Integration of a Notch-dependent mesenchymal gene program and Bmp2-driven cell invasiveness regulates murine cardiac valve formation
Luis Luna-Zurita, … , José María Pérez-Pomares, José Luis de la Pompa
Luis Luna-Zurita, … , José María Pérez-Pomares, José Luis de la Pompa
Published September 20, 2010
Citation Information: J Clin Invest. 2010;120(10):3493-3507. https://doi.org/10.1172/JCI42666.
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Integration of a Notch-dependent mesenchymal gene program and Bmp2-driven cell invasiveness regulates murine cardiac valve formation

Abstract

Cardiac valve formation is crucial for embryonic and adult heart function. Valve malformations constitute the most common congenital cardiac defect, but little is known about the molecular mechanisms regulating valve formation and homeostasis. Here, we show that endocardial Notch1 and myocardial Bmp2 signal integration establish a valve-forming field between 2 chamber developmental domains. Patterning occurs through the activation of endocardial epithelial-to-mesenchymal transition (EMT) exclusively in prospective valve territories. Mice with constitutive endocardial Notch1 activity ectopically express Hey1 and Heyl. They also display an activated mesenchymal gene program in ventricles and a partial (noninvasive) EMT in vitro that becomes invasive upon BMP2 treatment. Snail1, TGF-β2, or Notch1 inhibition reduces BMP2-induced ventricular transformation and invasion, whereas BMP2 treatment inhibits endothelial Gsk3β, stabilizing Snail1 and promoting invasiveness. Integration of Notch and Bmp2 signals is consistent with Notch1 signaling being attenuated after myocardial Bmp2 deletion. Notch1 activation in myocardium extends Hey1 expression to nonchamber myocardium, represses Bmp2, and impairs EMT. In contrast, Notch deletion abrogates endocardial Hey gene transcription and extends Bmp2 expression to the ventricular endocardium. This embryonic Notch1-Bmp2-Snail1 relationship may be relevant in adult valve disease, in which decreased NOTCH signaling causes valve mesenchyme cell formation, fibrosis, and calcification.

Authors

Luis Luna-Zurita, Belén Prados, Joaquim Grego-Bessa, Guillermo Luxán, Gonzalo del Monte, Alberto Benguría, Ralf H. Adams, José María Pérez-Pomares, José Luis de la Pompa

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Figure 7

A model for concerted Notch1 and Bmp2 activities in CVF.

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A model for concerted Notch1 and Bmp2 activities in CVF. Left, schematic...
Left, schematic representations of the E9.5 heart. Right, schematics showing the different cardiac regions and developmental processes occurring within them. Green, ventricular myocardium; yellow, AVC myocardium; blue, atrial myocardium. ENCs expressing N1ICD are labeled red. Pink, invasive mesenchyme cells. Yellow arrows, myocardial signals; red arrows, endocardial signals. (A) WT embryo. AVC myocardial Bmp2 is required for Tgfb2, Notch1, Snail1, Snail2, and Twist1 expression. Endocardial Notch1 is required for Tgfb2 expression, activates Snail1 and Snail2, and represses Bmp2 in endocardium via Hey proteins. Bmp2 and Notch1 signals converge in AVC endocardium to promote complete EMT. (B) Tie2-Cre;N1ICD embryo. Ectopic N1ICD expression in endocardium (left) activates mesenchymal genes, promotes noninvasive EMT in ventricles but not in atria, and leads to loss of chamber identity. (C) cTnT-Cre;N1ICD and Nkx2.5-Cre;N1ICD embryos. Ectopic N1ICD expression in myocardium leads to ectopic Hey1 expression and Bmp2 repression. Myocardial AVC identity is lost, and EMT is severely affected. (D) Molecular pathways downstream of Notch during cardiac EMT. LOF and GOF data (this report and refs. 19, 42, and 43) indicate that Notch represses Bmp2 via Hey target activation. Endocardial Notch1 activates a mesenchyme gene program. The double-headed arrow linking Tgfb2 and Snail1 indicates the interdependence of both genes. Myocardial Bmp2 converges with endocardial Notch1 signaling to promote mesenchyme gene activation and EMT in the AVC. Convergence of Notch1 and Bmp2 is reflected in Notch activation of Snail1 expression and Bmp2-mediated Snail1 nuclear stabilization, via Gsk3β inhibition (*).