Project description:Tracking distinct RNA populations using efficient and reversible covalent chemistry

Project description:Heterobifunctional proteolysis-targeting chimeric compounds leverage the activity of E3 ligases to induce degradation of target oncoproteins and exhibit potent preclinical antitumor activity. To dissect the mechanisms regulating tumor cell sensitivity to different classes of pharmacological "degraders" of oncoproteins, we performed genome-scale CRISPR/Cas9-based gene-editing studies. We observed that myeloma cell resistance to "degraders" of different targets (BET bromodomain proteins, CDK9) and operating through CRBN (degronimids) or VHL is primarily mediated by prevention of, rather than adaptation to, breakdown of the target oncoprotein; involves loss-of-function for the cognate E3 ligase or interactors/regulators of the respective cullin-RING ligase (CRL) complex. The substantial gene-level differences for CRBN- vs. VHL-based degraders explains mechanistically the lack of cross-resistance for degraders targeting the same protein via different E3 ligase/CRLs.

Project description:During Caenorhabditis elegans oocyte meiosis, a multi-protein complex localised between homologous chromosomes, the ring complex (RC), promotes chromosome congression through the action of the chromokinesin KLP-19. While some RC components are known, the mechanism of RC assembly has remained obscure. A germline-specific screen identified KLP-19 as a SUMO substrate in vivo and we found that the SUMO E3 ligase GEI-17/PIAS is required for KLP-19 recruitment to the RC. Additionally, KLP-19 is efficiently sumoylated in vitro in a GEI-17-dependent manner. Further biochemical analysis showed that KLP-19 and GEI-17 are efficiently modified by SUMO and that GEI-17 and another RC component, the kinase BUB-1, can interact non-covalently with SUMO. While SUMO conjugation is required for RC assembly, we also provide evidence consistent with non-covalent SUMO interactions contributing to RC assembly in vivo. Our results highlight the importance of sumoylation and non-covalent SUMO interaction in regulating dynamic protein complex assembly during oocyte meiosis.

Project description:Temporal control of proteins in cells and living animals is crucial to improving the understanding of protein function in the post-genomic era. In addition, technologies that offer such control for engineered proteins could be used in therapeutic applications. Since regulation of proteins at a genomic or transcriptional level can be irreversible or a slow process, these tools may not be useful in settings where rapid temporal control is required to achieve immediate knockdown effects. PRoteolysis-TArgeting Chimeras (PROTACs) have emerged as a strategy to achieve rapid, post-translational control of protein abundance via recruitment of an E3 ligase to the target protein of interest. Here, we developed several PROTAC molecules by covalently linking the antibiotic trimethoprim (TMP) to pomalidomide, a small molecule ligand of the E3 ligase Cereblon. These molecules induce degradation of various proteins of interest (POIs) genetically fused to E. coli dihydrofolate reductase (eDHFR), the molecular target of TMP. We demonstrate that various eDHFR-tagged proteins, from fluorescent proteins to transcription factors and membrane-associated proteins, can be downregulated to 95% of maximum expression with our lead PROTAC molecule 7c. The data suggest that TMP-based PROTACs induce maximal degradation of POIs at drug concentrations that minimally affect the expression of immunomodulatory imide drug (IMiD)-sensitive neosubstrates. Finally, we show the ability to achieve multiplexed regulation with another known degron-PROTAC pair, and the formidable strength of our system for reversible protein regulation in a rodent model of metastatic cancer. Altogether, TMP PROTACs are a robust approach for selective and reversible degradation of eDHFR-tagged protein and have a strong potential for translation to in vivo models as well as dual degradation strategies with existing technologies.

Project description:The goal of this project was to use differential kinobeads profiling for the discrimination of reversible and irreversible kinase targets of different covalent kinase inhibitors. For this, differences in target engagement measured in a lysate- and a cell-based kinobeads assay were compared in a kinome-wide scale.

Project description:Proteolysis Targeting Chimeras (PROTACs) are molecules that induce proximity between target proteins and E3 ligases triggering target protein degradation. Pomalidomide, a widely used E3 ligase recruiter in PROTACs, can independently degrade other proteins, including zinc-finger (ZF) proteins, with vital roles in health and disease. This off-target degradation hampers the therapeutic applicability of pomalidomide-based PROTACs, requiring development of PROTAC design rules that minimize off-target degradation. Here we developed a highthroughput platform that interrogates off-target degradation and found that reported pomalidomide-based PROTACs induce degradation of several ZF proteins. We generated a library of pomalidomide analogs to understand how functionalising different positions of the phthalimide ring, hydrogen bonding, steric and hydrophobic effects impact ZF protein degradation. Modifications of appropriate size on the C5 position reduced off-target ZF degradation, which we validated through target engagement and proteomics studies. By applying these design principles, we developed ALK oncoprotein-targeting PROTACs with enhanced potency and minimal offtarget degradation.

