Maria Wartenberg

Reactive Oxygen Species as Intracellular Messengers During Cell Growth and Differentiation

Reactive oxygen species (ROS) are generated following ligand-receptor interactions and function as specific second messengers in signaling cascades involved in cell proliferation and differentiation. Although ROS are generated intracellularly by several sources, including mitochondria, the primary sources of ROS involved in receptor-mediated signaling cascades are plasma membrane oxidases, preferentially NADPH oxidases, with a rapid kinetics of activation and inactivation. This allows a tight up- and downregulation of intracellular ROS levels within the short time required for the transduction of signals from the plasma membrane to the cell nucleus. The mode of action of ROS may involve direct interaction with specific receptors, and/or redox-activation of members of signaling pathways such as protein kinases, protein phosphatases, and transcription factors. Furthermore, ROS act in concert with intracellular Ca2+ in signaling pathways which regulate the balance of cell proliferation versus cell cycle arrest and cell death. The delicate intracellular interplay between oxidizing and reducing equivalents allows ROS to function as second messengers in the control of cell proliferation and differentiation.

Cardiac specific differentiation of mouse embryonic stem cells

Embryonic stem (ES) cells may represent an alternative source of functionally intact cardiomyocytes for the causal treatment of cardiovascular diseases. However, this requires cardiac-specific differentiation of stem cells and the selection of pure lineages consisting of early embryonic cardiomyocytes. Therefore, an understanding of the basic mechanisms of heart development is essential for selective differentiation of embryonic stem cells into cardiac cells. The development of cardiac cells from embryonic stem cells is regulated by several soluble factors and signalling molecules together with cardiac specific transcription factors such as the zinc-finger GATA proteins and Nkx-2.5. GATA-4 and Nkx-2.5 seem to be essential for heart development. The use of enhanced green fluorescent protein (EGFP) under the control of cardiac-specific promoters in combination with the ES cell system has allowed for the functional characterisation of cardiac precursor cells. Embryonic stem cell-derived cardiomyocytes developmentally express similar cardiac-specific proteins, ion channels and signalling molecules to that of adult cardiomyocytes. Furthermore, identification of growth factors and signalling molecules under cell culture conditions is crucial for the selective cardiac differentiation of embryonic stem cells. Therefore, serum-free culture conditions have to be established in order to examine the influence of different growth factors and signalling molecules on cardiac development and/or formation from ES cells. Although significant progress has been made in generating cardiac cell lineage by the combination of genetically manipulative methods with selective culture conditions for cell transplantation therapy, one of the remaining future challenges for transplantation in humans is the immunological rejection of the engrafted cardiomyocytes.

Embryonic stem cells utilize reactive oxygen species as transducers of mechanical strain-induced cardiovascular differentiation

Growing stem cells are subjected to mechanical forces, which may initiate differentiation programs. Mechanical strain stimulated cardiovascular differentiation of mouse embryonic stem (ES) cells as evaluated by quantification of contracting cardiac foci and capillary areas, respectively. Mechanical strain rapidly elevated intracellular reactive oxygen species (ROS). After 24 h up‐regulation of NADPH oxidase subunits p22‐phox, p47‐phox, p67‐phox, and Nox‐4 as well as Nox‐1 and Nox‐4 mRNA was observed. In parallel, mechanical strain increased hypoxia‐inducible factor‐1α (HIF‐1α) and vascular endothelial growth factor (VEGF) mRNA and protein as well as MEF2C and GATA‐4 mRNA, which are involved in cardiovascular development. Furthermore, phosphorylation of extracellular‐regulated kinase 1,2 (ERK1,2), p38, and c‐jun N‐terminal kinase (c‐Jun NH2‐terminal kinase (JNK)) was observed. Stimulation of cardiovascular commitment, HIF‐1α, VEGF, and MEF2C expression as well as MAPK activation were abolished by free radical scavengers, whereas GATA‐4 expression was increased. Cardiomyogenesis was inhibited by the p38 inhibitor SB203580, the ERK1,2 inhibitor UO126, and the JNK inhibitor SP600125. Vasculogenesis/angiogenesis was blunted following inhibition of ERK1,2 and JNK, whereas p38 inhibition was ineffective. Our data outline a role of ROS as mechanotransducing molecules in mechanical strain‐stimulated cardiovascular differentiation of ES cells, and point toward a microenvironment of elevated ROS required for signaling cascades initiating cardiovascular differentiation programs.—Schmelter, M., Ateghang, B., Helmig, S., Wartenberg, M., Sauer, H. Embryonic stem cells utilize reactive oxygen species as transducers of mechanical strain‐induced cardiovascular differentiation. FASEB J. 20, E294–E306 (2006)

