Project description:Fluvastatin has been identified as novel inhibitors of metastasis in pancreatic cancer. In multiple in vivo and in vitro experiments the compounds phenotypic effects was validated. Since under drug treatment the transcriptomic changes in examined cell lines were rather small, we expected the underlying mechanistic effect to be on the level of the proteome and more importantly the phospho-proteome. To evaluate this assumption we performed label-free full proteome and phosphoproteomics experiments on Fluvastatin treated ASPC1 cells.

Project description:MYC-driven Group 3 medulloblastoma (MB) (subtype II) is a highly aggressive childhood brain tumor. Sensitivity of MYC-driven MBs to class I histone deacetylase inhibitors (HDACi) has been previously demonstrated in vitro and in vivo. We here characterize the transcriptional effects of class I HDAC inhibition in MYC-driven MB and explore beneficial drug combinations. MYC-amplified Group 3 MB cells (HD-MB03) were treated with class I HDACi entinostat. Changes in the gene expression profile compared to untreated control were quantified on a microarray. Gene set enrichment analysis, cytoscape enrichment mapping and ingenuity pathway analysis led to the identification of pathways affected by entinostat treatment. Five drugs interfering with these pathways (olaparib, idasanutlin, ribociclib, selinexor, vinblastine) were tested as single agents in metabolic activity assays in three MYC-amplified and two non-MYC-amplified MB cell lines. Synergy with entinostat was evaluated by dose response curve shift, combination index and zero interaction potency synergy model and validated in cell count and flow cytometry experiments in two MYC-amplified and one non-MYC-amplified MB cell line. The effect of the most promising drug combination (entinostat and olaparib) on DNA damage was evaluated by γH2A.X quantification in immunoblotting, fluorescence microscopy and flow cytometry. Entinostat treatment changed the expression of genes involved in 22 pathways, including downregulation of DNA damage response. The PARP1 inhibitors olaparib and pamiparib showed synergy with entinostat. The combination of entinostat and olaparib led to increased cell death, decreased viability and increased formation of double strand breaks selectively in MYC-amplified MB cells. MYC-amplified MB cells treated with entinostat and olaparib were particularly vulnerable to additional induction of DNA damage by doxorubicin. Non-MYC-amplified MB cells and normal human fibroblasts were not susceptible to this triple treatment. Our study identifies the combination of entinostat with olaparib and doxorubicin as a new potential therapeutic approach for MYC-driven Group 3 MB.

Project description:Combination of reverse- and chemical genetic screens reveals a network of novel angiogenesis inhibitors and targets Drug target identification and validation are bottlenecks in the drug discovery process. Accordingly there is a need to develop new methods to facilitate the development of much-needed innovative drugs. We have combined reverse- and chemical genetics to identify new targets modulating blood vessel development. Through mRNA expression profiling in mice we identified 155 drugable gene products that were enriched in the microvasculature. Orthologs of 50 of these candidates were knocked down in a reverse genetic screen in zebrafish. 16 of the 50 genes encoded products that affected angiogenesis. In parallel, screening of 300 known drugs and pharmacologically active compounds in a human cell-based angiogenesis assay identified 11 angiogenesis inhibitors. Strikingly the reverse- and chemical genetic screens identified an overlap of three gene products of the same superfamily of serine/threonine protein phosphatases and two compounds targeting that family. Furthermore, the gene products identified in the reverse genetic screen comprise an interacting network with the targets of the chemical genetic screen. Thus, combining reverse- and chemical genetic screens is a powerful approach to identify novel biological processes and drug targets in vertebrates. Keywords: Cell-type comparison 24 samples were analyzed, representing 8 sample groups. In every sample group, three biological replicates were hybridized separately. The microarrays were hybridized with a Cy3-labeled sample and Cy-5 labeled Common Reference (Universal Mouse Reference RNA, cat. No.: 740100, Stratagene) simultaneously.

Project description:LS1034 colorectal cancer cells were treated with DMSO vehicle control or 12 uM tepoxalin for 6 hours. Anti-cancer uses of non-oncology drugs have been found on occasion, but such discoveries have been serendipitous and rare. To fully discover activity against multiple tumor types, resource-intensive screening across hundreds of cancer cell lines is needed. We sought to create a public resource containing the growth inhibitory activity of 4,518 drugs tested across 578 human cancer cell lines. To accomplish this, we used PRISM, which involves the molecular barcoding of each cell line, followed by pooling of the barcoded lines. Relative barcode abundance following drug treatment versus controls thus reflects cell viability following drug treatment. We found that an unexpectedly large number of non-oncology drugs selectively inhibited subsets of cancer cell lines. Moreover, the killing activity of the majority of these drugs was predictable based on the molecular features of the cell lines. Mechanistic follow-up of several of these compounds revealed novel mechanisms. These results illustrate the potential of the PRISM drug repurposing resource as a starting point for new oncology therapeutic development.

Project description:Owing to safety concerns or insufficient potential for efficacy, only 0.01% to 0.02% of new drug candidates are approved for marketing. Drugs already on the market may be withdrawn or restricted to certain uses due to adverse effects (AEs) discovered after market introduction. Comprehensively investigating the on-/off-target effects of drugs can help expose AEs during the drug development process. In this study, we developed an integrative framework for systematic identification of on-/off-target pathways and elucidation of the underlying mechanisms, by combining expression profiling after drug treatment with gene perturbation of the primary drug target. Expression profiles from statin-treated cells and HMG-CoA reductase knockdowns were analyzed using the framework, allowing for identification of not only reported adverse effects but also novel candidates of off-target effects from statin treatment. Our findings may provide new insights for finding new usages or potential side effects of drug treatment.

