[Explore pharmacological mechanism of glycyrrhizin based on systems pharmacology].

To explore the pharmacological mechanism of glycyrrhizin with series methods of systems pharmacology, main diseases related to glycyrrhizin were obtained by text mining tool; and the target proteins of glycyrrhizin were obtained via the database of Polysearch and PubChem. Then, the target proteins interaction network of glycyrrhizin was built using the software called Cytoscape. Next, the protein groups related to glycyrrhizin were analyzed by using Gene Ontology (GO) tool, and the action pathway of its target proteins was analyzed by using enrichment method. Text mining results showed that the related diseases of glycyrrhizin included chronic hepatitis C, chronic hepatitis, hepatitis, HIV virus, liver cancer and so on. Gene ontology analysis indicated that glycyrrhizin played a role mainly through modification of proteins and chromatin. The signaling pathway enrichment results showed that the main action proteins of glycyrrhizin were related to MAPK signaling pathway, toll-like receptor signaling pathway, neurotrophic factor signaling pathway, cancer and apoptosis pathways. So we can conclude that glycyrrhizin may exert its biological functions primarily by regulating multiple pathways such as MAPK signaling pathway and Toll-like receptors signaling pathway. The pharmacological action of a drug can be rapidly and comprehensively analyzed by the ways of systems pharmacology.

Systems-Based Interactome Analysis for Hematopoiesis Effect of Angelicae sinensis Radix: Regulated Network of Cell Proliferation towards Hemopoiesis.

OBJECTIVE: To explore the molecular-level mechanism on the hematopoiesis effect of Angelicae sinensis Radix (ASR) with systems-based interactome analysis. METHODS: This systems-based interactome analysis was designed to enforce the workflow of "ASR (herb)→compound→target protein→internal protein actions→ending regulated protein for hematopoiesis". This workflow was deployed with restrictions on regulated proteins expresses in bone marrow and anemia disease and futher validated with experiments. RESULTS: The hematopoiesis mechanism of ASR might be accomplished through regulating pathways of cell proliferation towards hemopoiesis with cross-talking agents of spleen tyrosine kinase (SYK), Janus kinase 2 (JAK2), and interleukin-2-inducible T-cell kinase (ITK). The hematopoietic function of ASR was also validated by colony-forming assay performed on mice bone marrow cells. As a result, SYK, JAK2 and ITK were activated. CONCLUSION: This study provides a new approach to systematically study and predict the therapeutic mechanism for ASR based on interactome analysis towards biological process with experimental validations.