Project description:About 25% of cholangiocarcinoma (CCA) patients harbor KRAS mutations, being potentially amenable to direct KRAS inhibitors. Here, we investigated the activity of RAS(ON) multi-selective inhibitors, which target the active, GTP-bound state of both mutant and wild-type variants of canonical RAS isoforms, in CCA preclinical models and patients. RAS(ON) multi-selective inhibitors yield strong anticancer responses in cell- and patient-derived xenografts and in immunocompetent allograft models. Consistently, we describe responses to the RAS(ON) multi-selective inhibitor daraxonrasib in two KRASG12X patients with advanced CCA. RAS-GTP inhibition also potentiates the activity of the current standard-of-care CCA therapy to prolong survival in cell-derived human xenografts and mouse allografts. Furthermore, we demonstrate that both intrinsic and acquired resistance to RAS(ON) multi-selective inhibitors mainly rely on reconstitution of RAS signalling. Overall, our findings indicate that KRAS mutant CCA is addicted to RAS signalling for proliferation and support the potential clinical evaluation of RAS-GTP inhibition in CCA.

Project description:About 25% of cholangiocarcinoma (CCA) patients harbor KRAS mutations, being potentially amenable to direct KRAS inhibitors. Here, we investigated the activity of RAS(ON) multi-selective inhibitors, which target the active, GTP-bound state of both mutant and wild-type variants of canonical RAS isoforms, in CCA preclinical models and patients. RAS(ON) multi-selective inhibitors yield strong anticancer responses in cell- and patient-derived xenografts and in immunocompetent allograft models. Consistently, we describe responses to the RAS(ON) multi-selective inhibitor daraxonrasib in two KRASG12X patients with advanced CCA. RAS-GTP inhibition also potentiates the activity of the current standard-of-care CCA therapy to prolong survival in cell-derived human xenografts and mouse allografts. Furthermore, we demonstrate that both intrinsic and acquired resistance to RAS(ON) multi-selective inhibitors mainly rely on reconstitution of RAS signalling. Overall, our findings indicate that KRAS mutant CCA is addicted to RAS signalling for proliferation and support the potential clinical evaluation of RAS-GTP inhibition in CCA.

Project description:Small molecule KRASG12C(OFF) inhibitors that bind to the inactive GDP-bound state of KRAS have demonstrated efficacy in patients with KRASG12C mutant tumors, yet responses tend to be transient due to on-treatment resistance. Recently, a RAS(ON) G12C-selective inhibitor, which binds to the active GTP-bound state of KRAS, was introduced into the clinical settings. We generated cell line and PDX resistant models to KRAS G12C(OFF) and RAS(ON) G12C-selective inhibitors that displayed a variety of resistance mechanisms similar to the ones observed in human studies. Here we interrogated resistance mechanisms using a multi-omics strategy consisting of phosphoproteomics, exome sequencing, and RNA-sequencing then coupled these analyses to functional testing using small molecule screens, CRISPR screens and combination with RAS(ON) inhibitors that have entered clinical trials. We found two models that reactivate RAS signaling, either via KRASG12C gene amplification or NRASG13R mutation, and showed that tumors driven by these resistance mechanisms are vulnerable to dual inhibition by either RAS(ON) G12C-selective combined with RAS(ON) multi-selective inhibitor. Two models, which lack any discernable genomic alteration, acquired resistance associated with increased receptor tyrosine kinase activity and downstream persistent RAS activity, were sensitive to RAS-GTP inhibition by RAS(ON) multi-selective inhibitor. Finally, one model displayed epithelial-mesenchymal transition, loss of RAS activity and acquired dependence on cell cycle kinases and proteins associated with DNA damage response. Our work highlights KRASi-resistant states that could potentially be overcome with a RAS(ON) multi-selective inhibitor as a standalone agent or in carefully tailored combinations. It also identifies resistant tumors that have reduced RAS dependance, thereby necessitating alternative therapeutic strategies. These datasets compare parental LUN156 patient-derived xenograft tumors to those with acquired resistance to the KRAS G12C inhibitors, Adagrasib (AR) and RM-4998 (RR). Data are provided for protein expression (ID), global phosphorylation (IMAC), and tyrosine phosphorylation (pY) as indicated in the filenames.

