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ObjectiveTo observe the repair effect of Dahuanglingxian prescription (DHLX) on bile duct epithelial cells of rats. To explore whether its mechanism of action is to adjust the mutual binding of transforming growth factor -β (TGF-β) activated kinase 1(TAK1) and tumor necrosis factor receptor-associated factor 6 (TRAF6), and regulate the activation of the nuclear transcription factor -κB (NF-κB)/mitogen-activated protein kinase (MAPK) signaling pathway. MethodThe 20 SD rats were randomly divided into normal group and DHLX group, 10 rats in each group, were given saline and DHLX (320 mg·kg-1·d-1) for 8 days, to prepare normal serum and DHLX serum. Biliary epithelial cells were extracted from normal SD rats and divided into 9 groups: Normal group, model group (20 mg·L-1), LPS+DHLX group (20 mg·L-1+10% DHLX), LPS+PDTC group (20 mg·L-1+200 μmol·L-1), LPS+SB203580 group (20 mg·L-1+0.5 μmol·L-1), LPS+PDTC+SB203580 group (20 mg·L-1+200 μmol·L-1+0.5 μmol·L-1), LPS+PDTC+DHLX group (20 mg·L-1+200 μmol·L-1+10% DHLX serum), LPS+SB203580+DHLX group (20 mg·L-1+0.5 μmol·L-1+10% DHLX serum), LPS+PDTC+SB203580 +DHLX group (20 mg·L-1+200 μmol·L-1+0.5 μmol·L-1+10% DHLX serum). The microscopic observation of morphological changes in each group of cells after drug intervention. Enzyme-linked immunosorbent assay(ELISA) was used to detect the expression of (IL)-1β and IL-6 in each group of cells. Western blot detected the expression levels of TAK1 and TRAF6 proteins in each group of cells, Co-IP detected the interaction between TAK1 and TRAF6, and further observed the distribution and co-localization of TAK1 and TRAF6 using Laser confocal microscope. ResultAfter the action of LPS, the cell synapses are reduced, the cell body becomes significantly rounded and smaller, but the cell morphology of each group tends to be normal after medication. Compared with normal group, the expression levels of IL-1β and IL-6 in model group were significantly increased (P<0.05), while the expression level of TAK1 was decreased while the expression level of TRAF6 was increased (P<0.05). The content of TAK1-TRAF6 protein complex showed a decreasing trend, and the two proteins co-located in the cytoplasm. Compared with model group, the expression levels of IL-1β and IL-6 in LPS+DHLX group were significantly decreased (P<0.05), the expression level of TAK1 was increased and the expression level of TRAF6 was decreased (P<0.05), the content of TAK1-TRAF6 protein complex was significantly increased (P<0.01), and the two proteins were significantly co-located in cytoplasm. Compared with LPS+DHLX group, the expression levels of IL-1β and IL-6 in other groups were significantly decreased (P<0.05,P<0.01). TAK1-TRAF6 protein complex content in each group was significantly decreased after pathway blocker intervention (P<0.05), while TAK1-TRAF6 protein complex content in each group was significantly increased after pathway blocker combined with DHLX intervention (P<0.05). Co-localization of the TAK1-TRAF6 in cytoplasm was not obvious. ConclusionIn the LPS-induced inflammatory response of bile duct cells, the binding of TAK1 and TRAF6 showed a weakening trend, but DHLX could reverse the phenomenon, we think the mechanism of action may be related to promoting the mutual binding of TAK1 and TARF6 to inhibit the activation of the NF-κB/MAPK signaling pathway.
