Project description:In this study we tested if the transcriptional activity of circadian transcription factors, BMAL1 and CLOCK, can be repressed by small molecules in triple negative breast cancer cells. We validated that CRY inhibitors and proteasome inhibitors synergize and can recapitulate the phenotype of genetic knockdown of BMAL1 and CLOCK. To investigate the potential mechanism of the effect of this drug combination, we performed RNA sequencing analysis on cells treated with either single drug or drug combination at different time points.

Project description:mTOR is a central regulator of mammalian metabolism and physiology. Aberrant hyperactivation of this pathway promotes tumor growth and metastasis and drives tumor resistance to chemotherapy and cancer drugs, making mTOR an attractive cancer therapeutic target. mTOR inhibitors have been approved to treat cancer, however, the basis for drug sensitivity remains poorly understood. Here, whole exome sequencing of three chromophobe renal cell carcinoma (chRCC) patients with exceptional mTOR inhibitor sensitivity, uncovered USP9X deubiquitinase as the only mutated gene shared by the tumors. The clonal characteristics of the mutations, revealed by studying multiple patients’ primary and metastatic samples along the years, together with the low USP9X mutation rate in unselected chRCC series, reinforced a causal link between USP9X and mTOR inhibitor sensitivity. Rapamycin treatment of USP9X depleted HeLa and renal cancer 786-O cells and the pharmacological inhibition of USP9X, confirmed a crucial role of this protein in the patients’ sensitivity to mTOR inhibition. As no direct effect of USP9X in mTORC1 was detected, we performed ubiquitylome analyses that identified p62 as a direct USP9X target. Increased p62 ubiquitination and an augmented rapamycin effect upon bortezomib treatment, together with p62 and LC3 immunofluorescence assays, suggested that dysregulated autophagy in USP9X depleted cells can synergize with mTOR inhibitors. In summary, here we show that USP9X constitutes a potential novel marker of sensitivity to mTOR inhibitors in chRCC patients and represents a clinically exploitable strategy that could increase sensitivity to these drugs

Project description:Proteasome inhibitors, such as bortezomib and carfilzomib, have shown efficacy in anti-cancer therapy in hematological diseases but not in solid cancers. Here, we found that liposarcomas (LPS) are susceptible to proteasome inhibition, and identified drugs that synergize with carfilzomib, such as selinexor, an inhibitor of XPO1-mediated nuclear export. Through quantitative nuclear protein profiling and phospho-kinase arrays, we identified potential mode of actions of this combination, including interference with ribosome biogenesis and inhibition of pro-survival kinase PRAS40. Furthermore, by assessing global protein levels changes, FADS2, a key enzyme regulating fatty acids synthesis, was found down-regulated after proteasome inhibition. Interestingly, SC26196, an inhibitor of FADS2, synergized with carfilzomib. Finally, to identify further combinational options, we performed high-throughput drug screening and uncovered novel drug interactions with carfilzomib. For instance, cyclosporin A, a known immunosuppressive agent, enhanced carfilzomib’s efficacy in vitro and in vivo. Altogether, these results demonstrate that carfilzomib and its combinations could be repurposed for LPS clinical management.

Project description:Proteasome inhibitors, such as bortezomib and carfilzomib, have shown efficacy in anti-cancer therapy in hematological diseases but not in solid cancers. Here, we found that liposarcomas (LPS) are susceptible to proteasome inhibition, and identified drugs that synergize with carfilzomib, such as selinexor, an inhibitor of XPO1-mediated nuclear export. Through quantitative nuclear protein profiling and phospho-kinase arrays, we identified potential mode of actions of this combination, including interference with ribosome biogenesis and inhibition of pro-survival kinase PRAS40. Furthermore, by assessing global protein levels changes, FADS2, a key enzyme regulating fatty acids synthesis, was found down-regulated after proteasome inhibition. Interestingly, SC26196, an inhibitor of FADS2, synergized with carfilzomib. Finally, to identify further combinational options, we performed high-throughput drug screening and uncovered novel drug interactions with carfilzomib. For instance, cyclosporin A, a known immunosuppressive agent, enhanced carfilzomib’s efficacy in vitro and in vivo. Altogether, these results demonstrate that carfilzomib and its combinations could be repurposed for LPS clinical management.

Project description:In this study, we characterize significant molecular pathways activated in the blisters that form in EBS and employ a systematic drug repositioning screen to identify promising repositionable drugs for EBS. We implicate the PI3K/AKT/mTOR pathway as central in the EBS disease pathway and further validate our computational repositioning analysis by presenting clinical outcomes of two EBS patients treated with mTOR inhibitors.

Project description:There is an unmet clinical need to develop novel strategies to overcome resistance to tyrosine kinase inhibitors (TKIs) in patients with oncogene-driven lung adenocarcinoma (LUAD). Statins is a class of drugs that act as competitive inhibitors of 3-hydroxy-3-methyl-glutaryl-CoA reductase (HMGCR). The objective of this study was to determine if simvastatin could overcome TKI resistance using the vivo LUAD models. Mice implanted with patient-derived xenografts (PDXs) from osmertinib-resistant LUAD were treated with simvastatin, either alone or in combination with osmertinib. Tumors were assessed by RNA sequencing. RNA sequencing identified the proliferation, migration, and invasion-related genes (such as PI3K/Akt/mTOR, YAP/TAZ, focal adhesion, extracellular matrix receptor), proteasome-related genes, and integrin (α3β1, αvβ3) signaling pathways are significantly changed in these PDX tumors treated with simvastatin and the combo therapy.

