Abstract
F508del‐cystic fibrosis transmembrane conductance regulator (CFTR) is the major mutant responsible for cystic fibrosis (CF). ORKAMBI®, approved for patients bearing this mutant, contains lumacaftor (VX‐809) that partially corrects F508del‐CFTR's processing defect and ivacaftor (VX‐770) that potentiates its defective channel activity. Unfortunately, the clinical efficacy of ORKAMBI® is modest, highlighting the need to understand how the small molecules work so that superior compounds can be developed. Because, human CFTR (hCFTR) and zebrafish Cftr (zCftr) are structurally conserved as determined in recent cryo‐EM structural models, we hypothesized that the consequences of the major mutation and small molecule modulators would be similar for the two species of protein. As expected, like the F508del mutation in hCFTR, the homologous mutation in zCftr (F507del) is misprocessed, yet not as severely as the human mutant and this defect was restored by low‐temperature (27°C) culture conditions. After rescue to the cell surface, F507del‐zCftr exhibited regulated channel activity that was potentiated by ivacaftor. Surprisingly, lumacaftor failed to rescue misprocessing of the F507del‐zCftr at either 37 or 27°C suggesting that future comparative studies with F508del‐hCFTR would provide insight into its structure: function relationships. Interestingly, the robust rescue of F508del‐zCftr at 27°C and availability of methods for in vivo screening in zebrafish present the opportunity to define the cellular pathways underlying rescue.
Highlights
Cystic fibrosis (CF), the most prevalent genetic disease in Caucasians,[1,2] is caused by mutations in the CFTR gene and the loss of function of the cystic fibrosis transmembrane conductance regulator (CFTR) protein.[3]
The CFTR protein consists of two membrane‐spanning domains (MSD1, MSD2) with four intracellular loops (ICL1‐4), two nucleotide‐binding domains (NBD1, NBD2), and a regulatory (R) domain that harbors most of the protein kinase A (PKA) sites responsible for the phosphorylation‐dependent regulation of CFTR channel opening.[8]
We show that introduction of the major CF‐ causing mutation into zebrafish Cftr (zCftr) recapitulates the consequences observed in the human CFTR (hCFTR) protein but fails to model the pharmacological response to VX‐809
Summary
Cystic fibrosis (CF), the most prevalent genetic disease in Caucasians,[1,2] is caused by mutations in the CFTR gene and the loss of function of the cystic fibrosis transmembrane conductance regulator (CFTR) protein.[3]. The most common CF‐causing mutation results in deletion of phenylalanine at residue 508 (F508del‐hCFTR) in NBD1 of hCFTR This mutation causes defective folding of NBD1 and alters its assembly with the rest of the protein.[19,20,21,22] The misassembled mutant protein is misprocessed and retained in the endoplasmic reticulum.[23,24,25] it has been shown that culturing cells at a low temperature (27°C) can rescue the trafficking defect of F508del‐hCFTR and its expression at the cell surface, rescued channels still exhibit temperature‐dependent defects in gating and stability.[26,27,28] It remains to be determined if deletion of phenylalanine at the same position on NBD1 of zCftr will induce a similar molecular phenotype and enable the modeling of therapeutic strategies for the major mutation. We show that introduction of the major CF‐ causing mutation into zCftr recapitulates the consequences observed in the hCFTR protein but fails to model the pharmacological response to VX‐809
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