Role of reactive oxygen species and phosphatidylinositol 3-kinase in cardiomyocyte differentiation of embryonic stem cells.

Cardiotypic development in embryonic stem cell‐derived embryoid bodies may be regulated by reactive oxygen species (ROS). ROS were generated by a NADPH oxidase‐like enzyme which was transiently expressed during the time course of embryoid body development. Incubation with either H2O2 or menadione enhanced cardiomyogenesis, whereas the radical scavengers trolox, pyrrolidinedithiocarbamate and N‐acetylcysteine exerted inhibitory effects. The phosphatidylinositol 3‐kinase (PI‐3‐kinase) inhibitors LY294002 and wortmannin abolished cardiac commitment and downregulated ROS in embryoid bodies. Coadministration of LY294002 with prooxidants resumed cardiomyocyte differentiation, indicating a role for PI‐3‐kinase in the regulation of the intracellular redox state.

Regulation of the multidrug resistance transporter P-glycoprotein in multicellular tumor spheroids by hypoxia-inducible factor (HIF-1) and reactive oxygen species

Hypoxia in tumors is generally associated with chemoresistance and radioresistance. However, the correlation between the heterodimeric hypoxia‐inducible factor‐1 (HIF‐1) and the multidrug resistance transporter P‐glycoprotein (P‐gp) has not been investigated. Herein, we demonstrate that with increasing size of DU‐145 prostate multicellular tumor spheroids the pericellular oxygen pressure and the generation of reactive oxygen species decreased, whereas the α‐subunit of HIF‐1 (HIF‐1α) and P‐gp were up‐regulated. Furthermore, P‐gp was up‐regulated under experimental physiological hypoxia and chemical hypoxia induced by either cobalt chloride or desferrioxamine. The pro‐oxidants H2O2 and buthionine sulfoximine down‐regulated HIF‐1α and P‐gp, whereas up‐regulation was achieved with the radical scavengers dehydroascorbate, N‐acetylcysteine, and vitamin E. The correlation of HIF‐1α and P‐gp expression was validated by the use of hepatoma tumor spheroids that were either wild type (Hepa1) or mutant (Hepa1C4) for aryl hydrocarbon receptor nuclear translocator (ARNT), i.e., HIF‐1β. Chemical hypoxia robustly increased HIF‐1α as well as P‐gp expression in Hepa1 tumor spheroids, whereas no changes were observed in Hepa1C4 spheroids. Hence, our data demonstrate that expression of P‐gp in multicellular tumor spheroids is under the control of HIF‐1.

Effects of electrical fields on cardiomyocyte differentiation of embryonic stem cells

The effects of electromagnetic fields (EMFs) on the differentiation of cardiomyocytes in embryoid bodies derived from pluripotent embryonic stem (ES) cells were investigated. A single direct current (DC) field pulse was applied to 4‐day‐old embryoid bodies. The electrical field induced a hyperpolarization of the anode‐facing side of embryoid bodies and a depolarization at the cathode‐facing side. Significant effects of a single electrical field pulse applied for 90 s on cardiomyocyte differentiation were achieved with field strengths of 250 and 500 V/m, which increased both the number of embryoid bodies differentiating beating foci of cardiomyocytes and the size of the beating foci. The 500‐V/m electrical field increased intracellular reactive oxygen species (ROS), but not [Ca2+]i and activated nuclear factor kappa B (NF‐κB). A comparable increase in the number of beating embryoid bodies was achieved by an incubation for 1 h with H2O2 (1–10 nM), indicating that the electrical field effect was transduced via the intracellular generation of ROS. Because the radical scavengers dehydroascorbate and pyrrolidinedithiocarbamate (APDC) and the NF‐κB antagonist N‐tosyl‐L‐phenylalanine chloromethyl ketone (TPCK) inhibited cardiac differentiation, we assume that ROS and NF‐κB may play a role in early cardiac development. J. Cell. Biochem. 75:710–723, 1999.