Project description:We found that GSCs were highly sensitive to proteasome inhibition due to an underlying dependency on an increased protein synthesis rate, and loss of autophagy, associated with PTEN loss and activation of the PI3K/mTOR pathway. In contrast, combinatory inhibition of autophagy and the proteasome, resulted in enhanced cytotoxicity specifically in GSCs that did express PTEN. Finally, proteasome inhibition specifically increased cell death markers in 3D glioblastoma organoids, suppressed tumor growth, and increased survival of mice orthotopically engrafted with GSCs. As perturbations of the PI3K/mTOR pathway occur in nearly 50% of GBMs, these findings suggest that a significant fraction of these tumors could be vulnerable to proteasome inhibition.

Project description:Hsp70 inhibition affects many signaling pathways. We established how these effects are translated into changes in gene expression. Hsp70 is a promising anti-cancer target, and several inhibitors of Hsp70 have been recently developed. Interest to Hsp70 inhibitors as drug prototypes is, however, somewhat hampered by potential similarity of their physiological effects to effects of already well-developed Hsp90 inhibitors. JG-98 series of inhibitors is unique in its ability to target an allosteric site in the ATPase domain of Hsp70, which disrupts its interaction with a co-chaperone Bag3 and affects a variety of signaling pathways important for cancer development and survival. Here, we used the Broad Institute Connectivity Map platform to evaluate physiological effects of JG-98, and found that these effects are dissimilar from effects of Hsp90 inhibitors, thus justifying further development of this compound series. Further, using gene expression data and ActivSignal IPAD platform, we identified pathways modulated by JG-98. Some of these pathways were affected by JG-98 in Bag3-dependent and some pathways in Bag3-independent manner, indicating multiple mechanisms of JG-98 action. Using pooled shRNA genetic screen, we established gene sets that modulate the response of cancer cells to JG-98. Based on genetic and gene expression information, we developed approaches to predict potent combinations of JG-98 with known drugs. These predictions were validated by demonstrating that proteasome, RNApol II, Akt and RTK inhibitors synergize with anti-cancer effects of JG-98. Overall, in this study we analyze unique effects of Hsp70 inhibitors of JG-98 series on cell physiology and define potential drug combinations for clinical use of these inhibitors.

Project description:The mTOR (mammalian Target of Rapamycin) pathway is constitutively activated in Diffuse Large B-Cell Lymphoma (DLBCL). mTOR inhibition has been shown to have clinical activity in patients with DLBCL, although overall response rates remain low. We therefore evaluated differences in the transcriptome between DLBCL cell lines with differential sensitivity to the mTOR inhibitor Rapamycin, to (A) identify gene-expression patterns(GEP) capable of identifying sensitivity to Rapamycin, (B) understand the underlying mechanisms of resistance to Rapamycin in DLBCL and (C) identify bioactive molecules likely to synergize with mTOR inhibitors. Using Affymetrix HuGene ST 1.0 microarrays, we were able to identify a gene expression signature capable of accurately predicting sensitivity and resistance to Rapamycin in DLBCL cell lines. Pathway analysis identified the serine/threonine kinase Akt as central to the differentially-expressed gene network. Connectivity mapping of our datasets identified compounds targeting the AKT pathway with a high likelihood of reversing the GEP associated with resistance to Rapamycin. Specifically, we evaluated the HIV protease inhibitor (PI) Nelfinavir, which is known to have anti-cancer and Akt-inhibitory properties, as well as the small molecule Akt inhibitor MK-2206, for their potential to synergize with to Rapamycin in DLBCL. Nelfinavir and MK-2206 caused profound inhibition of cell viability in combination with Rapamycin in DLBCL cell lines. Low nanomolar concentrations of Rapamycin inhibited phosphorylation of Akt and also downstream targets of activated mTOR when used in combination with these Akt inhibitors. These findings have the potential to significantly improve patient selection for mTOR inhibitor therapy, and to improve rates and depths of response. More broadly, they support the use of global RNA expression and connectivity mapping to improve patient selection and identify synergistic drug combinations for cancer therapy. DLBCL cell lines were tested for Rapamycin sensitivity and classified as "sensitive" or "resistant." Genome-wide analysis of all cell lines were performed using the Affymetrix HuGene ST 1.0 Array Platform. Genes with differential expression between sensitive and resistant cell lines were analyzed using Statistical Analysis of Microarrays (SAM) software, and a signature of genes determnined. This signature was found to accurately predict sensitivity or resistance of other DLBCL cell lines, and to identify the protein kinase Akt as central to resistance.

Project description:Bruton’s tyrosine kinase (BTK) inhibitor Ibrutinib has been shown to synergize in vitro with proteasome inhibitors (PIs) in reducing the viability of cells derived from B-cell malignancies, but the mechanism is not known. We report here that an off-target effect of Ibrutinib causes synergy because not all BTK inhibitors exhibited the synergistic effect, and those that synergized did so even in cells that do not express BTK. The allosteric BTK inhibitor CGI-1746 showed the strongest synergy. Co-treatment of cells with CGI-1746 increased PI-induced expression of heat shock proteins and accumulation of ubiquitin conjugates. The CGI-1746 inhibited the degradation of a model substrate by a purified 26S proteasome. CGI-1746, but not other BTK inhibitors, allosterically inhibited ATPase activity and 2 and 1 peptidase activities of the 26S proteasomes. Although the effect is unlikely to contribute to the anti-neoplastic activity of BTK inhibitors in multiple myeloma and mantle cell lymphoma, it demonstrates a conceptually novel mode of inhibition that may aid the development of more potent proteasome inhibitors and improve response in solid tumors clinically.