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(Circulation Research. 2005;96:526.)
© 2005 American Heart Association, Inc.

Molecular Medicine

Coronary Artery and Orifice Development Is Associated With Proper Timing of Epicardial Outgrowth and Correlated Fas Ligand Associated Apoptosis Patterns

Ismail Eralp, Heleen Lie-Venema, Marco C. DeRuiter, Nynke M.S van den Akker, Ad J.J.C. Bogers, Monica M.T. Mentink, Robert E. Poelmann, Adriana C. Gittenberger-de Groot

From the Department of Anatomy and Embryology (I.E., H.L.-V., M.C.D.R., N.M.S.v.d.A., M.M.T.M., R.E.P., A.C.G.-d.G.), Leiden University Medical Center, Leiden, The Netherlands; and the Department of Cardio-Thoracic Surgery (I.E., A.J.J.C.B), Erasmus Medical Center, Rotterdam, The Netherlands.

Correspondence to Prof Dr A.C. Gittenberger-de Groot, Department of Anatomy and Embryology, Leiden University Medical Center, PO Box 9602, 2300 RC Leiden, The Netherlands. E-mail acgitten{at}lumc.nl

The proepicardial organ provides differentiated cell types to the myocardial wall and facilitates coronary development. Ingrowth of the coronary arteries into the aorta has recently been linked to apoptosis. This study was set up to examine the effect of an inhibition of epicardial outgrowth on apoptotic patterning and coronary development. Epicardial outgrowth was blocked at HH15–17 in quail embryos, which survived until HH25–35 (n=33). Embryos with complete inhibition of outgrowth did not survive after HH29. These embryos presented with thin compact myocardium, devoid of vessels. In embryos with delayed epicardial outgrowth the phenotype was less severe, and surviving embryos were studied up to HH35. In these embryos, myocardial vascularization was poor and apoptosis in the peritruncal region at HH30 was diminished. Embryos at HH35 displayed an abnormal coronary network and absent coronary orifices. In a further set of experiments (n=10), outgrowth was inhibited in chicken embryos at HH15, followed by transplantation of a quail proepicardial organ into the pericardial cavity to rescue cardiac phenotype. These chimeras were studied at HH29 and HH35. Myocardial development was restored; however, in 3 of 4 embryos (HH35), the coronary orifices were absent. Examination of double stainings of quail-chicken chimeras revealed that EPDCs produce Fas ligand as an apoptotic inductor at sites of coronary ingrowth. In the absence of proper timing of epicardial outgrowth, myocardial development and vascularization are disturbed. Also apoptosis in the peritruncal region is diminished. During later development, this leads to defective or absent connections of the coronary system to the systemic circulation.

Key Words: coronary arteries • myocardium • epicardium • apoptosis • development

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