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  • Renormalization of myoglobin-ligand binding energetics by quantum many-body effects.

Renormalization of myoglobin-ligand binding energetics by quantum many-body effects.

Proceedings of the National Academy of Sciences of the United States of America (2014-04-11)
Cédric Weber, Daniel J Cole, David D O'Regan, Mike C Payne
ABSTRACT

We carry out a first-principles atomistic study of the electronic mechanisms of ligand binding and discrimination in the myoglobin protein. Electronic correlation effects are taken into account using one of the most advanced methods currently available, namely a linear-scaling density functional theory (DFT) approach wherein the treatment of localized iron 3d electrons is further refined using dynamical mean-field theory. This combination of methods explicitly accounts for dynamical and multireference quantum physics, such as valence and spin fluctuations, of the 3d electrons, while treating a significant proportion of the protein (more than 1,000 atoms) with DFT. The computed electronic structure of the myoglobin complexes and the nature of the Fe-O2 bonding are validated against experimental spectroscopic observables. We elucidate and solve a long-standing problem related to the quantum-mechanical description of the respiration process, namely that DFT calculations predict a strong imbalance between O2 and CO binding, favoring the latter to an unphysically large extent. We show that the explicit inclusion of the many-body effects induced by the Hund's coupling mechanism results in the correct prediction of similar binding energies for oxy- and carbonmonoxymyoglobin.

MATERIALS
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Titanium, tube, 100mm, outside diameter 4.25mm, inside diameter 3.75mm, wall thickness 0.25mm, annealed, 99.6+%
Sigma-Aldrich
Titanium, foil, thickness 0.025 mm, 99.98% trace metals basis
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Titanium, wire, diam. 0.25 mm, 99.7% trace metals basis
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Titanium, foil, thickness 2.0 mm, 99.7% trace metals basis
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Titanium(IV) oxide, rutile, <001>, (single crystal substrate), ≥99.9% trace metals basis, L × W × thickness 10 mm × 10 mm × 0.5 mm
Titanium, tube, 200mm, outside diameter 2.03mm, inside diameter 1.55mm, wall thickness 0.24mm, annealed, 99.6+%
Titanium, tube, 500mm, outside diameter 6.35mm, inside diameter 4.57mm, wall thickness 0.89mm, annealed, 99.6+%
Titanium, microfoil, disks, 10mm, thinness 0.1μm, specific density 42.8μg/cm2, permanent mylar 3.5μm support, 99.6+%
Titanium, rod, 200mm, diameter 4mm, annealed, 99.6+%
Titanium, tube, 500mm, outside diameter 25.4mm, inside diameter 23.62mm, wall thickness 0.89mm, annealed, 99.6+%
Titanium, rod, 490mm, diameter 2mm, annealed, 99.6+%
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Titanium, rod, 25mm, diameter 16mm, as drawn, 99.99+%
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Titanium, tube, 100mm, outside diameter 6.1mm, inside diameter 5.1mm, wall thickness 0.5mm, annealed, 99.6+%
Titanium, rod, 100mm, diameter 9.5mm, annealed, 99.99+%
Titanium, tube, 500mm, outside diameter 10.3mm, inside diameter 8.7mm, wall thickness 0.8mm, annealed, 99.6+%
Titanium, rod, 1000mm, diameter 16mm, annealed, 99.6+%
Titanium, wire, straight, 1000mm, diameter 1.0mm, as drawn, 99.6+%
Titanium, rod, 50mm, diameter 20mm, as drawn, 99.99+%
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Titanium, rod, 200mm, diameter 9.5mm, annealed, 99.99+%
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Titanium, wire reel, 100m, diameter 1.0mm, annealed, 99.6+%
Titanium, rod, 1000mm, diameter 3.0mm, annealed, 99.6+%
Titanium, tube, 200mm, outside diameter 1.6mm, inside diameter 1.2mm, wall thickness 0.2mm, hard, 99.6+%
Titanium, wire reel, 10m, diameter 1.5mm, as drawn, 99.6+%
Titanium, rod, 100mm, diameter 10mm, annealed, 99.6+%