An immuno-electron microscopical analysis of transcribing multinucleosomal templates: what happens to the histones?

Transcription dynamics stabilizes nucleus-like layer structure in chromatin brush

We use a brush of DNA in a solution of transcriptional machinery and histone proteins to theoretically predict that this brush shows phase separation due to the instability arising from the disassembly of nucleosomes during transcription. In the two-phase coexistent state, collapsed chains (with relatively large nucleosome occupancy) lie at the grafting surface and swollen chains (with relatively small nucleosome occupancy) are distributed at the space above the collapsed chains, analogous to the structure of chromatin in differentiated cells. This layer structure is stabilized by the lateral osmotic pressure of swollen chains. For a relatively small grafting density, DNA brushes show tricritical points because the entropic elasticity with respect to the lateral excursion of swollen chains balances with the lateral osmotic pressure of these chains. At the tricritical points, DNA brushes show large fluctuations of local nucleosome concentration, which may be reminiscent of the fluctuations observed in embryonic stem cells.

Transcription Driven Phase Separation in Chromatin Brush

We theoretically predict the local density of nucleosomes on DNA brushes in a solution of molecules, which are necessary for transcription and the assembly of nucleosomes. Our theory predicts that in a confined space, DNA brushes show phase separation, where a region of relatively large nucleosomal occupancy coexists with a region of smaller nucleosomal occupancy. This phase separation is driven by an instability arising from the fact that the rate of transcription increases as the nucleosomal occupancy decreases due to the excluded volume interactions between nucleosomes and RNA polymerase during thermal diffusion and, in turn, nucleosomes are (in some cases) desorbed from DNA when RNA polymerase collides with nucleosomes during transcription. The miscibility phase diagram shows critical points, which are sensitive to the rate constants involved in transcription, the changes of interactions of DNA chain segments by assembling nucleosomes, and pressures that are applied to the brushes.

Active nucleosome displacement: a theoretical approach

Three-quarters of eukaryotic DNA are wrapped around protein cylinders forming so-called nucleosomes that block the access to the genetic information. Nucleosomes need therefore to be repositioned, either passively (by thermal fluctuations) or actively (by molecular motors). Here we introduce a theoretical model that allows us to study the interplay between a motor protein that moves along DNA (e.g., an RNA polymerase) and a nucleosome that it encounters on its way. We aim at describing the displacement mechanisms of the nucleosome and the motor protein on a microscopic level to understand better the intricate interplay between the active step of the motor and the nucleosome-repositioning step. Different motor types (Brownian ratchet versus power-stroke mechanism) that perform very similarly under a constant load are shown to have very different nucleosome repositioning capacities.

Stochastic model for nucleosome sliding under an external force

Heat-induced diffusion of nucleosomes along DNA is an experimentally well-studied phenomenon, presumably induced by twist defects that propagate through the wrapped DNA portion. The diffusion constant depends dramatically on the local mechanical properties of the DNA and the presence of DNA-binding ligands. This has been quantitatively understood by a stochastic three-state model. Future experiments are expected to allow application of forces on the nucleosome that induce a directed sliding. By extending the three-state model, the present work studies theoretically the response of the nucleosome to such external forces and how it is affected by the mechanical properties of the DNA and the presence of DNA-binding ligands.

Peeling and sliding in nucleosome repositioning

We investigate the mechanisms of histone sliding and detachment with a stochastic model that couples thermally induced, passive histone sliding with active motor-driven histone unwrapping. Analysis of a passive loop or twist defect-mediated histone sliding mechanism shows that diffusional sliding is enhanced as larger portions of the DNA is peeled off the histone. The mean times to histone detachment and the mean distance traveled by the motor complex prior to histone detachment are computed as functions of the intrinsic speed of the motor. Fast motors preferentially induce detachment over sliding. However, for a fixed motor speed, increasing the histone-DNA affinity (and thereby decreasing the passive sliding rate) increases the mean distance traveled by the motor.

