Recognition of Nucleosomes by Chromatin Factors: Lessons from Data-Driven Docking-Based Structures of Nucleosome-Protein Complexes

Publication date

2020

Authors

Horn, VeltenISNI 0000000500483679
van Ingen, HugoISNI 0000000388457648

Editors

Logie, C.
Knoch, T.A.

Advisors

Supervisors

Document Type

Part of book
Open Access logo

License

cc_by

Abstract

The function of chromatin ultimately depends on the many chromatin-associated proteins and protein complexes that regulate all DNA-templated processes such as transcription, repair and replication. As the molecular docking platform for these proteins, the nucleosome is the essential gatekeeper to the genome. As such, the nucleosome-binding activity of a myriad of proteins is essential for a healthy cell. Here, we review the molecular basis of nucleosome-protein interactions and classify the different binding modes available. The structural data needed for such studies not only come from traditional sources such as X-Ray crystallography but also increasingly from other sources. In particular, we highlight how partial interaction data, derived from for example NMR or mutagenesis, are used in data-driven docking to drive the modeling of the complex into an atomistic structure. This approach has opened up detailed insights for several nucleosome-protein complexes that were intractable or recalcitrant to traditional methods. These structures guide the formation of new hypotheses and advance our understanding of chromatin function at the molecular level.

Keywords

nucleosome, protein interactions, epigenetics, chromatin binding, acidic patch, histone tails, post-translational modifications, data-driven docking, NMR spectroscopy, XL-MS, crystallography, cryo-EM, structural models

Citation

Horn, V & van Ingen, H 2020, Recognition of Nucleosomes by Chromatin Factors: Lessons from Data-Driven Docking-Based Structures of Nucleosome-Protein Complexes. in C Logie & T A Knoch (eds), Chromatin and Epigenetics. IntechOpen, pp. 21-46. https://doi.org/10.5772/intechopen.81016