Project description:E3 ubiquitin ligases of the Cullin RING Ligase (CRL) family assemble into multiprotein complexes to diversify substrate adaptors and ensure selectivity in substrate engagement for degradation. Here we show a novel mechanism whereby mutations in substrate adaptors can drive neo-substrate degradation in cancer. KBTBD4 is a CRL3 substrate adaptor harbouring recurrent indel mutations in a subset of non-WNT/non-SHH medulloblastomas. We show that these mutations, arising in the substrate recognition domain of KBTBD4, promote the recruitment and ubiquitylation of the REST Corepressor (CoREST), which forms a complex to modulate chromatin accessibility and transcriptional programmes. We observe that this neomorphic activity of KBTBD4 mutants induces changes in epigenetic markers and significant alterations in transcription, diverting normal cellular programmes towards increased stemness. These results highlight mutation-driven neomorphic E3 ligase activity as a previously unrecognised mechanism in tumorigenesis, with implications for medulloblastoma pathogenesis and treatment.

Project description:Testis-restricted melanoma antigen (MAGE) proteins are frequently hijacked in cancer and play a critical role in tumorigenesis. MAGEs assemble with E3 ubiquitin ligases and function as substrate adaptors that direct the ubiquitination of novel targets, including key tumor suppressors. However, how MAGEs recognize their targets is unknown and has impeded development of MAGE-directed therapeutics. Here, we report the structural basis for substrate recognition by MAGE ubiquitin ligases. Biochemical analysis of the degron motif recognized by MAGE-A11 and the crystal structure of MAGE-A11 bound to the PCF11 substrate uncovered a conserved substrate binding cleft (SBC) in MAGEs. Mutation of the SBC disrupted substrate recognition by MAGEs and blocked MAGE-A11 oncogenic activity. A chemical screen for inhibitors of MAGE-A11:substrate interaction identified 4-aminoquniolines as potent inhibitors of MAGE-A11 that show selective cytotoxicity. These findings provide important insights into the large family of MAGE ubiquitin ligases and identify approaches for development of cancer-specific therapeutics.

Project description:PRMT5 is an essential arginine methyltransferase and a therapeutic target in MTAP null cancers. PRMT5 utilizes adaptor proteins for substrate recruitment through a previously undefined mechanism. Here, we identify an evolutionarily conserved peptide sequence shared among the three known substrate adaptors (CLNS1A, RIOK1 and COPR5) and show it is necessary and sufficient for interaction with PRMT5. We demonstrate that PRMT5 uses modular adaptor proteins containing a common binding motif for substrate recruitment, comparable to other enzyme classes such as kinases and E3 ligases. We structurally resolve the interface with PRMT5 and show via genetic perturbation that it is required for methylation of adaptor-recruited substrates including the spliceosome, histones, and ribosome assembly complexes. Further, disruption of this site affects Sm spliceosome stability and activity, leading to intron retention. Genetic disruption of the PRMT5-substrate adaptor interface leads to a hypomorphic decrease in growth of MTAP null tumor cells in vitro and in vivo, and is thus a novel site for development of therapeutic inhibitors of PRMT5.

Project description:E3 ubiquitin ligases of the Cullin RING Ligase (CRL) family assemble into multiprotein complexes to diversify substrate adaptors and ensure selectivity in substrate engagement for degradation. Here we show a novel mechanism whereby mutations in substrate adaptors can drive neo-substrate degradation in cancer. KBTBD4 is a CRL3 substrate adaptor harbouring recurrent indel mutations in a subset of non-WNT/non-SHH medulloblastomas. We show that these mutations, arising in the substrate recognition domain of KBTBD4, promote the recruitment and ubiquitylation of the REST Corepressor (CoREST), which forms a complex to modulate chromatin accessibility and transcriptional programmes. We observe that this neomorphic activity of KBTBD4 mutants induces changes in epigenetic markers and significant alterations in transcription, diverting normal cellular programmes towards increased stemness. These results highlight mutation-driven neomorphic E3 ligase activity as a previously unrecognised mechanism in tumorigenesis, with implications for medulloblastoma pathogenesis and treatment.

Project description:Cullin-RING finger Ligases (CRLs) represent the largest family of E3 ubiquitin ligases and are responsible for ubiquitination of ~20% of cellular proteins degraded through the proteasome, catalyzing the transfer of E2-loaded ubiquitin to a substrate. Eight Cullins were described in vertebrates and among them, CUL4 associates with DDB1 acting as an adaptor to form the CUL4-DDB1 ubiquitin ligase complex, involved in protein ubiquitination and regulation of many cellular processes. The specificity of CUL4-DDB1 is mediated by substrate recognition adaptors named DDB1/CUL4 associated factors (DCAFs), which are characterized by the presence of a short structural motif of approximately 40 amino acids terminating in a tryptophan (W)-aspartic acid (D) dipeptide, the WD40 domain. Using different approaches (bioinformatics/structural analyses), independent studies suggested at least 60 different WD40 containing proteins that could act as adaptors for the DDB1/CUL4 complex. In this study, we aimed to validate the DCAFs based on their interaction with DDB1 and to define new partners and potential substrates of each DCAF using affinity purification followed by mass spectrometry. Using BioID and AP-MS approaches, we confirmed seven WDR40 protein that can be considered as DCAF with a high confidence level. Because identification of protein substrates of E3-ubiquitin ligases is not always guaranteed by identifying protein interactions, changes in protein stability and protein degradation was measured by pulse-SILAC to identify the protein substrates targeted for proteasomal degradation by each DCAFs. In conclusion, this work provides new insights into the roles of DCAFs as substrate adaptors for the DDB1-CUL4 complex, identifies the proteins targeting and the cellular processes that are involved.

