AIM: The differentiation efficiencies of human embryonic stem cell (hESC) lines differ from each other. To assess this in more detail we studied the cardiac differentiation of eight hESC lines derived in the same laboratory. RESULTS: Substantial variation in growth and in the ability to form beating areas was seen between the different hESC lines; line HS346 gave the best efficiency (9.4%), while HS293 did not differentiate into beating colonies at all. Nine germ layer and differentiation markers were quantified during early differentiation in four hESC lines. The expression levels of Brachyury T, MESP1 and NKX2.5 were highest in the most efficient cardiac line (HS346). A systematic characterization of the beating cells revealed proper cardiac marker expression, electrophysiological activity, and pharmacological response. CONCLUSIONS: The hESC lines derived in the same laboratory varied considerably in their potential to differentiate into beating cardiomyocytes. None of the expression markers could clearly predict cardiac differentiation potential, although the expression of early cardiomyogenic genes was upregulated in the best cardiac line. The proper cardiomyocyte characteristics and pharmacological response indicate that these cells could be used as a model for human cardiomyocytes in pharmacological and toxicological analyses when investigating new heart medications or cardiac side-effects.
AIM: The differentiation efficiencies of human embryonic stem cell (hESC) lines differ from each other. To assess this in more detail we studied the cardiac differentiation of eight hESC lines derived in the same laboratory. RESULTS: Substantial variation in growth and in the ability to form beating areas was seen between the different hESC lines; line HS346 gave the best efficiency (9.4%), while HS293 did not differentiate into beating colonies at all. Nine germ layer and differentiation markers were quantified during early differentiation in four hESC lines. The expression levels of Brachyury T, MESP1 and NKX2.5 were highest in the most efficient cardiac line (HS346). A systematic characterization of the beating cells revealed proper cardiac marker expression, electrophysiological activity, and pharmacological response. CONCLUSIONS: The hESC lines derived in the same laboratory varied considerably in their potential to differentiate into beating cardiomyocytes. None of the expression markers could clearly predict cardiac differentiation potential, although the expression of early cardiomyogenic genes was upregulated in the best cardiac line. The proper cardiomyocyte characteristics and pharmacological response indicate that these cells could be used as a model for human cardiomyocytes in pharmacological and toxicological analyses when investigating new heart medications or cardiac side-effects.
Authors: Laura Riolobos; Roli K Hirata; Cameron J Turtle; Pei-Rong Wang; German G Gornalusse; Maja Zavajlevski; Stanley R Riddell; David W Russell Journal: Mol Ther Date: 2013-04-30 Impact factor: 11.454
Authors: Kristiina Rajala; Bettina Lindroos; Samer M Hussein; Riikka S Lappalainen; Mari Pekkanen-Mattila; Jose Inzunza; Björn Rozell; Susanna Miettinen; Susanna Narkilahti; Erja Kerkelä; Katriina Aalto-Setälä; Timo Otonkoski; Riitta Suuronen; Outi Hovatta; Heli Skottman Journal: PLoS One Date: 2010-04-19 Impact factor: 3.240
Authors: Zaruhi Karabekian; Hao Ding; Gulnaz Stybayeva; Irina Ivanova; Narine Muselimyan; Amranul Haque; Ian Toma; Nikki G Posnack; Alexander Revzin; David Leitenberg; Michael A Laflamme; Narine Sarvazyan Journal: Tissue Eng Part A Date: 2015-09-10 Impact factor: 3.845