Approximately 200 BRAF mutant alleles have been identified in human tumours. Activating BRAF mutants cause feedback inhibition of GTP-bound RAS, are RAS-independent and signal either as active monomers (class 1) or constitutively active dimers (class 2)1. Here we characterize a third class of BRAF mutants—those that have impaired kinase activity or are kinase-dead. These mutants are sensitive to ERK-mediated feedback and their activation of signalling is RAS-dependent. The mutants bind more tightly than wild-type BRAF to RAS–GTP, and their binding to and activation of wild-type CRAF is enhanced, leading to increased ERK signalling. The model suggests that dysregulation of signalling by these mutants in tumours requires coexistent mechanisms for maintaining RAS activation despite ERK-dependent feedback. Consistent with this hypothesis, melanomas with these class 3 BRAF mutations also harbour RAS mutations or NF1 deletions. By contrast, in lung and colorectal cancers with class 3 BRAF mutants, RAS is typically activated by receptor tyrosine kinase signalling. These tumours are sensitive to the inhibition of RAS activation by inhibitors of receptor tyrosine kinases. We have thus defined three distinct functional classes of BRAF mutants in human tumours. The mutants activate ERK signalling by different mechanisms that dictate their sensitivity to therapeutic inhibitors of the pathway.
The enteric nervous system (ENS) is the largest component of the autonomic nervous system with neuron numbers surpassing those present in the spinal cord1. The ENS has been called the “second brain”1 given its autonomy, remarkable neurotransmitter diversity and complex cytoarchitecture. Defects in ENS development are responsible for many human disorders including Hirschsprung's disease (HSCR). HSCR is a caused by the developmental failure of ENS progenitors to migrate into the GI tract in particular the distal colon2. Human ENS development remains poorly understood due to the lack of an easily accessible model system.Here we demonstrate the efficient derivation and isolation of ENS progenitors from human pluripotent stem cells (hPSCs) and their further differentiation into functional enteric neurons. In vitro derived ENS precursors are capable of targeted migration in the developing chick embryo and extensive colonization of the adult mouse colon. In vivo engraftment and migration of hPSC-derived ENS precursors rescues disease-related mortality in HSCR mice (EDNRBs-l/s-l), though mechanism of action remains unclear. Finally, EDNRB null mutant ENS precursors enable modeling of HSCR-related migration defects and the identification of Pepstatin A as candidate therapeutics. Our study establishes the first hPSC-based platform for the study of human ENS development and presents cell and drug-based strategies for the treatment of HSCR.
Most KRAS G12C mutant non-small cell lung cancer (NSCLC) patients experience clinical benefit from selective KRAS G12C inhibition, while patients with colorectal cancer (CRC) bearing the same mutation rarely respond. To investigate the cause of the limited efficacy of KRAS G12C inhibitors in CRC, we examined the effects of AMG510 in KRAS G12C CRC cell lines. Unlike NSCLC cell lines, KRAS G12C CRC models have high basal receptor tyrosine kinase (RTK) activation and are responsive to growth factor stimulation. In CRC lines, KRAS G12C inhibition induces higher phospho-ERK rebound than in NSCLC cells. Although upstream activation of several RTKs interferes with KRAS G12C blockade, we identify EGFR signaling as the dominant mechanism of CRC resistance to KRAS G12C inhibitors. The combinatorial targeting of EGFR and KRAS G12C is highly effective in CRC cells, patient-derived organoids and xenografts, suggesting a novel therapeutic strategy to treat KRAS G12C CRC patients.
assisted with the initial computational analyses. H.Z. helped with the mouse in vivo experiment. K.J. assisted with patient selection. P.R. performed the nested control study, and assisted with patient sample procurement and survival analyses. P.R. and C.S. also performed the patient clinical annotation. J.S.R. viewed the FFPE slides, performed the laser microdissection and provided intellectual support. C.K. supervised the SWI/SNF complex ChIP-seq, helped with the SWI/SNF complex ChIP-seq data interpretation and provided intellectual insights.
Purpose: Defects in genes in the DNA repair pathways significantly contribute to prostate cancer progression. We hypothesize that overexpression of DNA repair genes may also drive poorer outcomes in prostate cancer. The ribonucleotide reductase small subunit M2 (RRM2) is essential for DNA synthesis and DNA repair by producing dNTPs. It is frequently overexpressed in cancers, but very little is known about its function in prostate cancer.Experimental Design: The oncogenic activity of RRM2 in prostate cancer cells was assessed by inhibiting or overexpressing RRM2. The molecular mechanisms of RRM2 function were determined. The clinical significance of RRM2 overexpression was evaluated in 11 prostate cancer clinical cohorts. The efficacy of an RRM2 inhibitor (COH29) was assessed in vitro and in vivo. Finally, the mechanism underlying the transcriptional activation of RRM2 in prostate cancer tissue and cells was determined.Results: Knockdown of RRM2 inhibited its oncogenic function, whereas overexpression of RRM2 promoted epithelial mesenchymal transition in prostate cancer cells. The prognostic value of RRM2 RNA levels in prostate cancer was confirmed in 11 clinical cohorts. Integrating the transcriptomic and phosphoproteomic changes induced by RRM2 unraveled multiple oncogenic pathways downstream of RRM2. Targeting RRM2 with COH29 showed excellent efficacy. Thirteen putative RRM2-targeting transcription factors were bioinformatically identified, and FOXM1 was validated to transcriptionally activate RRM2 in prostate cancer.Conclusions: We propose that increased expression of RRM2 is a mechanism driving poor patient outcomes in prostate cancer and that its inhibition may be of significant therapeutic value.
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