Project description:Lung cancer is associated with high prevalence and mortality, and despite significant successes with targeted drugs in genomically defined subsets of lung cancer and immunotherapy, the majority of patients currently does not benefit from these therapies. Through a targeted drug screen, we found the recently approved multi-kinase inhibitor midostaurin to have potent activity in several lung cancer cells independent of its intended target, PKC, or a specific genomic marker. To determine the underlying mechanism of action we applied a layered functional proteomics approach and a new data integration method. Using chemical proteomics, we identified multiple midostaurin kinase targets in these cells. Network-based integration of these targets with quantitative tyrosine and global phosphoproteomics data using protein-protein interactions from the STRING database and NetworKIN substrate prediction suggested multiple targets are relevant for the mode of action of midostaurin. Subsequent functional validation using RNA interference and selective small molecule probes showed that simultaneous inhibition of TBK1, PDK1 and AURKA was required to elicit midostaurin’s cellular effects. Immunoblot analysis of downstream signaling nodes showed that combined inhibition of these targets altered PI3K/AKT and cell cycle signaling pathways that in part converged on PLK1. Furthermore, rational combination of midostaurin with the more potent PLK1 inhibitor BI2536, which is in advanced clinical trials, elicited strong synergy. Our results demonstrate that combination of complementary functional proteomics approaches and subsequent network-based data integration can reveal novel insight into the complex mode of action of multi-kinase inhibitors, actionable targets for drug discovery and cancer vulnerabilities. Finally, we illustrate how this knowledge can be utilized for the rational design of synergistic drug combinations with high potential for clinical translation.

Project description:Lung cancer is associated with high prevalence and mortality, and despite significant successes with targeted drugs in genomically defined subsets of lung cancer and immunotherapy, the majority of patients currently does not benefit from these therapies. Through a targeted drug screen, we found the recently approved multi-kinase inhibitor midostaurin to have potent activity in several lung cancer cells independent of its intended target, PKC, or a specific genomic marker. To determine the underlying mechanism of action we applied a layered functional proteomics approach and a new data integration method. Using chemical proteomics, we identified multiple midostaurin kinase targets in these cells. Network-based integration of these targets with quantitative tyrosine and global phosphoproteomics data using protein-protein interactions from the STRING database suggested multiple targets are relevant for the mode of action of midostaurin. Subsequent functional validation using RNA interference and selective small molecule probes showed that simultaneous inhibition of TBK1, PDK1 and AURKA was required to elicit midostaurin’s cellular effects. Immunoblot analysis of downstream signaling nodes showed that combined inhibition of these targets altered PI3K/AKT and cell cycle signaling pathways that in part converged on PLK1. Furthermore, rational combination of midostaurin with the more potent PLK1 inhibitor BI2536, which is in advanced clinical trials, elicited strong synergy. Our results demonstrate that combination of complementary functional proteomics approaches and subsequent network-based data integration can reveal novel insight into the complex mode of action of multi-kinase inhibitors, actionable targets for drug discovery and cancer vulnerabilities. Finally, we illustrate how this knowledge can be utilized for the rational design of synergistic drug combinations with high potential for clinical translation.

Project description:PARP1 inhibitors (PARP1is ) display single-agent anticancer activity in small cell lung cancer (SCLC) and other neuroendocrine tumors independent of BRCA1/2 mutations. Here, we determined the differential efficacy of multiple clinical PARP1is in SCLC cells. Compared to the other PARP1is (rucaparib, olaparib and niraparib), talazoparib displayed the highest potency across SCLC, also in SLFN11-negative cells. Chemical proteomics identified PARP16 as a unique talazoparib target in addition to PARP1. Silencing PARP16 significantly reduced cell survival, particularly in combination with PARP1 inhibition. Drug combination screening revealed talazoparib synergy with the WEE1/PLK1 inhibitor, adavosertib. Global phosphoproteomics identified disparate effects on cell cycle and DNA damage response signaling, illustrating underlying mechanisms. Synergy with adavosertib was more pronounced for talazoparib than olaparib and silencing PARP16 further reduced cell survival in combination with olaparib and adavosertib. Together, these data suggest that PARP16 contributes to talazoparib’s overall mechanism of action and constitutes a new actionable target in SCLC.

