Sickle Cell Hemoglobin Drugged with Cyclic Peptides is Aggregation Incompetent

Sickle cell disease is a monogenic blood disorder associated with a mutation in the HBB gene encoding for the β-globin of normal adult hemoglobin (HbA). This mutation transcribes into a Gluβ6→Val-β6 substitution in the β-globins, inducing the polymerization of this hemoglobin form (HbS) when in the T-state. Despite advances in stem cell and gene therapy and the recent approval of a new anti-sickling drug, therapeutic limitations persist. Herein, we demonstrate through molecular dynamics and umbrella sampling, that (unrestrained) blockage of the hydrophobic pocket involved in the lateral contact of the HbS fibers by 5-mer cyclic peptides (CPs) recently proposed as SCD aggregation inhibitors (J. Med. Chem. 2023, 66, 16062), is enough to turn the dimerization of HbS thermodynamically unfavorable. Amongst these potential drugs, some exhibit an estimated pocket abandonment probability of around 15-20% within the simulations’ timeframe, and an impressive specificity towards the mutated Val-β6. Additionally, we show that the dimerization can be thermodynamically unfavored by blocking a nearby region while the pocket remains undrugged. These results are compared with curcumin, an antisickling molecule and a pan-assay interference compound, with a good binding affinity for different proteins and protein domains. Our results confirm the potential of some of these CPs as anti-sickling drugs to reduce the concentration of aggregation-competent HbS.