Macrophage-mediated IL-6 signaling drives ryanodine receptor–2 calcium leak in postoperative atrial fibrillation
Joshua A. Keefe, … , Dobromir Dobrev, Xander H.T. Wehrens
Joshua A. Keefe, … , Dobromir Dobrev, Xander H.T. Wehrens
Published March 6, 2025
Citation Information: J Clin Invest. 2025;135(9):e187711. https://doi.org/10.1172/JCI187711.
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Research Article Cardiology Immunology

Macrophage-mediated IL-6 signaling drives ryanodine receptor–2 calcium leak in postoperative atrial fibrillation

Abstract

Postoperative atrial fibrillation (poAF) is AF occurring days after surgery, with a prevalence of 33% among patients undergoing open-heart surgery. The degree of postoperative inflammation correlates with poAF risk, but less is known about the cellular and molecular mechanisms driving postoperative atrial arrhythmogenesis. We performed single-cell RNA-seq comparing atrial nonmyocytes from mice with and without poAF, which revealed infiltrating CCR2+ macrophages to be the most altered cell type. Pseudotime trajectory analyses identified Il-6 as a gene of interest driving in macrophages, which we confirmed in pericardial fluid collected from human patients after cardiac surgery. Indeed, macrophage depletion and macrophage-specific Il6ra conditional knockout (cKO) prevented poAF in mice. Downstream STAT3 inhibition with TTI-101 and cardiomyocyte-specific Stat3 cKO rescued poAF, indicating a proarrhythmogenic role of STAT3 in poAF development. Confocal imaging in isolated atrial cardiomyocytes (ACMs) uncovered what we believe to be a novel link between STAT3 and CaMKII-mediated ryanodine receptor–2 (RyR2)-Ser(S)2814 phosphorylation. Indeed, nonphosphorylatable RyR2S2814A mice were protected from poAF, and CaMKII inhibition prevented arrhythmogenic Ca2+ mishandling in ACMs from mice with poAF. Altogether, we provide multiomic, biochemical, and functional evidence from mice and humans that IL-6-STAT3-CaMKII signaling driven by infiltrating atrial macrophages is a pivotal driver of poAF, which portends therapeutic utility for poAF prevention.

Authors

Joshua A. Keefe, Yuriana Aguilar-Sanchez, J. Alberto Navarro-Garcia, Isabelle Ong, Luge Li, Amelie Paasche, Issam Abu-Taha, Marcel A. Tekook, Florian Bruns, Shuai Zhao, Markus Kamler, Ying H. Shen, Mihail G. Chelu, Na Li, Dobromir Dobrev, Xander H.T. Wehrens

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Figure 1

Single-cell landscape of poAF.

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Single-cell landscape of poAF. (A) UMAP plots and (B) cell distributions...
(A) UMAP plots and (B) cell distributions of scRNAseq analysis of atrial nonmyocytes from sham (n = 3 mice, 9,090 cells) and TAF (n = 3 mice, 8,596 cells) mice. (C) Macrophage annotation and (D) reclustering of macrophages (n = 4,946 cells) with (E) quantification of macrophage subtypes. (F) Flow cytometry with (G) quantification showing increased atrial CD11b+ macrophages in TAF versus sham mice that was reversed by CL. Each dot represents 1 mouse. (H) Incidence of poAF was decreased after CL macrophage depletion. Number of mice per group is depicted. (I) Sample ECG tracings after atrial burst pacing. (J) poAF duration in Sh, TAF, and CL mice. Please note that these data show that macrophages are the most prominent cell type altered in poAF, and that macrophage depletion prevented poAF. P value in B was obtained from χ2 test comparing the proportion of macrophages in Sham versus TAF. P value in E was obtained from χ2 test comparing the proportion of proinflammatory/mixed versus nonproinflammatory/mixed macrophage subtypes in Sham versus TAF. P values in (G and J) were obtained from 1-way ANOVA followed by Tukey’s posthoc tests at α = 0.05. P values in H were obtained from χ2 tests comparing the proportion of positive poAF events. CL, clodronate liposome; Anti, anti-inflammatory; B, B cell; DC, dendritic cell, EC, endothelial cell; ECG, electrocardiogram; FB, fibroblast; Mac, macrophages; Mur, mural; PMN, polymorphonuclear neutrophil; poAF, postoperative atrial fibrillation; Pro/infil, proinflammatory/infiltrating; Prolif, proliferating; SMC, smooth muscle cell; T, T cell; Th, thoracotomy.