Stimulation of ES-cell-derived cardiomyogenesis and neonatal cardiac cell proliferation by reactive oxygen species and NADPH oxidase.

After birth the proliferation of cardiac cells declines, and further growth of the heart occurs by hypertrophic cell growth. In the present study the cell proliferation capacity of mouse embryonic stem (ES) cells versus neonatal cardiomyocytes and the effects of reactive oxygen species (ROS) on cardiomyogenesis and cardiac cell proliferation of ES cells was investigated. Low levels of hydrogen peroxide stimulated cardiomyogenesis of ES cells and induced proliferation of cardiomyocytes derived from ES cells and neonatal mice, as investigated by nuclear translocation of cyclin D1, downregulation of p27Kip1, phosphorylation of retinoblastoma (Rb), increase of Ki-67 expression and incorporation of BrdU. The observed effects were blunted by the free radical scavengers vitamin E and 2-mercaptoglycin (NMPG). In ES cells ROS induced expression of the cardiac-specific genes encoding α-actin, β-MHC, MLC2a, MLC2v and ANP as well as the transcription factors GATA-4, Nkx-2.5, MEF2C, DTEF-1 and the growth factor BMP-10. During differentiation ES cells expressed the NADPH oxidase isoforms Nox-1, Nox-2 and Nox-4. Treatment of cardiac cells with ROS increased Nox-1, Nox-4, p22-phox, p47-phox and p67-phox proteins as well as Nox-1 and Nox-4 mRNA, indicating feed-forward regulation of ROS generation. Inhibition of NADPH oxidase with diphenylen iodonium chloride (DPI) and apocynin abolished ROS-induced cardiomyogenesis of ES cells. Our data suggest that proliferation of neonatal and ES-cell-derived cardiac cells involves ROS-mediated signalling cascades and point towards an involvement of NADPH oxidase in cardiovascular differentiation of ES cells.

Modulation of Calcium-Activated Potassium Channels Induces Cardiogenesis of Pluripotent Stem Cells and Enrichment of Pacemaker-Like Cells

Background— Ion channels are key determinants for the function of excitable cells, but little is known about their role and involvement during cardiac development. Earlier work identified Ca2+-activated potassium channels of small and intermediate conductance (SKCas) as important regulators of neural stem cell fate. Here we have investigated their impact on the differentiation of pluripotent cells toward the cardiac lineage. Methods and Results— We have applied the SKCa activator 1-ethyl-2-benzimidazolinone on embryonic stem cells and identified this particular ion channel family as a new critical target involved in the generation of cardiac pacemaker-like cells: SKCa activation led to rapid remodeling of the actin cytoskeleton, inhibition of proliferation, induction of differentiation, and diminished teratoma formation. Time-restricted SKCa activation induced cardiac mesoderm and commitment to the cardiac lineage as shown by gene regulation, protein, and functional electrophysiological studies. In addition, the differentiation into cardiomyocytes was modulated in a qualitative fashion, resulting in a strong enrichment of pacemaker-like cells. This was accompanied by induction of the sino-atrial gene program and in parallel by a loss of the chamber-specific myocardium. In addition, SKCa activity induced activation of the Ras-Mek-Erk signaling cascade, a signaling pathway involved in the 1-ethyl-2-benzimidazolinone–induced effects. Conclusions— SKCa activation drives the fate of pluripotent cells toward mesoderm commitment and cardiomyocyte specification, preferentially into nodal-like cardiomyocytes. This provides a novel strategy for the enrichment of cardiomyocytes and in particular, the generation of a specific subtype of cardiomyocytes, pacemaker-like cells, without genetic modification.

