Molecular insights of inhibition in sickle hemoglobin polymerization upon glutathionylation: hydrogen/deuterium exchange mass spectrometry and molecular dynamics simulation-based approach

In sickle cell anemia, polymerization of hemoglobin in its deoxy state leads to the formation of insoluble fibers that result in sickling of red blood cells. Stereo-specific binding of isopropyl group of beta Val6, the mutated amino-acid residue of a tetrameric sickle hemoglobin molecule (HbS), with hydrophobic groove of another HbS tetramer initiates the polymerization. Glutathionylation of beta Cys93 in HbS was reported to inhibit the polymerization. However, the mechanism of inhibition in polymerization is unknown to date. In our study, the molecular insights of inhibition in polymerization were investigated by monitoring the conformational dynamics in solution phase using hydrogen/deuterium exchange-based mass spectrometry. The conformational rigidity imparted due to glutathionylation of HbS results in solvent shielding of beta Val6 and perturbation in the conformation of hydrophobic groove of HbS. Additionally, molecular dynamics simulation trajectory showed that the stereo-specific localization of glutathione moiety in the hydrophobic groove across the globin subunit interface of tetrameric HbS might contribute to inhibition in polymerization. These conformational insights in the inhibition of HbS polymerization upon glutathionylation might be translated in the molecularly targeted therapeutic approaches for sickle cell anemia.