Lysozyme 1 inflamed CCR2(+) macrophages promote obesity-induced cardiac dysfunction
Autor/innen
- L. Zhang
- H. Han
- A. Xu
- A. Sathe
- S. Fu
- J. Zhao
- W. Cai
- Y. Yang
- J. Liu
- H. Bai
- J. Ben
- X. Zhu
- X. Li
- Q. Yang
- Z. Wang
- Y. Gu
- C. Xing
- G.G. Schiattarella
- S.Y. Cheng
- H. Zhang
- Q. Chen
Journal
- Circulation Research
Quellenangabe
- Circ Res 135 (5): 596-613
Zusammenfassung
BACKGROUND: Macrophages are key players in obesity-associated cardiovascular diseases, which are marked by inflammatory and immune alterations. However, the pathophysiological mechanisms underlying macrophage's role in obesity-induced cardiac inflammation are incompletely understood. Our study aimed to identify the key macrophage population involved in obesity-induced cardiac dysfunction and investigate the molecular mechanism that contributes to the inflammatory response. METHODS AND RESULTS: Though analyzing in-depth cardiac macrophage clusters identified by single macrophage RNA-sequencing, we find that the Ccr2 cluster undergoes a functional transition from homeostatic maintenance to proinflammation. Our data highlight specific changes in macrophage behavior during cardiac dysfunction under metabolic challenge. Consistently, inducible ablation of CCR2(+)CX3CR1(+) macrophages by a dual recombinase-based lineage-tracing approach or selective deletion of macrophage C-C chemokine receptor 2 (CCR2) prevents obesity-induced cardiac dysfunction. At the mechanistic level, we demonstrate that the obesity-induced functional shift of CCR2-expressing macrophages is mediated by the CCR2/ATF3/lysozyme 1/NF-κB (nuclear factor kappa B) signaling. Finally, we uncover a noncanonical role for lysozyme 1 as a transcription activator, binding to the (RelA) promoter, driving NF-κB signaling, and strongly promoting inflammation and cardiac dysfunction in obesity. CONCLUSIONS: Our findings suggest that lysozyme 1 may represent a potential target for the diagnosis of obesity-induced inflammation and the treatment of obesity-induced heart disease.