RT Journal Article SR Electronic T1 A synthetic nanofibrillar matrix promotes in vitro hepatic differentiation of embryonic stem cells and induced pluripotent stem cells JF Journal of Cell Science JO J. Cell Sci. FD The Company of Biologists Ltd SP 5391 OP 5399 DO 10.1242/jcs.129767 VO 126 IS 23 A1 Yamazoe, Taiji A1 Shiraki, Nobuaki A1 Toyoda, Masashi A1 Kiyokawa, Nobutaka A1 Okita, Hajime A1 Miyagawa, Yoshitaka A1 Akutsu, Hidenori A1 Umezawa, Akihiro A1 Sasaki, Yutaka A1 Kume, Kazuhiko A1 Kume, Shoen YR 2013 UL http://jcs.biologists.org/content/126/23/5391.abstract AB Embryonic stem (ES) cells recapitulate normal developmental processes and serve as an attractive source for routine access to a large number of cells for research and therapies. We previously reported that ES cells cultured on M15 cells, or a synthesized basement membrane (sBM) substratum, efficiently differentiated into an endodermal fate and subsequently adopted fates of various digestive organs, such as the pancreas and liver. Here, we established a novel hepatic differentiation procedure using the synthetic nanofiber (sNF) as a cell culture scaffold. We first compared endoderm induction and hepatic differentiation between murine ES cells grown on sNF and several other substrata. The functional assays for hepatocytes reveal that the ES cells grown on sNF were directed into hepatic differentiation. To clarify the mechanisms for the promotion of ES cell differentiation in the sNF system, we focused on the function of Rac1, which is a Rho family member protein known to regulate the actin cytoskeleton. We observed the activation of Rac1 in undifferentiated and differentiated ES cells cultured on sNF plates, but not in those cultured on normal plastic plates. We also show that inhibition of Rac1 blocked the potentiating effects of sNF on endoderm and hepatic differentiation throughout the whole differentiation stages. Taken together, our results suggest that morphological changes result in cellular differentiation controlled by Rac1 activation, and that motility is not only the consequence, but is also able to trigger differentiation. In conclusion, we believe that sNF is a promising material that might contribute to tissue engineering and drug delivery.