Mediating ERK1/2 signaling rescues congenital heart defects in a mouse model of Noonan syndrome
Tomoki Nakamura, … , Gerald W. Dorn II, Jeffrey Robbins
Tomoki Nakamura, … , Gerald W. Dorn II, Jeffrey Robbins
Published August 1, 2007
Citation Information: J Clin Invest. 2007;117(8):2123-2132. https://doi.org/10.1172/JCI30756.
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Research Article Cardiology

Mediating ERK1/2 signaling rescues congenital heart defects in a mouse model of Noonan syndrome

Abstract

Noonan syndrome (NS) is an autosomal dominant disorder characterized by a wide spectrum of defects, which most frequently include proportionate short stature, craniofacial anomalies, and congenital heart disease (CHD). NS is the most common nonchromosomal cause of CHD, and 80%–90% of NS patients have cardiac involvement. Mutations within the protein tyrosine phosphatase Src homology region 2, phosphatase 2 (SHP2) are responsible for approximately 50% of the cases of NS with cardiac involvement. To understand the developmental stage– and cell type–specific consequences of the NS SHP2 gain-of-function mutation, Q79R, we generated transgenic mice in which the mutated protein was expressed during gestation or following birth in cardiomyocytes. Q79R SHP2 embryonic hearts showed altered cardiomyocyte cell cycling, ventricular noncompaction, and ventricular septal defects, while, in the postnatal cardiomyocyte, Q79R SHP2 expression was completely benign. Fetal expression of Q79R led to the specific activation of the ERK1/2 pathway, and breeding of the Q79R transgenics into ERK1/2-null backgrounds confirmed the pathway’s necessity and sufficiency in mediating mutant SHP2’s effects. Our data establish the developmental stage–specific effects of Q79R cardiac expression in NS; show that ablation of subsequent ERK1/2 activation prevents the development of cardiac abnormalities; and suggest that ERK1/2 modulation could have important implications for developing therapeutic strategies in CHD.

Authors

Tomoki Nakamura, Melissa Colbert, Maike Krenz, Jeffery D. Molkentin, Harvey S. Hahn, Gerald W. Dorn II, Jeffrey Robbins

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Figure 2

Histological findings.

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Histological findings. (A) Four-chamber view of the hearts at E16.5 (ori...
(A) Four-chamber view of the hearts at E16.5 (original magnification, ×4). Ventricular noncompaction, VSDs (arrowheads), and abnormal anatomy of the interventricular groove (*) are prominent in the β-MHC Q79R hearts, while the α-MHC WT and Q79R and β-MHC WT hearts appear to be normal. (B) Longitudinal ventricular sections at 3 months after birth, stained with H&E (original magnification, ×4). Each image shows the right-ventricular free wall on the left and the ventricular septum on the right. Despite SHP2 overexpression in the postnatal cardiomyocytes, no abnormalities were seen in the α-MHC WT and Q79R hearts. In the β-MHC Q79R hearts, the ventricular noncompaction observed in the embryonic stage continued to present postnatally. (C) Masson trichrome staining of the right-ventricular free walls from the rectangular area indicated in B (original magnification, ×10). For each panel at least 5 hearts were analyzed. For all panels, orientation is apical on the right and basal on the left. (D) Representative photograph of an end-stage failing heart in the β-MHC Q79R mouse (6 weeks old; original magnification, ×2.8). Compared with those of the Ntg littermates, β-MHC Q79R hearts showed both atrial and ventricular dilatation and abnormal interventricular groove anatomy (*). Left-ventricular hypofunction caused regurgitation toward the left atrium, resulting in massive thrombi. (E and F) Analyses of heart weight to body weight (HW/BW) ratio and lung weight to body weight (LW/BW) ratio in age- and sex-matched mice (3 months after birth, n = 8 [4 male, 4 female]). HW/BW and LW/BW ratios were increased in β-MHC Q79R mice. *P < 0.005.