Project description:Induction of Multiple Alternative Mitogenic Signaling Pathways Accompanies Emergence of Slowly Growing Drug-Tolerant Cancer Cells

Project description:Despite the recent remarkable progress of targeted therapies for the clinical management of many cancers, response rates remain lower than desired and long-term response durability is often poor due to drug resistance. A major contributor to treatment failure is drug-induced cellular adaptation to therapy, whereby systems-level reprogramming permits a drug-tolerant phenotype that may gradually lead to cell cycle re-entry and portend relapse. Drug adaptation is known to rapidly implicate complex signaling and transcriptional regulatory networks, but the scale and temporal dynamics of these remodeling events have yet to be fully resolved. Here, we used mass spectrometry-based phosphoproteomics and RNA sequencing to capture molecular snapshots within the first minutes, hours, and days of BRAF kinase inhibitor exposure in a drug-tolerant human BRAF-mutant melanoma model. By enriching specific phospho-motifs associated with mitogenic kinases, we were able to detect and monitor thousands of protein phosphorylation sites over a three-day period of drug treatment, followed by a six-day drug holiday to characterize the plasticity of the adaptive response. We observed early and sustained inhibition of the BRAF-ERK axis, gradual downregulation of canonical cell cycle-dependent phosphorylation events, and a clear delineation between three distinct phase transitions toward drug tolerance, which was almost completely reversible following drug removal. Through measuring the time evolution of large-scale networks, we were able to exploit phosphoproteome and transcriptome dynamics to infer kinetically-defined regulatory modules, revealing a concerted response to oncogenic BRAF inhibition involving cellular metabolism, RNA processing, and mitogenic signaling that demonstrated strong agreement with prior knowledge. The adaptive response to BRAF inhibition was dominated by a compensatory induction of SRC-family kinase (SFK) signaling, which we found to be at least partially driven by impaired redox homeostasis and accumulation of reactive oxygen species – providing a fine degree of temporal, mechanistic, and phosphorylation site-specific context to an important axis in tumor cell survival. This induction sensitized cells to co-treatment with an SFK inhibitor, and combination therapy significantly outperformed single-agent BRAF inhibition across a panel of patient-derived melanoma cell lines and in an orthotopic mouse xenograft model, underscoring the high translational potential for measuring the temporal dynamics of signaling and transcription networks under therapeutic challenge.

Project description:Here we describe the use of multiple forward genetic screens executed in parallel to identify those genes, and their cognate pathways, that when overexpressed, silenced or mutated confer resistance in BRAF mutant colon cancer to a BRAF/MEK/EGFR inhibitor combination. We demonstrate that this resistance landscape is finite, relatively constrained to a small number of pathways and that it is possible to exploit the evolutionary dynamics that underpins the clonal expansion of drug resistant cells therapeutically.

Project description:Anti-BRAF mutation drug resistance enhances EGFR expression in melanomas

Project description:Melanoma cell lines were assessed for differences in gene expression patterns between the lines sensitive and resistant to BRAF and MEK inhibitor drugs. 22 BRAF-mutant melanoma cell lines were assessed for response to BRAF and MEK inhibitors in a 3 day drug treatment dose response assay. Based on the IC50, 18 lines were found to be responsive to BRAF or MEK inhibition and 4 were resistant. Normalised gene expression data generated from experimental replicate affymetrix arrays was assessed to identify differential patterns of inherent gene expression between the cell lines grouped as drug-responsive or drug-resistant. This were used to idenify specific candidate genes and pathways associated with inherent BRAF/MEK inhibitor drug resistance in melanoma cells.

Project description:Treatment of BRAF-mutant melanomas with MAP-kinase pathway inhibitors is paradigmatic of the promise of precision cancer therapy but also highlights problems with drug resistance that limit patient benefit. We use live-cell imaging, single-cell analysis and molecular profiling to show that exposure of tumor cells to RAF/MEK inhibitors elicits a heterogeneous response in which some cells die, some arrest and a remaining fraction adapts to drug. Drug-adapted cells up-regulate markers of the neural crest (e.g. NGFR), a melanocyte precursor, and grow slowly. To identify genes associated with acquisition of the slowly-cycling, vemurafenib-adapted state, we performed RNA sequencing (RNA-seq) on COLO858 cells (that show the slowly-cycling phenotype) exposed to drug for 24 and 48 h; drug-treated MMACSF cells served as a control. Transcriptional profiling implicates a c-Jun/ECM/FAK/Src cascade in adaptive resistance to RAF inhibition.

Project description:A major contributor to poor sensitivity to anti-cancer kinase inhibitor therapy is drug-induced cellular adaptation, whereby remodeling of signaling and gene regulatory networks permits a drug-tolerant phenotype. Here, we resolve the scale and kinetics of critical subcellular events following oncogenic kinase inhibition and preceding cell cycle re-entry, using mass spectrometry-based phosphoproteomics and RNA sequencing to capture molecular snapshots within the first minutes, hours, and days of BRAF kinase inhibitor exposure in a human BRAF-mutant melanoma model of adaptive therapy resistance. By enriching specific phospho-motifs associated with mitogenic kinase activity, we monitored the dynamics of thousands of growth- and survival-related protein phosphorylation events under oncogenic BRAF inhibition and drug removal. We observed early and sustained inhibition of the BRAF-ERK axis, gradual downregulation of canonical cell cycle-dependent signals, and three distinct and reversible phase transitions toward quiescence. Statistical inference of kinetically-defined regulatory modules revealed a concerted response to oncogenic BRAF inhibition and a dominant compensatory induction of SRC family kinase (SFK) signaling, which we found to be at least partially driven by accumulation of reactive oxygen species via impaired redox homeostasis. This induction sensitized cells to co-treatment with an SFK inhibitor across a panel of patient-derived melanoma cell lines and in an orthotopic mouse xenograft model, underscoring the translational potential for measuring the temporal dynamics of signaling and transcriptional networks under therapeutic challenge.

Project description:The development of drug resistance is a major limiting factor to the efficacy of BRAF inhibitor therapy for melanoma. The goal of this study was to identify and characterize pathways that contribute to adaptive drug resistance to BRAF inhibitors.

Project description:Anti-BRAF mutation drug resistance enhances EGFR expression in melanomas [expression profiling]

Project description:Anti-BRAF mutation drug resistance enhances EGFR expression in melanomas [methylation profiling]