Structure and non-reactive dynamics of the dimeric catalytic domain of human carbonic anhydrase IX

Abstract

Despite the availability of high resolution crystal structure of the catalytic domain of human carbonic anhydrase IX (denoted as HCA IX-c), its solution structure and functional dynamics are mostly unknown. In this article, we report classical molecular dynamics (MD) simulation studies on the structure and non-reactive dynamics of dimeric HCA IX-c (d-HCA IX-c, with chains A and B) in water and compare them to each chain simulated in water as a monomeric solute (mA/mB). While the average solution structures appear to be largely similar in all systems, d-HCA IX-c shows significant deviations from mA and mB in terms of non-reactive reorganization of the active site needed to initiate the rate determining proton transfer step between a zinc-bound water and one of the sidechain N-atoms of a distal histidine residue (His-64). First, 2−6 water molecules are found to form fluctuating hydrogen bonded networks that would serve as proton paths across the active site. A minimally frustrated core of each monomer in the dimeric protein is found to be associated with a significantly higher likelihood of forming complete proton transfer pathways mediated by 2 water molecules synchronously at the two active sites hosted by the monomeric chains. The relative stability and kinetics of transition between two major sidechain rotamers of His-64 are also affected by dimerization. The sidechain rotation of His-64 is found to involve at least one transition as slow as 105s−1 in chain A of d-HCA IX-c thereby rendering it slower than the actual rate determining proton transfer step. This observation indicates an important deviation from the widely accepted mechanism of catalysis by HCAs.