Discovery of a picomolar potency pharmacological corrector of the mutant CFTR chloride channel

N Pedemonte, F Bertozzi, E Caci, F Sorana… - Science …, 2020 - science.org
N Pedemonte, F Bertozzi, E Caci, F Sorana, P Di Fruscia, V Tomati, L Ferrera
Science Advances, 2020science.org
F508del, the most frequent mutation causing cystic fibrosis (CF), results in mistrafficking and
premature degradation of the CFTR chloride channel. Small molecules named correctors
may rescue F508del-CFTR and therefore represent promising drugs to target the basic
defect in CF. We screened a carefully designed chemical library to find F508del-CFTR
correctors. The initial active compound resulting from the primary screening underwent
extensive chemical optimization. The final compound, ARN23765, showed an extremely …
F508del, the most frequent mutation causing cystic fibrosis (CF), results in mistrafficking and premature degradation of the CFTR chloride channel. Small molecules named correctors may rescue F508del-CFTR and therefore represent promising drugs to target the basic defect in CF. We screened a carefully designed chemical library to find F508del-CFTR correctors. The initial active compound resulting from the primary screening underwent extensive chemical optimization. The final compound, ARN23765, showed an extremely high potency in bronchial epithelial cells from F508del homozygous patients, with an EC50 of 38 picomolar, which is more than 5000-fold lower compared to presently available corrector drugs. ARN23765 also showed high efficacy, synergy with other types of correctors, and compatibility with chronic VX-770 potentiator. Besides being a promising drug, particularly suited for drug combinations, ARN23765 represents a high-affinity probe for CFTR structure-function studies.
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