小脑
计算生物学
化学
DNA连接酶
限制
泛素连接酶
组合化学
模块化设计
计算机科学
药物发现
娴熟的
纳米技术
相扑蛋白
合成生物学
化学生物学
作者
David M. Whalley,Olivier Lorthioir,Niall A. Anderson,Erin Braybrooke,S. C. Coote,Sylvain Demanze,Holly Douglas,Okky Dwichandra Putra,Katie Proctor,Yuanyuan Si,Sam Staniland,Stephen Stokes,Alfie Woodhouse
标识
DOI:10.1038/s41467-026-74673-x
摘要
Glutarimide-containing Cereblon (CRBN) ligands are critical motifs for PROTACs, molecular glue degraders and next-generation Cereblon E3 ligase modulatory drugs (CELMoDs), which represent promising therapeutic modalities in targeted protein degradation. However, the multistep synthetic routes required to access glutarimide scaffolds continue to present formidable challenges for medicinal chemists, limiting rapid structure-activity relationship (SAR) exploration and late-stage diversification. To streamline access to these privileged motifs, modular and efficient methodologies are still highly desirable. Here, we report a unified organocatalytic synthesis platform for the rapid assembly of diverse glutarimide derivatives from readily available nitrogen heterocycles. Employing a sequence of phosphine-catalysed C-N bond formation, metal-free Giese addition and acid-mediated cyclisation, this approach provides high selectivity, broad functional group tolerance and operational simplicity under conditions amenable to both multigram synthesis and high-throughput parallel synthesis. Using this platform, we rapidly prepare CRBN binder libraries, access control analogues (for example, N‑alkylated glutarimides) and perform late‑stage functionalisation of bioactive molecules. This strategy could offer a transformative solution for the efficient and cost-effective synthesis of CRBN-targeted therapeutics and chemical biology probes, overcoming longstanding synthetic bottlenecks in the field.
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