Project description:Multiple myeloma (MM) remains a challenging hematological malignancy demanding innovative therapeutic strategies. Targeting MYC, the notorious yet traditionally undruggable oncogene, presents an appealing avenue. Here, using a genome-scale CRISPR/Cas9 screen, we identify the WNK lysine deficient protein kinase 1 (WNK1) as a regulator of MYC expression in MM cells. Genetic and pharmacological inhibition of WNK1 reduces MYC expression, and further, disrupts the MYC-dependent transcriptional program. Mechanistically, WNK1 inhibition attenuates the activity of the immunoglobulin heavy chain (IgH) enhancer, thus reducing MYC transcription when this locus is translocated near the MYC locus. WNK1 inhibition profoundly impacts MM cell behaviors, leading to growth inhibition, cell cycle arrest, senescence, and apoptosis. Importantly, the WNK inhibitor WNK463 synergizes with various anti-MM compounds, and inhibits MM growth in primary patient samples as well as xenograft mouse models. Collectively, our study uncovers WNK1 as a potential therapeutic target in MM.

Project description:Oleil hydroxytyrosol (HTOL) exerts anti-myeloma activity by antagonizing key survival pathways in malignant plasma cells

Project description:Multiple myeloma (MM) cells are addicted to MYC and its direct transactivation target IRF4 for proliferation and survival. MYC and IRF4 are still considered “undruggable” as the majority of small molecule inhibitors suffers from low potency, suboptimal pharmacokinetic properties and undesirable off-target effects. Indirect inhibition of MYC/IRF4 emerges as a therapeutic vulnerability in MM. Here, we uncover an unappreciated tumor suppressive role of C-terminal Binding Protein 2 (CTBP2) in MM via strong inhibition of the MYC-IRF4 axis. In contrast to epithelial cancers, CTBP2 is frequently downregulated in MM, in association with shortened survival, hyperproliferative features and adverse clinical outcomes. Restoration of CTBP2 exhibited potent anti-tumor effects against MM in vitro and in vivo, with marked repression of MYC-IRF4 network genes. Mechanistically, CTBP2 impeded transcription of MYC and IRF4 by histone H3 lysine 27 deacetylation (H3K27ac), and indirectly via activation of MYC repressor IFIT3. In addition, activation of interferon gene signature by CTBP2 suggested its concomitant immunomodulatory role in MM. Epigenetic studies revealed contribution of polycomb-mediated silencing and DNA methylation to CTBP2 inactivation in MM. Notably, inhibitors of Enhance of zeste homolog 2 (EZH2), histone deacetylase (HDACs) and DNA methyltransferase (DNMTs) currently under evaluation in clinical trials were effective in restoring CTBP2 expression in MM. Our findings indicated that loss of CTBP2 plays an essential role in myelomagenesis and decipher an additional mechanistic link on MYC-IRF4 dysregulation in MM. We envision that identification of novel critical regulators would facilitate the development of selective and effective approaches for treating this MYC/IRF4-addicted malignancy.

Project description:Deubiquitylases (DUBs) remove ubiquitin from proteins. In the context of cancer, their inhibition can induce the degradation of oncoproteins, that may otherwise be “undruggable”. Multiple myeloma (MM) is the second most common hematological malignancy with poor outcome and high sensitivity towards ubiquitin-proteasome-system (UPS) inhibitory therapies. However, the role of DUBs in MM pathophysiology and therapy has remained elusive. Starting from genetic screening for DUB dependencies in MM, we here identify OTUD6B as a central vulnerability in MM that drives the G1/S cell cycle transition by means of deubiquitylating and stabilizing LIN28B subsequent to LIN28B phosphorylation. LIN28B regulates miRNA biogenesis and exerts high expression in embryonic stem cells that becomes re-established in certain tumors, including MM. Binding of LIN28B at G1/S activates OTUD6B, which otherwise remains in a catalytically inactive state. As a consequence, stabilized LIN28B drives MYC expression via inhibition of let7 microRNAs, which in turn allows for a rapid transition of MM cells from G1 to S phase. Analyses of primary MM patient samples reveal a positive correlation of OTUDB6B expression with poor outcome, high MYC expression and MYC target gene induction, suggesting that high MYC levels in MM result from an activation of the OTUD6B-LIN28B nexus. Together, we here specify phosphorylation and cell cycle-dependent substrate binding as a means by which OTUD6B becomes activated to drive the G1/S transition via the LIN28B-MYC axis and nominate OTUD6B and LIN28B as actionable vulnerabilities in MM.

Project description:Multiple Myeloma (MM) is a frequently incurable hematological cancer in which over activity of MYC plays a central role, notably through upregulation of ribosome biogenesis and translation. To better understand the oncogenic program driven by MYC and investigate its potential as a therapeutic target, we screened a chemically diverse small molecule library for anti-MM activity. The most potent hits identified were rocaglate-scaffold inhibitors of translation initiation. Expression profiling of MM cells revealed reversion of the oncogenic MYC-driven transcriptional program by CMLD010509, our most promising rocaglate. Proteome-wide, reversion correlated with selective depletion of short-lived proteins key to MM growth and survival, most notably MYC, MDM2, CCND1, MAF and MCL-1. The efficacy of CMLD010509 in mouse models of MM confirmed the therapeutic relevance of these findings in vivo and supports the feasibility of targeting the oncogenic MYC-driven translation program in MM with rocaglates.

