Project description:Targeted protein degradation is a groundbreaking modality in drug discovery ; however, further improvement of the degradation efficacy is demanded. Here, we identify small molecules that enhance the targeted degradation of the anticancer target BRD4 and related hard-to-degrade targets BRD2/3 induced by CRL2VHL- or CRL4CRBN -based PROTACs. The chemicals include inhibitors of cellular signaling pathways such as poly-ADP ribosylation (PARG inhibitor PDD00017273), unfolded protein response (PERK inhibitor GSK2606414), and protein stabilization (HSP90 inhibitor luminespib). Mechanistically, PARG inhibition promotes TRIP12-mediated K29/K48-linked branched ubiquitylation of BRD4 by facilitating chromatin dissociation of BRD4 and formation of the BRD4–PROTAC– CRL2VHL ternary complex; by contrast, HSP90 inhibition promotes BRD4 degradation after the ubiquitylation step. Consequently, these signal inhibitors sensitize cells to the PROTAC-induced apoptosis. Combining the treatment with these chemicals further increases the efficacy of a highly potent PROTAC, SIM1. We propose that various cell intrinsic signaling pathways spontaneously counteract chemically induced target degradation, which can be liberated by specific inhibitors.

Project description:MDM2 inhibitor remarkably induced biomineralization in hDPSCs but it remained the problem that p53 activation is insufficient due to MDM2-p53 autoregulatory feedback loop. To overcome the limitation of the MDM2 inhibitors, we applied proteolysis targeting chimera (PROTAC), a technology that degrades a protein of interest (POI) by intracellular ubiquitin-proteasome system. Hence, we propose a strategy to induce hard tissue regeneration by MDM2-targeting PROTAC technology. We selected Nutlin-3 of POI ligand among various MDM2 inhibitors based on the screening process, and the selected CRBN of E3 ligase ligand. The MDM2-PROTAC synthesis platform was designed by each ligand combination. By performing the degradation test for selected compounds, we evaluated the characteristics of the developed MDM2 PROTAC such as the maximal degradation concentration (DCmax), the half of maximal degradation concentration (DC50), and half-lifetime. To investigate gene expression profiling of MDM2-targeting small molecules, we conducted RNA-sequencing under MDM2 PROTAC and Nutlin-3 (POI ligand) treated conditions. We not only confirmed a robust effect on biomineralization by MDM2-targeting small molecules but also demonstrated the potent osteogenic differentiation ability of MDM2 PROTAC when compared to an MDM2 inhibitor. MDM2-PROTAC significantly increased mRNA levels of osteogenic differentiation marker genes. Also, the significant bone generation effect of MDM2 PROTAC was validated in an ovariectomy (OVX)-induced osteoporosis animal model. Through these results, it is expected that a new therapeutic modality for hard tissue regeneration will be possible, and the application range of the PROTAC system can be expanded.

Project description:In spite of gathering evidence that ubiquitylation can direct non-degradative outcomes, most investigations of ubiquitylation in T cells remain focused on degradation. Here we integrated proteomic and transcriptomic datasets to establish a framework for predicting degradative or non-degradative outcomes of ubiquitylation in primary CD4+ T cells. Di-glycine remnant proteomics revealed ubiquitylated proteins, while whole cell proteomic and transcriptomic data were used to predict whether ubiquitylated proteins showed evidence of degradation. Applying this analysis to ubiquitylated proteins with functions in TCR signaling led us to the prediction that early T cell activation promotes increased non-degradative ubiquitylation. Supporting this, we observed an increase in non-proteasome targeted K29, K33 and K63 polyubiquitin chains during T cell activation, while K48 chains appeared unchanged. This study reveals over 1,200 proteins that are ubiquitylated in primary CD4+ T cells and supports the relevance of non-proteasomally targeted ubiquitin chains in T cell signaling.

