Project description:The E3 ligase factor cereblon (CRBN) is a target of thalidomide and lenalidomide, which are therapeutic agents used in the treatment of hematopoietic malignancies and as ligands for targeted protein degradation. These agents are proposed to mimic a naturally occurring degron; however, the structural motif recognized by the thalidomide-binding domain of CRBN is unknown. Here, we report that C-terminal cyclic imides, post-translational modifications that arise from intramolecular cyclization of glutamine or asparagine residues, are degrons for CRBN. Dipeptides bearing the cyclic imide degron are substitutes for thalidomide when embedded within bifunctional small molecule degraders. Installation of the degron to the C-terminus of proteins induces CRBN-dependent ubiquitylation and degradation in vitro and in cells. C-Terminal cyclic imides are previously underappreciated post-translational modifications found throughout the human proteome that are endogenously recognized and removed by CRBN. The discovery of the cyclic imide degron defines a novel regulatory process controlled by these modifications, which may impact the development of therapeutic agents that engage CRBN.

Project description:Our studies establish the unique properties of the cyclimids as versatile warheads in TPD and a systematic biochemical approach for quantifying ternary complex formation to predict their cellular degradation activity, which together will accelerate the development of novel CRBN-targeting bifunctional degraders.

Project description:In the 1950s the drug thalidomide administered as a sedative to pregnant women led ot the birth of thousands of children with multiple defects. Despite its teratogenicity, thalidomide and ist IMiD derivatives recently emerged as effective treatments for multiple myeloma and 5q-dysplasia. IMiDs target the CUL4-RBX1-DDB1-CRBN (CRL4(CRBN)) ubiquitin ligase. Through an unbiased screen we identify the homeobox trranscription factor MEIS2 as an endogenous substrate of CRL4(CRBN). By definition, a specific target of CRL4(CRBN) is expected to have a very low intensity on negative control arrays (E1_E2), (E1_CRBN), (E1_E2_Cdt2), (E1_E2_Cdt2_revlimid), (E1_E2_Cdt2_CSN) or with CRL4(CRBN) in presence of inhibitor (E1_E2_CRBN_revlimid) and high intensity on arrays with CRL4(CRBN) (E1_E2_CRBN) or CRL4(CRBN) in presence of CSN (E1_E2_CRBN_CSN) Accordingly 16 protein microarrays were subjected to in vitro ubiquitylation using the following enzyme combinations: 3x Uba1+UbcH5a; 2x Uba1+UbcH5a+CRL4(DDB2); 3x Uba1+UbcH5a+CRL4(CRBN); 2x Uba1+UbcH5a+CRL4(CRBN)+lenalidomide; 2x Uba1+UbcH5a+CRL4(CRBN)+CSN; 2x Uba1+UbcH5a+CRL4(Cdt2); 1x Uba1+UbcH5a+CRL4(Cdt2)+CSN; 1x Uba1+UbcH5a+CRL4(Cdt2)+lenalidomide

Project description:As small molecule degrader technology has developed, it has raised the question of whether E3 ligases could be induced to self-ubiquitinate. To examine this question, we generated six CRBN-CRBN degraders (also referred to as homo-PROTACs) and six CRBN-VHL degraders (hetero-PROTACs). From these compounds we identified two potent and selective CRBN degraders (ZXH-4-130 and ZXH-4-137), both of which are CRBN-VHL compounds. Comparison of these compounds to previously reported small molecule CRBN degraders further validated our observation that CRBN-VHL compounds are more potent degraders of CRBN than CRBN-CRBN compounds.

Project description:As small molecule degrader technology has developed, it has raised the question of whether E3 ligases could be induced to self-ubiquitinate. To examine this question, we generated six CRBN-CRBN degraders (also referred to as homo-PROTACs) and six CRBN-VHL degraders (hetero-PROTACs). From these compounds we identified two potent and selective CRBN degraders (ZXH-4-130 and ZXH-4-137), both of which are CRBN-VHL compounds. Comparison of these compounds to previously reported small molecule CRBN degraders further validated our observation that CRBN-VHL compounds are more potent degraders of CRBN than CRBN-CRBN compounds.

Project description:As small molecule degrader technology has developed, it has raised the question of whether E3 ligases could be induced to self-ubiquitinate. To examine this question, we generated six CRBN-CRBN degraders (also referred to as homo-PROTACs) and six CRBN-VHL degraders (hetero-PROTACs). From these compounds we identified two potent and selective CRBN degraders (ZXH-4-130 and ZXH-4-137), both of which are CRBN-VHL compounds. Comparison of these compounds to previously reported small molecule CRBN degraders further validated our observation that CRBN-VHL compounds are more potent degraders of CRBN than CRBN-CRBN compounds.

