Theoretical Investigations of Nitric Oxide Channeling in Mycobacterium tuberculosis Truncated Hemoglobin N

AUTOR(ES)

Daigle, Richard

FONTE

The Biophysical Society

RESUMO

Mycobacterium tuberculosis group I truncated hemoglobin trHbN catalyzes the oxidation of nitric oxide (•NO) to nitrate with a second-order rate constant k ≈ 745 μM−1 s−1 at 23°C (nitric oxide dioxygenase reaction). It was proposed that this high efficiency is associated with the presence of hydrophobic tunnels inside trHbN structure that allow substrate diffusion to the distal heme pocket. In this work, we investigated the mechanisms of •NO diffusion within trHbN tunnels in the context of the nitric oxide dioxygenase reaction using two independent approaches. Molecular dynamics simulations of trHbN were performed in the presence of explicit •NO molecules. Successful •NO diffusion from the bulk solvent to the distal heme pocket was observed in all simulations performed. The simulations revealed that •NO interacts with trHbN at specific surface sites, composed of hydrophobic residues located at tunnel entrances. The entry and the internal diffusion of •NO inside trHbN were performed using the Long, Short, and EH tunnels reported earlier. The Short tunnel was preferentially used by •NO to reach the distal heme pocket. This preference is ascribed to its hydrophobic funnel-shape entrance, covering a large area extending far from the tunnel entrance. This funnel-shape entrance triggers the frequent formation of solvent-excluded cavities capable of hosting up to three •NO molecules, thereby accelerating •NO capture and entry. The importance of hydrophobicity of entrances for •NO capture is highlighted by a comparison with a polar mutant for which residues at entrances were mutated with polar residues. A complete map of •NO diffusion pathways inside trHbN matrix was calculated, and •NO molecules were found to diffuse from Xe cavity to Xe cavity. This scheme was in perfect agreement with the three-dimensional free-energy distribution calculated using implicit ligand sampling. The trajectories showed that •NO significantly alters the dynamics of the key amino acids of Phe62(E15), a residue proposed to act as a gate controlling ligand traffic inside the Long tunnel, and also of Ile119(H11), at the entrance of the Short tunnel. It is noteworthy that •NO diffusion inside trHbN tunnels is much faster than that reported previously for myoglobin. The results presented in this work shed light on the diffusion mechanism of apolar gaseous substrates inside protein matrix.

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