Abstract Body (Do not enter title and authors here): Background: Coronary microembolization (CME) is a common reason for periprocedural myocardial infarction after coronary interventions. S-nitrosylation (SNO), a prototypic redox-based posttranslational modification, is involved in the pathogenesis of several cardiovascular diseases.
Purpose: To explore the role of SNO of aconitase-2 (ACO2) in CME-induced cardiac injury, as well as the mechanism by which SNO-ACO2 modulates myocardial injury in response to CME.
Methods: CME models were established in C57BL/6J mice by injecting 300,000 polyethylene microspheres (diameter 9 µm) into the left ventricle chamber with the occlusion of the ascending aorta. S-nitrosylated proteins and SNO sites of ACO2 were identified through LC-MS/MS analysis. De-nitrosylation of ACO2 was achieved by the mutation of SNO site or overexpression of the de-nitrosylation enzyme thioredoxin 1 (TRX1). Interacting effectors of SNO-ACO2 were screened through LC-MS/MS and confirmed by coimmunoprecipitation. Neonatal rat ventricular myocytes (NRVMs) were used for ACO2 enzyme activity analysis, mitochondrial morphology and function.
Results: Cardiac injury was exacerbated by CME as demonstrated by impaired cardiac contractile function, increased fibrosis, microinfarct size. We identified 789 S-nitrosylated proteins in CME mouse hearts, and ACO2 is one of the highly S-nitrosylated proteins. The increased level of SNO-ACO2 was verified by immunoblot assay in CME mouse hearts and hypoxia-stimulated NRVMs. SNO site of ACO2 at cysteine 126 was identified by LC-MS/MS and confirmed in NRVMs. De-nitrosylation of ACO2 by the mutation of cysteine 126 or overexpression of TRX1 both greatly improved the activity of ACO2 by 39.7% and 31.4% respectively, further restored the mitochondrial function, and attenuated CME-induced cardiac injury. Mechanistically, SNO-ACO2 at cysteine 126 suppressed the interaction between ACO2 and NFU1, an iron-sulfur (Fe-S) cluster scaffold protein. The dissociation from NFU1 deprived ACO2 of the Fe-S cluster and the enzyme activity, thereby promoting the disruption of the mitochondrial tricarboxylic acid cycle and cardiac injury.
Conclusions: Our data defined a previously unrecognized role of SNO-ACO2 in CME-induced cardiac injury. We demonstrated that SNO-ACO2 at cysteine 126 disrupted ACO2/NFU1 interaction to exacerbate myocardial injury after CME. Our results suggested that de-nitrosylation of ACO2 may provide a new therapeutic target for the treatment of CME.