Exploration on "Efficacy-toxicity" Association Mechanisms of Tripterygium wilfordii Polyglycoside Tablets Against Rheumatoid Arthritis Based on Multi-omics Integrated Regulatory Network / 中国实验方剂学杂志

ABSTRACT

ObjectiveTo explore the "efficacy-toxicity" association mechanisms of Tripterygium wilfordii polyglycoside tablets （TWPT） by establishing and analyzing an interaction network associated with the clinical efficacy of TWPT in the treatment of rheumatoid arthritis （RA） and TWPT-induced liver injury. MethodOn the basis of the TWPT efficacy-related gene expression profile and TWPT-induced liver injury-related protein expression profile which were both obtained from our clinical cohorts， the "efficacy-toxicity" association network of TWPT was constructed， and the key network targets were identified by calculating the topological values of the nodes， including the degree， closeness and betweenness. After that， the biological functions and pathways of the key network targets were investigated by enrichment analysis. ResultA total of 119 differentially expressed genes （58 up-regulated and 61 down-regulated） between RA patients with TWPT well and weak response were identified as TWPT efficacy-related genes by clinical transcriptomics， and 49 differentially expressed proteins （36 up-regulated and 13 down-regulated） were demonstrated to be TWPT-induced liver injury-related proteins by clinical proteomics. In addition， the clinical symptom enrichment analysis indicated that the TWPT efficacy-related genes were significantly associated with various clinical symptoms of arthralgia in traditional Chinese medicine and clinical phenotypes of modern medicine， and most of the TWPT-induced liver injury-related proteins were involved in digestive system abnormalities. Therefore， the aforementioned multi-omics data represented the main clinical symptoms of TWPT treating RA and inducing liver injury. Mechanically， the "efficacy-toxicity" association network revealed that both TWPT efficacy-related genes and TWPT-induced liver injury-related core proteins were involved in the "immune-inflammatory" imbalance， especially playing an important role in neutrophil degranulation， complement cascade reaction， and immune-inflammatory response mediated by protein post-translational modification. Notably， the above genes and proteins were also enriched in various signaling pathways related to cell proliferation and cell cycle regulation， such as RAS and mitogen-activated protein kinase （MAPK） signaling pathway， and in several liver functional processes， such as glycogen metabolism and redox reaction. ConclusionThis study systematically explained the "efficacy-toxicity" association characteristics and molecular mechanisms of TWPT by applying a research strategy integrating clinical phenomics， transcriptomics and proteomics， laying a good data foundation for exploring the "efficacy enhancing and toxicity-reducing" mechanisms of TWPT.