Project description:Small molecule KRASG12C(OFF) inhibitors that bind to the inactive GDP-bound state of KRAS have demonstrated efficacy in patients with KRASG12C mutant tumors, yet responses tend to be transient due to on-treatment resistance. Recently, a RAS(ON) G12C-selective inhibitor, which binds to the active GTP-bound state of KRAS, was introduced into the clinical settings. We generated cell line and PDX resistant models to KRAS G12C(OFF) and RAS(ON) G12C-selective inhibitors that displayed a variety of resistance mechanisms similar to the ones observed in human studies. Here we interrogated resistance mechanisms using a multi-omics strategy consisting of phosphoproteomics, exome sequencing, and RNA-sequencing then coupled these analyses to functional testing using small molecule screens, CRISPR screens and combination with RAS(ON) inhibitors that have entered clinical trials. We found two models that reactivate RAS signaling, either via KRASG12C gene amplification or NRASG13R mutation, and showed that tumors driven by these resistance mechanisms are vulnerable to dual inhibition by either RAS(ON) G12C-selective combined with RAS(ON) multi-selective inhibitor. Two models, which lack any discernable genomic alteration, acquired resistance associated with increased receptor tyrosine kinase activity and downstream persistent RAS activity, were sensitive to RAS-GTP inhibition by RAS(ON) multi-selective inhibitor. Finally, one model displayed epithelial-mesenchymal transition, loss of RAS activity and acquired dependence on cell cycle kinases and proteins associated with DNA damage response. Our work highlights KRASi-resistant states that could potentially be overcome with a RAS(ON) multi-selective inhibitor as a standalone agent or in carefully tailored combinations. It also identifies resistant tumors that have reduced RAS dependance, thereby necessitating alternative therapeutic strategies. These datasets compare parental Lu65 cells to those with acquired resistance to RM-4998. Data are provided for protein expression (ID), global phosphorylation (IMAC), and tyrosine phosphorylation (pY) as indicated in the filenames.

Project description:Small molecule KRASG12C(OFF) inhibitors that bind to the inactive GDP-bound state of KRAS have demonstrated efficacy in patients with KRASG12C mutant tumors, yet responses tend to be transient due to on-treatment resistance. Recently, a RAS(ON) G12C-selective inhibitor, which binds to the active GTP-bound state of KRAS, was introduced into the clinical settings. We generated cell line and PDX resistant models to KRAS G12C(OFF) and RAS(ON) G12C-selective inhibitors that displayed a variety of resistance mechanisms similar to the ones observed in human studies. Here we interrogated resistance mechanisms using a multi-omics strategy consisting of phosphoproteomics, exome sequencing, and RNA-sequencing then coupled these analyses to functional testing using small molecule screens, CRISPR screens and combination with RAS(ON) inhibitors that have entered clinical trials. We found two models that reactivate RAS signaling, either via KRASG12C gene amplification or NRASG13R mutation, and showed that tumors driven by these resistance mechanisms are vulnerable to dual inhibition by either RAS(ON) G12C-selective combined with RAS(ON) multi-selective inhibitor. Two models, which lack any discernable genomic alteration, acquired resistance associated with increased receptor tyrosine kinase activity and downstream persistent RAS activity, were sensitive to RAS-GTP inhibition by RAS(ON) multi-selective inhibitor. Finally, one model displayed epithelial-mesenchymal transition, loss of RAS activity and acquired dependence on cell cycle kinases and proteins associated with DNA damage response. Our work highlights KRASi-resistant states that could potentially be overcome with a RAS(ON) multi-selective inhibitor as a standalone agent or in carefully tailored combinations. It also identifies resistant tumors that have reduced RAS dependance, thereby necessitating alternative therapeutic strategies. These datasets compare parental H358 cells to those with acquired resistance to the KRAS G12C inhibitor, AMG510. Data are provided for protein expression (ID), global phosphorylation (IMAC), and tyrosine phosphorylation (pY) as indicated in the filenames.

