Litcius/Paper detail

DNA nanoflower Oligo-PROTAC for targeted degradation of FUS to treat neurodegenerative diseases

Ruixin Ge, Miao Chen, Sijin Wu, Sirui Huang, Ping Zhou, Minghui Cao, Fan Zhang, Jinzhi Zang, Yigao Zhu, Jingrui Li, Gang Ni, Zhihao Yang, Qingchao Li, Wei Pan, Liang Zhang, Min Liu, Chenghao Xuan, Haiyang Yu, Jun Zhou, Songbo Xie

2025Nature Communications17 citationsDOIOpen Access PDF

Abstract

Oligonucleotide-based medicine faces challenges in efficiently crossing the blood-brain barrier and rapidly reducing toxic proteins. To address these challenges, here we establish an integrated modality, brain-penetrant DNA nanoflowers incorporated with oligonucleotide-based proteolysis targeting chimeras. Using FUS as a proof-of-concept, mutations of which cause frontotemporal dementia and amyotrophic lateral sclerosis, we demonstrate that a FUS-engaging RNA oligonucleotide crosslinked to a ligand for Cereblon efficiently degrade FUS and its cytoplasmic disease-causing mutants through a ubiquitin-proteasomal pathway. The DNA nanoflower contains hundreds of oligonucleotide binding sites and transferrin receptor-engaging aptamers, allowing efficient loading of the oligonucleotide-based degrader and engaging transferrin receptors for brain delivery. A single dose intravenous injection of this modality reaches brain parenchyma within 2 h and degrades 80% FUS protein there, sustained for two weeks without noticeable toxicity. DNA nanoflower oligonucleotide-based degrader is a therapeutic strategy for neurodegenerative diseases that leverages the advantages of designer oligonucleotides and targeted protein degradation. Targeted degradation has the potential to treat diseases associated with pathological protein build up. Here, the authors report on an oligo-PROTAC which degrades FUS, a protein associated with frontotemporal dementia, demonstrating delivery on DNA nanoflowers for increase blood-brain barrier crossing and retention.

Topics & Concepts

NanoflowerDNADegradation (telecommunications)Computational biologyBiologyChemistryCell biologyMolecular biologyGeneticsBiochemistryComputer scienceCatalysisTelecommunicationsProtein Degradation and InhibitorsPeptidase Inhibition and AnalysisUbiquitin and proteasome pathways
DNA nanoflower Oligo-PROTAC for targeted degradation of FUS to treat neurodegenerative diseases | Litcius