Hierarchical architecture influences calcium dynamics in engineered cardiac muscle

Changes in myocyte cell shape and tissue structure are concurrent with changes in electromechanical function in both the developing and diseased heart. While the anisotropic architecture of cardiac tissue is known to influence the propagation of the action potential, the influence of tissue architecture and its potential role in regulating excitation–contraction coupling (ECC) are less well defined. We hypothesized that changes in the shape and the orientation of cardiac myocytes induced by spatial arrangement of the extracellular matrix (ECM) affects ECC. To test this hypothesis, we isolated and cultured neonatal rat ventricular cardiac myocytes on various micropatterns of fibronectin where they self-organized into tissues with varying degrees of anisotropy. We then measured the morphological features of these engineered myocardial tissues across several hierarchical dimensions by measuring cellular aspect ratio, myocyte area, nuclear density and the degree of cytoskeletal F-actin alignment. We found that when compared with isotropic tissues, anisotropic tissues have increased cellular aspect ratios, increased nuclear densities, decreased myocyte cell areas and smaller variances in actin alignment. To understand how tissue architecture influences cardiac function, we studied the role of anisotropy on intracellular calcium ([Ca2+]i) dynamics by characterizing the [Ca2+]i–frequency relationship of electrically paced tissues. When compared with isotropic tissues, anisotropic tissues displayed significant differences in [Ca2+]i transients, decreased diastolic baseline [Ca2+]i levels and greater [Ca2+]i influx per cardiac cycle. These results suggest that ECM cues influence tissue structure at cellular and subcellular levels and regulate ECC.

[1]  Y. Rudy,et al.  Basic mechanisms of cardiac impulse propagation and associated arrhythmias. , 2004, Physiological reviews.

[2]  J. Molkentin Dichotomy of Ca2+ in the heart: contraction versus intracellular signaling. , 2006, The Journal of clinical investigation.

[3]  R C Barr,et al.  Electrophysiological effects of remodeling cardiac gap junctions and cell size: experimental and model studies of normal cardiac growth. , 2000, Circulation research.

[4]  William C. Messner,et al.  Probing Cellular Dynamics with a Chemical Signal Generator , 2009, PloS one.

[5]  D. A. Gomes,et al.  Nuclear Ca2+ regulates cardiomyocyte function. , 2008, Cell calcium.

[6]  D. Atsma,et al.  Forced Alignment of Mesenchymal Stem Cells Undergoing Cardiomyogenic Differentiation Affects Functional Integration With Cardiomyocyte Cultures , 2008, Circulation research.

[7]  Kevin Kit Parker,et al.  Myofibrillar Architecture in Engineered Cardiac Myocytes , 2008, Circulation research.

[8]  Y. Hirota,et al.  Visualization of biphasic Ca2+ diffusion from cytosol to nucleus in contracting adult rat cardiac myocytes with an ultra-fast confocal imaging system. , 1999, Cell calcium.

[9]  J. Le Guennec,et al.  Streptomycin reverses a large stretch induced increases in [Ca2+]i in isolated guinea pig ventricular myocytes. , 1994, Cardiovascular research.

[10]  Anil K. Jain,et al.  Fingerprint Image Enhancement: Algorithm and Performance Evaluation , 1998, IEEE Trans. Pattern Anal. Mach. Intell..

[11]  L. Clerc Directional differences of impulse spread in trabecular muscle from mammalian heart. , 1976, The Journal of physiology.

[12]  Sean P Sheehy,et al.  Nuclear morphology and deformation in engineered cardiac myocytes and tissues. , 2010, Biomaterials.

[13]  V. Fast,et al.  Microscopic conduction in cultured strands of neonatal rat heart cells measured with voltage-sensitive dyes. , 1993, Circulation research.

[14]  R. Tsien,et al.  A new generation of Ca2+ indicators with greatly improved fluorescence properties. , 1985, The Journal of biological chemistry.

[15]  Mark-Anthony Bray,et al.  Multidimensional detection and analysis of Ca2+ sparks in cardiac myocytes. , 2007, Biophysical journal.

