Timed inhibition of p38MAPK directs accelerated differentiation of human embryonic stem cells into cardiomyocytes

Background aimsHeart failure therapy with human embryonic stem cell (hESC)-derived cardiomyocytes (hCM) has been limited by the low rate of spontaneous hCM differentiation. As others have shown that p38 mitogen-activated protein kinase (p38MAPK) directs neurogenesis from mouse embryonic stem cells, we investigated whether the p38MAPK inhibitor, SB203580, might influence hCM differentiation.MethodsWe treated differentiating hESC with SB203580 at specific time-points, and used flow cytometry, immunocytochemistry, quantitative real-time (RT)–polymerase chain reaction (PCR), teratoma formation and transmission electron microscopy to evaluate cardiomyocyte formation.ResultsWe observed that the addition of inhibitor resulted in 2.1-fold enrichment of spontaneously beating human embryoid bodies (hEB) at 21 days of differentiation, and that 25% of treated cells expressed cardiac-specific α-myosin heavy chain. This effect was dependent on the stage of differentiation at which the inhibitor was introduced. Immunostaining and teratoma formation assays demonstrated that the inhibitor did not affect hESC pluripotency; however, treated hESC gave rise to hCM exhibiting increased expression of sarcomeric proteins, including cardiac troponin T, myosin light chain and α-myosin heavy chain. This was consistent with significantly increased numbers of myofibrillar bundles and the appearance of nascent Z-bodies at earlier time-points in treated hCM. Treated hEB also demonstrated a normal karyotype by array comparative genomic hybridization and viability in vivo following injection into mouse myocardium.ConclusionsThese studies demonstrate that p38MAPK inhibition accelerates directed hCM differentiation from hESC, and that this effect is developmental stage-specific. The use of this inhibitor should improve our ability to generate hESC-derived hCM for cell-based therapy.     

Fetal bovine serum enables cardiac differentiation of human embryonic stem cells

During development, cardiac commitment within the mesoderm requires endoderm-secreted factors. Differentiation of embryonic stem cells into the three germ layers in vitro recapitulates developmental processes and can be influenced by supplements added to culture medium. Hence, we investigated the effect of fetal bovine serum (FBS) and KnockOut serum replacement (SR) on germ layers specification and cardiac differentiation of H1 human embryonic stem cells (hESC) within embryoid bodies (EB). At the time of EB formation, FBS triggered an increased apoptosis. As assessed by quantitative PCR on 4-, 10-, and 20-day-old EB, FBS promoted a faster down-regulation of pluripotency marker Oct4 and an increased expression of endodermal (Sox17, alpha-fetoprotein, AFP) and mesodermal genes (Brachyury, CSX). While neuronal and hematopoietic differentiation occurred in both supplements, spontaneously beating cardiomyocytes were only observed in FBS. Action potential (AP) morphology of hESC-derived cardiomyocytes indicated that ventricular cells were present only after 2 months of culture. However, quantification of myosin light chain 2 ventricular (mlc2v)-positive areas revealed that mlc2v-expressing cardiomyocytes could be detected already after 2 weeks of differentiation, but not in all beating clusters. In conclusion, FBS enabled cardiac differentiation of hESC, likely in an endodermal-dependent pathway. Among cardiac cells, ventricular cardiomyocytes differentiated over time, but not as the predominant cardiac cell subtype.     

A dual role of the GTPase Rac in cardiac differentiation of stem cells

The function of the GTPase Rac1, a molecular switch transducing intracellular signals from growth factors, in differentiation of a specific cell type during early embryogenesis has not been investigated. To address the question, we used embryonic stem (ES) cells differentiated into cardiomyocytes, a model that faithfully recapitulates early stages of cardiogenesis. Overexpression in ES cells of a constitutively active Rac (RacV12) but not of an active mutant (RacL61D38), which does not activate the NADPH oxydase generating ROS, prevented MEF2C expression and severely compromised cardiac cell differentiation. This resulted in poor expression of ventricular myosin light chain 2 (MLC2v) and its lack of insertion into sarcomeres. Thus ES-derived cardiomyocytes featured impaired myofibrillogenesis and contractility. Overexpression of MEF2C or addition of catalase in the culture medium rescued the phenotype of racV12 cells. In contrast, RacV12 specifically expressed in ES-derived ventricular cells improved the propensity of cardioblasts to differentiate into beating cardiomyocytes. This was attributed to both a facilitation of myofibrillogenesis and a prolongation in their proliferation. The dominant negative mutant RacN17 early or lately expressed in ES-derived cells prevented myofibrillogenesis and in turn beating of cardiomyocytes. We thus suggest a stage-dependent function of the GTPase during early embryogenesis.     

