Abstract
Lupus nephritis (LN), a severe renal complication of systemic lupus erythematosus (SLE), results from immune abnormalities. Qingre Kasen granules (QS), which have chicory as the main ingredient, play a significant role in treating various inflammatory and immune system diseases. This study aimed to identify LN biomarkers and mechanisms via systems biology approach, and multi-omics integration, and to screen potential active ingredients of QS for the treatment of LN. First, bioinformatics and machine learning were used to screen five genes, namely CHI3L1, CX3CR1, GBP2, CCND1, and PKP4, as well as the NF-kappaB signaling pathway. An external dataset was then employed to confirm that GBP2 plays a crucial role in the pathogenesis of LN. Immune infiltration analysis revealed significant changes in the proportion of CD4(+) T cells. Subsequently, an LN mouse model was established to evaluate QS's therapeutic effects. Results showed that QS treatment significantly improved symptoms and alleviated renal damage in these mice. Metabolomics and Western blot analyses further demonstrated that abnormal elevations of proteins related to purine metabolism and the NF-kappaB pathway were closely associated with LN's pathogenesis. Finally, molecular docking and MMGBSA binding energy calculations identified cichoriin as a key component. Molecular dynamics simulations further predicted a strong binding affinity between cichoriin and GBP2, along with favorable ADMET properties. In summary, GBP2 is a key druggable gene in LN. This study verifies QS's efficacy and positions cichoriin as a novel immunomodulator acting on the GBP2/NF-kappaB axis.