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.     

Specific cleavage of chromatin by restriction nucleases.

Digestion of mouse and rat liver nuclei with a restriction nuclease from Bacillus subtilis (Bsu) is examined in continuation of previous work from this laboratory (Pfeiffer et al., 1975, Nature 258, 450). The finding of more than 95% C in the 5'-termini of the DNA fragments generated during digestion with Bsu shows that the participation of endogenous nucleases in Bsu digestion is extremely small. The restriction nuclease Hae III, an isoschizomer of Bsu, yields identical degradation patterns. The patterns conform to what one expects from statistical calculations based on a nucleosome structure of chromatin with a region preferentially accessible to the nuclease of 40-50 nucleotide pairs per nucleosome. Integrity of the histones is maintained during digestion with restriction nucleases. Digestion of mouse liver nuclei with EcoRII shows that most if not all of the satellite DNA is organized in a nucleosome structure. Also in rat liver, much of the repetitive DNA appears to be present in nucleosomes.     

Organization of 5S genes in chromatin of Xenopus laevis.

The chromatin organization of the genes coding for 5S RNA in Xenopus laevis has been investigated with restriction endonucleases and micrococcal nuclease. Digestion of nuclei from liver, kidney, blood and kidney cells maintained in culture with micrococcal nuclease reveals that these Xenopus cells and tissues have shorter nucleosome repeat lengths than the corresponding cells and tissues from other higher organisms. 5S genes are organized in nucleosomes with repeat lengths similar to those of the bulk chromatin in liver (178 bp) and cultured cells (165 bp); however, 5S gene chromatin in blood cells has a shorter nucleosome repeat (176 bp) than the bulk of the genome in these cells (184 bp). From an analysis of the 5S DNA fragments produced by extensive restriction endonuclease cleavage of chromatin in situ, no special arrangement of the nucleosomes with respect to the sequence of 5S DNA can be detected. The relative abundance of 5S gene multimers follows a Kuhn distribution, with about 57% of all HindIII sites cleaved. This suggests that HindIII sites can be cleaved both in the nucleosome core and linker regions.     

DNA methylation affects nuclear organization, histone modifications, and linker histone binding but not chromatin compaction

DNA methylation has been implicated in chromatin condensation and nuclear organization, especially at sites of constitutive heterochromatin. How this is mediated has not been clear. In this study, using mutant mouse embryonic stem cells completely lacking in DNA methylation, we show that DNA methylation affects nuclear organization and nucleosome structure but not chromatin compaction. In the absence of DNA methylation, there is increased nuclear clustering of pericentric heterochromatin and extensive changes in primary chromatin structure. Global levels of histone H3 methylation and acetylation are altered, and there is a decrease in the mobility of linker histones. However, the compaction of both bulk chromatin and heterochromatin, as assayed by nuclease digestion and sucrose gradient sedimentation, is unaltered by the loss of DNA methylation. This study shows how the complete loss of a major epigenetic mark can have an impact on unexpected levels of chromatin structure and nuclear organization and provides evidence for a novel link between DNA methylation and linker histones in the regulation of chromatin structure.     

Satellite DNA sequence content of polylysine-titratable and nuclease-resistant fractions of mouse liver hepatoma chromatin.

Micrococcal nuclease digestion of mouse TLT liver hepatoma chromatin proceeds rapidly to the point where approximately 35% of the DNA is recoverable by centrifugation of the chromatin DNA through 3M CsCl. The satellite DNA sequence content of this recoverable DNA is the same as whole chromatin DNA (10%). The 11s (penultimate digestion product) monomer, as well as intermediate multiples and relatively undigested large chromatin segments are separable on steep hlycerol gradients. The DNA isolated from these fractions also contains the normal 10% satellite DNA content. Progressive polylysine titration of chromatin followed by nuclease digestion gives anomalous recoveries of DNA but, nonetheless, the satellite sequence content titration of chromatin, followed by pronase and then nuclease digestion, again gave recoverable DNA with a satellite sequence content of 10%. These results are discussed in terms of the conclusion that nucleosome (or upsilon-body) structures are distributed in a random fashion over the genome.     

Ribosomal DNA sequences attached to the nuclear matrix

The organization of rat liver ribosomal DNA (rDNA) as matrix-attached DNA loops was examined using a protocol which fractionates chromatin from discrete regions of DNA loops. Southern blot analysis of matrix-attached and solubilized chromatin DNA fragments demonstrated that rDNA is associated with the matrix via its 5' and 3' nontranscribed spacer sequences (NTS). Although the 45 S rRNA coding sequences were approximately threefold enriched in matrix preparations, the recovery of this DNA (unlike the NTS) was dependent on the extent of nuclease digest and proportional to the length of the matrix-attached DNA fragments. The data suggest that rDNA is organized as matrix-attached DNA loops and only the NTS are directly involved in matrix binding. Further, we demonstrated that while the kinetics and extent of nuclease digestion were similar in all regions of the DNA loops, the nuclease digestion pattern of bulk nuclear and matrix DNA showed a typical nucleosome organization, but the rDNA fragments retained with the nuclear matrix did not.     