Transforming growth factor-beta2 enhances differentiation of cardiac myocytes from embryonic stem cells

Stem cell therapy holds great promise for the treatment of injured myocardium, but is challenged by a limited supply of appropriate cells. Three different isoforms of transforming growth factor-beta (TGF-beta) -beta1, -beta2, and -beta3 exhibit distinct regulatory effects on cell growth, differentiation, and migration during embryonic development. We compared the effects of these three different isoforms on cardiomyocyte differentiation from embryonic stem (ES) cells. In contrast to TGF-beta1, or -beta3, treatment of mouse ES cells with TGF-beta2 isoform significantly increased embryoid body (EB) proliferation as well as the extent of the EB outgrowth that beat rhythmically. At 17 days, 49% of the EBs treated with TGF-beta2 exhibited spontaneous beating compared with 15% in controls. Cardiac myocyte specific protein markers sarcomeric myosin and alpha-actin were demonstrated in beating EBs and cells isolated from EBs. In conclusion, TGF-beta2 but not TGF-beta1, or -beta3 promotes cardiac myocyte differentiation from ES cells.     

Ultrastructural comparison of developing mouse embryonic stem cell- and in vivo-derived cardiomyocytes

Embryonic stem cells (ESCs) are expected to become a powerful tool for future regenerative medicine and developmental biology due to their capacity for self-renewal and pluripotency. The present study involves characterization and particularly, the ultrastructure of ESC-derived cardiomyocytes (ESC-CMs). Spontaneously differentiated murine (C57BL/6) ESC-CMs were cultured for 21 days. At different stages, growth characteristics of the CMs were assessed by immunocytochemistry, RT-PCR, transmission electron microscopy, and by addition of chronotropic drugs. EB-derived spontaneously beating cells expressed markers characteristic of CMs including alpha-actinin, desmin, troponin I, sarcomeric myosin heavy chain (MHC), pan-cadherin, connexin 43, cardiac alpha-MHC, cardiac beta-MHC, atrial natriuretic factor (ANF), and myosin light chain isoform-2V (MLC-2V) and responded to drugs in a maturation- and dose-dependent manner. At the ultrasructural level, maturation proceeded with increasing time in culture. In 7+21 days CMs, all sarcomeric components, such as Z-discs, A-, I- and H-bands as well as M-lines, T-tubules, intercalated discs, and the sarcoplasmic reticulum were present. Our data suggest that ESCs can differentiate into functional mature CMs in vitro. Furthermore, ESC-CMs may provide an ideal model for the study of cardiomyocytic development and may be useful for cell therapy of various cardiac diseases.     

'Working' cardiomyocytes exhibiting plateau action potentials from human placenta-derived extraembryonic mesodermal cells

The clinical application of cell transplantation for severe heart failure is a promising strategy to improve impaired cardiac function. Recently, an array of cell types, including bone marrow cells, endothelial progenitors, mesenchymal stem cells, resident cardiac stem cells, and embryonic stem cells, have become important candidates for cell sources for cardiac repair. In the present study, we focused on the placenta as a cell source. Cells from the chorionic plate in the fetal portion of the human placenta were obtained after delivery by the primary culture method, and the cells generated in this study had the Y sex chromosome, indicating that the cells were derived from the fetus. The cells potentially expressed 'working' cardiomyocyte-specific genes such as cardiac myosin heavy chain 7beta, atrial myosin light chain, cardiac alpha-actin by gene chip analysis, and Csx/Nkx2.5, GATA4 by RT-PCR, cardiac troponin-I and connexin 43 by immunohistochemistry. These cells were able to differentiate into cardiomyocytes. Cardiac troponin-I and connexin 43 displayed a discontinuous pattern of localization at intercellular contact sites after cardiomyogenic differentiation, suggesting that the chorionic mesoderm contained a large number of cells with cardiomyogenic potential. The cells began spontaneously beating 3 days after co-cultivation with murine fetal cardiomyocytes and the frequency of beating cells reached a maximum on day 10. The contraction of the cardiomyocytes was rhythmical and synchronous, suggesting the presence of electrical communication between the cells. Placenta-derived human fetal cells may be useful for patients who cannot supply bone marrow cells but want to receive stem cell-based cardiac therapy.     

The effects of prolonged gravity vector randomization on differentiation of precursour cells in vitro

It was shown that proliferative rate of human mesenchymal stem cells (hMSCs) decreased during gravity vector randomization (clinorotation). Clinorotated hMSCs exhibited changes in expression of some external cell markers and adhesion molecules. Marked suppression of osteogenic differentiation of hMSC as to formation of bone nodules and calcium deposits was observed. F-actin stress fibers of cytoskeleton were altered in clinorotated cultures. Prolonged clinorotation of embryoid bodies (EBs) resulted in a delay of embryonic stem cells (ESCs) differentiation into cardiomyocytes. Percentage of beating cardiomyocytes in each EB was significantly reduced. Thus, long-term gravity vector randomization decreases the differentiation processes of precursor cells in vitro.     

