleosome cores were prepared from AGM nuclei with micrococcal nuclease, exonuclease III and nuclease S1. The core DNA population derived from alpha-satellite DNA containing chromatin was purified from total core DNA by denaturation of the DNA, reassociation to a low Cot value, and hydroxyapatite chromatography to separate the renatured satellite fraction. After end-labeling the termini of the alpha-satellite containing core DNA fragments were mapped by high resolution gel electrophoresis relative to known restriction sites along the 172 bp repeat unit of the satellite DNA. The results show that nucleosomes occupy eight strictly defined positions on the alpha-satellite DNA which could be determined with an accuracy of +/- 1 base pair. Approximately 35% of all nucleosomes are organized in one of these frames while the other seven registers contribute about 10% each.

Histone acetylation in chromatin containing mouse satellite DNA

Histone acetylation in transcriptionally inactive chromatin has been studied with chromatin containing mouse satellite DNA. The latter was obtained by digestion of nuclei from Ehrlich ascites tumor cells with the restriction nuclease Bsp, which degrades main-band DNA but leaves satellite DNA intact. The enzyme-resistant material was separated by gel filtration. Satellite DNA amounted to 65% of the total DNA in this fraction. When the cells were grown in the presence of sodium n-butyrate to inhibit histone deacetylation, a few, if any, hyperacetylated forms of core histones were found in satellite chromatin. Conversely, the highest quantity of tetraacetylated H4 molecules was found in the fractions containing the most extensively degraded chromatin.

Nucleosome distribution on the Jk and Ck immunoglobulin gene segments of mouse liver chromatin

The chromatin structure of the transcriptionally inactive kappa immunoglobulin gene in mouse liver was investigated by mainly employing indirect endlabeling on Bsp RI restriction nuclease digestions of intact nuclei. The disclosed strong (about 85%) but not uniform protection of the Bsp RI sites by nucleosomes is inconsistent with both a uniquely sequence-oriented localization and a completely random distribution of nucleosomes in this region of the genome. Several possibly applicable models are discussed. A model with multiple phases and non-uniform linker lengths cannot be excluded; however a largely random localization with a weak superimposed organization in two confined areas was tested and found sufficient for explaining the data.

Analysis of highly purified satellite DNA containing chromatin from the mouse

A purification scheme for satellite DNA containing chromatin from mouse liver has been developed. It is based on the highly condensed state of the satellite chromatin and also takes advantage of its resistance to digestion by certain restriction nucleases. Nuclei are first treated with micrococcal nuclease and the satellite chromatin enriched 3-5 fold by extraction of the digested nuclei under appropriate conditions. Further purification is achieved by digestion of the chromatin with a restriction nuclease that leaves satellite DNA largely intact but degrades non-satellite DNA extensively. In subsequent sucrose gradient centrifugation the rapidly sedimenting chromatin contains more than 70% satellite DNA. This material has the same histone composition as bulk chromatin. No significant differences were detected in an analysis of minor histone variants. Nonhistone proteins are present only in very low amounts in the satellite chromatin fraction, notably the HMG proteins are strongly depleted.

Non-random arrangement of nucleosomes in satellite I containing chromatin of rat liver

The location of nucleosomes on the nucleotide sequence of rat satellite I DNA was investigated using micrococcal nuclease, exonuclease III, and restriction nucleases as tools. Hae III cleaved the satellite DNA containing chromatin very preferentially in the linker region. Nucleosomes were found predominantly in three defined positions on the 370 bp satellite I monomer unit. This type of arrangement occurs on not more than half of the satellite DNA containing chromatin while the rest of this chromatin is arranged differently. The arrangement of nucleosomes with high probability in preferred frames and with low probability in less preferred frames may be a general phenomenon which can be discussed as a possible mechanism to modulate sequence recognition.