Abstract
Cystic fibrosis (CF) is a severe genetic disorder caused by loss-of-function mutations in the CFTR gene. Gene-editing approaches have the potential to correct such mutations. This systematic review outlines the mechanisms of the main CRISPR-based technologies, and, through cross-study comparisons, analyzes 27 research articles that applied them to target CF-causing variants. We report and discuss the strategy design, target cell selection, editing efficiency, prevalence of editing byproducts, and levels of CFTR functional restoration achieved in each work, with the aim of providing technical insights for further exploration of CRISPR-based gene-editing approaches. Our findings show that the F508del and W1282X mutations were the most extensively studied CF-causing variants, though over fifteen mutations were targeted overall. The majority of works under review explored the use of homology-directed repair or base editing, with a growing number of studies reporting efficient prime editing. Some studies tackled multiple individual mutations, compared different editors, or tested strategies across various models, while others focused on approaches that rescue CFTR function without directly correcting a mutation. Several works also proposed strategies that could address multiple variants with a single approach, while others highlighted technical difficulties in editing certain regions of the CFTR gene. This cross-study comparison also emphasizes the need for standardized reporting of editing efficiency and functional recovery, and stresses the importance of further single-cell RNA sequencing and in vivo studies to reach clinically relevant conclusions. As gene-editing techniques continue to evolve, and with over 60 ongoing CRISPR-based clinical trials, there is growing optimism for meaningful advancements in CF gene-editing therapeutics.