A biomimetic gelatin-based platform elicits a pro-differentiation effect on podocytes through mechanotransduction

Mufeng Hu, Evren U. Azeloglu, Amit Ron, Khanh Hoa Tran-Ba, Rhodora C. Calizo, Iman Tavassoly, Smiti Bhattacharya, Gomathi Jayaraman, Yibang Chen, Vera Rabinovich, Ravi Iyengar, James C. Hone, John C. He, Laura J. Kaufman

Research output: Contribution to journalArticlepeer-review

28 Scopus citations

Abstract

Using a gelatin microbial transglutaminase (gelatin-mTG) cell culture platform tuned to exhibit stiffness spanning that of healthy and diseased glomeruli, we demonstrate that kidney podocytes show marked stiffness sensitivity. Podocyte-specific markers that are critical in the formation of the renal filtration barrier are found to be regulated in association with stiffness-mediated cellular behaviors. While podocytes typically de-differentiate in culture and show diminished physiological function in nephropathies characterized by altered tissue stiffness, we show that gelatin-mTG substrates with Young's modulus near that of healthy glomeruli elicit a pro-differentiation and maturation response in podocytes better than substrates either softer or stiffer. The pro-differentiation phenotype is characterized by upregulation of gene and protein expression associated with podocyte function, which is observed for podocytes cultured on gelatin-mTG gels of physiological stiffness independent of extracellular matrix coating type and density. Signaling pathways involved in stiffness-mediated podocyte behaviors are identified, revealing the interdependence of podocyte mechanotransduction and maintenance of their physiological function. This study also highlights the utility of the gelatin-mTG platform as an in vitro system with tunable stiffness over a range relevant for recapitulating mechanical properties of soft tissues, suggesting its potential impact on a wide range of research in cellular biophysics.

Original languageEnglish
Article number43934
JournalScientific Reports
Volume7
DOIs
StatePublished - 6 Mar 2017

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