AUTHOR=Martinovich Kelly M. , Kicic Anthony , Stick Stephen M. , Johnsen Russell D. , Fletcher Sue , Wilton Steve D. 

TITLE=Investigating the Implications of CFTR Exon Skipping Using a Cftr Exon 9 Deleted Mouse Model

JOURNAL=Frontiers in Pharmacology

VOLUME=13

YEAR=2022

URL=https://www.frontiersin.org/journals/pharmacology/articles/10.3389/fphar.2022.868863

DOI=10.3389/fphar.2022.868863

ISSN=1663-9812

ABSTRACT=<p><bold>Introduction:</bold> Severity and disease progression in people with Cystic Fibrosis (CF) is typically dependent on their genotype. One potential therapeutic strategy for people with specific mutations is exon skipping with antisense oligonucleotides (AO). <italic>CFTR</italic> exon 9 is an in-frame exon and hence the exclusion of this exon would excise only 31 amino acids but not alter the reading frame of the remaining mRNA. Splice mutations 1209 + 1 G &gt; C and 1209 + 2 T &gt; G were documented to cause <italic>CFTR</italic> exon 9 skipping and these variants were reported to manifest as a milder CF disease, therefore exon 9 skipping could be beneficial for people with class I mutations that affect exon 9 such as p.Trp401X. While the impact of exon 9 skipping on gene expression and cellular pathways can be studied in cells <italic>in vitro</italic>, trace amount of full-length normal or mutated material could confound the evaluation. To overcome this limitation, the impact of <italic>CFTR</italic> exon 9 skipping on disease phenotype and severity is more effectively evaluated in a small animal model. It was hypothesised that antisense oligonucleotide-mediated skipping this particular exon could result in a “mild mouse CF phenotype”.</p><p><bold>Methods:</bold><italic>Cftr</italic> exon 9 deleted mice were generated using homologous recombination. Survival of homozygous (<italic>Cftr</italic><sup><italic>Δ9/Δ9</italic></sup>) and heterozygous (<italic>Cftr</italic><sup><italic>Δ9/+</italic></sup>) mice was compared to that of other CF mouse models, and lung and intestinal organ histology examined for any pathologies. Primary airway epithelial cells (pAECs) were harvested from <italic>Cftr</italic><sup><italic>Δ9/Δ9</italic></sup> mice and cultured at the Air Liquid Interface for CFTR functional assessment using Ussing Chamber analysis.</p><p><bold>Results:</bold> A <italic>Cftr</italic><sup><italic>Δ9/Δ9</italic></sup> mouse model presented with intestinal obstructions, and at time of weaning (21 days). <italic>Cftr</italic><sup><italic>Δ9/Δ9</italic></sup> mice had a survival rate of 83% that dropped to 38% by day 50. Histological sections of the small intestine from <italic>Cftr</italic><sup><italic>Δ9/Δ9</italic></sup> mice showed more goblet cells and mucus accumulation than samples from the <italic>Cftr</italic><sup><italic>Δ9/+</italic></sup> littermates. Airway epithelial cell cultures established from <italic>Cftr</italic><sup><italic>Δ9/Δ9</italic></sup> mice were not responsive to forskolin stimulation.</p><p><bold>Summary:</bold> The effect of <italic>Cftr</italic> exon 9 deletion on Cftr function was assessed and it was determined that the encoded Cftr isoform did not result in a milder “mouse CF disease phenotype,” suggesting that <italic>Cftr</italic> exon 9 is not dispensable, although further investigation in human CF pAECs would be required to confirm this observation.</p>