Litcius/Paper detail

Blockade of the Notch Signaling Pathway Promotes M2 Macrophage Polarization to Suppress Cardiac Fibrosis Remodeling in Mice With Myocardial Infarction

Zhi Li, Miao Nie, Liming Yu, Dengshun Tao, Qiang Wang, Yuanchen He, Yu Liu, Yuji Zhang, Hongguang Han, Huishan Wang

2022Frontiers in Cardiovascular Medicine31 citationsDOIOpen Access PDF

Abstract

Myocardial infarction (MI) is regarded as a serious ischemic heart disease on a global level. The current study set out to explore the mechanism of the Notch signaling pathway in the regulation of fibrosis remodeling after the occurrence of MI. First, experimental mice were infected with recombination signal binding protein J (RBP-J) shRNA and empty adenovirus vector, followed by the establishment of MI mouse models and detection of cardiac function. After 4 weeks of MI, mice in the sh-RBP-J group were found to exhibit significantly improved cardiac function relative to the sh-NC group. Moreover, knockdown of RBP-J brought about decreased infarct area, promoted cardiac macrophages M2 polarization, reduced cardiac fibrosis, and further decreased transcription and protein expressions of inflammatory factors and fibrosis-related factors. Furthermore, downregulation of cylindromatosis (CYLD) using si-CYLD reversed the results that knockdown of RBP-J inhibited fibrogenesis and the release of inflammatory factors. Altogether, our findings indicated that the blockade of Notch signaling promotes M2 polarization of cardiac macrophages and improves cardiac function by inhibiting the imbalance of fibrotic remodeling after MI.

Topics & Concepts

Gene knockdownMacrophage polarizationDownregulation and upregulationFibrosisCardiac fibrosisNotch signaling pathwayBlockadeCardiac function curveMyocardial infarctionMedicineVentricular remodelingInternal medicineSignal transductionCancer researchEndocrinologyMacrophageCardiologyCell biologyReceptorBiologyHeart failureApoptosisIn vitroBiochemistryGeneCardiac Fibrosis and RemodelingNF-κB Signaling PathwaysPeptidase Inhibition and Analysis