Project description:Aberrant activation of Hedgehog (Hh) signaling pathway plays important roles in both oncogenesis and targeted therapy of many cancers. The clinical application of FDA-approved Hh-targeted Smoothened inhibitor (SMOi) drugs is hindered due to the emergence of various primary or acquired drug resistance, indicating the need of novel anti-Hh therapies. Our previous studies demonstrate that epigenetic/transcriptional targeted therapies represent a promising direction for anti-Hh drug development. In this study, we identified CDK9 and CDK12, two transcription elongation regulators, as novel therapeutic targets for antagonizing the aberrant Hh pathway and overcoming SMOi resistance. CDK9 inhibition and CDK12 inhibition exhibited similarly potent anti-Hh activities when treating various SMOi responsive or resistant Hh-driven tumor models as previously reported BET inhibition or CDK7 inhibition. We also utilized SHH-subtype medulloblastoma (SHH-MB) as the representative Hh-driven cancer model to perform Super-enhancer (SE) analysis and elucidate the crucial roles of SE in Hh-driven oncogenesis and above-mentioned anti-Hh epigenetic/transcriptional targeted therapies. Furthermore, we identified IRS1, encoding a critical component and cytoplasmic adaptor protein of the IGF pathway, as an oncogenic Hh-driven SE target gene and effective therapeutic target of multiple Hh-driven tumor models, including the SMOi-resistant ones. Collectively, our study demonstrates that the SE-driven transcriptional dependencies represent promising therapeutic vulnerabilities for suppressing the aberrant Hh pathway and overcoming the SMOi resistance. As CDK9 inhibitor and IRS inhibitor drugs have already entered human clinical trials for cancer treatment, our study provides comprehensive preclinical support for expanding their trials to Hh-driven cancers in near future.

Project description:Resistance to clinically available targeted drugs has become a critical issue in hedgehog-driven cancer treatment. Our previous studies have demonstrated two epigenetic/transcriptional targeted therapeutic strategies, BET inhibition and CDK7 inhibition, could overcome both primary and acquired resistance to Smoothened inhibitor (SMOi) drugs, providing a promising direction for novel anti-hedgehog drug development. In this study, we performed CRISPR-Cas9 screening of epigenetic/transcriptional targeted sgRNA library in hedgehog-driven medulloblastoma (SHH-MB) cells and combined with tumor dataset analyses to identify other potential epigenetic/transcriptional targeted strategies for treating aberrant hedgehog pathway and overcoming SMOi-resistance. Our results demonstrated structure specific recognition protein 1 (SSRP1), a subunit of Facilitates Chromatin Transcription (FACT) complex, was a hedgehog-induced essential oncogene and therapeutic target of hedgehog-driven cancer. FACT inhibitor CBL0137, which has entered human clinical trials against cancer, could effectively suppress multiple mouse and human hedgehog-driven cancer models that are either SMOi-responsive or -resistant both in vitro and in vivo. Mechanistically, CBL0137 exerted its anti-hedgehog activity mainly through targeting the transcription of GLI1/2, which are core transcription factors of hedgehog pathway. ChIP-qPCR analyses further revealed SSRP1 could bind to the promoter regions of GLI1/2, while CBL0137 treatment substantially disrupted these interactions. Moreover, CBL0137 could work synergistically with BET inhibitor or CDK7 inhibitor on antagonizing aberrant hedgehog pathway and growth of either SMOi-responsive or -resistant hedgehog-driven cancer models. Taken together, our study identified FACT inhibition as another promising epigenetic/transcriptional targeted therapeutic strategy for treating hedgehog-driven cancer and overcoming SMOi-resistance.

Project description:We demonstrate that the loss of CDK12 protein or activity, unlike CDK9 or CDK7, significantly upregulates the expression of certain genes, including genes whose activation contributes to the anti-proliferative effects of CDK12 inhibition. In HER2+ breast cancer, a malignancy where CDK12 is almost invariably co-amplified with HER2, CDK12 inhibition drives up the expression of MYC, which is toxic to HER2+ cancer cells. This upregulation of c-myc largely mediates the killing effect of CDK12 inhibition. Therefore, we report a novel mode of regulation of gene expression via CDK12, which represents a promising target for cancer driven by HER2 gene amplification.

Project description:Comparison of gene expression changes in Ptch-deficient mouse medulloblastoma cell line SmoWT-MB upon treatment with SMOi GDC-0449 or BETi JQ1. The hypothesis is that they can both inhibit the expressions of Hh signaling target genes in this Hh-driven tumor cell line. Total RNA from JQ1 or GDC-0449 treated SmoWT-MB cells in comparison with DMSO treated cells

Project description:Comparison of gene expression changes in Ptch-deficient mouse medulloblastoma cell line SmoWT-MB upon treatment with SMOi GDC-0449 or BETi JQ1. The hypothesis is that they can both inhibit the expressions of Hh signaling target genes in this Hh-driven tumor cell line.

Project description:Here we describe the development of CKIα inhibitors, which co-target the transcriptional kinases CDK7 and CDK9, thereby augmenting CKIα-induced p53 activation and its anti-leukemic activity. Oncogene-driving super-enhancers (SEs) are highly sensitive to CDK7/9 inhibition. We identified multiple newly-gained SEs in primary mouse AML cells and demonstrate that the inhibitors abolish many SEs and preferentially suppress the transcription elongation of SE-driven oncogenes. We show that blocking CKIα together CDK7 and/or CDK9 synergistically stabilize p53, deprive leukemia cells of survival and proliferation-maintaining SE-driven oncogenes, and induce apoptosis.