Project description:BRCA1/2-deficient ovarian carcinoma (OC) has been shown to be particularly sensitive to PARP inhibitors (PARPis) and BRCA1/2 mutation status is currently used as a predictive biomarker for PARPi therapy. Despite eliciting major clinical benefit for the majority of patients, a significant proportion of BRCA1/2-deficient OC tumors do not respond to PARPis for reasons that are incompletely understood. Using an integrated chemical, phospho- and ADP-ribosylation proteomics approach we sought to develop additional mechanism-based biomarker candidates for PARPi therapy in OC and identify new targets for combination therapy to overcome primary resistance. Chemical proteomics with PARPi baits in a BRCA1-isogenic OC cell line pair, as well as patient-derived BRCA1-profiecient and deficient tumor samples, and subsequent validation by co-immunoprecipitation showed differential PARP1 and PARP2 protein complex composition with Ku70 and Ku80 in PARPi-sensitive, BRCA1-deficient UWB1.289 (UWB) cells compared to PARPi-insensitive, BRCA1-reconstituted UWB1.289 (UWB+B) cells. Global phosphoproteomics and ADP-ribosylation proteomics furthermore revealed that rucaparib induced the cell cycle pathway and NHEJ pathway in UWB cells, but down-regulated ErbB signaling in UWB+B cells. In addition, we observed AKT PARylation and pro-survival AKT-mTOR signaling in UWB+B cells after PARPi treatment. Consistently, synergy of PARPis with DNAPK or AKT inhibitors was more pronounced in UWB+B cells identifying these pathways as actionable vulnerabilities. In conclusion, the combination of chemical proteomics, phosphoproteomics and ADP-ribosylation proteomics can identify differential PARP1/2 complexes and diverse, but actionable drug compensatory signaling in OC.

Project description:PARP1 inhibitors (PARP1is ) display single-agent anticancer activity in small cell lung cancer (SCLC) and other neuroendocrine tumors independent of BRCA1/2 mutations. Here, we determined the differential efficacy of multiple clinical PARP1is in SCLC cells. Compared to the other PARP1is (rucaparib, olaparib and niraparib), talazoparib displayed the highest potency across SCLC, also in SLFN11-negative cells. Chemical proteomics identified PARP16 as a unique talazoparib target in addition to PARP1. Silencing PARP16 significantly reduced cell survival, particularly in combination with PARP1 inhibition. Drug combination screening revealed talazoparib synergy with the WEE1/PLK1 inhibitor, adavosertib. Global phosphoproteomics identified disparate effects on cell cycle and DNA damage response signaling, illustrating underlying mechanisms. Synergy with adavosertib was more pronounced for talazoparib than olaparib and silencing PARP16 further reduced cell survival in combination with olaparib and adavosertib. Together, these data suggest that PARP16 contributes to talazoparib’s overall mechanism of action and constitutes a new actionable target in SCLC.

Project description:CRISPR knockout screening on MOLM-13 cells with midostaurin or gilteritinib

Project description:LC-MS/MS was used to profile total phosphotyrosine phosphatase in acute myeloid leukemia (AML) in order to find potential biomarkers, drug targets, signatures for AML classification, and its relationship with total phosphotyrosine amount in the samples.

