Symmetry of a partially-ligated state maintained by dynamics in a negatively cooperative system Article Swipe

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Rebecca Strawn , P. S. Murthy , Rüdiger Ettrich , István Pelczer , Jannette Carey ·

YOU? · · 2024 · Open Access · · DOI: https://doi.org/10.3389/frbis.2024.1359979 · OA: W4392108744

Symmetry was a key concept underlying the MWC model for allostery advanced in 1965 by Monod, Wyman, and Changeux. The reciprocal interactions of symmetrically-arranged identical subunits were proposed to stabilize multimeric assemblies together with the free energy from bound ligands that progressively favor a monomer-like state. Structural symmetry of subunits was assumed to be maintained in the partially-ligated states, even if ligand placement itself is not symmetric. Partially-ligated states can be populated sufficiently for experimental study only in negatively cooperative systems, which were not considered in the MWC model. The work reported here uses 1 H, 13 C, 15 N, and 19 F NMR to evaluate the structural symmetry of the hexameric arginine repressor of E. coli , a negatively cooperative system, with a single bound L-arginine ligand. The analysis indicates that the singly-ligated hexamer maintains structural symmetry as probed by these four NMR nuclei. The results are consistent with earlier molecular dynamics simulations suggesting that the global dynamics of the singly-ligated assembly are harnessed to maintain structural symmetry. The results extend MWC symmetry concepts to this negatively cooperative system, and indicate a role for global dynamics in allostery.