Identification of Plateled-derived Growth Factor-BB as Cardiogenesis-Inducing Factor in Mouse Embryonic stem cells under Serum-free Conditions

Background/Aims: Embryonic stem (ES) cells may represent an alternative source of functionally mature cardiomyocytes for the treatment of heart diseases. ES cells spontaneously differentiate into spheroidal aggregates, also referred to as embryoid bodies (EBs). The identification of growth factors playing a decisive role in cardiogenesis is a crucial issue for the generation of mature cardiomyocytes. Methods: In order to identify growth factors promoting cardiac development, we established a new differentiation protocol using a defined serum-replacement medium (SRM) containing 5µg/ml insulin and 5µg/ml transferrin in combination with Dulbecco’s Modified Eagle Medium (DMEM). Furthermore, we added platelet-derived growth factor-BB (PDGF-BB) or sphingosine-1-phosphate (SPP) to promote cardiac differentiation. Results: Using SRM/DMEM, we obtained a 6-fold increase of cardiac specific myosin heavy chain α and β (cMHCα/β) in relation to 0,2% foetal calf serum (FCS)/DMEM (= 100%). Stimulation of EBs with PDGF-BB in the presence of SRM/DMEM resulted in a further 2,6-fold enhancement in comparison with the SRM/DMEM-induced increase of cMHCα/β (= 100%). A parallel increase in the number of beating EBs was observed. Similar results were obtained after stimulation of EBs with 5µg/ml SPP. Conclusion: We established a serum-free protocol and identify PDGF-BB and SPP as potent factors promoting cardiogenesis in ES cells.

Phosphatidylinositol 3-Kinase-dependent Membrane Recruitment of Rac-1 and p47phox Is Critical for α-Platelet-derived Growth Factor Receptor-induced Production of Reactive Oxygen Species

Platelet-derived growth factor (PDGF) plays a critical role in the pathogenesis of proliferative diseases. NAD(P)H oxidase (Nox)-derived reactive oxygen species (ROS) are essential for signal transduction by growth factor receptors. Here we investigated the dependence of PDGF-AA-induced ROS production on the cytosolic Nox subunits Rac-1 and p47phox, and we systematically evaluated the signal relay mechanisms by which the αPDGF receptor (αPDGFR) induces ROS liberation. Stimulation of the αPDGFR led to a time-dependent increase of intracellular ROS levels in fibroblasts. Pharmacological inhibitor experiments and enzyme activity assays disclosed Nox as the source of ROS. αPDGFR activation is rapidly followed by the translocation of p47phox and Rac-1 from the cytosol to the cell membrane. Experiments performed in p47phox(-/-) cells and inhibition of Rac-1 or overexpression of dominant-negative Rac revealed that these Nox subunits are required for PDGF-dependent Nox activation and ROS liberation. To evaluate the signaling pathway mediating PDGF-AA-dependent ROS production, we investigated Ph cells expressing mutant αPDGFRs that lack specific binding sites for αPDGFR-associated signaling molecules (Src, phosphatidylinositol 3-kinase (PI3K), phospholipase Cγ, and SHP-2). Lack of PI3K signaling (but not Src, phospholipase Cγ, or SHP-2) completely abolished PDGF-dependent p47phox and Rac-1 translocation, increase of Nox activity, and ROS production. Conversely, a mutant αPDGFR able to activate only PI3K was sufficient to mediate these subcellular events. Furthermore, the catalytic PI3K subunit p110α (but not p110β) was identified as the crucial isoform that elicits αPDGFR-mediated production of ROS. Finally, bromodeoxyuridine incorporation and chemotaxis assays revealed that the lack of ROS liberation blunted PDGF-AA-dependent chemotaxis but not cell cycle progression. We conclude that PI3K/p110α mediates growth factor-dependent ROS production by recruiting p47phox and Rac-1 to the cell membrane, thereby assembling the active Nox complex. ROS are required for PDGF-AA-dependent chemotaxis but not proliferation.