Project description:Combination of reverse- and chemical genetic screens reveals a network of novel angiogenesis inhibitors and targets Drug target identification and validation are bottlenecks in the drug discovery process. Accordingly there is a need to develop new methods to facilitate the development of much-needed innovative drugs. We have combined reverse- and chemical genetics to identify new targets modulating blood vessel development. Through mRNA expression profiling in mice we identified 155 drugable gene products that were enriched in the microvasculature. Orthologs of 50 of these candidates were knocked down in a reverse genetic screen in zebrafish. 16 of the 50 genes encoded products that affected angiogenesis. In parallel, screening of 300 known drugs and pharmacologically active compounds in a human cell-based angiogenesis assay identified 11 angiogenesis inhibitors. Strikingly the reverse- and chemical genetic screens identified an overlap of three gene products of the same superfamily of serine/threonine protein phosphatases and two compounds targeting that family. Furthermore, the gene products identified in the reverse genetic screen comprise an interacting network with the targets of the chemical genetic screen. Thus, combining reverse- and chemical genetic screens is a powerful approach to identify novel biological processes and drug targets in vertebrates. Keywords: Cell-type comparison

Project description:Cell lines have been used for drug discovery as useful models of cancers; however, they do not recapitulate cancers faithfully, especially in the points of rapid growth rate and microenvironment independency. Consequently, the majority of conventional anti-cancer drugs are less sensitive to slow growing cells and do not target microenvironmental support, although most primary cancer cells grow slower than cell lines and depend on microenvironmental support. Here, we developed a novel high throughput drug screening system using patient-derived xenograft (PDX) cells of lymphoma that maintained primary cancer cell phenotype more than cell lines. The library containing 2613 known pharmacologically active substance and off-patent drugs were screened by this system. We could find many compounds showing higher cytotoxicity than conventional anti-tumor drugs. Especially, pyruvinium pamoate showed the highest activity, and its strong anti-tumor effect was confirmed also in vivo. We extensively investigated its mechanism of action and found that it inhibited glutathione supply from stromal cells to lymphoma cells, implying the importance of the stromal protection from ox 1 idative stress for lymphoma cell survival and a new therapeutic strategy for lymphoma. Our system introduces a primary cancer cell phenotype into cell-based phenotype screening and sheds new light on anti-cancer drug development. Global gene expression profiles of PDX cells showed high similarity to those of original primary cells. The correlation coefficient of gene expression profiles between PDX cells and the originalprimary cells was 0.814-0.890.

Project description:The goal of the CTD2 Pancancer Drug Activity DREAM Challenge is to foster the development and benchmarking of algorithms to predict targets of chemotherapeutic compounds from post-treatment transcriptional data. The drug perturbational profiles on 11 cell lines for 32 kinase inhibitors with well-established targets were provided to challenge participants, without revealing the identity of the drugs. These profiles were used to predict the drug-targets of the 32 anonymized drugs using publically available datasets for training.

Project description:New antifungal drugs are urgently needed due to the currently limited selection, the emergence of drug resistance, and the toxicity of several commonly used drugs. To identify drug leads, we screened small molecules using a Saccharomyces reporter bioassay in which the yeast heterologously expresses Hik1, a group III hybrid histidine kinase (HHK) from Magnaporthe grisea. Group III HHKs are integral in fungal cell physiology, and highly conserved throughout this kingdom; they are absent in mammals, making them an attractive drug target. Our screen identified compounds 13 and 33, which showed robust activity against numerous fungal genera including Candida, Cryptococcus and molds such as Aspergillus and Rhizopus. Drug-resistant Candida from patients were also highly susceptible to compounds 13 and 33. While the compounds do not act directly on HHKs, microarray analysis showed that compound 13 induced transcripts associated with oxidative stress, and compound 33, transcripts linked with heavy metal stress. Both compounds were highly active against Candida biofilm, in vitro and in vivo, and exerted synergy with fluconazole, which was inactive alone. Thus, we identified potent, broad-spectrum antifungal drug leads from a small molecule screen using a high-throughput, yeast reporter bioassay. Two-color experimental design testing the effects of 2 antifungal compounds (13 and 33) after 0, 20, 40 60 min. In the referred publication, the t=20, 40, 60 data was normalized against the t=0 data

Project description:Cell lines have been used for drug discovery as useful models of cancers; however, they do not recapitulate cancers faithfully, especially in the points of rapid growth rate and microenvironment independency. Consequently, the majority of conventional anti-cancer drugs are less sensitive to slow growing cells and do not target microenvironmental support, although most primary cancer cells grow slower than cell lines and depend on microenvironmental support. Here, we developed a novel high throughput drug screening system using patient-derived xenograft (PDX) cells of lymphoma that maintained primary cancer cell phenotype more than cell lines. The library containing 2613 known pharmacologically active substance and off-patent drugs were screened by this system. We could find many compounds showing higher cytotoxicity than conventional anti-tumor drugs. Especially, pyruvinium pamoate showed the highest activity, and its strong anti-tumor effect was confirmed also in vivo. We extensively investigated its mechanism of action and found that it inhibited glutathione supply from stromal cells to lymphoma cells, implying the importance of the stromal protection from ox 1 idative stress for lymphoma cell survival and a new therapeutic strategy for lymphoma. Our system introduces a primary cancer cell phenotype into cell-based phenotype screening and sheds new light on anti-cancer drug development.