Pluripotent stem cell-derived cardiomyocytes are currently being investigated for in vitro human heart models and as potential therapeutics for heart failure. In this study, we have developed a differentiation protocol that minimizes the need for specific human embryonic stem cell (hESC) line optimization. We first reduced the heterogeneity that exists within the starting population of bulk cultured hESCs by using cells adapted to single-cell passaging in a 2-dimensional (2D) culture format. Compared with bulk cultures, single-cell cultures comprised larger fractions of TG30hi/OCT4hi cells, corresponding to an increased expression of pluripotency markers OCT4 and NANOG, and reduced expression of early lineage-specific markers. A 2D temporal differentiation protocol was then developed, aimed at reducing the inherent heterogeneity and variability of embryoid body-based protocols, with induction of primitive streak cells using bone morphogenetic protein 4 and activin A, followed by cardiogenesis via inhibition of Wnt signaling using the small molecules IWP-4 or IWR-1. IWP-4 treatment resulted in a large percentage of cells expressing low amounts of cardiac myosin heavy chain and expression of early cardiac progenitor markers ISL1 and NKX2-5, thus indicating the production of large numbers of immature cardiomyocytes (∼65,000/cm2 or ∼1.5 per input hESC). This protocol was shown to be effective in HES3, H9, and, to a lesser, extent, MEL1 hESC lines. In addition, we observed that IWR-1 induced predominantly atrial myosin light chain (MLC2a) expression, whereas IWP-4 induced expression of both atrial (MLC2a) and ventricular (MLC2v) forms. The intrinsic flexibility and scalability of this 2D protocol mean that the output population of primitive cardiomyocytes will be particularly accessible and useful for the investigation of molecular mechanisms driving terminal cardiomyocyte differentiation, and potentially for the future treatment of heart failure.
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References
1.
HansenA, EderA, BonstrupM, FlatoM, MeweM, SchaafS, AksehirliogluB, SchworerA, UebelerJ, EschenhagenT. 2010. Development of a drug screening platform based on engineered heart tissue. Circ Res, 107:35–44.
2.
HeJ-Q, JanuaryCT, ThomsonJA, KampTJ. 2007. Human embryonic stem cell-derived cardiomyocytes: drug discovery and safety pharmacology. Expert Opin Drug Discov, 2:739–753.
3.
DenningC, AndersonD. 2008. Cardiomyocytes from human embryonic stem cells as predictors of cardiotoxicity. Drug Discov Today Ther Strateg, 5:223–232.
4.
BraamSR, TertoolenL, van de StolpeA, MeyerT, PassierR, MummeryCL. 2009. Prediction of drug-induced cardiotoxicity using human embryonic stem cell-derived cardiomyocytes. Stem Cell Res, 4:107–116.
5.
VantlerM, KarikkinethBC, NaitoH, TiburcyM, DidiéM, NoseM, RosenkranzS, ZimmermannW-H. 2010. PDGF-BB protects cardiomyocytes from apoptosis and improves contractile function of engineered heart tissue. J Mol Cell Cardiol, 48:1316–1323.
StevensKR, PabonL, MuskheliV, MurryCE. 2009. Scaffold-free human cardiac tissue patch created from embryonic stem cells. Tissue Eng Part A, 15:1211–1222.
8.
StevensKR, KreutzigerKL, DuprasSK, KorteFS, RegnierM, MuskheliV, NourseMB, BendixenK, ReineckeH, MurryCE. 2009. Physiological function and transplantation of scaffold-free and vascularized human cardiac muscle tissue. PNAS, 106:16568–16573.
LaflammeMA, ChenKY, NaumovaAV, MuskheliV, FugateJA, DuprasSK, ReineckeH, XuC, HassanipourMet al. 2007. Cardiomyocytes derived from human embryonic stem cells in pro-survival factors enhance function of infarcted rat hearts. Nat Biotech, 25:1015–1024.
15.
NiebrueggeS, BauwensCL, PeeraniR, ThavandiranN, MasseS, SevaptisidisE, NanthakumarK, WoodhouseK, HusainM, KumachevaE, ZandstraPW. 2009. Generation of human embryonic stem cell-derived mesoderm and cardiac cells using size-specified aggregates in an oxygen-controlled bioreactor. Biotechnol Bioeng, 102:493–507.
16.
BeqqaliA, KlootsJ, Ward-van OostwaardD, MummeryC, PassierR. 2006. Genome-wide transcriptional profiling of human embryonic stem cells differentiating to cardiomyocytes. Stem Cells, 24:1956–1967.
17.
GraichenR, XuX, BraamSR, BalakrishnanT, NorfizaS, SiehS, SooSY, ThamSC, MummeryCet al. 2008. Enhanced cardiomyogenesis of human embryonic stem cells by a small molecular inhibitor of p38 MAPK. Differentiation, 76:357–370.
18.
XuC, PoliceS, HassanipourM, GoldJD. 2006. Cardiac bodies: a novel culture method for enrichment of cardiomyocytes derived from human embryonic stem cells. Stem Cells Dev, 15:631–639.
19.
XuXQ, GraichenR, SooSY, BalakrishnanT, RahmatSNB, SiehS, ThamSC, FreundC, MooreJet al. 2008. Chemically defined medium supporting cardiomyocyte differentiation of human embryonic stem cells. Differentiation, 76:958–970.
20.