[16]  S. Haskill,et al.  Signal transduction from the extracellular matrix , 1993, The Journal of cell biology.

[17]  N. Severs,et al.  The cardiac muscle cell. , 2000, BioEssays : news and reviews in molecular, cellular and developmental biology.

[18]  Engineering design of a cardiac myocyte , 2007 .

[19]  K. Rakušan,et al.  Normal and hypertrophic growth of the rat heart: changes in cell dimensions and number. , 1978, The American journal of physiology.

[20]  M. Spach,et al.  The stochastic nature of cardiac propagation at a microscopic level. Electrical description of myocardial architecture and its application to conduction. , 1995, Circulation research.

[21]  D. Bers Cardiac excitation–contraction coupling , 2002, Nature.

[22]  W. Robberecht,et al.  Abnormal intracellular ca(2+)homeostasis and disease. , 2000, Cell calcium.

[23]  E. White,et al.  Activation of Na+–H+ exchange and stretch‐activated channels underlies the slow inotropic response to stretch in myocytes and muscle from the rat heart , 2004, The Journal of physiology.

[24]  Ning Wang,et al.  Directional control of lamellipodia extension by constraining cell shape and orienting cell tractional forces , 2002, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[25]  K K Parker,et al.  Symmetry-breaking in mammalian cell cohort migration during tissue pattern formation: role of random-walk persistence. , 2005, Cell motility and the cytoskeleton.

[26]  Sean P Sheehy,et al.  Sarcomere alignment is regulated by myocyte shape. , 2008, Cell motility and the cytoskeleton.

[27]  Y Rudy,et al.  Ionic mechanisms of propagation in cardiac tissue. Roles of the sodium and L-type calcium currents during reduced excitability and decreased gap junction coupling. , 1997, Circulation research.

[28]  M. Aschner,et al.  Polymorphic ventricular tachycardia and abnormal Ca2+ handling in very-long-chain acyl-CoA dehydrogenase null mice. , 2007, American journal of physiology. Heart and circulatory physiology.

[29]  F. Lu,et al.  The effect of streptomycin on stretch-induced electrophysiological changes of isolated acute myocardial infarcted hearts in rats { , 2007 .

[30]  M. Endoh Force-frequency relationship in intact mammalian ventricular myocardium: physiological and pathophysiological relevance. , 2004, European journal of pharmacology.

[31]  A. M. Scher,et al.  Effect of Tissue Anisotropy on Extracellular Potential Fields in Canine Myocardium in Situ , 1982, Circulation research.

[32]  J. Sadoshima,et al.  The cellular and molecular response of cardiac myocytes to mechanical stress. , 1997, Annual review of physiology.

[33]  D M Bers,et al.  Calcium fluxes involved in control of cardiac myocyte contraction. , 2000, Circulation research.

[34]  Kevin Kit Parker,et al.  Control of myocyte remodeling in vitro with engineered substrates , 2009, In Vitro Cellular & Developmental Biology - Animal.

[35]  E. White,et al.  Do stretch-induced changes in intracellular calcium modify the electrical activity of cardiac muscle? , 2003, Progress in biophysics and molecular biology.

[36]  Robin I. M. Dunbar,et al.  Muscular Thin Films for Building Actuators and Powering Devices , 2007 .

[37]  N. Bursac,et al.  Cardiomyocyte Cultures With Controlled Macroscopic Anisotropy: A Model for Functional Electrophysiological Studies of Cardiac Muscle , 2002, Circulation research.

[38]  Kenneth B Walsh,et al.  Changes in cardiac myocyte morphology alter the properties of voltage-gated ion channels. , 2002, Cardiovascular research.

[39]  Kevin Kit Parker,et al.  Symmetry breaking in cultured mammalian cells , 2007, In Vitro Cellular & Developmental Biology - Animal.

[40]  Harold Bien,et al.  Scaffold topography alters intracellular calcium dynamics in cultured cardiomyocyte networks. , 2004, American journal of physiology. Heart and circulatory physiology.