The influence of 10n and 10n+5 linker lengths on chromatin fiber topologies explored by mesoscale modeling.

The structural organization of chromatin is intricately influenced by the length of linker DNA connecting nucleosomes. Some studies have suggested preferred linker lengths of 10n and 10n+5 base pairs (bp) (n = integer). Because these lengths dictate the rotational orientation of successive nucleosomes in the fiber axis, they can markedly affect chromatin fiber compaction and topology. Using a refined mesoscale chromatin model with 5-bp resolution, we investigate the influence of linker DNA periodicity, linker histone density, salt concentration, and starting fiber topology on chromatin architecture for regular fibers versus "life-like" fibers, the latter with irregular spacing between nucleosomes. Our results reveal that regular fibers with 10n linkers exhibit compact zigzag configurations, whereas 10n+5 linkers generate more open and flexible structures. However, these effects are pronounced only for short linker lengths, as longer linkers are more heterogeneous. Moreover, increased linker histone density further enhances compaction for long linker lengths, and lower salt concentration modifies chromatin topologies, diminishing periodicity-driven effects. In addition, any periodicity effect in tightly packed solenoid configurations is much less pronounced. All these trends for regular fibers are reduced in life-like fibers with irregularly spaced nucleosomes, despite having the same average spacing. Moreover, the trend details depend highly on specific features of the fiber architecture as designed in experiments and simulations. Overall, our study highlights how reported differences depend on modeling details and emphasizes the role of linker DNA length in regulating chromatin fiber architecture and its potential implications for genome accessibility and expression.