Project description:Small molecule KRASG12C(OFF) inhibitors that bind to the inactive GDP-bound state of KRAS have demonstrated efficacy in patients with KRASG12C mutant tumors, yet responses tend to be transient due to on-treatment resistance. Recently, a RAS(ON) G12C-selective inhibitor, which binds to the active GTP-bound state of KRAS, was introduced into the clinical settings. We generated cell line and PDX resistant models to KRAS G12C(OFF) and RAS(ON) G12C-selective inhibitors that displayed a variety of resistance mechanisms similar to the ones observed in human studies. Here we interrogated resistance mechanisms using a multi-omics strategy consisting of phosphoproteomics, exome sequencing, and RNA-sequencing then coupled these analyses to functional testing using small molecule screens, CRISPR screens and combination with RAS(ON) inhibitors that have entered clinical trials. We found two models that reactivate RAS signaling, either via KRASG12C gene amplification or NRASG13R mutation, and showed that tumors driven by these resistance mechanisms are vulnerable to dual inhibition by either RAS(ON) G12C-selective combined with RAS(ON) multi-selective inhibitor. Two models, which lack any discernable genomic alteration, acquired resistance associated with increased receptor tyrosine kinase activity and downstream persistent RAS activity, were sensitive to RAS-GTP inhibition by RAS(ON) multi-selective inhibitor. Finally, one model displayed epithelial-mesenchymal transition, loss of RAS activity and acquired dependence on cell cycle kinases and proteins associated with DNA damage response. Our work highlights KRASi-resistant states that could potentially be overcome with a RAS(ON) multi-selective inhibitor as a standalone agent or in carefully tailored combinations. It also identifies resistant tumors that have reduced RAS dependance, thereby necessitating alternative therapeutic strategies. These datasets compare parental Lu65 cells to those with acquired resistance to the KRAS G12C inhibitor, Sotorasib. Data are provided for protein expression (ID), global phosphorylation (IMAC), and tyrosine phosphorylation (pY) as indicated in the filenames.

Project description:To address RAS pathway hyperactivation and targeted therapy resistance in KRASG12C-mutant NSCLC, we evaluated the potential of the RAS(ON) G12C-selective covalent inhibitor elironrasib and the RAS(ON) multi-selective inhibitor daraxonrasib combination to maximize RAS pathway suppression and forestall pathway reactivation in a series of preclinical models. We demonstrate that the RAS(ON) inhibitor doublet induces profound and sustained tumor regressions and overcomes the increased RAS pathway oncogenic flux that underlies resistance to inactive state–selective KRASG12C inhibitors in NSCLC. Additionally, in immune-competent preclinical models, the RAS(ON) inhibitor doublet enhances tumor immune recognition by boosting antigen presentation and remodeling the suppressive tumor microenvironment, thus promoting immune-dependent complete regressions and sensitization of an immuno-refractory model to checkpoint blockade. Collectively these findings provide a preclinical rationale for the evaluation of a targeted RAS(ON) inhibitor doublet therapy regimen in combination with immune checkpoint blockade in patients with KRASG12C-mutant NSCLC.

Project description:Pancreatic ductal adenocarcinoma (PDAC) is often driven by KRAS mutations, but inhibitors targeting the most frequent KRAS substitutions in PDAC are not yet approved in the clinic. We previously discovered that KRAS-mutant PDAC are sensitive to the combination of SHP2 and ERK inhibitors, recently investigated in the Phase I/Ib clinical trial NCT04916236. Lately, RAS(ON) multi-selective inhibitors have entered clinical development, representing a promise for mono or combination therapies in PDAC. However, resistance may arise even for combination therapies. Here, we aimed at anticipating mechanisms of resistance to SHP2 plus ERK or RAS(ON) multi-selective inhibitors. Through unbiased CRISPR-based screenings, we identified mTOR and JUN hyperactivation as interconnected mechanisms that overcome MAPK suppression. Functional genetic and pharmacological experiments pointed at JUN as the most downstream resistance mediator, and indirect therapeutic target, using MAP2K4 inhibitors. Alterations in the PI3K/AKT/mTOR and JUN pathways may serve as biomarkers for sensitivity/resistance in clinical trials testing MAPK inhibitors combinations in KRAS-mutant PDAC.

Project description:KRAS mutation is widely presumed to confer independence from upstream RTK signalling, however emerging evidence from mouse models of lung cancer suggests that ERBB RTKs may amplify signalling through RAS isoforms and participate in mutant RAS-driven lung cancer. This is one of 3 datasets where we examined the transcriptional impact of treatment of KRAS mutant human lung cancer cell lines with the multi-ERBB inhibitor Neratinib

Project description:KRAS mutation is widely presumed to confer independence from upstream RTK signalling, however emerging evidence from mouse models of lung cancer suggests that ERBB RTKs may amplify signalling through RAS isoforms and participate in mutant RAS-driven lung cancer. This is one of 3 datasets where we examined the transcriptional impact of treatment of KRAS mutant human lung cancer cell lines with the multi-ERBB inhibitor Neratinib