Project description:As small molecule degrader technology has developed, it has raised the question of whether E3 ligases could be induced to self-ubiquitinate. To examine this question, we generated six CRBN-CRBN degraders (also referred to as homo-PROTACs) and six CRBN-VHL degraders (hetero-PROTACs). From these compounds we identified two potent and selective CRBN degraders (ZXH-4-130 and ZXH-4-137), both of which are CRBN-VHL compounds. Comparison of these compounds to previously reported small molecule CRBN degraders further validated our observation that CRBN-VHL compounds are more potent degraders of CRBN than CRBN-CRBN compounds.

Project description:As small molecule degrader technology has developed, it has raised the question of whether E3 ligases could be induced to self-ubiquitinate. To examine this question, we generated six CRBN-CRBN degraders (also referred to as homo-PROTACs) and six CRBN-VHL degraders (hetero-PROTACs). From these compounds we identified two potent and selective CRBN degraders (ZXH-4-130 and ZXH-4-137), both of which are CRBN-VHL compounds. Comparison of these compounds to previously reported small molecule CRBN degraders further validated our observation that CRBN-VHL compounds are more potent degraders of CRBN than CRBN-CRBN compounds.

Project description:The precise molecular mechanism of action and targets through which thalidomide and related immunomodulatory drugs (IMiDs) exert their anti-tumor effects remains unclear. We investigated the role of cereblon (CRBN), a primary teratogenic target of thalidomide, in the anti-myeloma activity of IMiDs. CRBN depletion is initially cytotoxic to human myeloma cells but surviving cells with stable CRBN depletion become highly resistant to both lenalidomide and pomalidomide, but not to the unrelated drugs bortezomib, dexamethasone and melphalan. Acquired deletion of CRBN was found to be the primary genetic event differentiating isogenic MM1.S cell lines cultured to be sensitive or resistant to lenalidomide and pomalidomide. Gene expression changes induced by lenalidomide were dramatically suppressed in the presence of CRBN depletion further demonstrating that CRBN is required for lenalidomide activity. Downstream targets of CRBN include interferon regulatory factor 4 (IRF4) previously reported to also be a target of lenalidomide. Patients exposed to and putatively resistant to lenalidomide had lower CRBN levels in paired samples before and after therapy. In summary, CRBN is an essential requirement for IMiD activity, and a possible biomarker for the clinical assessment of anti-myeloma efficacy. We included 15 samples from multiple myeloma cell lines.

Project description:Lenalidomide is a therapeutically active compound that binds to E3 ubiquitin ligase recruiter cereblon (CRBN) and induces cytotoxicity. We have identified eukaryotic translation initiation factor 2 subunit C2 (EIF2C2) as a new member of CRBN-downstream binding protein that plays an important role in microRNA (miRNA) maturation and function. The treatment of immunomodulatory drug (IMiD)-sensitive multiple myeloma (MM) cells with lenalidomide altered the steady-state levels of CRBN, EIF2C2 and miRNAs and induced apoptosis. However, although the treatment of IMiD-resistant MM cells with lenalidomide altered the steady-state levels of CRBN, EIF2C2 and miRNAs, but did not massively induce apoptosis. In contrast, silencing of EIF2C2 with its small hairpin RNA significantly altered the levels of miRNAs and induced apoptosis regardless of whether those cells are sensitive or resistant to IMiDs. Therefore, EIF2C2 could be considered as a new drug target for overcoming IMiDs resistance in MM cells. To find the role of EIF2C2 in MM cell growth, OCI-My5 cell lines My5/LV and My5/CRBN, with low and high CRBN expression, respectively, were treated 12 different ways. The steady-state levels of miRNAs between (1) My5/LV, EIF2C2-shRNA-treated My5/LV and EIF2C2-cDNA-treated My5/LV cells, (2) My5/CRBN, EIF2C2-shRNA-treated My5/CRBN and EIF2C2-cDNA-treated My5/CRBN cells, (3) My5/LV cells, My5/LV cells treated with 10 µM lenalidomide for 72 hours or 120 hours, and EIF2C2-cDNA-treated My5/LV cells treated with 10 µM lenalidomide for 72 hours, and (4) My5/CRBN cells, My5/CRBN cells treated with 10 µM lenalidomide for 72 hours or 120 hours, and EIF2C2-cDNA-treated My5/CRBN cells treated with 10 µM lenalidomide for 72 hours, were compared in this array.