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Objective: “Same treatment for different diseases” is a unique treatment strategy under the guidance of traditional Chinese medicine (TCM) theory. Codonopsis Radix (Codonopsis pilosula, Dangshen in Chinese) with spleen-fortifying effect was employed to understand the strategy of “Same treatment for different diseases”, based on its common mechanism in the treatment of gastric diseases including gastric ulcer, gastritis and gastric cancer via network pharmacology research. Methods: Network pharmacology research methods were used to analyze the interaction network and potential mechanisms of Dangshen in treating gastric ulcer, gastritis and gastric cancer. The active components and their target proteins of Dangshen were integrated from TCMSP, BATMAN-TCM databases. The targets of gastric ulcer, gastritis and gastric cancer were collected through GeneCards, PubMed, TDD and DisGeNET Database. Through screening, the key components and the key targets of Dangshen in treating gastric ulcer, gastritis and gastric cancer were obtained. After KEGG pathway analysis and GO analysis, the important pathways and biological processes were analyzed. Results: Through data and literature mining, the common and specific pharmaceutical effects and mechanism of Dangshen were summarized in these three gastric lesions. It was shown that Dangshen mainly acted on gastric ulcer, gastritis and gastric cancer through the overall regulation of the PI3K-AKT signaling pathway. With the development of the disease, it will gradually increase the control of inflammation through TNF, NF-κB and other inflammation-related signaling pathways to reduce inflammatory damage. For tumorigenesis, it pays more attention to inhibiting the ErbB signaling pathways to reduce the proliferation and migration of tumor cells. In addition, Dangshen's regulation of HIF-1 signaling pathway may also be beneficial for the treatment of gastric ulcer, gastritis and gastric cancer. Conclusion: Dangshen achieves spleen-fortifying effect on gastric diseases including gastric ulcer, gastritis and gastric cancer through multiple targets in multiple pathways, especially PI3K-AKT pathway and HIF-1 pathway. It could provide a scientific basis for understanding the strategy of “Same treatment for different diseases” in traditional Chinese medicine.
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Objective: “Same treatment for different diseases” is a unique treatment strategy in traditional Chinese medicine. Two kinds of malignant respiratory diseases endanger human health-chronic obstructive pulmonary disease (COPD) and lung cancer. Citrus Grandis Exocarpium (Huajuhong in Chinese, HJH), a famous herbal, is always applied by Chinese medicine practitioners to dispersion the lung to resolve phlegm based on “syndrome differentiation and treatment” theory. However, the common mechanism for HJH's treatment of COPD and lung cancer is not clear. Methods: In this study, based on network pharmacology and molecular docking technology, the common mechanism of HJH in the treatment of COPD and lung cancer was studied. The active ingredients and related targets of HJH were integrated from TCMSP, BATMAN-TAM, STP, and Pubchem databases. The standard names of these targets were united by UniProt database. Targets of COPD and lung cancer were enriched through GeneCards, NCBI (Gene), Therapeutic Target Database, and DisGeNET (v7.0) databases. Then the intersection targets of HJH and diseases were obtained. The STRING network and the Cytoscape 3.7.2 were used to construct PPI network, the DAVID database was used to perform GO and KEGG analysis. Then Cytoscape 3.6.1 was used to build “ingredient-target-signal pathway” network. Finally, AutoDock 1.5.6 software was used to perform molecular docking of key proteins and molecules. Results: Eleven active ingredients in HJH were obtained by searching the database, corresponding to 184 HJH-COPD-lung cancer targets intersection. The results of biological network analysis showed that naringenin, the active component in HJH, could mainly act on target proteins such as AKT1, EGFR. Then through positive regulation of vasoconstriction and other biological processes, naringenin could regulate estrogen signaling pathway, VEGF signaling pathway, HIF-1 signaling pathway, ErbB signaling pathway, PI3K-Akt signaling pathway to play an important role in the treatment of both COPD and lung cancer. Conclusion: Network pharmacology was employed to systematically investigate the active ingredients and targets of HJH in treatment of COPD and lung cancer. And then, the common pharmacodynamic network of HJH for the two malignant respiratory diseases was firstly described. Furthermore, naringenin was proved to strongly bind with AKT1 and EGFR. It may provide the scientific basis for understanding the “Same treatment for different diseases” strategy in traditional Chinese medicine and inspirit subsequent drug discovery for COPD, lung cancer and other malignant lung diseases.