ABSTRACT
INTRODUCTION: PD-L1, via its interactions with PD-1, constitutes the key immune checkpoint that allows cancer cells to escape immune surveillance. Targeting PD-1/PD-L1 with monoclonal antibodies (mAbs) led to spectacular success in clinical oncology. However, the inherent limitations of mAbs and increasing findings about the immune-related adverse events (iRAEs) prompted intense research in the field of small-molecule inhibitors of PD-L1. AREAS COVERED: This review covers inhibitors of PD-L1 reported in patents published in the online databases of the World Intellectual Property Organization and European Patent Office in the 2022-2023 period. This review provides a landscape of available inhibitors, including their chemical structures, activity, and stage of development. EXPERT OPINION: Small-molecule inhibitors impairing PD-L1/PD-1 interaction represent an attractive alternative to mAbs. In recent years, the field of small-molecule and macrocyclic inhibitors targeting PD-L1 has grown rapidly. The majority (if not all) of small-molecule inhibitors developed recently, similarly to their predecessors, act through a dimerization mechanism of PD-L1, followed by its internalization into the cytosol. In contrast, macrocyclic peptides act purely through a competition mechanism as protein-protein interaction inhibitors. The ongoing clinical trials should ultimately reveal which strategy has real clinical potential and may complement or even replace mAbs-based therapies.
ABSTRACT
Here, we report the fragment-based drug discovery of potent and selective fragments that disrupt the Spire2-FMN2 but not the Spire1-FMN2 interaction. Hit fragments were identified in a differential scanning fluorimetry-based screen of an in-house library of 755 compounds and subsequently validated in multiple orthogonal biophysical assays, including fluorescence polarization, microscale thermophoresis, and 1H-15N HSQC nuclear magnetic resonance. Extensive structure-activity relationships combined with molecular docking followed by chemical optimization led to the discovery of compound 13, which exhibits micromolar potency and high ligand efficiency (LE = 0.38). Therefore, this fragment represents a validated starting point for the future development of selective chemical probes targeting the Spire2-FMN2 interaction.
