Cardiac pericytes mediate the remodeling response to myocardial infarction
Pearl Quijada, Shuin Park, Peng Zhao, Kamal S.S. Kolluri, David Wong, Kevin D. Shih, Kai Fang, Arash Pezhouman, Lingjun Wang, Ali Daraei, Matthew D. Tran, Elle M. Rathbun, Kimberly N. Burgos Villar, Maria L. Garcia-Hernandez, Thanh T.D. Pham, Charles J. Lowenstein, M. Luisa Iruela-Arispe, S. Thomas Carmichael, Eric M. Small, Reza Ardehali
Pearl Quijada, Shuin Park, Peng Zhao, Kamal S.S. Kolluri, David Wong, Kevin D. Shih, Kai Fang, Arash Pezhouman, Lingjun Wang, Ali Daraei, Matthew D. Tran, Elle M. Rathbun, Kimberly N. Burgos Villar, Maria L. Garcia-Hernandez, Thanh T.D. Pham, Charles J. Lowenstein, M. Luisa Iruela-Arispe, S. Thomas Carmichael, Eric M. Small, Reza Ardehali
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Research Article Cardiology Vascular biology

Cardiac pericytes mediate the remodeling response to myocardial infarction

Abstract

Despite the prevalence of pericytes in the microvasculature of the heart, their role during ischemia-induced remodeling remains unclear. We used multiple lineage-tracing mouse models and found that pericytes migrated to the injury site and expressed profibrotic genes, coinciding with increased vessel leakage after myocardial infarction (MI). Single-cell RNA-Seq of cardiac pericytes at various time points after MI revealed the temporally regulated induction of genes related to vascular permeability, extracellular matrix production, basement membrane degradation, and TGF-β signaling. Deleting TGF-β receptor 1 in chondroitin sulfate proteoglycan 4–expressing (Cspg4-expressing) cells reduced fibrosis following MI, leading to a transient improvement in the cardiac ejection fraction. Furthermore, genetic ablation of Cspg4-expressing cells resulted in excessive vascular permeability, a decline in cardiac function, and increased mortality in the second week after MI. These data reveal an essential role for cardiac pericytes in the control of vascular homeostasis and the fibrotic response after acute ischemic injury, information that will help guide the development of novel strategies to preserve vascular integrity and attenuate pathological cardiac remodeling.

Authors

Pearl Quijada, Shuin Park, Peng Zhao, Kamal S.S. Kolluri, David Wong, Kevin D. Shih, Kai Fang, Arash Pezhouman, Lingjun Wang, Ali Daraei, Matthew D. Tran, Elle M. Rathbun, Kimberly N. Burgos Villar, Maria L. Garcia-Hernandez, Thanh T.D. Pham, Charles J. Lowenstein, M. Luisa Iruela-Arispe, S. Thomas Carmichael, Eric M. Small, Reza Ardehali

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Figure 3

Cardiac pericytes dissociate from the microvasculature following MI.

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Cardiac pericytes dissociate from the microvasculature following MI. (A)...
(A) Using IHC, the evaluation of Cspg4-lineage cells (red) was relative to ECs identified by the nuclear protein marker ERG (green) 7 days after infarction. Scale bars: 20 μm. (B) Analysis of pericyte-EC interactions using Amnis ImageStream Technology following sham surgery or 7 days of MI. Pericytes are labeled in orange, ECs are labeled with CD31 antibody (purple), and nucleated cells were visualized by staining with DRAQ5 (red) and overlayed with bright-field images. Scale bars: 10 μm. Images in A and B are representative of 3 sham and 4 7dMI experiments. (C) Pericyte-EC interactions were reduced in Cspg4-lineage mice following 7 days of MI. n = three sham and n = four 7dMI hearts. An unpaired, 2-tailed Student’s t test was performed to compare sham and 7dMI hearts. (D) Sham and (E) 7dMI Cspg4CreER/+ R26tdT/+ mice were subjected to an intramyocardial injection of 2 μL TAM immediately followed by surgery. (D) tdTomato+ pericytes were observed near the injection site in the sham-operated animals, whereas (E) tdTomato+ pericytes were discovered proximal and distal to the injection site following 7 days of MI. Yellow arrows indicate tdTomato+ cells. Scale bars: 200 μm. Images in D and E are representative of 3 sham and MI experiments each. (F) Visualization of pericytes relative to intact microvasculature in MI-injured hearts around the BZ regions. Isolectin (intact vasculature) is shown in green. Scale bars: 20 μm. (G) Percentage of pericytes in regions proximal (0–45 μm) or distal to the BZ area (>45 μm) following a time course of MI. n = 3 each for sham, 2dMI, 4dMI, 7dMI, and 14dMI hearts. Data were analyzed by 1-way ANOVA with Tukey’s multiple-comparison test. (H) Pericyte volume (μm3) was increased at post-MI days 7 and 14. n = 3 sham, 2dMI, 4dMI, 7dMI and 14dMI hearts. Data were analyzed by 1-way ANOVA with Tukey’s multiple-comparison test. (I) Visualization of pericytes relative to intact and leaky microvasculature in healthy (sham-treated) or MI-injured hearts around the BZ regions. Isolectin (intact vasculature, green) and dextran (leaky vasculature, white) was administered to mice on the day of isolation. Scale bars: 20 μm. Data in F and I are representative of 3 sham, 2dMI, 4dMI, 7dMI, and 14dMI experiments. *P < 0.05 and **P < 0.01.