Cardiomyocyte PDGFR-β signaling is an essential component of the mouse cardiac response to load-induced stress
Vishnu Chintalgattu, … , Mark L. Entman, Aarif Y. Khakoo
Vishnu Chintalgattu, … , Mark L. Entman, Aarif Y. Khakoo
Published January 11, 2010
Citation Information: J Clin Invest. 2010;120(2):472-484. https://doi.org/10.1172/JCI39434.
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Research Article Cardiology

Cardiomyocyte PDGFR-β signaling is an essential component of the mouse cardiac response to load-induced stress

Abstract

PDGFR is an important target for novel anticancer therapeutics because it is overexpressed in a wide variety of malignancies. Recently, however, several anticancer drugs that inhibit PDGFR signaling have been associated with clinical heart failure. Understanding this effect of PDGFR inhibitors has been difficult because the role of PDGFR signaling in the heart remains largely unexplored. As described herein, we have found that PDGFR-β expression and activation increase dramatically in the hearts of mice exposed to load-induced cardiac stress. In mice in which Pdgfrb was knocked out in the heart in development or in adulthood, exposure to load-induced stress resulted in cardiac dysfunction and heart failure. Mechanistically, we showed that cardiomyocyte PDGFR-β signaling plays a vital role in stress-induced cardiac angiogenesis. Specifically, we demonstrated that cardiomyocyte PDGFR-β was an essential upstream regulator of the stress-induced paracrine angiogenic capacity (the angiogenic potential) of cardiomyocytes. These results demonstrate that cardiomyocyte PDGFR-β is a regulator of the compensatory cardiac response to pressure overload–induced stress. Furthermore, our findings may provide insights into the mechanism of cardiotoxicity due to anticancer PDGFR inhibitors.

Authors

Vishnu Chintalgattu, Di Ai, Robert R. Langley, Jianhu Zhang, James A. Bankson, Tiffany L. Shih, Anilkumar K. Reddy, Kevin R. Coombes, Iyad N. Daher, Shibani Pati, Shalin S. Patel, Jennifer S. Pocius, George E. Taffet, L. Maximillian Buja, Mark L. Entman, Aarif Y. Khakoo

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Figure 2

Cardiac-specific PDGFR-β–knockout mice develop ventricular dilatation and heart failure in response to pressure overload.

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Cardiac-specific PDGFR-β–knockout mice develop ventricular dilatation an...
(A) PCR of genomic DNA from tails, skeletal muscle (SM), or hearts (Hrt) from newborn cardiac-specific PDGFR-β–knockout mice (PdgfrbNkx-Cre) mice using primer pairs specific for floxed allele (upper band) or deleted allele (lower band). Results are representative of 3 independent experiments. (B) Western blot of cardiac lysates from 4-week-old Nkx2.5-Cre:Pdgfrbfl/fl mice (PdgfrbNkx-Cre) or non–Cre-expressing littermate control (Pdgfrbfl/fl) mice probed with an antibody against PDGFR-β. (C) Ratio of right/left (R/L) peak carotid velocity 24 hours after 8- to 12-week-old PdgfrbNkx-Cre or Pdgfrbfl/fl mice were exposed to TAC (n = 8 in each group). (D) Cardiac ejection fraction of Pdgfrbfl/fl mice or PdgfrbNkx-Cre mice prior to TAC (day 0) or at various time points after TAC, as measured by MRI. (E) Heart weight/body weight ratios of Pdgfrbfl/fl versus PdgfrbNkx-Cre mice prior to TAC (day 0) or 14 days after TAC. (F) Representative short-axis MRI still frame images taken at the mid-ventricular level in Pdgfrbfl/fl or PdgfrbNkx-Cre mice prior to TAC exposure (left panels) or 14 days after TAC exposure (right panels). (G) Ratio of lung weight/body weight of Pdgfrbfl/fl versus PdgfrbNkx-Cre mice prior to TAC or 14 days after TAC. P values were determined by unpaired, 2-tailed Student’s t test. Numbers inside the bars indicate the number of animals analyzed.