Project description:Post-translational modifications of the transcription elongation complex provide mechanisms to fine-tune gene expression, yet their specific impacts on RNA polymerase II regulation remain difficult to ascertain. Here, in Schizosaccharomyces pombe, we examine the role of Cdk9, and related Mcs6/Cdk7 and Lsk1/Cdk12 kinases, on transcription at base-pair resolution with Precision Run-On sequencing (PRO-seq). Within a minute of Cdk9 inhibition, phosphorylation of Pol II-associated factor, Spt5 is undetectable. The effects of Cdk9 inhibition are more severe than inhibition of Cdk7 and Cdk12, resulting in a shift of Pol II towards the transcription start site (TSS). A time course of Cdk9 inhibition reveals that early transcribing Pol II can escape promoter-proximal regions, but with a severely reduced rate of only ~400 bp/min. Our results in fission yeast suggest the existence of a conserved global regulatory checkpoint that requires Cdk9 kinase activity.

Project description:RAC1P29S is the third most prevalent hotspot mutation in sun-exposed melanoma. RAC1 alterations in cancer are correlated with poor prognosis, resistance to standard chemotherapy, and insensitivity to targeted inhibitors. Although RAC1P29S mutations in melanoma and RAC1 alterations in several other cancers are increasingly evident, the RAC1-driven biological mechanisms contributing to tumorigenesis remain unclear. Lack of rigorous signaling analysis has prevented identification of alternative therapeutic targets for RAC1P29S-harboring melanomas. To investigate the RAC1P29S-driven effect on downstream molecular signaling pathways, we generated an inducible RAC1P29S expression melanocytic cell line and performed RNA-sequencing (RNA-seq) coupled with multiplexed kinase inhibitor beads and mass spectrometry (MIBs/MS) to establish enriched pathways from the genomic to proteomic level. Our proteogenomic analysis identified CDK9 as a potential new and specific target in RAC1P29S-mutant melanoma cells. In vitro, CDK9 inhibition impeded the proliferation of in RAC1P29S-mutant melanoma cells and increased surface expression of PD-L1 and MHC Class I proteins. In vivo, combining CDK9 inhibition with anti-PD-1 immune checkpoint blockade significantly inhibited tumor growth only in melanomas that expressed the RAC1P29S mutation. Collectively, these results establish CDK9 as a novel target in RAC1-driven melanoma that can further sensitize the tumor to anti-PD-1 immunotherapy.

Project description:RAC1P29S is the third most prevalent hotspot mutation in sun-exposed melanoma. RAC1 alterations in cancer are correlated with poor prognosis, resistance to standard chemotherapy, and insensitivity to targeted inhibitors. Although RAC1P29S mutations in melanoma and RAC1 alterations in several other cancers are increasingly evident, the RAC1-driven biological mechanisms contributing to tumorigenesis remain unclear. Lack of rigorous signaling analysis has prevented identification of alternative therapeutic targets for RAC1P29S-harboring melanomas. To investigate the RAC1P29S-driven effect on downstream molecular signaling pathways, we generated an inducible RAC1P29S expression melanocytic cell line and performed RNA-sequencing (RNA-seq) coupled with multiplexed kinase inhibitor beads and mass spectrometry (MIBs/MS) to establish enriched pathways from the genomic to proteomic level. Our proteogenomic analysis identified CDK9 as a potential new and specific target in RAC1P29S-mutant melanoma cells.In vitro, CDK9 inhibition impeded the proliferation of in RAC1P29S-mutant melanoma cells and increased surface expression of PD-L1 and MHC Class I proteins.In vivo, combining CDK9 inhibition with anti-PD-1 immune checkpoint blockade significantly inhibited tumor growthonly in melanomas that expressed the RAC1P29Smutation. Collectively, these results establish CDK9 as a novel target in RAC1-driven melanoma that can further sensitize the tumor to anti-PD-1 immunotherapy.

Project description:P-TEFb and CDK12 facilitate transcription elongation by RNA polymerase II and play prominent roles in cancer. Understanding their functional interplay could inform novel anti-cancer strategies. While inhibition of CDK12 downregulates unique sets of genes, eliciting genomic instability that is being exploited for novel therapies, little is known about the significance of transcriptional induction in CDK12-targeted cells. We show that inhibition of CDK12 in colon cancer-derived cells activates P-TEFb and induces genes of key cancer signaling pathways, including p53 and NF-kB. Mechanistically, cancer cells become exquisitely dependent on P-TEFb through activation of p53-dependent apoptosis and attenuation of NF-kB-dependent proliferation. Furthermore, we show that the DNA damage-responsive ATM kinase mediates these effects. While ATM is required for the synthetic lethality of CDK12 and P-TEFb co-targeting in p53-proficient cells, co-inhibition of ATM and CDK12 synergizes in decreasing viability of p53-deficient cells. Finally, pairwise targeting of CDK12, P-TEFb and transcription initiation kinase CDK7 stimulates p53-dependent apoptosis of cancer cell spheroids. We propose that the stimulation of Pol II pause release by P-TEFb at the signal-responsive genes underlies the dependence of CDK12-targeted cancer cells on P-TEFb. Together, our work provides a rationale for combinatorial targeting of CDK12 and P-TEFb or the induced oncogenic pathways in cancer.