Objective To investigate the mechanism of action of Guizhi Fuling pill in treating chro-nic prostatitis(CP)using network pharmacology and molecular docking techniques.Methods Compo-nents of Guizhi Fuling pill were collected from the Traditional Chinese Medicines Systems Pharmacolo-gy Platform(TCMSP),and target information was obtained from the SwissTarget database.Targets for chronic prostatitis were screened from the GeneCards,OMIM,CTD,and DisGeNET disease data-bases.A protein-protein interaction(PPI)network was established and analyzed.Gene ontology(GO)functional annotation and Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway en-richment analysis were performed using the DAVID database.The Cytoscape software was employed to construct an association network linking the components of Guizhi Fuling Pill,their targets,and the targets of chronic prostatitis.Molecular docking was conducted using AutoDock Vina software to verify the binding stability between the components of Guizhi Fuling pill and their targets.Results After screening and deduplication in the TCMSP database,76 components of Guizhi Fuling Pill were iden-tified,and 655 component targets were retrieved from the SwissTarget database.There were 190 intersecting targets between GuizhiFuling Pill and chronic prostatitis.GO analysis indicated that Guizhi Fuling Pill may treat chronic prostatitis by participating in processes such asapoptosis,ATP binding,and signal transduction.KEGG analysis suggested that Guizhi Fuling Pill can regulate pathways such as phosphatidylinositol 3-kinase(PI3K)/protein kinase B(AKT)and mitogen-acti-vated protein kinase(MAPK)to intervene in chronic prostatitis.Molecular docking data demonstra-ted that the components of Guizhi Fuling pill exhibited stable conformations with their targets.Con-clusion The components of Guizhi Fuling Pill can stably bind to their targets and exert therapeutic effects on chronic prostatitis through multiple targets and pathways.

Objective To investigate the regulatory effect and molecular mechanism of solute carrier family 1 member 5 (SLC1A5) -tetraspanin superfamily member 1 (TM4SF1) complex on cisplatin resistance in esophageal squamous cell carcinoma (ESCC) cells. Methods SLC1A5-overexpressing Eca109 cells were constructed using lentiviral vectors, and the effect of SLC1A5 on cisplatin sensitivity was assessed through cell viability assays. Western blotting (WB) was employed to detect SLC1A5 expression in Eca109 cells and cisplatin-resistant Eca109 cells (Eca109-R). SLC1A5 expression was knocked down in Eca109-R cells using lentiviral vectors, and cisplatin sensitivity was examined thereafter. Quantitative real-time polymerase chain reaction (qRT-PCR) was utilized to analyze the influence of SLC1A5 knockdown on the expression of key genes involved in DNA damage repair in Eca109-R cells. In SLC1A5-knockdown Eca109-R cells, cell viability assays were performed to evaluate the sensitivity to cisplatin after RAD50 overexpression. Additionally, Eca109 cells were separately or co-overexpressed with SLC1A5 and TM4SF1 using lentiviral vectors, and the effect of the SLC1A5-TM4SF1complex on RAD50 expression and cisplatin resistance was examined through cell viability assays. Results Compared with control cells, Eca109 cells overexpressing SLC1A5 exhibited enhanced cisplatin resistance (P < 0.05). Eca109-R cells showed increased SLC1A5 protein expression, and knockdown of SLC1A5 cells were more sensitivity to cisplatin (P < 0.05). RAD50 gene expression was significantly downregulated upon SLC1A5 knockdown under cisplatin treatment (P < 0.05). Knockdown of SLC1A5 inhibited RAD50 protein expression, and overexpression of RAD50 in SLC1A5-knockdown cells significantly restored cisplatin resistance (P < 0.05). Co-overexpression of SLC1A5 and TM4SF1 can further up-regulate the expression of RAD50, and the drug resistance of the cells to cisplatin was enhanced compared with the control cells(P < 0.05). Conclusion The SLC1A5-TM4SF1 complex promotes cisplatin resistance in ESCC cells by upregulating RAD50 expression.