Transcription elongation through a chromatin template

DNA transaction events occurring during cell life (replication, transcription, recombination, repair, cell division) are always linked to severe changes in the topological state of the double helix. However, since naked DNA almost does not exist in eukaryote nucleus but rather interacts with various proteins, including ubiquitous histones, these topological changes happen in a chromatin context. This review focuses on the role of chromatin fiber structure and dynamics in the regulation of transcription, with an almost exclusive emphasis on the elongation step. Beside a brief overview of our knowledge about transcribed chromatin, we will see how recent mechanistic and biochemical studies give us new insights into the way cell could modulate DNA supercoiling and chromatin conformational dynamics. The participation of topoisomerases in this complex ballet is discussed, since recent data suggest that their role could be closely related to the precise chromatin structure. Lastly, some future prospects to carry on are proposed, hoping this review will help in stimulating discussions and further investigations in the field.

The nucleosome: a transparent, slippery, sticky and yet stable DNA-protein complex

Roughly three quarters of eucaryotic DNA are tightly wrapped onto protein cylinders organized in so-called nucleosomes. Despite this fact, the wrapped DNA cannot be inert since DNA is at the heart of many crucial life processes. We focus here on physical mechanisms that might allow nucleosomes to perform a great deal of such processes, specifically 1) on unwrapping fluctuations that give DNA-binding proteins access to the wrapped DNA portions without disrupting the nucleosome as a whole, 2) on corkscrew sliding along DNA and some implications and on 3) tail-bridging-induced attraction between nucleosomes as a means of controlling higher-order folding.

Theory of Nucleosome Corkscrew Sliding in the Presence of Synthetic DNA Ligands

Histone octamers show a heat-induced mobility along DNA. Recent theoretical studies have established two mechanisms that are qualitatively and quantitatively compatible with in vitro experiments on nucleosome sliding: octamer repositioning through one-base-pair twist defects and through ten-base-pair bulge defects. A recent experiment demonstrated that the repositioning is strongly suppressed in the presence of minor-groove binding DNA ligands. In the present study, we give a quantitative theory for nucleosome repositioning in the presence of such ligands. We show that the experimentally observed octamer mobilities are consistent with the picture of bound ligands blocking the passage of twist defects through the nucleosome. This strongly supports the model of twist defects inducing a corkscrew motion of the nucleosome as the underlying mechanism of nucleosome sliding. We provide a theoretical estimate of the nucleosomal mobility without adjustable parameters, as a function of ligand concentration, binding affinity, binding site orientation, temperature and DNA anisotropy. Having this mobility in hand, we speculate on the interaction between a nucleosome and a transcribing RNA polymerase, and suggest a novel mechanism that might account for polymerase-induced nucleosome repositioning on short DNA templates.

Histone Release during Transcription: NAP1 Forms a Complex with H2A and H2B and Facilitates a Topologically Dependent Release of H3 and H4 from the Nucleosome†

Transcription through a multinucleosomal template was studied to determine why histones are released to the nascent RNA. It was first determined in competition experiments between DNA and RNA that histones H2A and H2B have a 20-fold preference for binding RNA over DNA; a preference was not seen for histones H3 and H4. Histones H3 and H4 would preferentially bind RNA, provided they were in an octameric complex with H2A and H2B. In transcription studies with T7 RNA polymerase, H3 and H4 were transferred to the nascent RNA, provided the template was linear. If the DNA was topologically restrained, which is a condition that more closely maintains transcription-induced stresses, H3 and H4 would not release. Histones H3 and H4 would be released from this template when H2A and H2B were present, a release that was enhanced by the presence of nucleosome assembly protein-1 (NAP1). Since a small quantity of H2A and H2B is sufficient to facilitate this transfer, it is proposed that H2A and H2B function to repeatedly shuttle H3 and H4 from the template DNA to the RNA. Cross-linked histones (dimethylsuberimidate-cross-linked octamer) were reconstituted into nucleosomes and found to be transferred to the RNA at the same frequency as un-cross-linked histones, an indication that such large complexes can be released during transcription. Transcription was carried out in the presence of Escherichia coli topoisomerase I so that positive coils would accumulate on the DNA. Histones H3 and H4 would again not be transferred from this DNA, unless H2A and H2B were present. In this instance, however, when NAP1 was present, the shuttling of H3 and H4 to the RNA caused a significant depletion of H2A and H2B from the positively coiled DNA. These results are discussed with regard to current models for transcription through nucleosomes.