Project description:Cancer is a heterocellular disease composed of tumor cells and stromal cells. Although stromal cells are known to regulate cancer progression, oncogene-dependent signalling through heterocellular cancer systems remains poorly elucidated. Here, we describe KRASG12D-dependent ‘reciprocal’ signalling across tumor and stromal Pancreatic Ductal Adenocarcinoma (PDA) cells. Heterocellular multivariate phosphoproteomics demonstrates how an oncogenic cue (KRASG12D), a trans-cellular signal (SHH), and stromal cells drive a reciprocal response in tumor cells. KRASG12D-dependent reciprocal signalling regulates the tumor cell phosphoproteome, total proteome, and mitochondria activity via an IGFR1/AXL-AKT axis. The reciprocal KRASG12D signalling state requires a heterocellular context and is unreachable by cell-autonomous oncogenic KRAS alone. These findings provide evidence that oncogenic KRAS regulates tumor cells via heterocellular reciprocation. Comparison between FACS resolved iKRAS cells (previously in co-culture with PSCs) pertubed with a SHH antibody

Project description:Cancer is a heterocellular disease composed of tumor cells and stromal cells. Although stromal cells are known to regulate cancer progression, oncogene-dependent signalling through heterocellular cancer systems remains poorly elucidated. Here, we describe KRASG12D-dependent ‘reciprocal’ signalling across tumor and stromal Pancreatic Ductal Adenocarcinoma (PDA) cells. Heterocellular multivariate phosphoproteomics demonstrates how an oncogenic cue (KRASG12D), a trans-cellular signal (SHH), and stromal cells drive a reciprocal response in tumor cells. KRASG12D-dependent reciprocal signalling regulates the tumor cell phosphoproteome, total proteome, and mitochondria activity via an IGFR1/AXL-AKT axis. The reciprocal KRASG12D signalling state requires a heterocellular context and is unreachable by cell-autonomous oncogenic KRAS alone. These findings provide evidence that oncogenic KRAS regulates tumor cells via heterocellular reciprocation.

Project description:Oncogenic mutations in tumor cells regulate signaling both within tumor cells and heterotypic stromal cells. However, whether oncogenes regulate tumor cell signaling via stromal cells is poorly understood. Here we show that oncogenic KRAS (KRAS-G12D) uniquely regulates tumor cell signaling via stromal cells. By combining cell-specific proteome labeling with phosphoproteomic multiplexing we conducted a multivariate analysis of heterocellular KRAS-G12D signaling in Pancreatic Ductal Adenocarcinoma (PDA) cells. By engaging heterotypic fibroblasts, KRAS-G12D drives unique reciprocal signaling in tumor cells to employ additional kinases and double the number of regulated signaling nodes from cell-autonomous KRAS-G12D. Heterocellular signaling produces a distinct tumor cell phosphoproteome, total proteome, and increase mitochondria capacity via an IGF1R/AXL-AKT axis. Reciprocal KRAS-G12D phenotypes require a heterocellular context and are unreachable by cell-autonomous KRAS-G12D alone. These results demonstrate oncogene signaling should be viewed as a heterocellular process and our existing homocellular perspective underrepresents the extent of oncogene signaling in cancer.

Project description:Subcutanesouly tumors from both Bmal1+/+ and Bmal1-/- mice were used to isolated stromal vascular fractions (SVF). Tumor cells with GFP+ signals were exclusive. Remain GFP- cells were collected to do RNAseq.

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Project description:Oncogene-induced senescence (OIS) is a tumor suppression mechanism that blocks cell proliferation in response to oncogenic signalling. OIS is frequently accompanied by multinucleation; however, the origin of this is unknown. Here we show that multinucleate OIS cells originated mostly from failed mitosis. Prior to senescence, mutant RasV12 activation in primary human fibroblasts compromised mitosis, associated with abnormal expression of mitotic genes that enter M-phase. Simultaneously, RasV12 activation enhanced survival of damaged mitoses, culminating in extended mitotic arrest and aberrant exit from mitosis via mitotic slippage. ERK-dependent transcriptional up-regulation of Mcl1 was responsible for enhanced slippage of cells with mitotic defects and subsequent cell survival. Importantly, mitotic slippage and oncogene signalling synergistically induced senescence and key senescence regulators p21 and p16. We propose that activated Ras induces transcriptional changes that predispose cells undergoing OIS to mitotic stress and multinucleation. We used RNA-seq of IMR90 cells with inducible expression of oncogenic RasV12 that were synchronised in mitosis, to characterise the nature of mitotic defects that lead to multinucleation of oncogene-induced senescent cells

Project description:To characterize the genetic basis of hybrid male sterility in detail, we used a systems genetics approach, integrating mapping of gene expression traits with sterility phenotypes and QTL. We measured genome-wide testis expression in 305 male F2s from a cross between wild-derived inbred strains of M. musculus musculus and M. m. domesticus. We identified several thousand cis- and trans-acting QTL contributing to expression variation (eQTL). Many trans eQTL cluster into eleven ‘hotspots,’ seven of which co-localize with QTL for sterility phenotypes identified in the cross. The number and clustering of trans eQTL - but not cis eQTL - were substantially lower when mapping was restricted to a ‘fertile’ subset of mice, providing evidence that trans eQTL hotspots are related to sterility. Functional annotation of transcripts with eQTL provides insights into the biological processes disrupted by sterility loci and guides prioritization of candidate genes. Using a conditional mapping approach, we identified eQTL dependent on interactions between loci, revealing a complex system of epistasis. Our results illuminate established patterns, including the role of the X chromosome in hybrid sterility.