Project description:Cyclin dependent kinase 9 (CDK9), a key regulator of transcriptional elongation, has long been considered a promising target for cancer therapy, particularly for cancers driven by transcriptional dysregulation. However, despite promising early clinical data in blood cancers using pan-CDK inhibitors that potently inhibit CDK9 such as Dinaciclib and Flavopiridol, no selective CDK9 inhibitors have been clinically approved. Here we show that a multi-targeted CDK inhibitor can be used to develop a selective CDK9 degrader exemplified by THAL-SNS-032, a hetero-bifunctional molecule composed of SNS-032, a CDK2,7,9 inhibitor conjugated to thalidomide, a small molecule binder of Cereblon. We demonstrate that THAL-SNS-032 can recruit the E3 ubiquitin ligase Cereblon to CDK9 and induce its proteasome-mediated degradation. Treatment of cells with low nanomolar concentrations of THAL-SNS-032 resulted in rapid and efficient CDK9 degradation but did not affect levels of other SNS-032 targets, including CDK2 and CDK7. Consistent with this selective degradation phenotype, transcriptional profiling of THAL-SNS-032 indicated that its transcriptional effects were more similar to that of a selective CDK9 inhibitor, NVP2, than that of the nonselective SNS-032 parent compound. Moreover, THAL-SNS-032, in contrast to traditional CDK9 inhibitors, retained potent pro-apoptotic activity even after compound removal from cells. This suggests that degradation of CDK9 leads to prolonged cytotoxic effects as compared to CDK9 inhibition. Thus, our findings suggest that thalidomide conjugation may be a promising strategy for converting multi-targeting inhibitors into selective degraders, and that the pharmacological effects of kinase degradation can be distinct from kinase inhibition.
Project description:Cyclin dependent kinase 9 (CDK9), a key regulator of transcriptional elongation, has long been considered a promising target for cancer therapy, particularly for cancers driven by transcriptional dysregulation. However, despite promising early clinical data in blood cancers using pan-CDK inhibitors that potently inhibit CDK9 such as Dinaciclib and Flavopiridol, no selective CDK9 inhibitors have been clinically approved. Here we show that a multi-targeted CDK inhibitor can be used to develop a selective CDK9 degrader exemplified by THAL-SNS-032, a hetero-bifunctional molecule composed of SNS-032, a CDK2,7,9 inhibitor conjugated to thalidomide, a small molecule binder of Cereblon. We demonstrate that THAL-SNS-032 can recruit the E3 ubiquitin ligase Cereblon to CDK9 and induce its proteasome-mediated degradation. Treatment of cells with low nanomolar concentrations of THAL-SNS-032 resulted in rapid and efficient CDK9 degradation but did not affect levels of other SNS-032 targets, including CDK2 and CDK7. Consistent with this selective degradation phenotype, transcriptional profiling of THAL-SNS-032 indicated that its transcriptional effects were more similar to that of a selective CDK9 inhibitor, NVP2, than that of the nonselective SNS-032 parent compound. Moreover, THAL-SNS-032, in contrast to traditional CDK9 inhibitors, retained potent pro-apoptotic activity even after compound removal from cells. This suggests that degradation of CDK9 leads to prolonged cytotoxic effects as compared to CDK9 inhibition. Thus, our findings suggest that thalidomide conjugation may be a promising strategy for converting multi-targeting inhibitors into selective degraders, and that the pharmacological effects of kinase degradation can be distinct from kinase inhibition.
Project description:Neuroblastoma (NB), the most common extracranial solid tumor of childhood, is responsible for approximately 15% of cancer-related mortality in children. Aberrant activation of cyclin-dependent kinases (CDKs) has been shown to contribute to tumor cell progression in many cancers including NB. Therefore, small molecule inhibitors of CDKs comprise a strategic option in cancer therapy. Here we show that a novel multiple-CDK inhibitor, dinaciclib (SCH727965, MK-7965), exhibits potent anti-proliferative effects on a panel of NB cell lines by blocking the activity of CDK2 and CDK9. Dinaciclib also significantly sensitized NB cell lines to the treatment of chemotherapeutic agents such as doxorubicin (Dox) and etoposide (VP-16). Furthermore, dinaciclib revealed in vivo antitumor efficacy in an orthotopic xenograft mouse model of two NB cell lines and blocked tumor development in the TH-MYCN transgenic NB mouse model. Taken together, this study suggests that CDK2 and CDK9 are potential therapeutic targets in NB and that abrogating CDK2 and CDK9 activity by small molecules like dinaciclib is a promising strategy and a treatment option for NB patients.
