IL-13 promotes functional recovery after myocardial infarction via direct signaling to macrophages
Santiago Alvarez-Argote, Samantha J. Paddock, Michael A. Flinn, Caelan W. Moreno, Makenna C. Knas, Victor A. Almeida, Sydney L. Buday, Amirala Bakhshian Nik, Michaela Patterson, Yi-Guang Chen, Chien-Wei Lin, Caitlin C. O’Meara
Santiago Alvarez-Argote, Samantha J. Paddock, Michael A. Flinn, Caelan W. Moreno, Makenna C. Knas, Victor A. Almeida, Sydney L. Buday, Amirala Bakhshian Nik, Michaela Patterson, Yi-Guang Chen, Chien-Wei Lin, Caitlin C. O’Meara
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Research Article Cardiology

IL-13 promotes functional recovery after myocardial infarction via direct signaling to macrophages

Abstract

There is great interest in identifying signaling pathways that promote cardiac repair after myocardial infarction (MI). Prior studies suggest a beneficial role for IL-13 signaling in neonatal heart regeneration; however, the cell types mediating cardiac regeneration and the extent of IL-13 signaling in the adult heart after injury are unknown. We identified an abundant source of IL-13 and the related cytokine, IL-4, in neonatal cardiac type 2 innate lymphoid cells, but this phenomenon declined precipitously in adult hearts. Moreover, IL-13 receptor deletion in macrophages impaired cardiac function and resulted in larger scars early after neonatal MI. By using a combination of recombinant IL-13 administration and cell-specific IL-13 receptor genetic deletion models, we found that IL-13 signaling specifically to macrophages mediated cardiac functional recovery after MI in adult mice. Single transcriptomics revealed a subpopulation of cardiac macrophages in response to IL-13 administration. These IL-13–induced macrophages were highly efferocytotic and were identified by high IL-1R2 expression. Collectively, we elucidated a strongly proreparative role for IL-13 signaling directly to macrophages following cardiac injury. While this pathway is active in proregenerative neonatal stages, reactivation of macrophage IL-13 signaling is required to promote cardiac functional recovery in adults.

Authors

Santiago Alvarez-Argote, Samantha J. Paddock, Michael A. Flinn, Caelan W. Moreno, Makenna C. Knas, Victor A. Almeida, Sydney L. Buday, Amirala Bakhshian Nik, Michaela Patterson, Yi-Guang Chen, Chien-Wei Lin, Caitlin C. O’Meara

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Figure 6

rIL-13 induces a unique macrophage cluster at 4 dpi.

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rIL-13 induces a unique macrophage cluster at 4 dpi. (A) Uniform Manifol...
(A) Uniform Manifold Approximation and Projection (UMAP) plot of live leukocytes isolated from mouse hearts at 4 and 7 dpi after PBS or rIL-13 daily administration. Four samples were given: PBS at 4 dpi, PBS at 7 dpi, rIL-13 at 4 dpi, rIL-13 at 7 dpi. n = 2 or 3 mice per sample. (B) Violin plots showing expression of unique markers that defined the identity of each of the 7 clusters identified in A. (C) Feature plots showing expression of macrophage specific markers in clusters 3 and 7 and unique neutrophils markers in cluster 4. (D) Clusters 3 and 7 from A were reclustered, resulting in 5 unique clusters (clusters 0–4), among which 0, 1, and 3 correspond to macrophages and 2 and 4 are DCs. (E and F) UMAP plots and pie charts showing the contribution of each sample to each macrophage cluster. Mac3 is 98% derived from rIL-13 4 dpi. (G) Heatmap showing top 50 DEG in Mac1 and Mac3 at 4 dpi only. Top colors represent cluster ID. Color scale bar represents directionality of expression (log FC threshold 0.7. Adjusted P < 0.1 × 10–17). (H) Ingenuity pathway analysis identified top upregulated canonical pathways in macrophage clusters 1 and 3. Color scale bar represents directionality of expression. Circle size represents statistical significance. (I) Violin plots showing expression of IFN response elements in macrophage clusters 0, 1, and 3. (J) Violin plots showing expression of phagocytic associated markers and extracellular matrix remodeling factors in macrophage clusters 0, 1, and 3.