Project description:Bromodomain extraterminal protein (BETP) inhibitors transcriptionally repress oncoproteins which undermines the growth and survival of AML cells. However, BETi treatment causes accumulation of BETPs, associated with reversible binding and incomplete inhibition of BRD4, which potentially compromises the activity of BETi in AML cells. Unlike BETi, BET-PROTAC (proteolysis-targeting chimera) ARV-825 recruits and utilize an E3-ubiquitin ligase to effectively degrade BETPs in AML cells. BET-PROTACs induce more apoptosis than BETi of mtRUNX1 AML cells. BET-PROTAC treatment induced more perturbations in the mRNA and protein expressions than BETi. It was noted that treatment with BETi or BET-PROTAC caused significant and sustained depletion of RUNX1 in AML cells. We also determined the effects of global depletion of RUNX1 in mtRUNX1 expressing AML OCI-AML5 cells. We observed an overlap in the signature of RUNX1 knockdown by shRNA with that of OTX015 and ARV-825 in OCI-AML5 cells.

Project description:Small GTPase proteins usually serve as molecular switches in various biological process, such as the proliferation, survival, and migration of cells. Mutations or aberrant activations of small GTPase proteins, such as Ras, are frequently observed in various kinds of cancers. Drug discovery efforts that target the Ras family proteins are making breakthroughs, while the discovery of efficient inhibitors that target the Rho family proteins is still stagnant. Protein members from the Rho family, such as RhoA and Cdc42, are key regulators of the migration and invasion of cancer cells. Thus inhibitors of the Rho family proteins are promising to become drug candidates that target cancer metastasis, which is a principal cause of cancer recurrence and chemotherapy failure. Here we show the discovery and characterization of a novel covalent inhibitor named DC-RC-063 that targets the Rho family proteins, using a combined approach of computations and experiments. Revealed by solved crystal structures, compound DC-RC-063 inhibited the activation of RhoA, by disrupting protein-protein interactions, in an allosteric manner. As compound DC-RC-063 inhibited the migration and invasion of breast cancer MDA-MB-231 cells, our findings proved that the Rho family proteins are targetable for covalent inhibitors via an allosteric mechanism. The novel binding site revealed by this inhibitor can be exploited for further development of anti-cancer drugs that target cancer metastasis.

Project description:Protein degradation is an emerging therapeutic strategy with a unique molecular pharmacology that enables the disruption of all functions associated with a target. This is particularly relevant for proteins depending on molecular scaffolding, such as transcription factors or receptor tyrosine kinases (RTKs). To address tractability of multiple RTKs for chemical degradation by the E3 ligase cereblon (CRBN), we synthesized a series of phthalimide degraders based on the promiscuous kinase inhibitors sunitinib and PHA665752. While both series failed to induce degradation of their consensus targets, individual molecules displayed pronounced efficacy in leukemia cell lines. Orthogonal target identification supported by molecular docking led us to identify the translation termination factor G1 to S phase transition 1 (GSPT1) as a converging off-target resulting from inadvertent E3 ligase modulation. This research highlights the importance of monitoring degradation events that are independent of the respective targeting ligand as a unique feature of small-molecule degraders.

Project description:PROteolysis Targeting Chimeras (PROTACs) are bifunctional molecules that degrade target proteins through recruiting E3 ligases. However, their application is limited in part because few E3 ligases can be recruited by known E3 ligase ligands. In this study, we identified piperlongumine (PL), a natural product, as a covalent E3 ligase recruiter, which induces CDK9 degradation when it is conjugated with SNS032, a CDK9 inhibitor. The lead conjugate 955 can potently degrade CDK9 in a ubiquitin-proteasome-dependent manner and is much more potent than SNS-032 against various tumor cells in vitro. Mechanistically, we identified KEAP1 as the E3 ligase recruited by 955 to degrade CDK9 through a TurboID-based proteomics study, which was further confirmed by KEAP1 knockout and the nanoBRET ternary complex formation assay. In addition, PL-Ceritinib conjugate can degrade EML4-ALK fusion oncoprotein, suggesting that PL may have a broader application as a covalent E3 ligase ligand in targeted protein degradation.