TMT-based proteomics reveals methylprotodioscin alleviates oxidative stress and inflammation via COX6C in myocardial infraction

The effect of methylprotodioscin (MPD), a steroidal saponin obtained from medicinal plants, on myocardial infarction (MI) remains elusive. In this study, HL-1 and AC16 cells were subjected to injury induced by hypoxic environment, and a mouse model of MI was established by ligating the left anterior...

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Veröffentlicht in:Biomedicine & pharmacotherapy 2024-11, Vol.180, p.117489, Article 117489
Hauptverfasser: Xu, Zhihui, Song, Tingyu, Yang, Xiufang, Cong, Linhao, Yin, Lianhong, Xu, Youwei, Han, Xu, Gao, Meng, Xu, Lina
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Sprache:eng
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Zusammenfassung:The effect of methylprotodioscin (MPD), a steroidal saponin obtained from medicinal plants, on myocardial infarction (MI) remains elusive. In this study, HL-1 and AC16 cells were subjected to injury induced by hypoxic environment, and a mouse model of MI was established by ligating the left anterior descending. MPD significantly increased viabilities and proliferations, improved the stability of MMP, reduced ROS and inflammatory factor levels in hypoxia cardiomyocytes. Moreover, MPD significantly improved cardiac functions, increased the ventricular ejection fraction and short axis shortening rate of mice with MI, reduced the infarction area, alleviated oxidative stress and increased ATPase activities. Then, differentially expressed proteins (DEPs) were discovered and evaluated using tandem mass tag (TMT)-based proteomics and bioinformatics approaches. Compared with sham group, there were 420 DEPs in the cardiac tissue of MI group, likewise, 163 DEPs in MPD group were identified compared to MI group. By validating, the expression of COX6C was elevated in MI group and declined in MPD groups, consistent with the TMT-based proteomics results. Correspondingly, p-NF-κB expression was downregulated, while Nrf2 and SOD expressions were upregulated by MPD. Moreover, si-COX6C transfection blocked the regulatory effects of MPD on COX6C-mediated inflammation and oxidative stress in MI. Our findings indicate that MPD, a naturally occurring active ingredient, could effectively improve cardiac function. Its ability may result from regulating COX6C to reduce oxidative stress and suppress inflammation, suggesting that MPD is very attractive for the treatment of MI. [Display omitted] •MPD significantly reduces the damage of HL-1 and AC16 cells induced by hypoxia.•MPD improves myocardial function and histopathological changes in mice with MI.•MPD regulates COX6C expression in MI through TMT proteomics.•MPD regulates COX6C to alleviate oxidative stress and inflammatory in MI.
ISSN:0753-3322
1950-6007
1950-6007
DOI:10.1016/j.biopha.2024.117489