Project description:The PROTAC (proteolysis-targeting chimera) ARV-825 recruits bromodomain and extraterminal (BET) proteins to the E3 ubiquitin ligase cereblon, leading to degradation of BET proteins, including BRD4. Whereas the BET-protein inhibitor (BETi) OTX015 caused accumulation of BRD4, treatment with equimolar concentrations of ARV-825 caused sustained and profound depletion (>90%) of BRD4 and induced significantly more apoptosis in cultured and patient-derived (PD) CD34+ post-MPN sAML cells, while relatively sparing the CD34+ normal hematopoietic progenitor cells. RNA-Seq, Reversed Phase Protein Array and mass cytometry ‘CyTOF’ analyses demonstrated that ARV-825 caused greater perturbations in mRNA and protein expressions than OTX015 in sAML cells. Specifically, compared to OTX015, ARV-825 treatment caused more robust and sustained depletion of c-Myc, CDK4/6, JAK2, pSTAT3/5, PIM1 and Bcl-xL, while increasing the levels of p21 and p27. Compared to OTX015, PROTAC ARV-771 treatment caused greater reduction in leukemia burden and further improved survival of NSG mice engrafted with luciferase-expressing HEL92.1.7 cells. Co-treatment with ARV-825 and JAK inhibitor ruxolitinib was synergistically lethal against the established and PD-CD34+ sAML cells. Notably, ARV-825 induced high levels of apoptosis in the in vitro generated ruxolitinib-persister or ruxolitinib-resistant sAML cells. These findings strongly support the in vivo testing of the BRD4-PROTAC based combinations against post-MPN sAML.

Project description:BRD4 plays a major role in the transcription networks orchestrated by androgen receptor (AR) in castration resistant prostate cancer (CRPC) cells. Bromodomain and extraterminal protein (BET) inhibitors displace BRD4 protein from chromatin, resulting in the inhibition of oncogenic transcriptional programs. Several BET inhibitors (BETi) are currently being evaluated in clinical trials for a variety of malignancies, including CRPC. Here we describe a general mechanism of acquired resistance to BETi due to modulation of cellular pathways that are amenable to targeted therapies in CRPC cells. BETi resistant CRPC cells displayed cross resistance to a variety of BETi in the absence of gatekeeper mutations or persistent drug pump activation. Resistant cells exhibited reduced chromatin bound BRD4, and were less sensitive to Proteolysis Targeting Chimeric (PROTAC) -mediated degradation or genetic knockdown, suggesting a BRD4-independent transcription program. Transcriptomic analysis revealed reactivation of AR-signaling due to CDK9-mediated serine-81 phosphorylation of AR, with a consequent increase in sensitivity to CDK9 inhibitors and enzalutamide in BETi resistant cells. Additionally, increased DNA damage associated with PRC2-mediated transcriptional silencing of DNA damage response (DDR) genes was observed due to the loss of BRD4 from their proximal promoter regions in the resistant cells, leading to PARP inhibitor sensitivity. Collectively, our results identify the therapeutic limitation of BETi as a monotherapy in CRPC. However, data showing the reactivation of AR-signaling and increased DNA damage in the BETi resistant cells provide unique opportunities for combination therapies in managing CRPC.

Project description:Effect of PROTAC-mediated BRD4 degradation in acute myeloid leukemia

Project description:The BCL6 transcriptional repressor is a critical oncogene in diffuse large B-cell lymphomas (DLBCL). The specific BCL6 inhibitor RI-BPI potently kills DLBCL cells. We find that RI-BPI induces a particular gene expression signature in DLBCL. In order to identify classes of drugs that might synergize with RIBPI we examined the connectivity of this signature and found a strong association with HDAC and Hsp90 inhibitors. This was explained by the discovery that BCL6 directly represses the p300 lysine acetyltransferase and its co-factor BAT3. RI-BPI induced expression of p300 and BAT3, and p300 acetyltransferase activity, resulting in acetylation of p300 targets like p53 and Hsp90. As a consequence, RI-BPI could attenuate Hsp90 chaperone function, similar to the effect of Hsp90 and HDAC inhibitors. Induction of p300 and BAT3 was required for the anti-lymphoma effects of RI-BPI since specific blockade of either protein rescued DLBCL cells from the BCL6 inhibitor. RI-BPI synergistically killed DLBCL cells in combination with HDAC inhibitors (SAHA, TSA and VPA) and Hsp90 inhibitors (17-DMAG and PUH71). The combination of RI-BPI and SAHA, or RI-BPI and PU-H71 potently suppressed or even eradicated human DLBCL in mice. BCL6 repression of EP300 thus provides a basis for rational targeted combinatorial therapy for patients with DLBCL. Direct comparison of gene expression levels in DLBCL cell lines after 24hs of treatment with either a Bcl6 inhibitor peptide or control peptide