Project description:ALK and ROS1 fusions defines subsets of lung adenocarcinoma. Although ALK/ROS1 inhibitors improved therapeutic outcome of patients harboring those oncogenic fusions, complete responses were rare, and resistance eventually develops from the residual tumor. To under the mechanisms contributing to residual tumor formation, we performed phosphoproteomics to explore the signaling adaption shortly after ALK/ROS1 inhibition. We found the phosphorylation of Mig6, a potent inhibitor for EGFR, was decreased following ALK/ROS1 inhibition, impairing Mig6 binding and inhibition on EGFR. Furthermore, Mig6 mRNA and protein levels were decreased rapidly by ALK/ROS1 inhibitors, potentiating EGFR activity to support cell survival. We also uncovered a novel mechanism mediated by Mig6 to regulate EGFR activity without impacting EGFR phosphorylation, but rather altering signaling adaptor SHC1 binding to EGFR. Mig6 expression was also lost following long-term exposure to ALK/ROS1 inhibitors to support EGFR-mediated acquired resistance. Finally, a Mig6 EGFR-binding domain truncation mutation was identified in a patient-derived ROS1 cell line, rendering its resistance to ROS1 inhibitors but sensitivity to HER family inhibitors. Our work established a rationale to evaluate combinations of ALK/ROS1 and EGFR inhibitors to limit residual tumor formation, therefore preventing or delaying subsequent resistance emergence.

Project description:ALK and ROS1 fusions defines subsets of lung adenocarcinoma. Although ALK/ROS1 inhibitors improved therapeutic outcome of patients harboring those oncogenic fusions, complete responses were rare, and resistance eventually develops from the residual tumor. To under the mechanisms contributing to residual tumor formation, we performed phosphoproteomics to explore the signaling adaption shortly after ALK/ROS1 inhibition. We found the phosphorylation of Mig6, a potent inhibitor for EGFR, was decreased following ALK/ROS1 inhibition, impairing Mig6 binding and inhibition on EGFR. Furthermore, Mig6 mRNA and protein levels were decreased rapidly by ALK/ROS1 inhibitors, potentiating EGFR activity to support cell survival. We also uncovered a novel mechanism mediated by Mig6 to regulate EGFR activity without impacting EGFR phosphorylation, but rather altering signaling adaptor SHC1 binding to EGFR. Mig6 expression was also lost following long-term exposure to ALK/ROS1 inhibitors to support EGFR-mediated acquired resistance. Finally, a Mig6 EGFR-binding domain truncation mutation was identified in a patient-derived ROS1 cell line, rendering its resistance to ROS1 inhibitors but sensitivity to HER family inhibitors. Our work established a rationale to evaluate combinations of ALK/ROS1 and EGFR inhibitors to limit residual tumor formation, therefore preventing or delaying subsequent resistance emergence.

Project description:Dysfunction of cell cycle genes can lead to mitosis disruption and chromosomal instability (CIN), which is blamed for poor prognosis in colorectal cancer (CRC) patients, no matter with chemotherapy or not. Discovery therapeutic targets to abnormal cell cycle pathways in CRC may help to improve current therapy. By genome-widely profiling of differential expressed genes in 54 pairs of human colorectal tumor with matched normal mucosa, we found a functional enrichment in PLK1 signaling. Tumors with enriched PLK1 signaling are accompanied with dysfunction pathways related to cell cycle. Total PLK1 and phosphorylated PLK1 protein expression are associated with tumor recurrence and poor overall survival in a cohort of CRC patients. Combining PLK1 inhibitor with oxaliplatin shows a synergize effect to suppress the growth of CRC cell lines, xenograft tumors, preclinical patient-derived organoid and patient-derived xenograft tumors. RNA-seq data reveals that the cell cycle pathways were activated in oxaliplatin group but inhibited after PLK1 inhibitor treatment. CDC7 may be a key downstream effector of PLK1 induced oxaliplatin resistance and can be druggable. Further investigation showed that PLK1 inhibitor suppress the CDC7 expression via c-MYC transcriptional control. A strong positive correlation between PLK1 and CDC7 has been further confirmed in patients. Strikingly, functional studies confirm that combining CDC7 inhibitor with oxaliplatin can recapitulate the synergize effect in various CRC models, highlighting pharmacological target PLK1-MYC-CDC7 signaling as a potential therapeutic strategy for oxaliplatin based chemotherapy.