Yuting Huang , Kai Zhang , Xiao Wang , Kaimin Guo , Xiaoqiang Li , Feng Chen , Ruijiao Du , Sheng Li , Lan Li , Zhihui Yang , Danping Zhuo , Bingkai Wang , Wenjia Wang , Yunhui Hu , Miaomiao Jiang , Guanwei Fan
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However, the pharmacological mechanism of QSYQ in improving HFpEF is not well understood.</span></p></div><div><h3>Aim of the study</h3><p>The objective of the study is to investigate the cardioprotective effect and mechanism of QSYQ in HFpEF using the phenotypic dataset of HFpEF.</p></div><div><h3>Materials and methods</h3><p>HFpEF mouse models established by feeding mice combined high-fat diet and N<sup>ω</sup><span>-nitro-L-arginine methyl ester drinking water were treated with QSYQ. To reveal causal genes, we performed a multi-omics study, including integrative analysis of transcriptomics, proteomics, and metabolomics data. Moreover, adeno-associated virus (AAV)-based PKG inhibition confirmed that QSYQ mediated myocardial remodeling through PKG.</span></p></div><div><h3>Results</h3><p><span><span>Computational systems pharmacological analysis based on human transcriptome data for HFpEF showed that QSYQ could potentially treat HFpEF through multiple signaling pathways. Subsequently, integrative analysis of transcriptome and </span>proteome<span> showed alterations in gene expression in HFpEF. QSYQ regulated genes involved in inflammation, energy metabolism, myocardial hypertrophy, </span></span>myocardial fibrosis, and cGMP-PKG signaling pathway, confirming its function in the pathogenesis of HFpEF. Metabolomics analysis revealed fatty acid metabolism as the main mechanism by which QSYQ regulates HFpEF myocardial energy metabolism. Importantly, we found that the myocardial protective effect of QSYQ on HFpEF mice was attenuated after RNA interference-mediated knock-down of myocardial PKG.</p></div><div><h3>Conclusion</h3><p>This study provides mechanistic insights into the pathogenesis of HFpEF and molecular mechanisms of QSYQ in HFpEF. 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Moreover, adeno-associated virus (AAV)-based PKG inhibition confirmed that QSYQ mediated myocardial remodeling through PKG.</span></p></div><div><h3>Results</h3><p><span><span>Computational systems pharmacological analysis based on human transcriptome data for HFpEF showed that QSYQ could potentially treat HFpEF through multiple signaling pathways. Subsequently, integrative analysis of transcriptome and </span>proteome<span> showed alterations in gene expression in HFpEF. QSYQ regulated genes involved in inflammation, energy metabolism, myocardial hypertrophy, </span></span>myocardial fibrosis, and cGMP-PKG signaling pathway, confirming its function in the pathogenesis of HFpEF. Metabolomics analysis revealed fatty acid metabolism as the main mechanism by which QSYQ regulates HFpEF myocardial energy metabolism. 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引用次数: 3
摘要
中医理论认为气虚血瘀是保射血分数型心力衰竭的关键病机。气肾益气滴丸作为补气活血的代表性方药,一直被用于治疗心脏病。然而,芪syq改善HFpEF的药理机制尚不清楚。本研究的目的是利用HFpEF表型数据集,探讨QSYQ在HFpEF中的心脏保护作用及其机制。材料与方法采用高脂饲料与ω-硝基- l -精氨酸甲酯饮水联合喂养的方法建立小鼠fpef模型。为了揭示致病基因,我们进行了多组学研究,包括转录组学、蛋白质组学和代谢组学数据的综合分析。此外,基于腺相关病毒(adeno-associated virus, AAV)的PKG抑制证实了QSYQ通过PKG介导心肌重构。结果基于人类HFpEF转录组数据的计算系统药理学分析显示,QSYQ可能通过多种信号通路治疗HFpEF。随后,转录组和蛋白质组的综合分析显示HFpEF的基因表达发生了变化。QSYQ调节炎症、能量代谢、心肌肥大、心肌纤维化、cGMP-PKG信号通路等相关基因,证实其在HFpEF发病机制中的作用。代谢组学分析显示,脂肪酸代谢是QSYQ调控HFpEF心肌能量代谢的主要机制。重要的是,我们发现在RNA干扰介导的心肌pkg敲除后,QSYQ对HFpEF小鼠的心肌保护作用减弱。结论本研究为HFpEF的发病机制和QSYQ在HFpEF中的分子机制提供了机制上的见解。我们还发现PKG在心肌僵硬中的调节作用,使其成为心肌重构的理想治疗靶点。
Multi-omics approach for identification of molecular alterations of QiShenYiQi dripping pills in heart failure with preserved ejection fraction
Ethnopharmacological relevance
Traditional Chinese medicine theory believes that qi deficiency and blood stasis are the key pathogenesis of heart failure with preserved ejection fraction (HFpEF). As a representative prescription for replenishing qi and activating blood, QiShenYiQi dripping pills (QSYQ) has been used for treating heart diseases. However, the pharmacological mechanism of QSYQ in improving HFpEF is not well understood.
Aim of the study
The objective of the study is to investigate the cardioprotective effect and mechanism of QSYQ in HFpEF using the phenotypic dataset of HFpEF.
Materials and methods
HFpEF mouse models established by feeding mice combined high-fat diet and Nω-nitro-L-arginine methyl ester drinking water were treated with QSYQ. To reveal causal genes, we performed a multi-omics study, including integrative analysis of transcriptomics, proteomics, and metabolomics data. Moreover, adeno-associated virus (AAV)-based PKG inhibition confirmed that QSYQ mediated myocardial remodeling through PKG.
Results
Computational systems pharmacological analysis based on human transcriptome data for HFpEF showed that QSYQ could potentially treat HFpEF through multiple signaling pathways. Subsequently, integrative analysis of transcriptome and proteome showed alterations in gene expression in HFpEF. QSYQ regulated genes involved in inflammation, energy metabolism, myocardial hypertrophy, myocardial fibrosis, and cGMP-PKG signaling pathway, confirming its function in the pathogenesis of HFpEF. Metabolomics analysis revealed fatty acid metabolism as the main mechanism by which QSYQ regulates HFpEF myocardial energy metabolism. Importantly, we found that the myocardial protective effect of QSYQ on HFpEF mice was attenuated after RNA interference-mediated knock-down of myocardial PKG.
Conclusion
This study provides mechanistic insights into the pathogenesis of HFpEF and molecular mechanisms of QSYQ in HFpEF. We also identified the regulatory role of PKG in myocardial stiffness, making it an ideal therapeutic target for myocardial remodeling.
期刊介绍:
The Journal of Ethnopharmacology is dedicated to the exchange of information and understandings about people''s use of plants, fungi, animals, microorganisms and minerals and their biological and pharmacological effects based on the principles established through international conventions. Early people confronted with illness and disease, discovered a wealth of useful therapeutic agents in the plant and animal kingdoms. The empirical knowledge of these medicinal substances and their toxic potential was passed on by oral tradition and sometimes recorded in herbals and other texts on materia medica. Many valuable drugs of today (e.g., atropine, ephedrine, tubocurarine, digoxin, reserpine) came into use through the study of indigenous remedies. Chemists continue to use plant-derived drugs (e.g., morphine, taxol, physostigmine, quinidine, emetine) as prototypes in their attempts to develop more effective and less toxic medicinals.
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