Activation of the ERK1/2 cascade via pulsatile interstitial fluid flow promotes cardiac tissue assembly.

Deciphering the cellular signals leading to cardiac muscle assembly is a major challenge in ex vivo tissue regeneration. For the first time, we demonstrate that pulsatile interstitial fluid flow in three-dimensional neonatal cardiac cell constructs can activate ERK1/2 sixfold, as compared to static-cultivated constructs. Activation of ERK1/2 was attained under physiological shear stress conditions, without activating the p38 cell death signal above its basic level. Activation of the ERK1/2 signaling cascade induced synthesis of high levels of contractile and cell-cell contact proteins by the cardiomyocytes, while its inhibition diminished the inducing effects of pulsatile flow. The pulsed medium-induced cardiac cell constructs showed improved cellularity and viability, while the regenerated cardiac tissue demonstrated some ultra-structural features of the adult myocardium. The cardiomyocytes were elongated and aligned into myofibers with defined Z-lines and multiple high-ordered sarcomeres. Numerous intercalated disks were positioned between adjacent cardiomyocytes, and deposits of collagen fibers surrounded the myofibrils. The regenerated cardiac tissue exhibited high density of connexin 43, a major protein involved in electrical cellular connections. Our research thus demonstrates that by judiciously applying fluid shear stress, cell signaling cascades can be augmented with subsequent profound effects on cardiac tissue regeneration.

[1]  Lisa E. Freed,et al.  Accordion-Like Honeycombs for Tissue Engineering of Cardiac Anisotropy , 2008, Nature materials.

[2]  Payam Akhyari,et al.  Mechanical Stretch Regimen Enhances the Formation of Bioengineered Autologous Cardiac Muscle Grafts , 2002, Circulation.

[3]  L. Griffith,et al.  Capturing complex 3D tissue physiology in vitro , 2006, Nature Reviews Molecular Cell Biology.

[4]  Smadar Cohen,et al.  Optimization of cardiac cell seeding and distribution in 3D porous alginate scaffolds. , 2002, Biotechnology and bioengineering.

[5]  Tal Dvir,et al.  A novel perfusion bioreactor providing a homogenous milieu for tissue regeneration. , 2006, Tissue engineering.

[6]  B. Schumacher,et al.  Images in cardiovascular medicine. Fistulous communication between coronary sinus and left atrium. , 2002, Circulation.

[7]  Robert Langer,et al.  Advances in tissue engineering. , 2004, Current topics in developmental biology.

[8]  Smadar Cohen,et al.  “Designer” scaffolds for tissue engineering and regeneration , 2005 .

[9]  J. Leor,et al.  Stimulation of 42/44 kDa mitogen-activated protein kinases by arginine vasopressin in rat cardiomyocytes. , 1998, Biochimica et biophysica acta.

[10]  Smadar Cohen,et al.  Perfusion cell seeding and cultivation induce the assembly of thick and functional hepatocellular tissue-like construct. , 2009, Tissue engineering. Part A.

[11]  W. Zimmermann,et al.  Tissue Engineering of a Differentiated Cardiac Muscle Construct , 2002, Circulation research.

[12]  C. Willey,et al.  c-Raf/MEK/ERK Pathway Controls Protein Kinase C-mediated p70S6K Activation in Adult Cardiac Muscle Cells* , 2002, The Journal of Biological Chemistry.

[13]  H. Eppenberger,et al.  N-Cadherin: Structure, Function and Importance in the Formation of New Intercalated Disc-Like Cell Contacts in Cardiomyocytes , 2000, Heart Failure Reviews.

[14]  L. Shapiro,et al.  Novel alginate sponges for cell culture and transplantation. , 1997, Biomaterials.

[15]  Y. Takeishi,et al.  Activation of distinct signal transduction pathways in hypertrophied hearts by pressure and volume overload , 2004, Basic Research in Cardiology.

