| dc.description.abstract | Cystic fibrosis (CF) disease is a lethal genetic disease that causes persistent lung
infections, limits the ability to breathe, and significantly reduce the life expectancy.
In CF patients, mutations at cystic fibrosis transmembrane conductance regulator
(CFTR) make the CFTR become dysfunctional, leading to little or none chloride ion
transportation to outside the cell. Among many loss-of-function mutations of CFTR
protein, G551D, the third most common one, has been characterized as having a
lower open probability (Po) than wild-type (WT) channels. Currently, a novel
investigational compound named GLPG1837 is proved to be double more efficacious
than the commercial drug Ivacaftor (VX-770) and do not interfere with CFTR
stability in vitro experiments, but its affinity and mechanism have not been well
studied yet. This study reveals molecular insight into the effect of GLPG1837 on
CFTR protein by using molecular docking and targeted molecular dynamics (TMD)
simulation. The results proposed the same binding site but different mechanism of
GLPG1837 to the commercial one on a revised CFTR model particularly, the
stimulating effect of GLPG1837 on the first stage of the mutant channel gating
process. Our data confirmed the stronger effect of GLPG1837 than VX-770 in a
small perspective of in silico study, which contributes to the development of more
potent modalities correcting the effects of CFTR mutations. | en_US |
