Abstract
Elucidation of gene function by reverse genetics in animal models frequently is complicated by the functional redundancy of homologous genes. This obstacle often is compounded by the tight clustering of homologous genes, which precludes the generation of multigene-deficient animals through standard interbreeding of single-deficient animals. Here, we describe an iterative, multiplexed CRISPR-based approach for simultaneous gene editing in the complex seven-member human airway trypsin-like protease/differentially expressed in a squamous cell carcinoma (HAT/DESC) cluster of membrane-anchored serine proteases. Through four cycles of targeting, we generated a library of 18 unique congenic mouse strains lacking combinations of HAT/DESC proteases, including a mouse strain deficient in all seven proteases. Using this library, we demonstrate that HAT/DESC proteases are dispensable for term development, postnatal health, and fertility and that the recently described function of the HAT-like 4 protease in epidermal barrier formation is unique among all HAT/DESC proteases. The study demonstrates the potential of iterative, multiplexed CRISPR-mediated gene editing for functional analysis of multigene clusters, and it provides a large array of new congenic mouse strains for the study of HAT/DESC proteases in physiological and in pathophysiological processes.
Highlights
Elucidation of gene function by reverse genetics in animal models frequently is complicated by the functional redundancy of homologous genes
We demonstrate that HAT/DESC proteases are dispensable for term development, postnatal health, and fertility and that the recently described function of the HAT-like 4 protease in epidermal barrier formation is unique among all HAT/DESC proteases
The study demonstrates the potential of iterative, multiplexed CRISPR-mediated gene editing for functional analysis of multigene clusters, and it provides a large array of new congenic mouse strains for the study of HAT/DESC proteases in physiological and in pathophysiological processes
Summary
We used RT-PCR of mRNA isolated from tongue and testes of mice bred to homozygosity for all seven mutant Tmprss alleles (hereafter referred to as Tmprss11a,b,c,d,e,f,gϪ/Ϫ) followed by DNA sequencing to search for alternatively spliced mRNAs for each of the mutant Tmprss alleles that would restore an ORF and thereby be capable of producing truncated HAT/DESC protein products (albeit these would be unable to translocate to the extracellular/pericellular space or form disulfide bridges essential for protein folding and catalysis). No such mRNAs were identified (Fig. S1).
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