Project description:Molecular glue compounds induce protein-protein interactions that, in the context of a ubiquitin ligase, lead to protein degradation1. Unlike traditional enzyme inhibitors, these molecular glue degraders act substoichiometrically to catalyse the rapid depletion of previously inaccessible targets2. They are clinically effective and highly sought-after, but have thus far only been discovered serendipitously. Here, through systematically mining databases for correlations between the cytotoxicity of 4,518 clinical and preclinical small molecules and the expression levels of E3 ligase components across hundreds of human cancer cell lines3-5, we identify CR8-a cyclin-dependent kinase (CDK) inhibitor6-as a compound that acts as a molecular glue degrader. The CDK-bound form of CR8 has a solvent-exposed pyridyl moiety that induces the formation of a complex between CDK12-cyclin K and the CUL4 adaptor protein DDB1, bypassing the requirement for a substrate receptor and presenting cyclin K for ubiquitination and degradation. Our studies demonstrate that chemical alteration of surface-exposed moieties can confer gain-of-function glue properties to an inhibitor, and we propose this as a broader strategy through which target-binding molecules could be converted into molecular glues.
Project description:Objectives: Chordomas are slow-growing malignancies that commonly affect vital neurological structures. These neoplasms are highly resistant to current chemotherapeutic regimens and often recur after surgical intervention. Therefore, there is an urgent need to identify molecular targets and more robust drugs to improve chordoma patient outcomes. It is well accepted that cyclin-dependent protein kinase 9 (CDK9) has tumorigenic roles in various cancers; however, the expression and significance of CDK9 in chordoma remains unknown. Methods: Expression of CDK9 in chordoma cell lines and tumor tissues was examined by Western blot and immunohistochemistry (IHC). The correlation between CDK9 expression in patient tissues and clinical prognosis was analyzed. The functional roles of CDK9 in chordoma were investigated after the addition of small interfering RNA (siRNA) and CDK9 inhibitor (LDC000067). Cell growth and proliferation were assessed with MTT and clonogenic assays. The effect of CDK9 inhibition on chordoma cells was further evaluated with a three-dimensional (3D) cell culture model which mimics the in vivo environment. Results: CDK9 was expressed in both chordoma cell lines and chordoma tissues. High- expression of CDK9 correlated with recurrence and poor outcomes for chordoma patients. CDK9 silencing with siRNA decreased growth and proliferation of chordoma cells and lowered levels of Mcl-1 and RNA polymerase II (RNAP II) phosphorylation. Pharmacological inhibition of CDK9 with the small molecular inhibitor LDC000067 reduced cell growth, supported apoptosis, suppressed cell colony formation in a clonogenic assay, and decreased spheroid growth in 3D culture. Conclusion: We demonstrate that CDK9 expression in chordoma correlates with patient outcome, and, when inhibited, chordoma cell growth and proliferation significantly decreases. Taken together, these results support CDK9 as an emerging potential target in chordoma therapy.
Project description:Overexpression of PAK1, a druggable kinase, is common in several malignancies, and inhibition of PAK1 by small molecules has been shown to impede the growth and survival of such cells. Potent inhibitors of PAKs 1-3 have been described, but clinical development has been hindered by recent findings that PAK2 function is required for normal cardiovascular function in adult mice. A unique allosteric PAK1-selective inhibitor, NVS-PAK1-1, provides a potential path forward, but has modest potency. Here, we report the development of BJG-05-039, a PAK1-selective degrader consisting of NVS-PAK1-1 conjugated to lenalidomide, a recruiter of the E3 ubiquitin ligase substrate adaptor Cereblon. BJG-05-039 induced selective degradation of PAK1 and displayed enhanced anti-proliferative effects relative to its parent compound in PAK1-dependent, but not PAK2-dependent, cell lines. Our findings suggest that selective PAK1 degradation may confer more potent pharmacological effects compared with catalytic inhibition and highlight the potential advantages of PAK1-targeted degradation.
Project description:Targeted protein degradation is a powerful induced-proximity tool to control cellular protein concentrations using small molecules. However, the design of selective degraders remains empirical. Among bromodomain and extra-terminal (BET) family proteins, BRD4 is the primary therapeutic target over family members BRD2/3/T. Existing strategies for selective BRD4 degradation use pan-BET inhibitors optimized for BRD4:E3 ubiquitin ligase (E3) ternary complex formation, but these result in residual inhibition of undegraded BET-bromodomains by the pan-BET ligand, obscuring BRD4-degradation phenotypes. Using our selective inhibitor of the first BRD4 bromodomain, iBRD4-BD1 (IC50 = 12 nM, 23- to 6200-fold intra-BET selectivity), we developed dBRD4-BD1 to selectively degrade BRD4 (DC50 = 280 nM). Notably, dBRD4-BD1 upregulates BRD2/3, a result not observed with degraders using pan-BET ligands. Designing BRD4 selectivity up front enables analysis of BRD4 biology without wider BET-inhibition and simplifies designing BRD4-selective heterobifunctional molecules, such as degraders with new E3 recruiting ligands or for additional probes beyond degraders.