Generation of proximal tubule-enhanced kidney organoids from human pluripotent stem cells

Kidney organoids derived from human pluripotent stem cells (hPSCs) are now being used as models of renal disease and nephrotoxicity screening. However, the proximal tubules (PTs), which are responsible for most kidney reabsorption functions, remain immature in kidney organoids with limited expression of critical transporters essential for nephron functionality. Here, we describe a protocol for improved specification of nephron progenitors from hPSCs that results in kidney organoids with elongated proximalized nephrons displaying improved PT maturity compared with those generated using standard kidney organoid protocols. We also describe a methodology for assessing the functionality of the PTs within the organoids and visualizing maturation markers via immunofluorescence. Using these assays, PT-enhanced organoids display increased expression of a range of critical transporters, translating to improved functionality measured by substrate uptake and transport. This protocol consists of an extended (13 d) monolayer differentiation phase, during which time hPSCs are exposed to nephron progenitor maintenance media (CDBLY2), better emulating human metanephric progenitor specification in vivo. Following nephron progenitor specification, the cells are aggregated and cultured as a three-dimensional micromass on an air-liquid interface to facilitate further differentiation and segmentation into proximalized nephrons. Experience in culturing hPSCs is required to conduct this protocol and expertise in kidney organoid generation is advantageous. This protocol can be used to generate kidney organoids with elongated proximalized nephrons displaying improved proximal tubule maturity compared with those generated using standard kidney organoid protocols. This protocol generates kidney organoids with elongated proximalized nephrons displaying improved proximal tubule maturity compared with those generated using standard kidney organoid protocols.Methods for assessing the functionality of the proximal tubules within the organoids and visualizing maturation markers via immunofluorescence are also described.