Molecular dynamics-guided optimization of BGM0504 enhances dual-target agonism for combating diabetes and obesity.

The dual activation of glucagon-like peptide-1 receptor (GLP-1R) and glucose-dependent insulinotropic polypeptide receptor (GIPR) has emerged as a promising therapeutic strategy for managing type 2 diabetes and obesity. Tirzepatide, a dual agonist peptide, has exhibited superior clinical efficacy in glycemic and weight control compared to selective GLP-1R agonists. Nevertheless, the structural basis of Tirzepatide's extended half-life, attributed to an acylation side chain on the parent peptide, raises questions regarding its partial agonistic activity. Employing molecular dynamics simulations, we explored the dynamic processes of peptide-receptor interactions. We uncovered a crucial salt bridge between parent peptide and GLP-1R/GIPR at K20, a feature not discernible in cryo-electron microscopy structures. Building upon these insights, we developed an optimization strategy based on the parent peptide which involved repositioning the acylation side chain. The results of both in vitro and in vivo experiments demonstrated that the optimized peptide has twofold to threefold increase in agonistic activity compared to Tirzepatide while maintaining its extended half-life in plasma. This led to the design of BGM0504, which proved to be more effective than its predecessor, Tirzepatide, in both laboratory and animal studies.

Design and syntheses of a bimolecular STING agonist based on the covalent STING antagonist.

Cyclic GMP-AMP synthase and stimulator of interferon genes (cGAS-STING) signaling stimulators, an essential innate immunity component, monitor invading pathogen DNA and damaged self-DNA, making them an appealing target for drug development. The natural STING agonist, 2'3'-cGAMP, mounts and stabilizes the STING homodimer to trigger an antiviral or antitumor immune responses. However, cyclic-dinucleotide-based STING agonists show limited clinical effects owing to their short half-lives. To explore whether STING-dimer stabilizers could trigger STING signaling instead of cyclic dinucleotide-based molecules, we analyzed the structural characteristics of STING to design and synthesize a series of compounds based on the covalent STING inhibitor C-170, three of which were 23, 26, and 27, exhibited STING-dependent immune activation, both in vitro and in vivo. Compound 23 could act synergistically with cGAMP and other STING agonists as a promising moderate STING agonist. This indicates that promoting STING dimerization is a promising strategy for designing next-generation STING agonists.

Ginkgo Biflavones Cause p53 Wild-Type Dependent Cell Death in a Transcription-Independent Manner of p53.

Ginkgo biloba, as a medicinal plant in both traditional and western medicine, emerged as a potential therapeutic agent for the management of a variety of diseases, but ginkgo biflavones (bilobetin, isoginkgetin, and ginkgetin) application in cancer therapy and underlying mechanisms of action remained elusive. In the present study, we identified ginkgo biflavones as potential p53 activators that could enhance p53 protein expression level by inhibiting MDM2 protein expression. At the same time, they induced cell death independent of p53 transcriptional activity. Moreover, ginkgetin was a standout among ginkgo biflavones that reduced the survival of HCT-116 cells by induction of apoptosis and G2/M phase arrest. Furthermore, ginkgo biflavones induced ROS generation significantly, which resulted in ferroptosis. Finally, we provide evidence that ginkgetin strengthened the antitumor effect of fluorouracil (5-FU) in the HCT-116 colon cancer xenograft model. To sum up, ginkgo biflavones represent a new class of p53 activator that depends on the p53 wild-type status and warrants further exploration as potential anticancer agents.

Design, synthesis, and bioactivity study on Lissodendrins B derivatives as PARP1 inhibitor.

Poly(ADP-ribose) polymerase-1 (PARP1) is an enzyme that catalyzes the polymerization of ADP-ribose units to target proteins, and it is a potential target for anti-cancer drug discovery, especially for BRAC1/2 mutated tumors. In this study, a series of 2-aminoimidazole Lissodendrins B derivatives were designed, synthesized, and evaluated as PARP1 inhibitors. We found that compound D3 is better due to its PARP enzyme inhibitory activity and in vitro anti-cancer activity compared with other tested compounds. It could inhibit PARP1 enzymatic activity (IC50 = 17.46 µM) in the non-cell system and BRCA1-deficient HCC1937 and MDA-MB-436 cells growth (IC50 = 17.81 and 12.63 µM, respectively). Further study demonstrated that compound D3 inhibits tumor growth through multiple mechanisms, such as reduction of PARylation, accumulation of cellular DNA double-strand breaks, induction of G2/M cell cycle arrest, and subsequent apoptosis of BRCA1-deficient cells. Besides, the molecular docking study also confirmed that compound D3 could effectively occupy the active pocket of PARP1. Our findings provide a new skeleton structure for PARP1 inhibitor, and the results suggested that the compound D3 may serve as a potential lead compound to develop novel PARP1 inhibitors for cancer therapy.