Binding of ethidium bromide to fractionated chromatin

The DNA intercalators ethidium bromide and propidium iodide also bind to core histones

Eukaryotic DNA is compacted in the form of chromatin, in a complex with histones and other non-histone proteins. The intimate association of DNA and histones in chromatin raises the possibility that DNA-interactive small molecules may bind to chromatin-associated proteins such as histones. Employing biophysical and biochemical techniques we have characterized the interaction of a classical intercalator, ethidium bromide (EB) and its structural analogue propidium iodide (PI) with hierarchical genomic components: long chromatin, chromatosome, core octamer and chromosomal DNA. Our studies show that EB and PI affect both chromatin structure and function, inducing chromatin compaction and disruption of the integrity of the chromatosome. Calorimetric studies and fluorescence measurements of the ligands demonstrated and characterized the association of these ligands with core histones and the intact octamer in absence of DNA. The ligands affect acetylation of histone H3 at lysine 9 and acetylation of histone H4 at lysine 5 and lysine 8 ex vivo. PI alters the post-translational modifications to a greater extent than EB. This is the first report showing the dual binding (chromosomal DNA and core histones) property of a classical intercalator, EB, and its longer analogue, PI, in the context of chromatin.

Flow cytometric evaluation of DNA stainability with propidium iodide after histone H1 extraction

A flow cytometric evaluation of the effect of the histone H1 extraction on DNA stainability with propidium iodide was performed on isolated HeLa nuclei. Selective removal of the lysine-rich protein was attained by using two established techniques involving treatment with 0.7 M NaCl or low pH. DNA stainability was monitored at different dye/DNA-P ratios, varying from low to high saturating concentrations. Depletion of the histone H1from nuclei results in the transition from low to high affinity of a portion of binding sites, as shown by 1) the increase in fluorescence intensity after staining with the dye at low saturating concentrations and 2) the higher value of the fluorescence intensity ratio (FI5/FI50) exhibited by H1-depleted nuclei stained with a low (5 micrograms/ml) vs. a high (50 micrograms/ml) concentration, as compared with control samples.

The effect of various conditions of chromatin isolation on the nucleosomal structure of the isolated chromatin

Chromatin from calf thymus isolated under hypotonic conditions in the presence of various agents was investigated by methods of electron microscopy prior to and after EDTA treatment. It is shown that the presence of chelating agents and, especially, the application of considerable mechanical forces in the course of isolation may cause damage to the nucleosomal structure of the chromatin. Moreover, sufficiently great mechanical forces are liable to destroy the structure of the chromatin nucleosomal fibres even when they are packed in structures of a higher order of organization of the chromatin.

Binding of polylysine to chromatin subunits and cleavage by micrococcal nuclease. A comparison of accessible sites

Native chromatin and chromatin subunits (nucleosomes) were titrated with polylysine and digested with micrococcal nuclease and deoxyribonuclease I at individual lysine/nucleotide ratios. In contrast to earlier reports, which had been obtained using mechanically sheared chromatin, a comparison of the sites accessible for micrococcal nuclease and polylysine reveals that polylysine does not preferentially protect the micrococcal-nuclease-susceptible sites in chromatin. Similar results were obtained in digestion experiments with DNase I. From the experimental data presented we conclude that polylysine does not preferentially bind to the internucleosomal DNA, which is the prime target site for micrococcal nuclease, but rather to the total nucleosomal DNA moiety.