(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).