Project description:ZDHHC5-Mediated BRAF Palmitoylation Drives KRASG12C-Inhibitor Resistance and Sustains Oncogenic MAPK Signalling

Project description:The KRAS(G12C) mutation is the most common genetic mutation in North American lung adenocarcinoma patients. Recently, direct inhibitors of the KRASG12C protein have been developed and demonstrate clinical response rates of 37-43%. Importantly, these agents fail to generate durable therapeutic responses with median progression-free survival of ~6.5 months. To provide models for further preclinical improvement of these inhibitors, we generated three novel murine KRASG12C-driven lung cancer cell lines. The co-occurring NRASQ61L mutation in KRASG12C-positive LLC cells was deleted and the KRASG12V allele in CMT167 cells was edited to KRASG12C with CRISPR/Cas9 methods. Also, a novel murine KRASG12C line, mKRC.1, was established from a tumor generated in a genetically-engineered mouse model. The three lines exhibit similar in vitro sensitivities to KRASG12C inhibitors (MRTX-1257, AMG-510), but distinct in vivo responses to MRTX-849 ranging from progressive growth with orthotopic LLC-NRAS KO tumors to marked shrinkage with mKRC.1 tumors. All three cell lines exhibited synergistic in vitro growth inhibition with MRTX-1257 and the SHP2 inhibitor, RMC-4550 and the MRTX-849/RMC-4550 combination yielded tumor shrinkage in orthotopic LLC-NRAS KO tumors propagated in syngeneic mice. Notably, this synergistic combination response was lost in athymic nu/nu mice, supporting a growing literature demonstrating a role for adaptive immunity in the response to this class of drugs. These new models of murine KRASG12C mutant lung cancer should prove valuable for identifying improved therapeutic combination strategies with KRASG12C inhibitors.

Project description:KRASG12C inhibitors have been widely reported and studied in recent years. Some of the inhibitors, such as AMG510 and ARS1620, have been reported in clinical studies to be effective in treating patients with non-small cell lung cancer (NSCLC). However, the rapid development of drug resistance in tumor cells will delay the clinical application of these drugs. Therefore, how to block the resistance to these inhibitors in tumor cells with KRASG12C mutations is crucial. We report the alteration in transcriptomics of NSCLC cell line H358 after long-term ARS1620 treatment to explore the mechanism of H358 resistance.

Project description:Approved inhibitors of KRASG12C prevent oncogenic activation by sequestering the inactive, GDP-bound (OFF) form rather than directly binding and inhibiting the active, GTP-bound (ON) form of the protein. This suboptimal mechanism provides no direct target coverage against KRASG12C(ON). Expectedly, adaptive resistance to KRASG12C (OFF)-only inhibitors is observed in association with increased expression and activity of KRASG12C(ON). To provide optimal KRASG12C target coverage, we have developed BBO-8520, a first-in-class, direct dual inhibitor of KRASG12C(ON) and (OFF) forms. BBO-8520 binds in the Switch-II/Helix3 pocket, covalently modifies the target cysteine and disables effector binding to KRASG12C(ON). BBO-8520 exhibits potent signaling inhibition in growth factor activated states where current (OFF)-only inhibitors demonstrate little measurable activity. In vivo, BBO-8520 demonstrates rapid target engagement and inhibition of downstream signaling, resulting in durable tumor regression in multiple models, including those resistant to KRASG12C (OFF)-only inhibitors.

Project description:Inhibitors of the MAPKs, BRAF and MEK, induce tumor regression in the majority of patients with BRAF-mutant metastatic melanoma. The clinical benefit of MAPK inhibitors is restricted by the development of acquired resistance with half of those who benefit having progressed by 6-7 months and long-term responders uncommon. There remains no agreed treatment strategy on disease progression in these patients. Without published evidence, fears of accelerated disease progression on inhibitor withdrawal have led to the continuation of drugs beyond formal disease progression. We now demonstrate that treatment with MAPK inhibitors beyond disease progression can provide significant clinical benefit, and the withdrawal of these inhibitors led to a marked increase in the rate of disease progression in two patients. We also show that MAPK inhibitors retain partial activity in acquired resistant melanoma by examining drug-resistant clones generated to dabrafenib, trametinib or the combination of these drugs. All resistant sublines displayed a markedly slower rate of proliferation when exposed to MAPK inhibitors, and this coincided with a reduction in MAPK signalling, decrease in BrdU incorporation and S-phase inhibition. This cytostatic effect was also associated diminished levels of cyclin D1 and p-pRb.. Two short-term melanoma cultures generated from resistant tumour biopsies also responded to MAPK inhibition with comparable inhibitory changes in proliferation and MAPK signalling. These data provide a rationale for the continuation of BRAF and MEK inhibitors after disease progression and support the development of clinical trials to examine this strategy. Total RNA obtained from melanooma cell lines treated for 24h with dabrafenib, trametinib or combination of dabrafenib and trametinib

