TY - JOUR AU - Park, Hyun Jung AU - Fan, Zhenjiang AU - Bai, Yulong AU - Ren, Qidong AU - Rbaibi, Youssef AU - Long, Kimberly R. AU - Gliozzi, Megan L. AU - Rittenhouse, Natalie AU - Locker, Joseph D. AU - Poholek, Amanda C. AU - Weisz, Ora A. PY - 2020 M3 - Original Research TI - Transcriptional Programs Driving Shear Stress-Induced Differentiation of Kidney Proximal Tubule Cells in Culture JO - Frontiers in Physiology UR - https://www.frontiersin.org/articles/10.3389/fphys.2020.587358 VL - 11 SN - 1664-042X N2 - Cultured cell models are an essential complement to dissecting kidney proximal tubule (PT) function in health and disease but do not fully recapitulate key features of this nephron segment. We recently determined that culture of opossum kidney (OK) cells under continuous orbital shear stress (OSS) significantly augments their morphological and functional resemblance to PTs in vivo. Here we used RNASeq to identify temporal transcriptional changes upon cell culture under static or shear stress conditions. Comparison of gene expression in cells cultured under static or OSS conditions with a database of rat nephron segment gene expression confirms that OK cells cultured under OSS are more similar to the PT in vivo compared with cells maintained under static conditions. Both improved oxygenation and mechanosensitive stimuli contribute to the enhanced differentiation in these cells, and we identified temporal changes in gene expression of known mechanosensitive targets. We observed changes in mRNA and protein levels of membrane trafficking components that may contribute to the enhanced endocytic capacity of cells cultured under OSS. Our data reveal pathways that may be critical for PT differentiation in vivo and validate the utility of this improved cell culture model as a tool to study PT function. ER -