Project description:Chemical inducers of proximity (CIPs) stabilize biomolecular interactions, often causing a privileged rewiring of cellular biochemistry. While rational design strategies can expedite the discovery of heterobifunctional CIPs, molecular glues have predominantly been discovered by serendipity. Envisioning a prospective approach to discover molecular glues for a pre-selected target, we hypothesized that pre-existing ligands could be systematically decorated with chemical modifications to discover protein-ligand surfaces that are tuned to cooperatively engage another protein interface. Using high-throughput chemical synthesis to diversify a ligand for the transcriptional coactivator ENL with 3,163 structurally diverse chemical building blocks, we discovered a compound dHTC1 that elicits potent, selective, and stereochemistry-dependent degradation of ENL by induced binding to CRL4CRBN. Unlike prior CRBN-based degraders, dHTC1 binds the ligase with high affinity only after forming the ENL:dHTC1 complex, relying on a hybrid interface of protein-protein and protein-ligand contacts. Altogether, this study points toward an expanded chemical space for co-opting the therapeutically important substrate receptor, CRBN, and a second proof-of-concept extending this approach to BRD4 further validates high-throughput chemistry as a facile tool to discover new degraders

Project description:Glutarimide analogs, including thalidomide, redirect the E3 ubiquitin ligase CRL4CRBN to induce the ubiquitination and proteasomal degradation of specific zinc finger (ZF) proteins. While the core structural motif recognized by CRBN is characterized, it alone does not account for the full specificity of substrate recognition. To understand the impact of residues adjacent to the core motif, we constructed an extended ZF reporter library including all single ZFs and tandem ZF pairs in the human proteome totaling to 9,098 reporters from 1,655 ZF-containing proteins. We screened the activity of 29 glutarimide analogs against this ZF library leading to the identification and validation of compounds that collectively degrade 38 ZF reporters. High resolution cryo-electron microscopy and crystal structures of wild-type and mutant ZFs complexed with CRBN highlighted the significance of contacts outside the core ZF degron. We conducted systematic mutagenesis of both the ZFs and CRBN to investigate the role of individual amino acids and discovered that residues adjacent to the core ZF degron affect degradability, with single amino acid changes dictating drug specificity. Finally, we identified subtle chemical differences between glutarimide analogs that drastically broaden the target scope and redefine target selectivity. This study expands the scope of degradable ZF targets, including disease-driving transcription factors and provides a roadmap for the rational design of glutarimide analogs.

Project description:Glutarimide analogs, including thalidomide, redirect the E3 ubiquitin ligase CRL4CRBN to induce the ubiquitylation and proteasomal degradation of specific zinc finger (ZF) proteins. While the core structural motif recognized by CRBN is known, it alone does not account for the full specificity of substrate recognition. To understand the impact of residues adjacent to the core motif, we constructed a comprehensive ZF reporter library including all single ZFs and tandem ZF pairs in the human proteome totaling 9,097 reporters from 1,655 ZF-containing proteins. We performed a library-on-library screen of 29 glutarimide analogs against this ZF library identifying compounds that collectively degrade 38 ZF reporters. Cryo-electron microscopy and crystal structures of wild-type and mutant ZFs in complex with CRBN highlighted the significance of contacts outside the core ZF degron. We conducted systematic mutagenesis of both the ZFs and CRBN to investigate the role of individual amino acids and discovered that residues adjacent to the core ZF degron affect degradability, with single amino acid changes dictating drug specificity. The studies reveal subtle chemical differences between glutarimide analogs that significantly broaden the target scope and redefine target selectivity. This study catalogs the scope of degradable ZF targets, including disease-driving transcription factors, and defines modes of neosubstrate recruitment enabling the rational design of glutarimide analogs.