Effect of a partial trisomy in the mouse upon cellular and nuclear RNA

In a previous paper (Rake and Edwards, 1987) it was shown that the majority of the chromatin from trisomic mouse cells has nucleosomes with a smaller repeat length of DNA than the nucleosome repeat length of normal cells. Here it is shown that the RNA content of the total cell and of the nuclei is the same in all tissues studied, in both normal and trisomic cells. However, the amount per unit time or rate of RNA synthesis is depressed in the trisomic liver and brain nuclei. The depression of RNA synthesis could not be specified to the small trisomic section of the chromatin but instead must reflect the overall nuclear activity. These results, along with those of Devlinet al. (1988), indicate that the trisomic condition alters a substantial part of nuclear organization and activity, not just the small trisomic part.     

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

The nucleosome repeat structure of a rat liver chromatin component containing the satellite I DNA (repeat length 370 bp) was investigated. Digestion experiments with micrococcal nuclease, DNAase II, and the Ca2+/Mg2+-dependent endogenous nuclease of rat liver nuclei revealed a repeat unit of 185 nucleotide pairs which is shorter by approximately 10 bp than the repeat unit of the bulk chromatin of this cell type. The difference seems not to be related to the histone composition which was found to be similar in the two types of chromatin.     

Altered chromatin structure associated with a partial trisomy of chromosome 7 in the mouse

The chromatin of a mouse that is trisomic for part of chromosome 7 was investigated. Chromatin from trisomic tissue has a smaller average nucleosome DNA repeat length than chromatin from tissue taken from normal diploid littermates. DNA of the nucleosome cores is the same size in both normal and trisomic tissues. Not all of the nucleosome monomers have different repeat lengths. Normal and trisomic mouse kidney cells in tissue culture maintained their nucleosome repeat-length differences.     

Nucleosome structure in Aspergillus nidulans

The structure of chromatin from Aspergillus nidulans was studied using micrococcal nuclease and DNAase I. Limited digestion with micrococcal nuclease revealed a nucleosomal repeat of 154 base pairs for Aspergillus and 198 base pairs for rat liver. With more extensive digestion, both types of chromatin gave a similar quasi-limit product with a prominent fragment at 140 base pairs. The similarity of the two limit digests suggests that the structure of the 140 base pair nucleosome core is conserved. This implies that the difference in nucleosome repeat lengths between Aspergillus and rat liver is caused by a difference in the length of the DNA between two nucleosome cores. Digestion of Aspergillus chromatin with DNAase I produced a pattern of single-stranded fragments at intervals of 10 bases which was similar to that produced from rat liver chromatin.     

Selective release of HMG nonhistone proteins during DNase digestion of Tetrahymena chromatin at different stages of the cell cycle.

The possible role of LG-1, a Tetrahymena specific HMG protein found in the macronuclear chromatin (Hamana, K. and Iwai, K. (1979) J. Biochem. 86, 789-794), was examined in relation to the chromatin structure. The chromatin isolated from cells synchronized at different stages of the cell cycle contained about one molecule of LG-1 per nucleosome. Limited digestion of the chromatin with DNase I or micrococcal nuclease selectively released LG-1 with the nucleosomal core histones and H1 remained insoluble, bound to the resistant DNA. Depending on the cell stages several types of chromatin structure were distinguished by their nuclease sensitivity. However, the chromatin at different stages exhibited the similar behavior of the LG-1 release with the nucleases as a function of the degree of chromatin solubilization. The results suggest that LG-1 proteins play a role in the chromatin organization which is rather independent of the cell stages.     

Deoxyribonuclease II as a probe for chromatin structure. I. Location of cleavage sites

DNAase II has been shown to cleave condensed mouse liver chromatin at 100-bp² intervals while chromatin in the extended form is cleaved at 200-bp intervals (Altenburger et al., 1976). Evidence is presented here that DNA digestion patterns of a half-nucleosomal periodicity are also obtained upon DNAase II digestion of chicken erythrocyte nuclei and yeast nuclei, both of which differ in their repeat lengths (210 and 165 bp) from mouse liver chromatin. In the digestion of mouse liver nuclei a shift from the 100-bp to the 200-bp cleavage mode takes place when the concentration of monovalent cations present during digestion is decreased below 1 mM. When soluble chromatin prepared by micrococcal nuclease is digested with DNAase II the same type of shift occurs, albeit at higher ionic strength.In order to map the positions of the DNAase II cleavage sites on the DNA relative to the positions of the nucleosome cores, the susceptibility of DNAase II-derived DNA termini to exonuclease III was investigated. In addition, oligonucleosome fractions from HaeIII and micrococcal nuclease digests were end-labelled with polynucleotide kinase and digested with DNAase II under conditions leading to 100 and 200-bp digestion patterns. Analysis of the chain lengths of the resulting radioactively labelled fragments together with the results of the exonuclease assay allow the following conclusions. In the 200-bp digestion mode, DNAase II cleaves exclusively in the internucleosomal linker region. Also in the 100-bp mode cleavage occurs initially in the linker region. Subsequently, DNAase II cleaves at intranucleosomal locations, which are not, however, in the centre of the nucleosome but instead around positions 20 and 125 of the DNA associated with the nucleosome core. At late stages of digestion intranucleosomal cuts predominate and linkers that are still intact are largely resistant to DNAase II due to interactions between adjacent nucleosomes. These findings offer an explanation for the sensitivity of DNAase II to the higher-order structure of chromatin.