RATIONALE: Cardiomyocytes (CMs) differentiated from human pluripotent stem cells (PSCs) are increasingly being used for cardiovascular research, including disease modeling, and hold promise for clinical applications. Current cardiac differentiation protocols exhibit variable success across different PSC lines and are primarily based on the application of growth factors. However, extracellular matrix is also fundamentally involved in cardiac development from the earliest morphogenetic events, such as gastrulation. OBJECTIVE: We sought to develop a more effective protocol for cardiac differentiation of human PSCs by using extracellular matrix in combination with growth factors known to promote cardiogenesis. METHODS AND RESULTS: PSCs were cultured as monolayers on Matrigel, an extracellular matrix preparation, and subsequently overlayed with Matrigel. The matrix sandwich promoted an epithelial-to-mesenchymal transition as in gastrulation with the generation of N-cadherin-positive mesenchymal cells. Combining the matrix sandwich with sequential application of growth factors (Activin A, bone morphogenetic protein 4, and basic fibroblast growth factor) generated CMs with high purity (up to 98%) and yield (up to 11 CMs/input PSC) from multiple PSC lines. The resulting CMs progressively matured over 30 days in culture based on myofilament expression pattern and mitotic activity. Action potentials typical of embryonic nodal, atrial, and ventricular CMs were observed, and monolayers of electrically coupled CMs modeled cardiac tissue and basic arrhythmia mechanisms. CONCLUSIONS: Dynamic extracellular matrix application promoted epithelial-mesenchymal transition of human PSCs and complemented growth factor signaling to enable robust cardiac differentiation.
RATIONALE: Cardiomyocytes (CMs) differentiated from human pluripotent stem cells (PSCs) are increasingly being used for cardiovascular research, including disease modeling, and hold promise for clinical applications. Current cardiac differentiation protocols exhibit variable success across different PSC lines and are primarily based on the application of growth factors. However, extracellular matrix is also fundamentally involved in cardiac development from the earliest morphogenetic events, such as gastrulation. OBJECTIVE: We sought to develop a more effective protocol for cardiac differentiation of human PSCs by using extracellular matrix in combination with growth factors known to promote cardiogenesis. METHODS AND RESULTS: PSCs were cultured as monolayers on Matrigel, an extracellular matrix preparation, and subsequently overlayed with Matrigel. The matrix sandwich promoted an epithelial-to-mesenchymal transition as in gastrulation with the generation of N-cadherin-positive mesenchymal cells. Combining the matrix sandwich with sequential application of growth factors (Activin A, bone morphogenetic protein 4, and basic fibroblast growth factor) generated CMs with high purity (up to 98%) and yield (up to 11 CMs/input PSC) from multiple PSC lines. The resulting CMs progressively matured over 30 days in culture based on myofilament expression pattern and mitotic activity. Action potentials typical of embryonic nodal, atrial, and ventricular CMs were observed, and monolayers of electrically coupled CMs modeled cardiac tissue and basic arrhythmia mechanisms. CONCLUSIONS: Dynamic extracellular matrix application promoted epithelial-mesenchymal transition of human PSCs and complemented growth factor signaling to enable robust cardiac differentiation.
Authors: M Amit; M K Carpenter; M S Inokuma; C P Chiu; C P Harris; M A Waknitz; J Itskovitz-Eldor; J A Thomson Journal: Dev Biol Date: 2000-11-15 Impact factor: 3.582
Authors: David A Elliott; Stefan R Braam; Katerina Koutsis; Elizabeth S Ng; Robert Jenny; Ebba L Lagerqvist; Christine Biben; Tanya Hatzistavrou; Claire E Hirst; Qing C Yu; Rhys J P Skelton; Dorien Ward-van Oostwaard; Sue Mei Lim; Ouda Khammy; Xueling Li; Susan M Hawes; Richard P Davis; Adam L Goulburn; Robert Passier; Owen W J Prall; John M Haynes; Colin W Pouton; David M Kaye; Christine L Mummery; Andrew G Elefanty; Edouard G Stanley Journal: Nat Methods Date: 2011-10-23 Impact factor: 28.547
Authors: Young Wook Chun; David E Voyles; Rutwik Rath; Lucas H Hofmeister; Timothy C Boire; Henry Wilcox; Jae Han Lee; Leon M Bellan; Charles C Hong; Hak-Joon Sung Journal: J Biomech Date: 2015-10-08 Impact factor: 2.712
Authors: Joshua R Gershlak; Joshua I N Resnikoff; Kelly E Sullivan; Corin Williams; Raymond M Wang; Lauren D Black Journal: Biochem Biophys Res Commun Date: 2013-08-30 Impact factor: 3.575
Authors: Vincent C Chen; Jingjing Ye; Praveen Shukla; Giau Hua; Danlin Chen; Ziguang Lin; Jian-chang Liu; Jing Chai; Joseph Gold; Joseph Wu; David Hsu; Larry A Couture Journal: Stem Cell Res Date: 2015-08-13 Impact factor: 2.020
Authors: Philip D Tatman; Kathleen C Woulfe; Anis Karimpour-Fard; Danielle A Jeffrey; James Jaggers; Joseph C Cleveland; Karin Nunley; Matthew Rg Taylor; Shelley D Miyamoto; Brian L Stauffer; Carmen C Sucharov Journal: JCI Insight Date: 2017-07-20
Authors: Max R Salick; Brett N Napiwocki; Jin Sha; Gavin T Knight; Shahzad A Chindhy; Timothy J Kamp; Randolph S Ashton; Wendy C Crone Journal: Biomaterials Date: 2014-02-28 Impact factor: 12.479
Authors: Xintong Wang; Young Wook Chun; Lin Zhong; Manuel Chiusa; Daniel A Balikov; Audrey Y Frist; Chee C Lim; Simon Maltais; Leon Bellan; Charles C Hong; Hak-Joon Sung Journal: Int J Cardiol Date: 2015-04-18 Impact factor: 4.164
Authors: Alexandra Bizy; Guadalupe Guerrero-Serna; Bin Hu; Daniela Ponce-Balbuena; B Cicero Willis; Manuel Zarzoso; Rafael J Ramirez; Michelle F Sener; Lakshmi V Mundada; Matthew Klos; Eric J Devaney; Karen L Vikstrom; Todd J Herron; José Jalife Journal: Stem Cell Res Date: 2013-09-18 Impact factor: 2.020