Differential dissociation of chromatin digests: a novel approach revealing a hierarchy of DNA-protein interactions within chromatin domains.

We describe here a novel approach to the dissection of chromatin structure by extracting DNA fragments from digested nuclei irreversibly immobilized (via proteins) on Celite columns. Three successive gradients (NaCl, LiCl-urea, temperature) are used to release three families of DNA fragments: namely, the 'DNA adherence' classes DNA-0, DNA-I and DNA-II, respectively. This 'protein image' DNA chromatography separates DNA fragments in accordance with the tightness of their bonds with proteins in situ. There are at least two DNA-skeleton attachment sites differing from each other by their resistance to the dissociating agents used as well as their susceptibility to DNAase I and S1 nuclease treatments, DNA cross-linking and single-stranded breaks. Several lines of evidence show a specific, topological rather than chemical, DNA-protein linkage at the tight attachment site. A hierarchy of chromatin loops demarcated by these attachment sites was determined. The technique described is generally applicable and can be used both to probe DNA-protein interactions and to map specific DNA sequences within the chromatin domain.