Myocardin regulates BMP10 expression and is required for heart development
Jianhe Huang, John Elicker, Nina Bowens, Xi Liu, Lan Cheng, Thomas P. Cappola, Xiaohong Zhu, Michael S. Parmacek
Jianhe Huang, John Elicker, Nina Bowens, Xi Liu, Lan Cheng, Thomas P. Cappola, Xiaohong Zhu, Michael S. Parmacek
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Myocardin regulates BMP10 expression and is required for heart development

Abstract

Myocardin is a muscle lineage–restricted transcriptional coactivator that has been shown to transduce extracellular signals to the nucleus required for SMC differentiation. We now report the discovery of a myocardin/BMP10 (where BMP10 indicates bone morphogenetic protein 10) signaling pathway required for cardiac growth, chamber maturation, and embryonic survival. Myocardin-null (Myocd) embryos and embryos harboring a cardiomyocyte-restricted mutation in the Myocd gene exhibited myocardial hypoplasia, defective atrial and ventricular chamber maturation, heart failure, and embryonic lethality. Cardiac hypoplasia was caused by decreased cardiomyocyte proliferation accompanied by a dramatic increase in programmed cell death. Defective chamber maturation and the block in cardiomyocyte proliferation were caused in part by a block in BMP10 signaling. Myocardin transactivated the Bmp10 gene via binding of a serum response factor–myocardin protein complex to a nonconsensus CArG element in the Bmp10 promoter. Expression of p57kip2, a BMP10-regulated cyclin-dependent kinase inhibitor, was induced in Myocd–/– hearts, while BMP10-activated cardiogenic transcription factors, including NKX2.5 and MEF2c, were repressed. Remarkably, when embryonic Myocd–/– hearts were cultured ex vivo in BMP10-conditioned medium, the defects in cardiomyocyte proliferation and p57kip2 expression were rescued. Taken together, these data identify a heretofore undescribed myocardin/BMP10 signaling pathway that regulates cardiomyocyte proliferation and apoptosis in the embryonic heart.

Authors

Jianhe Huang, John Elicker, Nina Bowens, Xi Liu, Lan Cheng, Thomas P. Cappola, Xiaohong Zhu, Michael S. Parmacek

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Figure 4

Nkx2-5Cre+/MyocdF/F mutant embryos develop hypoplastic hearts attributable to a block in cell proliferation and increased apoptosis.

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Nkx2-5Cre+/MyocdF/F mutant embryos develop hypoplastic hearts attributa...
(A and B) E13.5 Nkx2-5Cre+/MyocdF/F mutant embryo (B) exhibits generalized edema and pericardial effusions (arrowhead) compared with MyocdF/F control embryo (A). (C and D) E10.5 control Nkx2-5Cre+/MyocdF/+/Rosa26 (C) and Nkx2-5Cre+MyocdF/F/Rosa 26 embryos (D) demonstrating intense blue staining (LacZ) throughout the myocardium; scale bars: 100 μm. (E and F) In situ hybridization analyses demonstrating myocardin mRNA (pink signal) throughout control hearts (E) and background levels in mutant hearts (F). Comparable myocardin is observed in the trachea and esophagus (arrowheads). Original magnification, ×40. (G and H) E12.5 MyocdF/F control (G) and Nkx2-5Cre+/MyocdF/F mutant (H) embryos demonstrating nuclear expression of myocardin (dark brown stain) in control hearts (G) and attenuated expression in mutant hearts. Inset panel shows low-power magnification of heart and surrounding tissues. Original magnification, ×400; ×40 (inset). (IL) E13.5 MyocdF/F control (I and K) and Nkx2-5Cre+/MyocdF/F mutant (J and L) embryos demonstrating thinning of the compact zone and trabecular myocardium and VSD (arrow) in the mutant hearts. Original magnification, ×40 (I and J); ×200 (K and L). (MO) E13.5 control (M) and conditional mutant (N) embryos immunostained for BrdU (orange) and MF20 (green) expression. Data expressed as relative number of BrdU-expressing cardiomyocytes in the mutant heart compared with the WT heart ± SEM (P < 0.01, control versus mutant). Original magnification, ×400. (PR) Apoptosis quantified in E12.5 control (P) and Nkx2-5Cre+/MyocdF/F (Q) hearts by TUNEL (green stain). Data are expressed as fold induction in TUNEL-positive cardiomyocytes per high power field in mutant compared with control hearts ± SEM (P < 0.01). Original magnification, ×200.