Litcius/Paper detail

DNA Tetrahedron-Driven Multivalent Proteolysis-Targeting Chimeras: Enhancing Protein Degradation Efficiency and Tumor Targeting

Shiqing Li, Tao Zeng, Zhixing Wu, Jiabao Huang, Xiuping Cao, Yana Liu, Shiyan Bai, Qi Chen, Chunsen Li, Chunhua Lü, Huanghao Yang

2025Journal of the American Chemical Society35 citationsDOI

Abstract

Proteolysis-targeting chimeras (PROTACs) are dual-functional molecules composed of a protein of interest (POI) ligand and an E3 ligase ligand connected by a linker, which can recruit POI and E3 ligases simultaneously, thereby inducing the degradation of POI and showing great potential in disease treatment. A challenge in developing PROTACs is the design of linkers and the modification of ligands to establish a multifunctional platform that enhances degradation efficiency and antitumor activity. As a programmable and modifiable nanomaterial, DNA tetrahedron can precisely assemble and selectively recognize molecules and flexibly adjust the distance between molecules, making them ideal linkers. Herein, we developed a multivalent PROTAC based on a DNA tetrahedron, named AS-TD2-PRO. Using DNA tetrahedron as a linker, we combined modules targeting tumor cells, recognizing E3 ligases, and multiple POI together. We took the undruggable target protein signal transducer and activator of transcription 3 (STAT3), associated with the etiology and progression in a variety of malignant tumors, as an example in this study. AS-TD2-PRO with two STAT3 recognition modules demonstrated good potential in enhancing tumor-specific targeting and degradation efficiency compared to traditional bivalent PROTACs. Furthermore, in a mouse tumor model, the superior therapeutic activity of AS-TD2-PRO was observed. Overall, DNA tetrahedron-driven multivalent PROTACs both serve as a proof of principle for multifunctional PROTAC design and introduce a promising avenue for cancer treatment strategies.

Topics & Concepts

ChemistryProteolysisTetrahedronDNACell biologyChimera (genetics)Degradation (telecommunications)BiochemistryCancer researchComputational biologyEnzymeGeneCrystallographyComputer scienceTelecommunicationsBiologyProtein Degradation and InhibitorsCAR-T cell therapy researchCancer therapeutics and mechanisms