Human jejunal enteroids for studies of epithelial drug transport and metabolism

Intestinal enteroids are stem cell-based “mini-guts” that mimic many aspects of the corresponding epithelial barrier in vivo . Here, we established and characterized differentiated apical-out (AO) and basal-out (BO) jejunal enteroids in suspension and followed their differentiation by quantitative global proteomics and different microscopic techniques. The barrier integrity and function and subcellular location of nutrient and clinically important drug transporters were investigated in the matured enteroids using live-cell microscopy. The presystemic metabolism of two drugs by CYP3A4 was determined and the results were used to predict the pharmacokinetics after oral administration by a PBPK population model. The differentiated AO enteroids displayed a protein profile that overlapped both qualitatively and quantitatively with that of freshly isolated jejunal enterocytes and tissue. They exhibited a morphology that recapitulates the mature villus enterocyte in vivo , formed an intact barrier with a well-developed glycocalyx and are impermeable to the hydrophilic low molecular weight compound lucifer yellow and transported a medium chain fatty acid derivative by FATP4 into lipid deposits. The clinically important ABC-transporters Pgp and BCRP were expressed at near in vivo levels, had the correct subcellular localization and effluxed their substrates. Terfenadine and midazolam were metabolized by CYP3A4 and the results were used to predict the clinical pharmacokinetics of the drugs after oral administration with good accuracy. We conclude that suspended 3D AO enteroids provide a physiologically relevant model for studies of intestinal function that offers convenient access to the apical surface and is easy to dispense in multi-wells formats for large scale experimentation.