Effects of histone tail domains on the rate of transcriptional elongation through a nucleosome.

The N-terminal tail domains of the core histones play important roles in gene regulation, but the exact mechanisms through which they act are not known. Recent studies suggest that the tail domains may influence the ability of RNA polymerase to elongate through the nucleosomal DNA and, thus, that posttranslational modification of the tail domains may provide a control point for gene regulation through effects on the elongation rate. We take advantage of an experimental system that uses bacteriophage T7 RNA polymerase as a probe for aspects of nucleosome transcription that are dominated by the properties of nucleosomes themselves. With this system, experiments can analyze the synchronous, real-time, single-passage transcription on the nucleosomal template. Here, we use this system to directly test the hypothesis that the tail domains may influence the "elongatability" of nucleosomal DNA and to identify which of the tail domains may contribute to this. The results show that the tail domains strongly influence the rate of elongation and suggest that the effect is dominated by the N-terminal domains of the (H3-H4)(2) tetramer. They further imply that tail-mediated octamer transfer is not essential for elongation through the nucleosome. Acetylation of the tail domains leads to effects on elongation that are similar to those arising from complete removal of the tail domains.

Coupled-enzymatic assays for the rate and mechanism of DNA site exposure in a nucleosome.

The packaging of DNA in nucleosomes presents obstacles to the action of gene regulatory proteins and polymerases on their natural chromatin substrates. We recently reported that nucleosomes exist in a conformational equilibrium, transiently exposing stretches of their DNA off the histone surface. Such "site exposure" processes potentially provide the needed access of proteins to DNA in chromatin. However, the experiments that reveal site exposure are carried out on timescales of tens of minutes to hours. The actual rates of site exposure are not known. Here we use T7 RNA polymerase and exonuclease III as probes to obtain a more relevant lower bound on the rate of nucleosomal site exposure. We find that the organization of DNA into nucleosomes detectably slows the elongation rate of the polymerase, but that full-length elongation, which requires access to all of the DNA, occurs on the seconds timescale. Independent experiments with exonuclease III, which probes the outermost DNA segments only, similarly show that site exposure in these regions occurs on a timescale of seconds or faster. We conclude that site exposure is sufficiently rapid that it may play a role in the initial binding of regulatory proteins to nucleosomal target sites. These rapid rates argue against a nucleosome sliding model for the mechanism of site exposure. Surprisingly, the measured rates may be too slow to account for the known rates of polymerase elongation in vivo. Mechanisms by which polymerase progression through nucleosomes might be catalyzed are discussed.

Nucleosome transcription studied in a real-time synchronous system: test of the lexosome model and direct measurement of effects due to histone octamer.

We report the development of an alternative approach to studies on nucleosome transcription in vitro. This model system allows us to follow the real-time, synchronous and single passage of RNA polymerase molecules as they progress through DNA packaged in nucleosomes. Results are obtained using phage T7 RNA polymerase with reconstituted nucleosomes prepared from native histones or from histones in which the two H3 Cys 110 thiol groups have been oxidized to form a disulfide bridge. The lengths and concentrations of radiolabeled transcripts produced as a function of time provide direct measurements of the velocities of transcription on naked DNA and on the nucleosomal particles, and allow both relative and absolute efficiencies of initiation, elongation and completion to be determined. These direct measurements of reveal new features of the elongation process. The velocities of elongation on the nucleosomal templates are slightly but reproducibly slower than those on naked DNA. This difference is found to be due to a slight increase in pausing on the nucleosomal templates. Remarkably, the sites of this increased pausing on the nucleosomal templates are also pause sites on the naked DNA. The velocities of elongation on native or oxidized nucleosomal templates are found to be identical to within +/- 10%. We conclude that nucleosomes having covalently bound H3 molecules are substrates for transcription, suggesting that the splitting of the nucleosome postulated in the lexosome model of nucleosome transcription is not a necessary event. Interesting future applications of this methodology are discussed.