In the drug development process, it is important to assess the contributions of drug-metabolizing enzymes and/or drug transporters to the intestinal pharmacokinetics of candidate compounds. For such assessments, chemical inhibitors are often used in in vitro systems. However, this practice poses two problems: one is the low expression levels of pharmacokinetic-related genes in conventional in vitro systems, such as Caco-2 cells, and the other is the off-target and less-efficient effects of their inhibitors. Here, as a model, we have established human biopsy-derived enteroids deficient in MDR1, a key efflux transporter. The expression levels and activities of other pharmacokinetic-related genes, such as CYP3A4, in the MDR1-knockout (KO) enteroid-derived monolayers were maintained at levels as high as those in the WT enteroid-derived monolayers. The contribution of MDR1 to the cytotoxicity of vinblastine, which CYP3A4 metabolized, was accurately evaluated by using the MDR1-KO enteroid-derived monolayers. In contrast, it could not be evaluated in the WT enteroid-derived monolayers treated by verapamil, a widely used MDR1 inhibitor, due to the off-target effect of verapamil, which also inhibits CYP3A4. The combination of human enteroid-derived monolayers and genome editing technology would be a powerful tool to evaluate the contributions of specific pharmacokinetic-related molecules.
Keywords: Gastrointestinal cytochrome P450; Gene editing/CRISPR; Intestinal transport.
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