Fibronectin Module FN<sup>III</sup>9 Adsorption at Contrasting Solid Model Surfaces Studied by Atomistic Molecular Dynamics Karina Kubiak-Ossowska Paul A. Mulheran Wieslaw Nowak 10.1021/jp5020077.s002 https://acs.figshare.com/articles/media/Fibronectin_Module_FN_sup_III_sup_9_Adsorption_at_Contrasting_Solid_Model_Surfaces_Studied_by_Atomistic_Molecular_Dynamics/2262031 The mechanism of human fibronectin adhesion synergy region (known as integrin binding region) in repeat 9 (FN<sup>III</sup>9) domain adsorption at pH 7 onto various and contrasting model surfaces has been studied using atomistic molecular dynamics simulations. We use an ionic model to mimic mica surface charge density but without a long-range electric field above the surface, a silica model with a long-range electric field similar to that found experimentally, and an Au {111} model with no partial charges or electric field. A detailed description of the adsorption processes and the contrasts between the various model surfaces is provided. In the case of our model silica surface with a long-range electrostatic field, the adsorption is rapid and primarily driven by electrostatics. Because it is negatively charged (−1e), FN<sup>III</sup>9 readily adsorbs to a positively charged surface. However, due to its partial charge distribution, FN<sup>III</sup>9 can also adsorb to the negatively charged mica model because of the absence of a long-range repulsive electric field. The protein dipole moment dictates its contrasting orientation at these surfaces, and the anchoring residues have opposite charges to the surface. Adsorption on the model Au {111} surface is possible, but less specific, and various protein regions might be involved in the interactions with the surface. Despite strongly influencing the protein mobility, adsorption at these model surfaces does not require wholesale FN<sup>III</sup>9 conformational changes, which suggests that the biological activity of the adsorbed protein might be preserved. 2014-08-21 00:00:00 Atomistic Molecular DynamicsThe mechanism Model Surfaces Studied protein model surfaces adsorption mica surface charge density FNIII 9 Fibronectin Module FNIII 9 Adsorption integrin binding region model silica surface fibronectin adhesion synergy region