Cardiac myofibroblast engulfment of dead cells facilitates recovery after myocardial infarction
Michio Nakaya, … , Shigekazu Nagata, Hitoshi Kurose
Michio Nakaya, … , Shigekazu Nagata, Hitoshi Kurose
Published December 5, 2016
Citation Information: J Clin Invest. 2017;127(1):383-401. https://doi.org/10.1172/JCI83822.
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Research Article Cardiology Inflammation

Cardiac myofibroblast engulfment of dead cells facilitates recovery after myocardial infarction

Abstract

Myocardial infarction (MI) results in the generation of dead cells in the infarcted area. These cells are swiftly removed by phagocytes to minimize inflammation and limit expansion of the damaged area. However, the types of cells and molecules responsible for the engulfment of dead cells in the infarcted area remain largely unknown. In this study, we demonstrated that cardiac myofibroblasts, which execute tissue fibrosis by producing extracellular matrix proteins, efficiently engulf dead cells. Furthermore, we identified a population of cardiac myofibroblasts that appears in the heart after MI in humans and mice. We found that these cardiac myofibroblasts secrete milk fat globule-epidermal growth factor 8 (MFG-E8), which promotes apoptotic engulfment, and determined that serum response factor is important for MFG-E8 production in myofibroblasts. Following MFG-E8–mediated engulfment of apoptotic cells, myofibroblasts acquired antiinflammatory properties. MFG-E8 deficiency in mice led to the accumulation of unengulfed dead cells after MI, resulting in exacerbated inflammatory responses and a substantial decrease in survival. Moreover, MFG-E8 administration into infarcted hearts restored cardiac function and morphology. MFG-E8–producing myofibroblasts mainly originated from resident cardiac fibroblasts and cells that underwent endothelial-mesenchymal transition in the heart. Together, our results reveal previously unrecognized roles of myofibroblasts in regulating apoptotic engulfment and a fundamental importance of these cells in recovery from MI.

Authors

Michio Nakaya, Kenji Watari, Mitsuru Tajima, Takeo Nakaya, Shoichi Matsuda, Hiroki Ohara, Hiroaki Nishihara, Hiroshi Yamaguchi, Akiko Hashimoto, Mitsuho Nishida, Akiomi Nagasaka, Yuma Horii, Hiroki Ono, Gentaro Iribe, Ryuji Inoue, Makoto Tsuda, Kazuhide Inoue, Akira Tanaka, Masahiko Kuroda, Shigekazu Nagata, Hitoshi Kurose

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Figure 9

MFG-E8 administration after MI improves cardiac function in vivo.

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MFG-E8 administration after MI improves cardiac function in vivo. (A) Sc...
(A) Schematic representation of MFG-E8 intramyocardial injection. (B) TUNEL-positive nuclei in border zone of PBS- or MFG-E8–administered mice (3.2 μg) (sham, n = 5; MI, n = 7) 3 days after MI. (C) MFG-E8 intramyocardial injection (1.6 or 3.2 μg) decreased expression of the upregulated inflammatory genes at the infarct (Inf), not remote (Rem), areas of hearts 3 days after MI (n = 4 each). (D) Temporal changes in echocardiographic parameters (LV end-diastolic internal diameter [LVIDd], LV end-systolic internal diameter [LVIDs], interventricular-septal thickness at end-diastole [IVSTd], ejection fraction, and fractional shortening) of PBS-treated (sham, n = 7, black-dotted lines; MI, n = 10, black lines) or MFG-E8–treated mice (sham, n = 7, red-dotted lines; MI; n = 7, red lines) 2, 6, 8, and 10 weeks after MI. (E) Hemodynamic parameters (dP/dtmax, -dP/dtmin, and Tau) of PBS-treated (sham, n = 3; MI, n = 7) or MFG-E8–treated mice (sham, n = 5; MI, n = 7) 10 weeks after MI. (F) Heart weight to body weight ratio of PBS-treated (sham, n = 7; MI, n = 10) or MFG-E8–treated mice (sham, n = 7; MI, n = 9) 10 weeks after MI. (G) Representative Masson’s trichrome–stained heart sections of PBS-administered (n = 6) or MFG-E8–administered mice (n = 5) 10 weeks after MI. Scale bars: 1 mm. Error bars represent the mean ± SEM. *P < 0.05; **P < 0.01; ***P < 0.001, 1-way ANOVA followed by Newman-Keuls analysis.