Project description:MYC is an oncoprotein transcription factor that is overexpressed in the majority cancers. Although MYC itself is considered undruggable, it may be possible to inhibit MYC by targeting the co-factors it uses to drive oncogenic gene expression patterns. Here, we use loss- and gain- of function approaches to interrogate how one MYC co-factor—Host Cell Factor (HCF)-1—contributes to MYC activity in a Burkitt lymphoma setting. We identify high-confidence direct targets of the MYC–HCF-1 interaction that are regulated through a recruitment-independent mechanism, including genes that control mitochondrial function and rate-limiting steps for ribosome biogenesis and translation. We describe how these gene expression events impact cell growth and metabolism, and demonstrate that the MYC–HCF-1 interaction is essential for tumor maintenance in vivo. This work highlights the MYC–HCF-1 interaction as a focal point for development of novel anti-cancer therapies.

Project description:Galectin-1 (Gal-1) is a lectin, involved in several processes related to cancer, including immunosuppression, angiogenesis, hypoxia, and metastases. Actually, the Gal-1 expression profile in multiple myeloma (MM) and its pathophysiological role in MM–induced angiogenesis and tumoral growth is unknown. Firstly, we found that Gal-1 was expressed by malignant plasma cells in MM patients and that its expression was up-regulated upon hypoxic treatment (1% of O2). Moreover the stable knock-down of Hypoxia Inducible Factor-1α (HIF-1α) in MM cells significantly downregulated Gal-1 expression. Thereafter, we performed Gal-1 inhibition by lentivirus shRNA anti-Gal-1 in human myeloma cell lines (HMCLs) showing that its suppression did not affect cell proliferation and survival but modified their transcriptional profiles either in hypoxia or hypoxia condition. Interestingly pro-angiogenic genes including MMP9 and CCL2 were downregulated and those anti-angiogenic SEMA3A and CXCL10 were up-regulated by Gal-1 inhibition in MM cells. Data were also validated by Real time PCR and at protein level. Consistently we found that Gal-1 suppression in MM cells significantly decreased their pro-angiogenic proprieties by an in vitro assay. These evidences were confirmed in mice injected either subcutaneously or intratibially with HMCLs carrying a stable infection with shRNA anti-inhibition of Gal-1 or with the control vector cell line. Gal-1 suppression in both models showed a significant reduction in the tumoral burden and microvascular density compared to the control mice. Moreover, Gal-1 suppression induced smaller lytic lesions on x-ray in the intratibially model. Overall, our data indicate that Gal-1 is a new potential therapeutic target in MM.

Project description:MYC is an oncoprotein transcription factor that is overexpressed in the majority cancers. Although MYC itself is considered undruggable, it may be possible to inhibit MYC by targeting the co-factors it uses to drive oncogenic gene expression patterns. Here, we use loss- and gain- of function approaches to interrogate how one MYC co-factor—Host Cell Factor (HCF)-1—contributes to MYC activity in a Burkitt lymphoma setting. We identify high-confidence direct targets of the MYC–HCF-1 interaction that are regulated through a recruitment-independent mechanism, including genes that control mitochondrial function and rate-limiting steps for ribosome biogenesis and translation. We describe how these gene expression events impact cell growth and metabolism, and demonstrate that the MYC–HCF-1 interaction is essential for tumor maintenance in vivo. This work highlights the MYC–HCF-1 interaction as a focal point for development of novel anti-cancer therapies.

Project description:Recent studies have highlighted the oncogenic roles of KDM5A; however, its molecular mechanism has not been fully delineated. Here we identifies KDM5A as a transcriptional activator of MYC target genes in multiple myeloma (MM). Genetic ablation of KDM5A or pharmacologic inhibition of KDM5 by novel inhibitor JQKD82 impairs MM cell growth. Gene expression profile reveals that JQKD82 decreases expression of MYC targets. Expression of MYC targets is similarly downregulated by KDM5A depletion, but little affected by KDM5B knockdown. Mechanistically, KDM5A co-localizes with MYC across the genome, and KDM5A and MYC coordinately promote MYC target gene transcription. The treatment with JQKD82 reduces phosphorylation level of RNA polymerase II (RNAPII), resulting in RNAPII pausing, accompanied by hyper-H3K4me3 status at the MYC loci. Finally, we shows that JQKD82 exerts anti-MM activity and prolongs overall survival in vivo mouse xenograft models. Our results delineate KDM5A function that reinforces MYC transcriptional program, and identify KDM5A as a potential therapeutic target in MM.

Project description:Recent studies have highlighted the oncogenic roles of KDM5A; however, its molecular mechanism has not been fully delineated. Here we identifies KDM5A as a transcriptional activator of MYC target genes in multiple myeloma (MM). Genetic ablation of KDM5A or pharmacologic inhibition of KDM5 by novel inhibitor JQKD82 impairs MM cell growth. Gene expression profile reveals that JQKD82 decreases expression of MYC targets. Expression of MYC targets is similarly downregulated by KDM5A depletion, but little affected by KDM5B knockdown. Mechanistically, KDM5A co-localizes with MYC across the genome, and KDM5A and MYC coordinately promote MYC target gene transcription. The treatment with JQKD82 reduces phosphorylation level of RNA polymerase II (RNAPII), resulting in RNAPII pausing, accompanied by hyper-H3K4me3 status at the MYC loci. Finally, we shows that JQKD82 exerts anti-MM activity and prolongs overall survival in vivo mouse xenograft models. Our results delineate KDM5A function that reinforces MYC transcriptional program, and identify KDM5A as a potential therapeutic target in MM.