Subunit structures of different electrophoretic forms of nucleosomes.

We have reported previously that five different electrophoretic forms of mononucleosomes (MI to MV) are produced upon treatment of mammalian chromatin with micrococcal nuclease. We show here that each of these mononucleosome classes possesses internal heterogeneity due to the presence of a variety of minor protein species. Defined subsets of mononucleosome classes MII to MV have been reconstituted by reassociating stripped nucleosomes with histone H1 and non-histone protein HMG-17. This procedure leads to the generation of the same five major electrophoretic forms of mononucleosomes found in native chromatin. From the results of one- and two-dimensional electrophoretic analyses on reconstituted samples, it is concluded that different mononucleosome classes possess the following subunit structures: MI, core histone octamer (8-mer); MII, 8-mer plus one copy of HMG-17; MIIIA, 8-mer plus one copy of histone H1; MIIIB, 8-mer plus two copies of HMG-17; MIV, 8-mer plus one copy each of histone H1 and HMG-17; and MV, 8-mer plus one copy of histone H1 and two copies of HMG-17. Equal numbers of HMG-14 molecules can substitute for HMG-17 and generate the same nucleosome components. Thus, mononucleosomes possess independent binding sites for at least 1 histone H1 molecule and 2 nonhistone chromosomal protein molecules. We show further that reassociated HMG-17 molecules can exhibit a rapid interchange between binding sites, even under conditions of low ionic strength.

Reassociation of histone H1 with nucleosomes.

The role of histone H1 in nucleosome heterogeneity and structure has been studied using a reconstitution procedure. Histone H1 and non-histone proteins are removed selectively from enzymatically fragmented chromatin by Dowex 50W-X2 treatment. The resulting "stripped" chromatin then is reassociated with purified histone H1 using step gradient dialysis. Material reconstituted in this manner was examined by gel electrophoresis, protein cross-linking, and chromatin fingerprinting. The results demonstrate that the histone H1 molecule efficiently binds to nucleosomes with fidelity in an apparent noncooperative manner. Polynucleosomes possess two specific binding sites for histone H1 per histone octamer; the first binding site is of higher affinity than the second. The 160-base pair nuclease digestion barrier and nucleosome electrophoretic class (MIII)n are established upon binding the 1st histone H1 molecule. Upon binding the 2nd histone H1 molecule, polynucleosomes assume a highly compact conformation. The experimental approach introduced here should permit determining whether nucleosomes possess independent specific binding sites for other chromosomal proteins, and should allow reconstitution of the other electrophoretic forms of nucleosomes which we have described previously.

Histone molar ratios among different electrophoretic forms of mono- and dinucleosomes.

The relative molar ratios of each of the histone classes and protein A24 have been determined in nuclei, chromatin, and different electrophoretic forms of mono- and dinucleosomes of cultured mouse cells. For this purpose, [3H]lysine- and [14C]arginine-labeled cells were used for sample preparations, and stoichiometries were estimated from protein radioactivity profiles and known amino acid compositions following sodium dodecyl sulfate (SDS)-gel electrophoresis. The results demonstrate that upper limits of one and two histone H1 molecules exist per mono- and dinucleosome, respectively. However, isolated nuclei contain less than one copy of histone H1 per nucleosome. In addition, among the chromatin subfractions studied, histones H3, H2B, and H4 are essentially equimolar, while histone H2A is less than equimolar by 19 +/- 9%. This latter finding offers direct support to the proposal of Goldknopf (Goldknopf, I. L., French, M. F., Musso, R., and Busch, H. (1977) Proc. Natl. Acad. Sci. U. S. A. 74, 5492-5495) that protein A24 replaces histone H2A in the octamer protein core of the nucleosome, since about 10% of the total histone H2A of cultured mouse cells is in the form of protein A24 and is present in nucleosomes. From the results of the present study, it is concluded that electrophoretic fractionation of mono- and dinucleosomes is not due to variable molar ratios or amounts of the four smaller histone classes, but depends on part on DNA length, the number of associated histone H1 molecules, and non-histone chromosomal proteins.