Abstract
Catechol O-methyltransferase (COMT) is a SAM- and Mg2+-dependent methyltransferase that regulates neurotransmitters through methylation. Simulations and experiments have identified divergent catecholamine substrate orientations in the COMT active site: molecular dynamics simulations have favored a monodentate coordination of catecholate substrates to the active site Mg2+, and crystal structures instead preserve bidentate coordination along with short (2.65 Å) methyl donor-acceptor distances. We carry out longer dynamics (up to 350 ns) to quantify interconversion between bidentate and monodentate binding poses. We provide a systematic determination of the relative free energy of the monodentate and bidentate structures in order to identify whether structural differences alter the nature of the methyl transfer mechanism and source of enzymatic rate enhancement. We demonstrate that the bidentate and monodentate binding modes are close in energy but separated by a 7 kcal/mol free energy barrier. Analysis of interactions in the two binding modes reveals that the driving force for monodentate catecholate orientations in classical molecular dynamics simulations is derived from stronger electrostatic stabilization afforded by alternate Mg2+ coordination with strongly charged active site carboxylates. Mixed semi-empirical-classical (SQM/MM) substrate C-O distances (2.7 Å) for the bidentate case are in excellent agreement with COMT X-ray crystal structures, as long as charge transfer between the substrates, Mg2+, and surrounding ligands is permitted. SQM/MM free energy barriers for methyl transfer from bidentate and monodentate catecholate configurations are comparable at around 21–22 kcal/mol, in good agreement with experiment (18–19 kcal/mol). Overall, the work suggests that both binding poses are viable for methyl transfer, and accurate descriptions of charge transfer and electrostatics are needed to provide balanced relative barriers when multiple binding poses are accessible, for example in other transferases.
Highlights
Quantum-mechanical/molecular-mechanics (QM/MM) simulation[1,2,3,4,5,6,7,8] has taken a central role in unraveling enzyme mechanism
The bidentate substrate analogue in these structures has two Mg2+-O bond distances averaging around 2.16 Å that are comparable to the 2.12 Å average distance for the remaining species in the active site (Asp141, Asp169, Asn170, and H2O) that coordinate Mg2+
Based on expected pKas, it is believed that Glu199 forms a hydrogen bond with the hydroxyl of one catechol, and the other oxygen proximal to the methyl group of SAM is deprotonated by Lys144 (Fig 1A)
Summary
Quantum-mechanical/molecular-mechanics (QM/MM) simulation[1,2,3,4,5,6,7,8] has taken a central role in unraveling enzyme mechanism. Challenges remain in fully enumerating sources of enzymatic rate enhancement even for fundamental reactions such as methyl transfer in PLOS ONE | DOI:10.1371/journal.pone.0161868. Science user facility, which was supported by the U. S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under Contract No DEAC02-06CH11357
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