Extension and long-range contacts drive chromatin clutches and aggregates.

Abstract

Chromatin organization plays a vital role in gene expression and DNA replication. Whether the local arrangement in vivo is a 10-nm array or 30-nm fiber remains controversial. Moreover, it remains unclear whether the structure and dynamics are closer to a liquid or solid on a larger scale. Multiple factors, such as DNA linker lengths, chromatin remodelers, histone modifications, and ionic environments, can affect the structure of chromatin. Using a near-atomistic coarse-grained model without additional assumptions, we studied the force-extension behavior of uniform canonical chromatin with 12 nucleosomes and 20-bp linkers. We found that forces below 3 pN result in a spring-like linear extension as nucleosomes undergo shear motions. However, forces beyond 3.5 pN break chromatin into trimer and tetramer clutches, thus enabling a dramatic non-uniform extension. Meanwhile, inter-chain contacts and interdigitation can facilitate chromatin unfolding. Under a crowding environment, chromatin unfolds and exposes more nucleosomal surfaces, allowing favorable inter-chain inter-nucleosomal interactions, such as stackings. These results reconcile observed ordered fibers in vitro and disordered arrays in vivo. The high nucleosome concentration and the tension provided by molecular motors can cause disordered chromatin arrays to prevail in vivo. These factors may be relevant to the irregularity of heterochromatin and mitotic chromosomes. Furthermore, the strong inter-chain contacts can lead to the formation of condensates. By applying such models under different nucleosome and salt concentrations, we will provide more insights into whether chromatin favors liquid- or solid-like states. We can also test whether long-range contacts can drive percolation transitions. Our simulations provide a detailed microscopic description of genome organization and characterize chromatin's local and bulk properties.