Targeted correction of a defective selectable marker gene in human epithelial cells by small DNA fragments

A novel gene targeting strategy, small fragment homologous replacement (SFHR), has been used to correct specific genomic lesions in human epithelial cells. The frequency of targeting was estimated to be 1-10%. However, given the genomic target, the cystic fibrosis transmembrane conductance regulator (CFTR) gene, it is difficult to accurately quantify targeting frequency. As an alternative to targeting CFTR, targeted correction of a mutant selectable marker or reporter gene would be more amenable to accurate and rapid quantification of gene targeting efficiency. The present study evaluates the conditions that modulate SFHR-mediated correction of a defective Zeocin antibiotic resistance (Zeo(r)) gene that has been inactivated by a 4-bp insertion. The conditions include delivery systems, plasmid-to-fragment ratio, fragment length, and fragment strandedness (single- or double-stranded DNA). Targeting fragments comprise the wild-type Zeo(r) gene sequence and were either 410 (Zeo1) or 458 bp (Zeo3). Expression vectors containing the corrected Zeo(r) gene were isolated as episomal plasmids or were allowed to stably integrate into cultured human airway epithelial cells. Correction of the Zeo(r) gene was phenotypically defined as restoration of resistance to Zeocin in either bacteria or epithelial cell clones. Extrachromosomal gene correction was assayed using polymerase chain reaction amplification, restriction enzyme digestion, DNA sequencing, and Southern blot hybridization analysis of DNA from isolated prokaryotic and eukaryotic clones. Neither random sequence alteration in the target episomal gene nor random integration of the small fragments was detected. Targeted correction efficiencies of up to 4% were attained. These studies provide insight into parameters that can be modulated for the optimization of SFHR-mediated targeting

Sequence-specific modification of genomic DNA by small DNA fragments

Small DNA fragments have been used to modify endogenous genomic DNA in both human and mouse cells. This strategy for sequence-specific modification or genomic editing, known as small-fragment homologous replacement (SFHR), has yet to be characterized in terms of its underlying mechanisms. Genotypic and phenotypic analyses following SFHR have shown specific modification of disease-causing genetic loci associated with cystic fibrosis, beta-thalassemia, and Duchenne muscular dystrophy, suggesting that SFHR has potential as a therapeutic modality for the treatment of monogenic inherited diseas