Disease phenotype of a ferret CFTR-knockout model of cystic fibrosis
Xingshen Sun, Hongshu Sui, John T. Fisher, Ziying Yan, Xiaoming Liu, Hyung-Ju Cho, Nam Soo Joo, Yulong Zhang, Weihong Zhou, Yaling Yi, Joann M. Kinyon, Diana C. Lei-Butters, Michelle A. Griffin, Paul Naumann, Meihui Luo, Jill Ascher, Kai Wang, Timothy Frana, Jeffrey J. Wine, David K. Meyerholz, John F. Engelhardt
Xingshen Sun, Hongshu Sui, John T. Fisher, Ziying Yan, Xiaoming Liu, Hyung-Ju Cho, Nam Soo Joo, Yulong Zhang, Weihong Zhou, Yaling Yi, Joann M. Kinyon, Diana C. Lei-Butters, Michelle A. Griffin, Paul Naumann, Meihui Luo, Jill Ascher, Kai Wang, Timothy Frana, Jeffrey J. Wine, David K. Meyerholz, John F. Engelhardt
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Technical Advance

Disease phenotype of a ferret CFTR-knockout model of cystic fibrosis

Abstract

Cystic fibrosis (CF) is a recessive disease that affects multiple organs. It is caused by mutations in CFTR. Animal modeling of this disease has been challenging, with species- and strain-specific differences in organ biology and CFTR function influencing the emergence of disease pathology. Here, we report the phenotype of a CFTR-knockout ferret model of CF. Neonatal CFTR-knockout ferrets demonstrated many of the characteristics of human CF disease, including defective airway chloride transport and submucosal gland fluid secretion; variably penetrant meconium ileus (MI); pancreatic, liver, and vas deferens disease; and a predisposition to lung infection in the early postnatal period. Severe malabsorption by the gastrointestinal (GI) tract was the primary cause of death in CFTR-knockout kits that escaped MI. Elevated liver function tests in CFTR-knockout kits were corrected by oral administration of ursodeoxycholic acid, and the addition of an oral proton-pump inhibitor improved weight gain and survival. To overcome the limitations imposed by the severe intestinal phenotype, we cloned 4 gut-corrected transgenic CFTR-knockout kits that expressed ferret CFTR specifically in the intestine. One clone passed feces normally and demonstrated no detectable ferret CFTR expression in the lung or liver. The animals described in this study are likely to be useful tools for dissecting CF disease pathogenesis and developing treatments.

Authors

Xingshen Sun, Hongshu Sui, John T. Fisher, Ziying Yan, Xiaoming Liu, Hyung-Ju Cho, Nam Soo Joo, Yulong Zhang, Weihong Zhou, Yaling Yi, Joann M. Kinyon, Diana C. Lei-Butters, Michelle A. Griffin, Paul Naumann, Meihui Luo, Jill Ascher, Kai Wang, Timothy Frana, Jeffrey J. Wine, David K. Meyerholz, John F. Engelhardt

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Figure 6

Generation of a gut-corrected transgenic CFTR–/– ferret by SCNT.

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Generation of a gut-corrected transgenic CFTR–/– ferret by SCNT. (A)...
(A) Schematic diagram of the FAPBi-HA-CFTR-PGK-Zeocin cassette used to generate transgenic ferrets expressing HA-tagged CFTR under the control of the FABPi promoter (FABP-Pr) and bovine growth hormone (BGH) poly-A. pFABP, plasmid FABP. (B) Primary fibroblasts were transfected with the linear transgenic fragment shown in A, and selected pools were used for SCNT. Four cloned kits were born, and the gross morphology of the intestine is shown. Clone-1 passed stool normally within 24 hours of birth, while clone-2, -3, and -4 suffered from MI and failed to pass stool. St, stomach. (C) PCR genotyping of the 4 transgenic FABP-HA-CFTR/CFTR–/– cloned kits. Genomic DNA from a CFTR+/+ kit served as a negative control, while plasmid DNA (pCFTR) harboring the transgene cassette was used as a positive control. The PCR reactions were designed to specifically detect a segment of the HA-tag and CFTR cDNA or the rat FABPi promoter as shown. (D) Detection of CFTR protein levels in intestinal lysates from the 4 FABP-HA-CFTR/CFTR–/– clones and a CFTR–/– kit by CFTR immunoprecipitation, followed by in vitro phosphorylation in the presence of [γ-32P]ATP and protein kinase A. (E) Comparison of CFTR protein levels using in vitro phosphorylation of immunoprecipitated CFTR from the intestine, lung, and liver of FABP-HA-CFTR/CFTR–/– clone-1. Lanes show results for CFTR+/+, CFTR–/–, and FABP-HA-CFTR/CFTR–/– clone-1 kits. The fully glycosylated band-C and partially processed band-B forms of CFTR are shown (note that migration of transgenic CFTR is slightly slower than that of endogenous CFTR, due to the presence of the HA-tag).