Mechanism of Paeoniae Radix Alba in the Treatment of Non-alcoholic Fatty Liver Disease Based on Sequential Metabolites Identification Approach, Network Pharmacology, and Binding Affinity Measurement.

Zhiqiang Luo,Guohua Yu,Guopeng Wang,Jing Wang,Wenning Yang,Xueyan Li,Xing Han,Xiaoquan Jiang,Yang Liu,Yuanyuan Shi,Muli Sen

doi:10.3389/fnut.2021.677659

Zhiqiang Luo, Guohua Yu + Show 9 more

Open Access

https://doi.org/10.3389/fnut.2021.677659

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Abstract

Screening functional food ingredients (FFI) from medicinal and edible plants (MEP) has still remained a great challenge due to the complexity of MEP and its obscure function mechanisms. Herein, an integrated strategy based on sequential metabolites identification approach, network pharmacology, molecular docking, and surface plasmon resonance (SPR) analysis was proposed for quickly identifying the active constituents in MEP. First, the sequential biotransformation process of MEP, including intestinal absorption and metabolism, and hepatic metabolism, was investigated by oral gavage, and intestinal perfusion with venous sampling method. Then the blood samples were analyzed by UPLC-Q Exactive Orbitrap HRMS. Second, the network pharmacology approach was used to explore the potential targets and possible mechanisms of the in vivo metabolites of MEP. Third, molecular docking and SPR approaches were used to verify the specific interactions between protein targets and representative ingredients. The proposed integrated strategy was successfully used to explore the heptoprotective components and the underlying molecular mechanism of Paeoniae Radix Alba (PRA). A total of 44 compounds were identified in blood samples, including 17 porotypes and 27 metabolites. The associated metabolic pathways were oxidation, methylation, sulfation, and glucuronidation. After further screening, 31 bioactive candidates and 377 related targets were obtained. In addition, the bioactive components contained in PRA may have therapeutic potentials for non-alcoholic fatty liver disease (NAFLD). The above results demonstrated the proposed strategy may provide a feasible tool for screening FFI and elaborating the complex function mechanisms of MEP.

Highlights

Medicinal and edible plants (MEP) has been extensively used for preventing and treating various diseases in China for centuries [1]
It should be noted that 15 metabolites were produced after passing the intestine, which may be mainly due to the metabolizing enzymes present in gut wall, suggesting that the intestine may play an important role in the first-pass metabolism of MEP
Compared with conventional metabolite identification method for partial metabolism in the whole metabolic route, we developed a sequential metabolites identification approach by integrating intestinal perfusion with venous sampling (IPVS) and LC/MS to characterize the dynamic biotransformation process of MEP

Summary

Introduction

Medicinal and edible plants (MEP) has been extensively used for preventing and treating various diseases in China for centuries [1]. MEP would be biotransformed progressively and orderly from the gastrointestinal tract and liver, to the systemic blood stream [2, 3]. Current metabolic studies are just focus on characterizing the metabolites in different biological samples, like urine, blood, bile and other tissues/organs, and they could not comprehensively illustrate the dynamic biotransformation process of MEP [4]. IPVS is recommended as it enables intestinal absorption/metabolism to occur at body temperature, and allows gut wall metabolism to be studied without interference by the confounding effects of liver metabolism [7, 8].

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