Project description:E3 ubiquitin ligases (E3s) confer specificity of protein degradation through the recognition of specific target substrates for ubiquitination and subsequent degradation, making E3s attractive candidates for drug development. There are over 600 annotated E3s in the human genome, yet the vast majority have no known substrate proteins, due in part to the limited scalability of methods to evaluate the vast number of potential E3-substrate interactions. To address this, we developed COMET (Combinatorial Mapping of E3 Targets), a combinatorial framework that can test the role of many specific E3s in regulating the abundance of many specific substrates, within the context of a single experiment. As a proof-of-concept, we applied COMET to identify specific E3 subunits of the SCF ubiquitin ligase complex that mediate the degradation of target substrates, including short-lived transcription factors (TFs). Our data suggest that many E3-substrate relationships are complex rather than simple 1:1 associations. Further, we provide computational models of E3-substrate interactions from our screen. Looking forward, we anticipate that COMET can be further scaled to enable comprehensive mapping of regulators of protein stability to their target substrates

Project description:Targeted protein degradation is a novel pharmacology established by drugs that recruit target proteins to E3 ubiquitin ligases. Based on the structure of the degrader and the target, different E3 interfaces are critically involved, thus forming defined "functional hotspots". Understanding disruptive mutations in functional hotspots informs on the architecture of the assembly, and highlights residues susceptible to acquire resistance phenotypes. Here, we employ haploid genetics to show that hotspot mutations cluster in substrate receptors of hijacked ligases, where mutation type and frequency correlate with gene essentiality. A Hybrid capture assay reveals resistance-conferring mutations after degrader treatment. 29 putative target genes were selected to be sequenced. Target gene enrichment from gDNA of treated cells was performed, followed by amplification and sequencing to identify mutations.

Project description:The Jasmonate pathway regulators MYC2, MYC3 and MYC4 are central nodes in plant signaling networks integrating environmental and developmental signals to fine-tune jasmonate defenses and plant growth. Hence, their activity needs to be tightly regulated in order to optimize plant fitness. Among the increasing number of mechanisms regulating MYCs activity, protein stability is arising as a major player. However, how the levels of MYCs proteins are modulated is still poorly understood. Here, we report that MYC2, MYC3 and MYC4 are targets of BPM proteins, which act as substrate adaptors of CUL3-based E3 ubiquitin ligases. Reduction-of-function of CUL3BPM in amiR-bpm lines, bpm235 triple mutants and cul3ab double mutants enhances MYC2 and MYC3 stability and accumulation, and potentiates plant responses to JA such as root-growth inhibition, and MYC-regulated gene expression. BPM3 protein is stabilized by JA, suggesting a new negative feed-back regulatory mechanism to control MYCs activity. Our results uncover a new layer for JA-pathway regulation by CUL3BPM–mediated degradation of MYC TFs.

Project description:The Jasmonate pathway regulators MYC2, MYC3 and MYC4 are central nodes in plant signaling networks integrating environmental and developmental signals to fine-tune jasmonate defenses and plant growth. Hence, their activity needs to be tightly regulated in order to optimize plant fitness. Among the increasing number of mechanisms regulating MYCs activity, protein stability is arising as a major player. However, how the levels of MYCs proteins are modulated is still poorly understood. Here, we report that MYC2, MYC3 and MYC4 are targets of BPM proteins, which act as substrate adaptors of CUL3-based E3 ubiquitin ligases. Reduction-of-function of CUL3BPM in amiR-bpm lines, bpm235 triple mutants and cul3ab double mutants enhances MYC2 and MYC3 stability and accumulation, and potentiates plant responses to JA such as root-growth inhibition, and MYC-regulated gene expression. BPM3 protein is stabilized by JA, suggesting a new negative feed-back regulatory mechanism to control MYCs activity. Our results uncover a new layer for JA-pathway regulation by CUL3BPM–mediated degradation of MYC TFs.

Project description:Cullin-RING finger ligases (CRLs) represent the largest family of ubiquitin ligases. They are responsible for the ubiquitination of ~20% of cellular proteins degraded through the proteasome, by catalyzing the transfer of E2-loaded ubiquitin to a substrate. Seven Cullins are described in vertebrates. Among them, CUL4 associates with DDB1 to form the CUL4-DDB1 ubiquitin ligase complex, which is involved in protein ubiquitination and in the regulation of many cellular processes. Substrate recognition adaptors named DDB1/CUL4 associated factors (DCAF) mediate the specificity of CUL4-DDB1 and have a short structural motif of approximately forty amino acids terminating in a tryptophan (W)-aspartic acid (D) dipeptide, called the WD40 domain. Using different approaches (bioinformatics/structural analyses), independent studies suggested that at least sixty WD40-containing proteins could act as adaptors for the DDB1/CUL4 complex. To better define this association and classification, the interaction of each DCAFs with DDB1 was determined, and new partners and potential substrates were identified. Using BioID and AP-MS approaches, we demonstrated that seven WD40 proteins can be considered DCAFs with a high confidence level. Identifying protein interactions does not always lead to identifying protein substrates for E3-ubiquitin ligases, so we measured changes in protein stability or degradation by pulse-SILAC to identify changes in protein degradation following the expression of each DCAF. In conclusion, these results provide new insights into the roles of DCAFs in regulating the activity of the DDB1-CUL4 complex, in protein targeting, and characterized the cellular processes involved