NAP1 catalyzes the formation of either positive or negative supercoils on DNA on basis of the dimer-tetramer equilibrium of histones H3/H4.

We have studied the tetramer-dimer equilibrium of histones H3/H4 and its effect on DNA supercoiling. Two approaches were found to shift the equilibrium toward dimer. In both instances, when deposited on DNA, the dimers formed positively coiled DNA. The first approach was to modify cysteine 110 of H3 with 5,5'-dithio-bis(2-nitrobenzoic acid (DTNB) and to directly add the histones to DNA at physiological ionic strength. The second approach involved adding an excess of the histone chaperone, nucleosome assembly protein 1 (NAP1) to the H3/H4 prior to deposition on the DNA. It was also observed that when H3/H4 were deposited in the tetrameric state, negatively coiled DNA was formed. The topological state of the DNA prior to deposition was also found to influence the final conformational state of H3/H4. It is proposed that in the tetrameric state, the H3-H3 interface has a left-handed pitch prior to binding DNA. In the dimeric state, the H3-H3 interface is not established until bound to DNA, at which point either the left or right-handed pitch will form on the basis of the initial topology of the DNA. Formaldehyde cross-linking and reversal were applied to identify the histone-histone interactions that facilitate the formation of positive stress. Higher-order interactions between multiple H3/H4 dimers were required to propagate this specific conformation. Changes in the conformational state of H3/H4 were also observed when the histones were bound to DNA prior to treatment with NAP1. It is proposed that these conformational changes in H3/H4 are involved in promoter activation and transcription elongation through nucleosomes.

Histone release during transcription: acetylation stabilizes the interaction of the H2A-H2B dimer with the H3-H4 tetramer in nucleosomes that are on highly positively coiled DNA.

A high level of the post-translational modification, acetylation, is found on the N-terminal regions of the core histones H2A, H2B, H3, and H4 and is primarily located in the nucleosomes of active genes. An in vitro transcription system was applied, which utilizes T7 RNA polymerase and template DNAs that are either moderately or highly positively coiled, to determine whether acetylation alters the dynamics of histone displacement from these templates during transcription. To measure displacement, an excess of a competitor (negatively coiled DNA reconstituted with unlabeled H3-H4) was included during the transcription process. Acetylated but not unacetylated (3)H-labeled H3-H4 was found to displace with high frequency from the moderately positively coiled template. This displacement of acetylated H3-H4 was not observed when the template was highly positively coiled. Acetylated (3)H-labeled H2A-H2B also preferentially displaced to the competitor, but in this instance, transcription-induced stress on the highly positively coiled template was required. The histone chaperone, NAP1, was found to facilitate the displacement of both H3-H4 and H2A-H2B. Surprisingly, when acetylated H2A-H2B and acetylated H3-H4 were reconstituted together in the same nucleosomes, the displacement of acetylated H2A-H2B was much reduced during transcription. We conclude that acetylation alters nucleosome stability by enhancing displacement of H3-H4, while decreasing the displacement of H2A-H2B. These results are discussed with regard to potential in vivo conditions in which these observations may be relevant.