Sensitivity of regions of chromatin containing hyperacetylated histones to DNAse I.

We have used DNase I as a probe for structural changes in regions of chromatin containing highly acetylated histones. The enzyme preferentially digests regions of chromatin that are associated with rapidly or highly acetylated histones, suggesting that nucleosomes in these regions are in a more accessible conformation. This sensitivity to DNase I may be related to the same factors which cause the differential digestion of active genes.     

H3 phosphorylation-dependent structural changes in chromatin. Implications for the role of very lysine-rich histones

Contrary to native H1/H5-containing chromatin where phosphorylation induces local structural changes affecting chromatin condensation, in stripped fibers phosphorylation of the totality of H3 molecules does not affect significantly chromatin conformation and DNA-protein interactions. Modification of H3 causes only a slight increase of flexibility of nucleosomal chains, despite important changes in histone topography revealed by immunochemical reactivity studies. We suggest that phosphorylation may only induce into the system the potential for dynamic change by modulating histone-histone interactions within and between nucleosomes, probably as a result of conformational change in the H3 protein. The signal for structural change would come from one or other factors (very lysine-rich histones, non-histones) that influence internucleosomal interactions at very specific locations in the chromatin, probably through protein-protein contacts. So, phosphorylation may modify a direct interaction between the N-terminal basic tail of H3 and very lysine-rich histones.     

Phosphorylation of the lysine-rich histones throughout the cell cycle.

The phosphorylating of the lysine-rich histone at various stages in the cell cycle has been studied. In rapidly dividing cell populations the lysine-rich histone is phosphorylated rapidly after synthesis and more slowly once bound to the chromosome. The half-life of hydrolysis of such interphase phosphorylation in 5 hr except during mitosis when the phosphata hydrolysis increases almost three-fold. During mitosis there is extensive phosphorylation at sites different from those phosphorylated during interphase and a smaller measure of sites common to both mitotic and interphase cells. The sites of mitotic phosphorylation are most critically distinguished from those phosphorylated in interphase by the rapidly hydrolysis of M-phase phosphohistone when the cells divide and enter the G1 phase of the cell cycle.     

Radioiodination of chicken erythrocyte histones H4 and H5 in chromatin.

The conformational state of histones in isolated chicken erythrocyte chromatin was studied using procedures developed for probing surface proteins on membranes. Under controlled conditions, only exposed tyrosyl residues react with iodide radicals, generated either by the oxidant, chloramine-T (paratoluenesulfonyl chloramide), or the enzyme lactoperoxidase, giving monoidotyrosine. Using 125-iodine, this study compared the reactive tyrosines in free and bound histones H4, and H5. The relative extent of iodination of these histones within (H4) and outside (H5) of the nucleosomes was measured after extraction and gel electrophoresis. Each of the histones was further analyzed for the extent of specific tyrosine iodination by separating the tryptic peptides by high voltage electrophoresis. The identity of the labeled peptide was determined by dansylation of the amino acids present in each hydrolyzed peptide. The results show that there is a difference in the conformational arrangement of these histones on chromatin and in the free forms, since in chromatin not all tyrosine residues are as accessible for iodination as in the denatured state. Residue 53 of histone H5 for instance is more reactive than residues 28 and 58, indicating that the segments containing the latter residues are involved in either protein-DNA or protein-protein interactions. In histone H4, preferential labeling of 2 of the 4 tyrosines present was also observed.     

Movement of histones in chromatin induced by shearing.

Methylation of accessible DNA within chromatin by restriction modification methylases from Haemophilus influenzae was used to detect movement of histones along the DNA strand during chromatin manipulation. Methylation at different stages of chromatin preparation was followed by titration of the nucleoprotein with ploy(D-lysine), digestion of chromosomal proteins with pronase and analysis of the DNA-poly(D-lysine) complex in steep cesium chloride gradients. Comparison of the specific radioactivities in the peak fractions of the free DNA and the DNA-poly(D-lysine) complex, respectively, reveals that lateral movement of histones, relative to specific sites in the DNA marked by restriction methylases, occurs during manipulation and fragmentation of chromatin.     

On the arrangement of histones in chromatin.

It was found that nucleoprotein particles formed after DNase I action on calf thymus chromatin contain single-stranded DNA fragments, associated with histones only by ionic linkages. These results suggest that histones in chromatin are bound ionically only to one polynucleotide strand of double-helical DNA, protecting it against nucleolytic attack.     

Reduced repeat length of nascent nucleosomal DNA is generated by replicating chromatin in vivo

Micrococcal nuclease digestion of nuclei from sea urchin embryos revealed transient changes in chromatin structure which resulted in a reduction in the repeat length of nascent chromatin DNA as compared with bulk DNA. This was considered to be entirely the consequence of in vivo events at the replication fork (Cell 14, 259, 1978). However, a micrococcal nuclease-generated sliding of nucleosome cores relative to nascent DNA, which might account for the smaller DNA fragments, was not excluded. In vivo [3H]thymidine pulse-labeled nuclei were fixed with a formaldehyde prior to micrococcal nuclease digestion. This linked chromatin proteins to DNA and thus prevented any in vitro sliding of histone cores. All the nascent DNAs exhibiting shorter repeat lengths after micrococcal nuclease digestion, were resolved at identical mobilities in polyacrylamide gels of DNA from fixed and unfixed nuclei. We conclude that these differences in repeat lengths between nascent and bulk DNA was generated in vivo by changes in chromatin structure during replication, rather than by micrococcal nuclease-induced sliding of histone cores in vitro.     

Removal of histone H1 exposes linker DNA in chromatin to DNAse I

After removal of histone H1 about 40% of DNA in chromatin acquires the sensitivity of naked DNA to DNAse I. Digestion of H1-depleted chromatin with DNAse I leads to a qualitative change in the digestion pattern, generating DNA fragments of approx. 200 b.p. and multiples, similar to those obtained with micrococcal nuclease. Both effects are reversed upon reconstitution of purified H1 to H1-depleted chromatin.     

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.     

On the occurrence of nucleosome phasing in chromatin.

We have found that DNAase I digestion of yeast, HeLa and chicken erythrocyte nuclei produces a pattern of DNA fragments spaced 10 bases apart and extending to at least 300 bases. This "extended ladder" of DNA fragments is most clearly seen with yeast, and least clearly with chicken erythrocytes. The appearance of regular and discrete bands at sizes much larger than the repeat size shows that the core particles (140 bp of DNA + H2A, H2B, H3 H4) in at least some fraction of chromatin are spaced in a particular fashion, by discrete lengths of spacer DNA, and not randomly. Based on the abundance of small repeats in yeast and from experiments with nucleosome oligomers, we conclude that the extended ladder and nucleosomal phasing probably arise mainly from regions in the chromatin in which nucleosome cores are closely packed or closely spaced (140-160 bp X n). Contributions from less closely packed but still accurately phased nucleosomes, however, cannot be entirely excluded.