Project description:Although KRASG12C inhibitors show clinical activity in patients with KRAS G12C mutated NSCLC and other solid tumor malignancies, response is limited by multiple mechanisms of resistance. The KRASG12C inhibitor JDQ443 shows enhanced preclinical antitumor activity combined with the SHP2 inhibitor TNO155, and the combination is currently under clinical evaluation. To identify rational combination strategies that could help overcome or prevent some types of resistance, we evaluated the duration of tumor responses to JDQ443 ± TNO155, alone or combined with the PI3Kα inhibitor alpelisib and/or the CDK4/6 inhibitor ribociclib, in xenograft models derived from a KRASG12C-mutant NSCLC line and investigated the genetic mechanisms associated with loss of response to combined KRASG12C/SHP2 inhibition.

Project description:Treatment with KRASG12C inhibitors such as sotorasib can produce substantial regression of tumors in some patients with non-small cell lung cancer (NSCLC). These patients require alternative treatment after acquiring resistance to the inhibitor. The mechanisms underlying this acquired resistance are unclear. The purpose of this study was to identify the mechanisms underlying acquired sotorasib resistance, and to explore potential treatments for rescuing patients with sotorasib-resistant KRASG12C NSCLC cells.

Project description:Genotype directed anti-cancer therapies such BRAF inhibitor in BRAF mutant melanoma can show remarkable clinical efficacy but resistance limits their benefit. We show that a transposon activation screen efficiently identifies resistance genes to BRAF and captures a number of previously uncharacterized resistance mechanisms, including an E3 ubiquitin ligase NEDD4L and the Hippo pathway effector WWTR1 (TAZ). Resistance can be reversed by combining BRAF inhibition with tyrosine kinase inhibitors as observed previously for other resistance genes. Moreover, an integrative analysis of several gain- and loss-of-function genetic screens performed in the same context reveals smaller functional diversity of resistance mechanisms to MAPK inhibition than suggested by the broad range of resistance genes identified, implying common therapeutic strategies. A375 cells with lentiviral vector controls or WWTR1 cDNA plasmid.

Project description:Covalent inhibitors of KRASG12C (KRASi) hold considerable progress for tumors driven by this oncogene yet early studies suggest rapid mechanisms of adaptive resistance that appear cell type dependent. To address these challenges, we performed mass spsectrometry baesd phosphoproteomics analysis in KRASG12C cell lines after short term treatment with ARS-1620 and compared phosphoproteomes of KRASG12C cells to understand signaling diversity. Our analysis suggests individual KRASG12C cells responds uniquely to perturbation of KRASG12C. Cell line models can be categorized in epithelial or mesenchymal subtypes and a similar pattern was observed in KRASG12C human lung cancer tumor tissues. ERBB2/3 signaling compensate for repressed ERK signaling following ARS-1620 treatment in epithelial cell type, and this subtype was also more responsive to inhibition of SHP2, IGFR, and SOS1. Conversely, FGFR signaling drives resistance to KRASi in mesenchymal cells in part via mTOR signaling. These studies suggest transcriptional subtypes of KRASG12C dictate responsiveness to specific combinations.

Project description:Covalent inhibitors of KRASG12C (KRASi) hold considerable progress for tumors driven by this oncogene yet early studies suggest rapid mechanisms of adaptive resistance that appear cell type dependent. To address these challenges, we performed mass spsectrometry baesd phosphoproteomics analysis in KRASG12C cell lines after short term treatment with ARS-1620 and compared phosphoproteomes of KRASG12C cells to understand signaling diversity. Our analysis suggests individual KRASG12C cells responds uniquely to perturbation of KRASG12C. Cell line models can be categorized in epithelial or mesenchymal subtypes and a similar pattern was observed in KRASG12C human lung cancer tumor tissues. ERBB2/3 signaling compensate for repressed ERK signaling following ARS-1620 treatment in epithelial cell type, and this subtype was also more responsive to inhibition of SHP2, IGFR, and SOS1. Conversely, FGFR signaling drives resistance to KRASi in mesenchymal cells in part via mTOR signaling. These studies suggest transcriptional subtypes of KRASG12C dictate responsiveness to specific combinations.