We previously demonstrated the CFTR correctors VX-445 (elexacaftor) and S-VX-121 (vanzacaftor) potentiate heterologously-expressed BK Ca channels, as well as in primary human bronchial epithelial cells (HBEs). This potentiation of BK Ca resulted in altered vasoreactivity and neuronal excitability. We postulated novel compounds could be identified that would potentiate BK Ca while not affecting CFTR. Herein, we demonstrate the enantiomer of vanzacaftor, R-VX-121, possesses these attributes. Using Fisher rat thyroid (FRT) cells expressing F508del CFTR, we demonstrate S-VX-121 corrects F508del CFTR, when incubated overnight, as assessed by an increase in transepithelial Cl - current (I Cl ) in response to forskolin, as well as the appearance of band C upon immunoblot (IB). In contrast, R-VX-121 failed to increase I Cl and induce band C. Importantly, R-VX-121 competed with S-VX-121 to eliminate the correction of F508del CFTR observed during both I Cl measurements and IB, indicating it associates with CFTR. Neither S- nor R-VX-121 potentiated CFTR, as assessed by changes in I Cl . Distinct from our CFTR results, both S- and R-VX-121 potentiated BK Ca in primary HBEs as well as during whole-cell patch-clamp recording of heterologously expressed α-BK Ca . Using wire myography, we demonstrate both S- and R-VX-12 vasodilate preconstricted mouse mesenteric arteries in a paxilline-dependent manner, confirming a role for BK Ca . In contrast, the CFTR inhibitor, CFTR inh172 did not alter the effects of S- and R-VX-121 on vasoreactivity, confirming CFTR is not involved in this response. These data demonstrate R-VX-121 represents a novel BK Ca potentiator that does not modulate CFTR function, suggesting R-VX-121 may be clinically useful as a BK Ca agonist.
Kolski‐Andreaco et al. (Mon,) studied this question.