An essential role for Notch in neural crest during cardiovascular development and smooth muscle differentiation
Frances A. High, Maozhen Zhang, Aaron Proweller, LiLi Tu, Michael S. Parmacek, Warren S. Pear, Jonathan A. Epstein
Frances A. High, Maozhen Zhang, Aaron Proweller, LiLi Tu, Michael S. Parmacek, Warren S. Pear, Jonathan A. Epstein
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Research Article

An essential role for Notch in neural crest during cardiovascular development and smooth muscle differentiation

Abstract

The cardiac outflow tract develops as a result of a complex interplay among several cell types, including cardiac neural crest cells, endothelial cells, and cardiomyocytes. In both humans and mice, mutations in components of the Notch signaling pathway result in congenital heart disease characterized by cardiac outflow tract defects. However, the specific cell types in which Notch functions during cardiovascular development remain to be defined. In addition, in vitro studies have provided conflicting data regarding the ability of Notch to promote or inhibit smooth muscle differentiation, while the physiological role for Notch in smooth muscle formation during development remains unclear. In this study, we generated mice in which Notch signaling was specifically inactivated in derivatives of the neural crest. These mice exhibited cardiovascular anomalies, including aortic arch patterning defects, pulmonary artery stenosis, and ventricular septal defects. We show that Notch plays a critical, cell-autonomous role in the differentiation of cardiac neural crest precursors into smooth muscle cells both in vitro and in vivo, and we identify specific Notch targets in neural crest that are implicated in this process. These results provide a molecular and cellular framework for understanding the role of Notch signaling in the etiology of congenital heart disease.

Authors

Frances A. High, Maozhen Zhang, Aaron Proweller, LiLi Tu, Michael S. Parmacek, Warren S. Pear, Jonathan A. Epstein

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Figure 2

Neural crest–specific expression of DNMAML results in cardiac outflow tract defects.

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Neural crest–specific expression of DNMAML results in cardiac outflow tr...
(A and B) Lateral view of the left side of hearts removed from E17.5 control (A) and Pax3Cre/+ DNMAML (B) embryos. Compared with the control pulmonary artery, the mutant pulmonary artery and ductus arteriosus are significantly narrowed (arrowheads in A and B). (C and D) Hematoxylin and eosin stained cross-sections through the hearts of E17.5 control (C) or Pax3Cre/+ DNMAML (D) embryos demonstrate a membranous ventricular septal defect in the mutant (arrow in D). (EJ) Photographs and drawings depicting the aortic arch phenotypes in several E17.5 embryos. A control embryo (E) shows the normal branching pattern of the great vessels. (F) Pax3Cre/+ DNMAML mutant showing an abnormal arch structure similar to the human defect known as persistent fifth arch. In addition, the ductus arteriosus is absent, and there is a retroesophageal right subclavian artery. (G) Pax3Cre/+ DNMAML mutant showing a right-sided aortic arch and isolated left subclavian artery arising from the pulmonary artery (arrowhead). (H) Pax3Cre/+ DNMAML mutant with an atretic ductus arteriosus (arrow) and isolated right subclavian artery (arrowhead). (I) Wnt1-Cre DNMAML mutant showing duplication of the left common carotid artery (arrows). (J) Wnt1-Cre DNMAML mutant with an absent ductus arteriosus. The asterisk indicates ventricular septal defects that were observed upon sectioning the hearts. rv, right ventricle; lv, left ventricle; ao, aorta; da, ductus arteriosus; rsa, right subclavian artery; rca, right common carotid artery; lca, left common carotid artery; lsa, left subclavian artery. Scale bars: 200 μm.