Transition in cardiac contractile sensitivity to calcium during the in vitro differentiation of mouse embryonic stem cells

Mouse embryonic stem (ES) cells differentiate in vitro into a variety of cell types including spontaneously contracting cardiac myocytes. We have utilized the ES cell differentiation culture system to study the development of the cardiac contractile apparatus in vitro. Difficulties associated with the cellular and developmental heterogeneity of this system have been overcome by establishing attached cultures of differentiating ES cells, and by the micro-dissection of the contracting cardiac myocytes from culture. The time of onset and duration of continuous contractile activity of the individual contracting myocytes was determined by daily visual inspection of the cultures. A functional assay was used to directly measure force production in ES cell-derived cardiac myocyte preparations. The forces produced during spontaneous contractions in the membrane intact preparation, and during activation by Ca2+ subsequent to chemical permeabilization of the surface membranes were determined in the same preparation. Results showed a transition in contractile sensitivity to Ca2+ in ES cell-derived cardiac myocytes during development in vitro. Cardiac preparations isolated from culture following the initiation of spontaneous contractile activity showed marked sensitivity of the contractile apparatus to activation by Ca2+. However, the Ca2+ sensitivity of tension development was significantly decreased in preparations isolated from culture following prolonged continuous contractile activity in vitro. The alteration in Ca2+ sensitivity obtained in vitro paralleled that observed during murine cardiac myocyte development in vivo. This provides functional evidence that ES cell-derived cardiac myocytes recapitulate cardiogenesis in vitro. Alterations in Ca2+ sensitivity could be important in optimizing the cardiac contractile response to variations in the myoplasmic Ca2+ transient during embryogenesis. The potential to stably transfect ES cells with cardiac regulatory genes, together with the availability of a functional assay using control and genetically modified ES cell- derived cardiac myocytes, will permit determination of the functional significance of altered cardiac gene expression during cardiogenesis in vitro.

[1]  R. Solaro,et al.  Changes in myofibrillar activation and troponin C Ca2+ binding associated with troponin T isoform switching in developing rabbit heart. , 1990, Circulation research.

[2]  P. Anderson,et al.  Developmental Changes in the Expression of Rabbit Left Ventricular Troponin T , 1988, Circulation research.

[3]  A. Fabiato,et al.  Computer programs for calculating total from specified free or free from specified total ionic concentrations in aqueous solutions containing multiple metals and ligands. , 1988, Methods in enzymology.

[4]  A. Fabiato Calcium release in skinned cardiac cells: variations with species, tissues, and development. , 1982, Federation proceedings.

[5]  R. Moss,et al.  The effect of altered temperature on Ca2(+)-sensitive force in permeabilized myocardium and skeletal muscle. Evidence for force dependence of thin filament activation , 1990, The Journal of general physiology.

[6]  M. B. Kelly,et al.  Force-pCa relation and troponin T isoforms of rabbit myocardium. , 1991, Circulation research.

[7]  G. Wallukat,et al.  Pluripotent mouse embryonic stem cells are able to differentiate into cardiomyocytes expressing chronotropic responses to adrenergic and cholinergic agents and Ca2+ channel blockers. , 1991, Differentiation; research in biological diversity.

[8]  R. Moss,et al.  Developmental changes in troponin T isoform expression and tension production in chicken single skeletal muscle fibres. , 1992, The Journal of physiology.

[9]  N J Sissman,et al.  Developmental landmarks in cardiac morphogenesis: comparative chronology. , 1970, The American journal of cardiology.

[10]  G. Lyons,et al.  In vitro chamber specification during embryonic stem cell cardiogenesis. Expression of the ventricular myosin light chain-2 gene is independent of heart tube formation. , 1993, The Journal of biological chemistry.

[11]  R. Zak Cell proliferation during cardiac growth. , 1973, The American journal of cardiology.

[12]  J. Leiden,et al.  Skeletal troponin C reduces contractile sensitivity to acidosis in cardiac myocytes from transgenic mice. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[13]  R Kemler,et al.  The in vitro development of blastocyst-derived embryonic stem cell lines: formation of visceral yolk sac, blood islands and myocardium. , 1985, Journal of embryology and experimental morphology.

[14]  T. Nosek,et al.  Changes in force and calcium sensitivity in the developing avian heart. , 1991, Canadian journal of physiology and pharmacology.

[15]  P. Howles,et al.  Developmental analysis of tropomyosin gene expression in embryonic stem cells and mouse embryos , 1993, Molecular and cellular biology.

[16]  T. Doetschman,et al.  Myosin heavy chain gene expression in mouse embryoid bodies. An in vitro developmental study. , 1991, The Journal of biological chemistry.

[17]  T. Doetschman,et al.  Embryonic stem cells as a model for cardiogenesis. , 1992, Trends in cardiovascular medicine.

[18]  A. Fabiato,et al.  CALCIUM‐INDUCED RELEASE OF CALCIUM FROM THE SARCOPLASMIC RETICULUM OF SKINNED CELLS FROM ADULT HUMAN, DOG, CAT, RABBIT, RAT, AND FROG HEARTS AND FROM FETAL AND NEW‐BORN RAT VENTRICLES * , 1978, Annals of the New York Academy of Sciences.

[19]  R L Moss,et al.  Greater hydrogen ion‐induced depression of tension and velocity in skinned single fibres of rat fast than slow muscles. , 1987, The Journal of physiology.

[20]  Donald Metcalf,et al.  Myeloid leukaemia inhibitory factor maintains the developmental potential of embryonic stem cells , 1988, Nature.

[21]  M. Diamond,et al.  Effect of different troponin T-tropomyosin combinations on thin filament activation. , 1987, Journal of molecular biology.

[22]  K. Chien,et al.  Transcriptional regulation during cardiac growth and development. , 1993, Annual review of physiology.

[23]  R. Moss,et al.  Variations in cross-bridge attachment rate and tension with phosphorylation of myosin in mammalian skinned skeletal muscle fibers. Implications for twitch potentiation in intact muscle , 1989, The Journal of general physiology.

[24]  Ha Won Kim,et al.  Mouse phospholamban gene expression during development in vivo and in vitro. , 1992, Circulation research.

[25]  W. Friedman,et al.  A Diminished Role for the Sarcoplasmic Reticulum in Newborn Myocardial Contraction: Effects of Ryanodine , 1989, Pediatric Research.

[26]  R. Godt,et al.  Influence of temperature upon contractile activation and isometric force production in mechanically skinned muscle fibers of the frog , 1982, The Journal of general physiology.

[27]  D. Allen,et al.  The cellular basis of the length-tension relation in cardiac muscle. , 1985, Journal of molecular and cellular cardiology.

[28]  G. Lyons,et al.  Developmental regulation of myosin gene expression in mouse cardiac muscle , 1990, The Journal of cell biology.