Project description:Neuroblastoma (NB) is the most common extracranial solid tumor of childhood, which is derived from primordial neural crest cells. dBET57, a new cereblon (CRBN) based inhibitor developed by PROTAC technology. It binds to the BET protein families BRD2, BRD3, and BRD4, which are recruited to the proteasome system for selective ubiquitination degradation. However, the function of dBET57 has not been assessed in NB models so far. In the present study, RNA-seq analysis was performed to explore the effect of dBET57 on NB cells.

Project description:Heat shock protein 90 (Hsp90) is an essential evolutionarily conserved molecular chaperone in eukaryotes. Cancer cells rely on Hsp90 to chaperone activated oncoproteins, and its involvement in numerous signaling pathways makes it an attractive target for drug development. Surprisingly, however, the impact of Hsp90 inhibitors on cancer cells is most commonly cytostatic, and efforts to enhance the anti-tumor activity of Hsp90 inhibitors in the clinic remain a significant challenge. In this study, we show that dual inhibition of Wee1 tyrosine kinase and Hsp90 causes prostate cancer cells to undergo apoptosis. Gene-expression profiling revealed that induction of the intrinsic apoptotic pathway by this drug combination coincided with transcriptional down-regulation of Survivin and Wee1, an outcome not seen in cells treated separately with either agent. At the translational level, expression of these two proteins as well as activated Akt was completely abrogated. Similar results were obtained in prostate cancer xenografts. These data establish a novel therapeutic strategy to enhance the efficacy of Hsp90 inhibitors in prostate cancer, and they provide a mechanistic rationale for stimulating the pro-apoptotic activity of Hsp90 inhibitors. In order to explore the mechanism underlying the enhanced cell death caused by Wee1 inhibitorII and 17-AAG combination, we performed microarray analysis using PC3 cells treated with Wee1 inhibitorII alone, 17-AAG alone, or the two drugs in combination. There are 12 samples in total. There are three experimental replicate. Samples 1, 5 and 9 are control (C) (untreated PC3- prostate cancer cells). Samples 2, 6, and 10 are cells treated with Wee1 inhibitor II (W). Samples 3, 7, and 11 are treated with 17-AAG (A), (an Hsp90 inhibitor). Samples 4, 8, and 12 are treated with both Wee1 inhibitorII and 17-AAG (WA). Samples 5 was removed from our analysis due to weak signal.

Project description:Target deconvolution of small molecule hits from phenotypic screens presents a major challenge. Illustrative of these are the many screens that have been conducted to find inhibitors for the Hedgehog (Hh) signaling pathway – a major developmental pathway with many implications in health and disease - with many hits but very few identified cellular targets. We here present a strategy for target identification based on Proteolysis-Targeting Chimeras (PROTACs), combined with label-free quantitative proteomics. We developed a PROTAC based on the downstream Hedgehog Pathway Inhibitor-1 (HPI-1), a phenotypic screen hit with unknown cellular target. Using our Hedgehog Pathway PROTAC (HPP) we identified and validated BET bromodomains to be the cellular targets of HPI-1. Furthermore, we found that HPP-9 has a unique mechanism of action as a long-acting Hh pathway inhibitor through prolonged BET bromodomain degradation. Collectively, we provide a powerful PROTAC-based approach for target deconvolution, that has answered the longstanding question of the cellular target of HPI-1 and yielded the first PROTAC that acts on the Hh pathway.