YangL, SoonpaaMH, AdlerED, RoepkeTK, KattmanSJ, KennedyM, HenckaertsE, BonhamK, AbbottGWet al. 2008. Human cardiovascular progenitor cells develop from a KDR+embryonic-stem-cell-derived population. Nature, 453:524–528.
21.
KattmanSJ, WittyAD, GagliardiM, DuboisNC, NiapourM, HottaA, EllisJ, KellerG. 2011. Stage-specific optimization of activin/nodal and BMP signaling promotes cardiac differentiation of mouse and human pluripotent stem cell lines. Cell Stem Cell, 8:228–240.
22.
PaigeSL, OsugiT, AfanasievOK, PabonL, ReineckeH, MurryCE. 2010. Endogenous wnt/β-catenin signaling is required for cardiac differentiation in human embryonic stem cells. PLoS ONE, 5:e11134.
23.
HoughSR, LaslettAL, GrimmondSB, KolleG, PeraMF. 2009. A continuum of cell states spans pluripotency and lineage commitment in human embryonic stem cells. PLoS ONE, 4:e7708.
24.
LaslettA, GrimmondS, GardinerB, StampL, LinA, HawesS, WormaldS, Nikolic-PatersonD, HaylockD, PeraM. 2007. Transcriptional analysis of early lineage commitment in human embryonic stem cells. BMC Dev Biol, 7:12.
25.
International-Stem-Cell-Initiative. 2007. Characterization of human embryonic stem cell lines by the International Stem Cell Initiative. Nat Biotech, 25:803–816.
26.
MurryCE, KellerG. 2008. Differentiation of embryonic stem cells to clinically relevant populations: lessons from embryonic development. Cell, 132:661–680.
27.
NaitoAT, ShiojimaI, AkazawaH, HidakaK, MorisakiT, KikuchiA, KomuroI. 2006. Developmental stage-specific biphasic roles of Wnt/β-catenin signaling in cardiomyogenesis and hematopoiesis. PNAS, 103:19812–19817.
28.
JacksonSA, SchiesserJ, StanleyEG, ElefantyAG. 2010. Differentiating embryonic stem cells pass through temporal windows that mark responsiveness to exogenous and paracrine mesendoderm inducing signals. PLoS ONE, 5:e10706.
29.
LeeLH, PeeraniR, UngrinM, JoshiC, KumachevaE, ZandstraP. 2009. Micropatterning of human embryonic stem cells dissects the mesoderm and endoderm lineages. Stem Cell Res, 2:155–162.
30.
CostaM, SourrisK, HatzistavrouT, ElefantyAG, StanleyEG. 2008. Expansion of human embryonic stem cells in vitro. Curr Protoc Stem Cell Biol Chapter 1Unit 1C 1 1-1C 1 7.
31.
ChenB, DodgeME, TangW, LuJ, MaZ, FanC-W, WeiS, HaoW, KilgoreJet al. 2009. Small molecule-mediated disruption of Wnt-dependent signaling in tissue regeneration and cancer. Nat Chem Biol, 5:100–107.
TakadaR, SatomiY, KurataT, UenoN, NoriokaS, KondohH, TakaoT, TakadaS. 2006. Monounsaturated fatty acid modification of Wnt protein: its role in Wnt secretion. Dev Cell, 11:791–801.
35.
BakerDEC, HarrisonNJ, MaltbyE, SmithK, MooreHD, ShawPJ, HeathPR, HoldenH, AndrewsPW. 2007. Adaptation to culture of human embryonic stem cells and oncogenesis in vivo. Nat Biotech, 25:207–215.
36.
DraperJS, SmithK, GokhaleP, MooreHD, MaltbyE, JohnsonJ, MeisnerL, ZwakaTP, ThomsonJA, AndrewsPW. 2004. Recurrent gain of chromosomes 17q and 12 in cultured human embryonic stem cells. Nat Biotech, 22:53–54.
37.
Werbowetski-OgilvieTE, BosseM, StewartM, SchnerchA, Ramos-MejiaV, RouleauA, WynderT, SmithM-J, DingwallS, CarterTet al. 2009. Characterization of human embryonic stem cells with features of neoplastic progression. Nat Biotech, 27:91–97.
38.
CaiC-L, LiangX, ShiY, ChuP-H, PfaffSL, ChenJ, EvansS. 2003. Isl1 identifies a cardiac progenitor population that proliferates prior to differentiation and contributes a majority of cells to the heart. Dev Cell, 5:877–889.
39.
ChienKR, ZhuH, KnowltonKU, Miller-HanceW, Van-BilsenM, O'BrienTX, EvansSM. 1993. Transcriptional regulation during cardiac growth and development. Annu Rev Physiol, 55:77–95.
40.
Chuva de Sousa LopesSM, HassinkRJ, FeijenA, van RooijenMA, DoevendansPA, TertoolenL, Brutel de la RivièreA, MummeryCL. 2006. Patterning the heart, a template for human cardiomyocyte development. Dev Dyn, 235:1994–2002.
HudsonJE, BrookeG, BlairC, WolvetangE, Cooper-WhiteJJ. 2011. Development of myocardial constructs using modulus-matched acrylated polypropylene glycol triol substrate and different nonmyocyte cell populations. Tissue Eng Part A, 17:2279–2289.
45.
BelA, Planat-BernardV, SaitoA, BonnevieL, BellamyV, SabbahL, BellabasL, BrinonB, VanneauxVet al. 2010. Composite cell sheets: a further step toward safe and effective myocardial regeneration by cardiac progenitors derived from embryonic stem cells. Circulation, 122:S118–S123.
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