Discovery of the PARP1 Inhibitors from Natural Compounds Using Structure-Based Virtual Screening and Bioactivity Evaluation.

Abstract

Background: PARP1 (poly ADP-ribose polymerase 1, also known as ADPRT1) plays a significant role in DNA repair and has become an attractive target for treating PARP1-related diseases, such as cancer.

Objective: This study aimed to discover inhibitors targeting PARP1 from the phytochemicals of Huangbai (Phellodendron chinense Schneid.), Baixianpi (Dictamnus dasycarpus Turcz.), and Shechuangzi (Cnidium monnieri (L.) Spreng.).

Methods: The chemical compositions of Huangbai, Baixianpi, and Shechuangzi were extracted from the HERB database. Next, a combination of molecular docking and PARP1 enzyme assay was used to identify PARP1 inhibitors from these chemical components. Finally, molecular dynamics simulation and binding free energy calculation were used to explore the detailed interaction mode of these inhibitors with PARP1.

Results: A total of 507 chemical constituents of Huangbai, Baixianpi, and Shechuangzi were collected from the HERB database. Four potential PARP1 inhibitors were screened based on molecular docking and PARP1 enzyme assay. Demethyleneberberine exhibited strong PARP1 inhibitory activity with an IC50 value of 2.0 ± 0.8 μM. The IC50 values of the inhibitory activities of 8-hydroxy dictanmnine, meranzin hydrate, and osthol on PARP1 ranged from 44 μM to 76 μM. Molecular dynamics simulation and binding free energy calculation suggested that the nonpolar interaction energies of HIS862, GLY863, TYR889, TYR896, PHE897, and TYR907 played a primary role in the binding of inhibitors to PARP1.

Conclusion: Integrating molecular simulation and bioactivity testing was found to be an effective approach for the rapid discovery of targeted PARP1 inhibitors. Demethyleneberberine demonstrated strong PRAP1 inhibitory activity and has a good prospect for development.