Nonmyocyte ERK1/2 signaling contributes to load-induced cardiomyopathy in Marfan mice
Rosanne Rouf, Elena Gallo MacFarlane, Eiki Takimoto, Rahul Chaudhary, Varun Nagpal, Peter P. Rainer, Jay G. Bindman, Elizabeth E. Gerber, Djahida Bedja, Christopher Schiefer, Karen L. Miller, Guangshuo Zhu, Loretha Myers, Nuria Amat-Alarcon, Dong I. Lee, Norimichi Koitabashi, Daniel P. Judge, David A. Kass, Harry C. Dietz
Rosanne Rouf, Elena Gallo MacFarlane, Eiki Takimoto, Rahul Chaudhary, Varun Nagpal, Peter P. Rainer, Jay G. Bindman, Elizabeth E. Gerber, Djahida Bedja, Christopher Schiefer, Karen L. Miller, Guangshuo Zhu, Loretha Myers, Nuria Amat-Alarcon, Dong I. Lee, Norimichi Koitabashi, Daniel P. Judge, David A. Kass, Harry C. Dietz
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Research Article Cardiology Genetics

Nonmyocyte ERK1/2 signaling contributes to load-induced cardiomyopathy in Marfan mice

Abstract

Among children with the most severe presentation of Marfan syndrome (MFS), an inherited disorder of connective tissue caused by a deficiency of extracellular fibrillin-1, heart failure is the leading cause of death. Here, we show that, while MFS mice (Fbn1C1039G/+ mice) typically have normal cardiac function, pressure overload (PO) induces an acute and severe dilated cardiomyopathy in association with fibrosis and myocyte enlargement. Failing MFS hearts show high expression of TGF-β ligands, with increased TGF-β signaling in both nonmyocytes and myocytes; pathologic ERK activation is restricted to the nonmyocyte compartment. Informatively, TGF-β, angiotensin II type 1 receptor (AT1R), or ERK antagonism (with neutralizing antibody, losartan, or MEK inhibitor, respectively) prevents load-induced cardiac decompensation in MFS mice, despite persistent PO. In situ analyses revealed an unanticipated axis of activation in nonmyocytes, with AT1R-dependent ERK activation driving TGF-β ligand expression that culminates in both autocrine and paracrine overdrive of TGF-β signaling. The full compensation seen in wild-type mice exposed to mild PO correlates with enhanced deposition of extracellular fibrillin-1. Taken together, these data suggest that fibrillin-1 contributes to cardiac reserve in the face of hemodynamic stress, critically implicate nonmyocytes in disease pathogenesis, and validate ERK as a therapeutic target in MFS-related cardiac decompensation.

Authors

Rosanne Rouf, Elena Gallo MacFarlane, Eiki Takimoto, Rahul Chaudhary, Varun Nagpal, Peter P. Rainer, Jay G. Bindman, Elizabeth E. Gerber, Djahida Bedja, Christopher Schiefer, Karen L. Miller, Guangshuo Zhu, Loretha Myers, Nuria Amat-Alarcon, Dong I. Lee, Norimichi Koitabashi, Daniel P. Judge, David A. Kass, Harry C. Dietz

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Figure 5

Functional improvement of mechanically loaded Fbn1C1039G/+ hearts correlates with reduced fibrosis.

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Functional improvement of mechanically loaded Fbn1C1039G/+ hearts correl...
(A) Representative Masson’s trichrome–stained heart sections of Fbn1C1039G/+ sham vs. TAC groups, with and without treatment, showing fibrosis stained in blue. Scale bars: 750 μm (top); 100 μm (bottom). (B) Quantification of fibrosis, quantified by total number of blue pixels normalized to whole tissue area and then to Fbn1+/+:sham data. n = 4–7 per group. (C) mRNA expression of TGF-β–responsive fibrogenic genes, normalized to Gapdh and then to Fbn1+/+:sham data, assessed by real-time RT-PCR. Col1a1, collagen type 1 a1; Spp1, osteopontin. n = 4–6 per group. *P < 0.05, **P < 0.01, ***P < 0.001, 1-way ANOVA, Tukey’s correction. In box-and-whisker plots, the lower and upper margins of each box define the 25th and 75th percentiles, respectively; the internal line defines the median, and the whiskers define the range. Values outside 1.5 times the interquartile distance are shown.