[16]  Elliot L Elson,et al.  The biochemical response of the heart to hypertension and exercise. , 2004, Trends in biochemical sciences.

[17]  H. Krum,et al.  p38 mitogen-activated protein kinase inhibition improves cardiac function and attenuates left ventricular remodeling following myocardial infarction in the rat. , 2004, Journal of the American College of Cardiology.

[18]  M. Moretti,et al.  Insulin-like growth factor-I and slow, bi-directional perfusion enhance the formation of tissue-engineered cardiac grafts. , 2009, Tissue engineering. Part A.

[19]  J. Leor,et al.  Bioengineered Cardiac Grafts: A New Approach to Repair the Infarcted Myocardium? , 2000, Circulation.

[20]  Milica Radisic,et al.  Functional assembly of engineered myocardium by electrical stimulation of cardiac myocytes cultured on scaffolds , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[21]  Jie Ren,et al.  Role of p38alpha MAPK in cardiac apoptosis and remodeling after myocardial infarction. , 2005, Journal of molecular and cellular cardiology.

[22]  M. Radisic,et al.  Pulsatile perfusion bioreactor for cardiac tissue engineering , 2008, Biotechnology progress.

[23]  G. Schmid-Schönbein,et al.  Mechanisms for regulation of fluid shear stress response in circulating leukocytes. , 2000, Circulation research.

[24]  S. Solomon,et al.  Angiotensin II receptor blockade and ventricular remodelling , 2005, Journal of the renin-angiotensin-aldosterone system : JRAAS.

[25]  T. Yue,et al.  Inhibition of p38 mitogen-activated protein kinase decreases cardiomyocyte apoptosis and improves cardiac function after myocardial ischemia and reperfusion. , 1999, Circulation.

[26]  S. Kudoh,et al.  Mechanical Stretch Induces Hypertrophic Responses in Cardiac Myocytes of Angiotensin II Type 1a Receptor Knockout Mice* , 1998, The Journal of Biological Chemistry.

[27]  J. Leor,et al.  Autospecies and post-myocardial infarction sera enhance the viability, proliferation, and maturation of 3D cardiac cell culture. , 2006, Tissue engineering.

[28]  P. Doevendans,et al.  Molecular determinants of myocardial hypertrophy and failure: alternative pathways for beneficial and maladaptive hypertrophy. , 2003, European heart journal.

[29]  J. Leor,et al.  Myocardial repair: from salvage to tissue reconstruction , 2008, Expert review of cardiovascular therapy.

[30]  S. Kudoh,et al.  Mechanical stress activates angiotensin II type 1 receptor without the involvement of angiotensin II , 2004, Nature Cell Biology.

[31]  P. Lévy,et al.  Angiotensin II induces tyrosine nitration and activation of ERK1/2 in vascular smooth muscle cells , 2005, FEBS letters.

[32]  Smadar Cohen,et al.  Cardiac Tissue Engineering, Ex-Vivo: Design Principles in Biomaterials and Bioreactors , 2003, Heart Failure Reviews.

[33]  Thomas Eschenhagen,et al.  Engineered heart tissue for regeneration of diseased hearts. , 2004, Biomaterials.

[34]  Y. Pinto,et al.  Overexpression of the human angiotensin II type 1 receptor in the rat heart augments load induced cardiac hypertrophy , 2001, Journal of Molecular Medicine.

[35]  Y. Granot,et al.  Stimulation of Mitogen-activated Protein Kinase and Na+/H+ Exchanger in Human Platelets , 1996, The Journal of Biological Chemistry.

[36]  Milica Radisic,et al.  Cardiac tissue engineering using perfusion bioreactor systems , 2008, Nature Protocols.

[37]  D. Yellon,et al.  Survival kinases in ischemic preconditioning and postconditioning. , 2006, Cardiovascular research.

[38]  Y. Mori,et al.  Mechanical stretch induces enhanced expression of angiotensin II receptor subtypes in neonatal rat cardiac myocytes. , 1996, Circulation research.