A systematic approach to decode the mechanism of Cornus in the treatment of hepatocellular carcinoma (HCC).

Cornus Officinalis (Cornus), the dried pulp of mature Cornus, is used to treat liver diseases. However, the pharmacological mechanism of Cornus in the treatment of hepatocellular carcinoma (HCC) has not been systematically studied. The chemical compounds and the bioactive chemical compounds of Cornus were screened through Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform (TCMSP). Gene Cards database was used to explore the targets in liver cancer pathogenesis. The disease-drug Venn diagram was constructed using the VENN 2.1 and the STRING database was used to analyze protein-protein Interaction Network (PPI). Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis were performed using the R package. Molecular docking was performed using Discovery Studio were assessed using Pymol and Discovery Studio 2016. Cell survival of BEL-7404 cells treated by Hydroxygenkwanin (HGK) were valued through CCK-8 assay. Expressions of caspase-3 and cleaved PARP was detected through Western blot. Pharmacological network diagrams of the Cornus compound-target network and HCC-related target network were successfully constructed. A total of 20 active compounds, 1841 predicted biological targets of Cornus, and 7100 HCC-related targets were identified. 37 target genes between Cornus and HCC were screened trough the network pharmacology. Molecular docking studies suggested that HGK has the highest affinity with caspase-3. HGK could induce apoptosis of HCC cells and significantly activate the caspase-3 protease activity in BEL-7404. This study systematically elaborated the mechanism of Cornus in the treatment of HCC and provided a new perspective to exploit Antineoplastic from Cornus.

d Rhamnose ß-hederin reverses chemoresistance of breast cancer cells by regulating exosome-mediated resistance transmission.

d Rhamnose ß-hederin (DRß-H), an active component extracted from the traditional Chinese medicinal plant Clematis ganpiniana, has been reported to be effective against breast cancer. Recent studies have also indicated that the isolated exosomes (D/exo) from docetaxel-resistant breast cancer cells MCF-7 (MCF-7/Doc) were associated with resistance transmission by delivering genetic cargo. However, the relevance of D/exo during DRß-H exposure remains largely unclear. In the present work, exosomes were characterized by morphology and size distribution. We reinforced the significant role of D/exo in spreading chemoresistance from MCF-7/Doc to recipient sensitive cells after absorption and internalization. DRß-H could reduce the formation and release of D/exo. Next, we demonstrated that DRß-H was able to reverse docetaxel resistance and that D/exo was responsible for DRß-H-mediated resistance reversal. We also found that DRß-H could decrease the expressions of several most abundant miRNAs (miR-16, miR-23a, miR-24, miR-26a, and miR-27a) transported by D/exo. Target gene prediction and pathway analysis showed the involvement of these selected miRNAs in pathways related to treatment failure. Our results suggested that DRß-H could reduce D/exo secretion from MCF-7/Doc cells and induce the reduction in resistance transmission via D/exo.