Structural and Thermodynamic Impact of Oncogenic Mutations on the Nucleosome Core Particle
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The nucleosome core particle (NCP) is essential for chromatin structure and function, serving as the fundamental unit of eukaryotic chromatin. Oncogenic mutations in core histones disrupt chromatin dynamics, altering DNA repair and transcription processes. Here, we investigate the molecular consequences of two mutations—H2BE76K and H4R92T—using 36 µs of all-atom molecular dynamics simulations and experimental biophysical assays. These mutations destabilize the H2B-H4 interface by disrupting critical salt bridges and hydrogen bonds, reducing binding free energy at this interface. Principal component analysis reveals altered helix conformations and increased interhelical distances in mutant systems. Thermal stability assays (TSA) and differential scanning calorimetry (DSC) confirm that these mutations lower the dimer dissociation temperature and reduce enthalpy compared to the wild type. Taken together, our results elucidate how these mutations compromise nucleosome stability and propose mechanisms through which they could modulate chromatin accessibility and gene dysregulation in cancer.
Statement of Significance
The nucleosome is the essential packaging unit of DNA. ‘Oncohistones’ which are histone mutations that are associated with cancer, are known to compromise the stability of the nucleosome and affect nucleosome sliding. Here we perform long-time molecular dynamics simulations of two buried histone core mutations, demonstrating that these mutations reduce the stability of the histone core at the H2B-H4 interface. Next, we demonstrate that these same mutations lower the dimer dissociation temperature and shift the nucleosome dissociation pathway.