Physical passaging of embryoid bodies generated from human pluripotent stem cells

Spherical three-dimensional cell aggregates called embryoid bodies (EBs), have been widely used in in vitro differentiation protocols for human pluripotent stem cells including human embryonic stem cells (hESCs) and human induced pluripotent stem cells (hiPSCs). Recent studies highlight the new devices and techniques for hEB formation and expansion, but are not involved in the passaging or subculture process. Here, we provide evidence that a simple periodic passaging markedly improved hEB culture condition and thus allowed the size-controlled, mass production of human embryoid bodies (hEBs) derived from both hESCs and hiPSCs. hEBs maintained in prolonged suspension culture without passaging (>2 weeks) showed a progressive decrease in the cell growth and proliferation and increase in the apoptosis compared to 7-day-old hEBs. However, when serially passaged in suspension, hEB cell populations were significantly increased in number while maintaining the normal rates of cell proliferation and apoptosis and the differentiation potential. Uniform-sized hEBs produced by manual passaging using a 1∶4 split ratio have been successfully maintained for over 20 continuous passages. The passaging culture method of hEBs, which is simple, readily expandable, and reproducible, could be a powerful tool for improving a robust and scalable in vitro differentiation system of human pluripotent stem cells.     

Hemato-endothelial differentiation from lentiviral-transduced human embryonic stem cells retains durable reporter gene expression under the control of ubiquitin promoter

Human embryonic stem (hES) cells are able to give rise to a variety of cell lineages under specific culture condition. An effective strategy for stable genetic modification in hES cells may provide a powerful tool for study of human embryogenesis and cell-based therapies. However, gene silences are documented in hES cells. In current study, we investigated whether genes controlled under ubiquitin promoter are expressed during hematopoietic-endothelial differentiation in hES cells. Undifferentiated hES cells (H1) were transduced by lentivirus encoding green fluorescent protein (GFP) gene under ubiquitin promoter. GFP-expressing hES cells (GFP-H1) were established after several rounds of mechanical selection under fluorescence microscope. GFP gene was stably expressed in hES cells throughout prolonged (> 50 passages) cultivation, and in differentiated embryo body (EB) and teratoma. Hematopoietic and endothelial markers, including KDR (VEGFR2), CD34, CD31, Tie-2, GATA-1 and GATA-2, were expressed at similar levels during hES cell differentiation in parent hES cells and GFP-H1 hES cells. CD34⁺ cells isolated from GFP-H1 hES cells were capable to generate hematopoietic colony-forming cells and tubular structure-forming cells. Differentiated GFP-EB formed vasculature structures in a semi-solid sprouting EB model. These results indicated that a transgene under ubiquitin promoter in lentiviral transduced hES cells retained its expression in undifferentiated hES cells and in hES-derived hematopoietic and endothelial cells. With the view of embryonic mesodermal developing events in humans, genetic modification of hES cells by lentiviral vectors provides a powerful tool for study of hematopoiesis and vasculogenesis.     

Characterization, chromosomal assignment, and role of LIFR in early embryogenesis and stem cell establishment of rabbits

Leukemia inhibitory factor (LIF) is a multifunctional cytokine with an important role during early embryonic development, implantation, and as an inhibitor of murine embryonic stem cell differentiation. It exerts its effects by binding to the leukemia inhibitory factor receptor, a heterodimer of two transmembrane proteins, the specific leukemia inhibitory factor receptor subunit, and the common gp130. A partial cDNA clone coding for the membrane-bound form of the specific rabbit leukemia inhibitory factor receptor was isolated from the genital ridge of 13.5 days postcoitum fetus. Fluorescent in situ hybridization analysis revealed that the rabbit leukemia inhibitory factor receptor gene is located on chromosome OCU11p11.1. It has been shown that the membrane-bound rabbit leukemia inhibitory factor receptor mRNA is expressed during embryo implantation but not at earlier developmental stages. Rabbit embryonic stem cell-like line establishment is improved in the presence of LIF, and those cells express both leukemia inhibitory factor and its receptor. The withdrawal of leukemia inhibitory factor results the differentiation of embryonic stem cell-like cells to beating myocardial-like cells. Our findings suggest that the self-renewal mechanism is similar in mouse and rabbit embryonic stem cells, and expands our knowledge on the role of the LIF-LIFR signal pathway in early rabbit embryogenesis and rabbit embryonic stem cell establishment.