New Insights into the Allosteric Mechanism of Human Hemoglobin from Molecular Dynamics Simulations

It is still difficult to obtain a precise structural description of the transition between the deoxy T-state and oxy R-state conformations of human hemoglobin, despite a large number of experimental studies. We used molecular dynamics with the Path Exploration with Distance Constraints (PEDC) method...

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Bibliographic Details
Published in:Biophysical journal 2002-06, Vol.82 (6), p.3224-3245
Main Authors: Mouawad, Liliane, Perahia, David, Robert, Charles H., Guilbert, Christophe
Format: Article
Language:English
Subjects:
Binding Sites
Biochemistry
Biophysical Phenomena
Biophysics
Dimerization
Heme - chemistry
Hemoglobins - chemistry
Humans
Hydrogen Bonding
In Vitro Techniques
Models, Molecular
Molecular biology
Oxyhemoglobins - chemistry
Protein Conformation
Protein Structure, Quaternary
Protein Structure, Secondary
Proteins
Rotation
Thermodynamics
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Summary:It is still difficult to obtain a precise structural description of the transition between the deoxy T-state and oxy R-state conformations of human hemoglobin, despite a large number of experimental studies. We used molecular dynamics with the Path Exploration with Distance Constraints (PEDC) method to provide new insights into the allosteric mechanism at the atomic level, by simulating the T-to-R transition. The T-state molecule in the absence of ligands was seen to have a natural propensity for dimer rotation, which nevertheless would be hampered by steric hindrance in the “joint” region. The binding of a ligand to the α subunit would prevent such hindrance due to the coupling between this region and the α proximal histidine, and thus facilitate completion of the dimer rotation. Near the end of this quaternary transition, the “switch” region adopts the R conformation, resulting in a shift of the β proximal histidine. This leads to a sliding of the β-heme, the effect of which is to open the β-heme’s distal side, increasing the accessibility of the Fe atom and thereby the affinity of the protein. Our simulations are globally consistent with the Perutz strereochemical mechanism.
ISSN:0006-3495
1542-0086
DOI:10.1016/S0006-3495(02)75665-8