Abstract
Why most of the in vivo experiments do not find the 30-nm chromatin fiber, well studied in vitro, is a puzzle. Two basic physical inputs that are crucial for understanding the structure of the 30-nm fiber are the stiffness of the linker DNA and the relative orientations of the DNA entering/exiting nucleosomes. Based on these inputs we simulate chromatin structure and show that the presence of non-histone proteins, which bind and locally bend linker DNA, destroys any regular higher order structures (e.g., zig-zag). Accounting for the bending geometry of proteins like nhp6 and HMG-B, our theory predicts phase-diagram for the chromatin structure as a function of DNA-bending non-histone protein density and mean linker DNA length. For a wide range of linker lengths, we show that as we vary one parameter, that is, the fraction of bent linker region due to non-histone proteins, the steady-state structure will show a transition from zig-zag to an irregular structure—a structure that is reminiscent of what is observed in experiments recently. Our theory can explain the recent in vivo observation of irregular chromatin having co-existence of finite fraction of the next-neighbor (i + 2) and neighbor (i + 1) nucleosome interactions.
Highlights
In cells, DNA, with the help of a large number of proteins, is packaged into a higher order structure known as chromatin
In this work we study the higher order folding of nucleosome-bound DNA taking into account the possibility of non-histone proteins binding along the linker region, bending the DNA locally
We investigate the influence of linker length on the formation of irregular structures
Summary
DNA, with the help of a large number of proteins, is packaged into a higher order structure known as chromatin. When the cells are preparing to divide, one observes that the DNA, with the help of many proteins, assumes a highly condensed structure. It is being thought that the 10-nm string of chromatin is further packaged in a hierarchical manner to produce this highly compact mitotic chromosome [1]. What this hierarchy of structures, if any, is and exactly how a DNA chain gets packaged into this highly compact form are interesting open questions [2,3,4]
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