Project description:High-throughput diversification of protein-ligand surfaces to discover chemical inducers of proximity

Project description:Transcriptional regulatory proteins are frequent drivers of oncogenesis and common targets for drug discovery. The transcriptional co-activator, ENL, which binds to chromatin through an acetyllysine reader YEATS domain, is preferentially required for the survival and pathogenesis of acute leukemia. Small molecules that inhibit the ENL YEATS domain show anti-leukemia effects in preclinical models, which is thought to be caused by the downregulation of pro-leukemic ENL target genes. However, the transcriptional effects of ENL YEATS domain inhibitors have not been studied in models of intrinsic or acquired resistance and, therefore, the connection between proximal transcriptional effects and downstream anti-proliferative effects is poorly understood. To address this, we identified models of intrinsic and acquired resistance and used them to study the effects of ENL YEATS domain inhibitors. We first discovered that ENL YEATS domain inhibition produces similar transcriptional responses in naive models of sensitive and resistant leukemia. We then performed a CRISPR/Cas9-based genetic modifier screen and identified in-frame deletions of the essential transcriptional regulator, PAF1, that confer resistance to ENL YEATS domain inhibitors. Using isogenic models of PAF1-mediated resistance, we again found that the downregulation of ENL target genes is shared in both sensitive and resistant leukemia. Altogether, these data support the conclusion that the suppression of ENL target genes is not sufficient to explain the anti-leukemia effects of ENL antagonists.

Project description:ENL is required for expression of MLL1-target genes as well as the aberrant gene expression in MLL1-r leukemia. We investigated the gene expression changes after selective chemical knockout of ENL in leukemia cells.

Project description:practipractical access to the portimines and analogs thereof simplified the development of photoaffinity analogs, which were used in chemical proteomic experiments to identify a primary target of portimine A as the 60S ribosomal export protein NMD3cal access to the portimines and analogs thereof simplified the development of photoaffinity analogs, which were used in chemical proteomic experiments to identify a primary target of portimine A as the 60S ribosomal export protein NMD3

Project description:Cereblon (CRBN), a substrate receptor of the E3 ubiquitin ligase complex CRL4CRBN, is the target of the immunomodulatory drugs lenalidomide and pomalidomide. Recently, it was demonstrated that binding of these drugs to CRBN promotes the ubiquitination and subsequent degradation of two common substrates, transcription factors Aiolos and Ikaros. Here we report that the pleiotropic pathway modifier CC-122, a new chemical entity termed pleiotropic pathway modifier binds CRBN and promotes degradation of Aiolos and Ikaros in diffuse large B-cell lymphoma (DLBCL) and T cells in vitro, in vivo and in patients, resulting in both cell autonomous as well as immunostimulatory effects. In DLBCL cell lines, CC-122-induced degradation or shRNA mediated knockdown of Aiolos and Ikaros correlates with increased transcription of interferon stimulated genes (ISGs) independent of interferon α, β, γ production and/or secretion and results in apoptosis in both ABC and GCB-DLBCL cell lines. Our results provide mechanistic insight into the cell of origin independent anti-lymphoma activity of CC-122, in contrast to the ABC subtype selective activity of lenalidomide. Microarray analysis of the OCI-LY10 activated B-cell diffuse large B-cell lymphoma (ABC-DLBCL) cell line treated with the compound CC-122 for 18 hours

Project description:pSILAC mass spectrometry reveals ZFP91 as novel IMiD dependent substrate of the CRL4CRBN ligase

Project description:Chemical modulation of protein function enables a mechanistic understanding of biological circuits and represents the foundation of most medicines. However, despite major efforts over decades of research, around 80% of the human proteome still lack functional ligands. Chemical proteomics allowed the advancement of fragment-based ligand discovery (FBLD) towards cellular systems and emerged as a promising strategy to detect reversible fragment-protein interactions that can be furnished into bioactive chemical probes. Limitations in scale and throughput have, however, stymied the interpretation of the resulting ligandability maps, thus complicating the identification of specific and actionable fragment-protein interactions. Here, we report reversible, global ligandability maps for 435 structurally different fragments, collectively representing 6739 discrete interactions. We benchmark the dataset by showing that identified fragments can be advanced to active chemical probes. Integrating multi-layered ligandability portraits with artificial intelligence (AI) and machine learning (ML) enabled quantitative and qualitative predictions of fragment interactomes via chemically interpretable models. The resulting, interactive catalogue of fragment-protein interactions and predictive models is expected to expedite ligand discovery efforts in a community-wide fashion and should facilitate the pursuit of hitherto undrugged target proteins.