Analysis of cystic fibrosis–associated P67L CFTR illustrates barriers to personalized therapeutics for orphan diseases
Carleen M. Sabusap, … , Jeong S. Hong, Eric J. Sorscher
Carleen M. Sabusap, … , Jeong S. Hong, Eric J. Sorscher
Published September 8, 2016
Citation Information: JCI Insight. 2016;1(14):e86581. https://doi.org/10.1172/jci.insight.86581.
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Research Article Cell biology Therapeutics

Analysis of cystic fibrosis–associated P67L CFTR illustrates barriers to personalized therapeutics for orphan diseases

Abstract

Emerging knowledge indicates the difficulty in categorizing unusual cystic fibrosis (CF) mutations, with regard to both pathogenic mechanism and theratype. As case in point, we present data concerning P67L mutation of the cystic fibrosis transmembrane conductance regulator (CFTR), a defect carried by a small number of individuals with CF and sometimes attributed to a channel conductance abnormality. Findings from our laboratory and others establish that P67L causes protein misfolding, disrupts maturation, confers gating defects, is thermally stable, and exhibits near normal conductance. These results provide one framework by which rare CF alleles such as P67L can be more comprehensively profiled vis-à-vis molecular pathogenesis. We also demonstrate that emerging CF treatments — ivacaftor and lumacaftor — can mediate pronounced pharmacologic activation of P67L CFTR. Infrequent CF alleles are often improperly characterized, in part, due to the small numbers of patients involved. Moreover, access to new personalized treatments among patients with ultra-orphan genotypes has been limited by difficulty arranging phase III clinical trials, and off-label prescribing has been impaired by high drug cost and difficulty arranging third party reimbursement. Rare CFTR mutations such as P67L are emblematic of the challenges to “precision” medicine, including use of the best available mechanistic knowledge to treat patients with unusual forms of disease.

Authors

Carleen M. Sabusap, Wei Wang, Carmel M. McNicholas, W. Joon Chung, Lianwu Fu, Hui Wen, Marina Mazur, Kevin L. Kirk, James F. Collawn, Jeong S. Hong, Eric J. Sorscher

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Figure 2

Functional assessment of the P67L cystic fibrosis transmembrane regulator (CFTR) mutant in polarized Fischer rat thyroid (FRT) and primary airway epithelial cells.

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Functional assessment of the P67L cystic fibrosis transmembrane regulato...
Ussing chamber experiments were carried out in FRT (A and B) or primary airway cells from 3 cystic fibrosis patients (genotypes P67L/F508del, F508del/F508del, F508del/F508del; C–F) at 37°C following 24 hours of treatment with DMSO (control) or 3 μM lumacaftor. Data showing short-circuit current (Isc) after luminal stimulation with forskolin (10 μM, far left arrows) and ivacaftor (300 nM, middle arrows) and inhibition by CFTR inh172 (30 μM, a CFTR inhibitor, far right arrows) are depicted in A, C, and E. Summary data is shown as mean ± SEM in B, D, and F (diamonds, forskolin; circles, ivacaftor + forskolin; triangles, inh172); some error bars are hidden by symbols. Variable response to lumacaftor is characteristic of the two independent homozygous F508del CFTR mutant patient codes shown in CF. Dot plots describe n = 3–4 filters (technical replicates for each cell line or patient sample) per condition (n = 2 for lumacaftor-treated WT/WT primary cells). *P < 0.05 for forskolin + ivacaftor stimulation; **P = 0.02 for inh172 inhibition (indicative of total constitutive + activated CFTR function), determined via 2-sample t test.