Project description:The experiment is a study of the effects of signal strength in the Ras pathway. In particular, we studied a gain-of-function mutant of Kras, KrasG12D. We generated these mutant mice and performed microarray analyses on RNA extracted from whole skin, comparing KrasG12D mice to wild-type mice, with three replicates of each.

Project description:RAS-MAPK activating mutations in NRAS, KRAS and PTPN11 were present in 24/55 (44%) cases in our series of diangosis and relapsed ALL. To evaluate the specific role of RAS-MAPK activating mutations in chemotherapy resistance in ALL we used primary isogenic leukemia cells expressing either Kras wild type or a mutant oncogenic form of Kras (Kras G12D) Mechanistically, functional dissection of Kras wild type and mutant Kras (Kras G12D) isogenic ALL cells demonstrated induction of methotrexate resistance, but also improved response to vincristine, in mutant Kras-expressing ALL cells. These results pave the road for the development of tailored personalized therapies for the treatment of relapsed ALL

Project description:Aberrant activation of RAS oncogenes is a prevalent event in lung adenocarcinoma, with somatic mutation of KRAS occurring in ~30% of tumors. Recently, we identified somatic mutation of the RAS-family GTPase RIT1 in lung adenocarcinoma, but relatively little is known about the biological pathways regulated by RIT1 and how these relate to the oncogenic KRAS network. Here we present (quantitative proteomic and) transcriptomic profiles from KRAS-mutant and RIT1-mutant isogenic lung epithelial cells and globally characterize the signaling networks regulated by each oncogene.

Project description:Breast Cancer (BC) has been associated with alterations in signaling through a number of growth factor and hormone regulated pathways. Mouse models for metastatic BC have been developed using oncoproteins that activate PI3K, Stat3 and Ras signaling. To determine the role of each pathway, we analyzed mouse mammary tumor formation when they were activated singly or pairwise. We used microarrays to detect differentially expressed genes in the KRas(G12D/+);CreT and R26(H1047R/+);KRas(G12D/+);CreT tumors Total RNA was extracted from tumors developed by Qiagen RNAeasy kit and hybridized on Affymetrix microarrays.

Project description:Mutations of the proto-oncogene KRas, together with the inactivation of the onco-suppressor genes APC and TP53, are considered to have an important role both in the carcinogenesis and in the colorectal tumor progression. The oncogene K-ras has activating mutations, especially in codon 12, in about 40% to 50% of colorectal carcinomas (Andreyev et al., 1998). The mechanism by which oncogenic K-ras alone contribuites to tumor progression in colon cancer is largely unknown. To this end, we have developed a model system where the colorectal adenocarcinoma cell line Colo741 has been stably trasfected with the Kras-G12V or Kras-G12D mutated oncogenes. Our results demonstrate how expression profiling data can be used to interpret changes in cellular characteristics induced by transfection and hence provide some clues as to the mechanisms by which different activated K-Ras impair processes mediated by endogenous wild-type KRas proteins. We made for the production of cell clones that could be utilized as useful in vitro models. The adenocarcinoma cell line Colo741 has been chosen to produce stable transfectants for two mutant forms of KRas2 (Gly12Val and Gly12Asp) and the wild-type coding sequence (as experiment control). After the transfection, the cells have been selected (with G418), cloned (by limited dilutions) and screened (by RT-PCR). The total RNAs, Dnase-treated, from five cell clones per condition, have been pooled. The samples, constituted by biotin-labeled cRNA, derived from a pool of five cell clones obtained from transfection of the adenocarcinoma cell line Colo741 with either pcDNA3.1-KRas2(Wt) or pcDNA3.1-KRas2(Gly12Val) or pcDNA3.1KRas2(Gly12Asp). They were hybridized to a Human Gene 1.0 ST array (Affymetrix). Two technical replicates have been performed for each condition.

Project description:Breast Cancer (BC) has been associated with alterations in signaling through a number of growth factor and hormone regulated pathways. Mouse models for metastatic BC have been developed using oncoproteins that activate PI3K, Stat3 and Ras signaling. To determine the role of each pathway, we analyzed mouse mammary tumor formation when they were activated singly or pairwise. We used microarrays to detect differentially expressed genes in the KRas(G12D/+);CreT and R26(H1047R/+);KRas(G12D/+);CreT tumors

Project description:KRAS mutations are present at a high frequency in human cancers. The development of therapies targeting mutated KRAS requires cellular and animal preclinical models. We exploited adeno-associated virus-mediated homologous recombination to insert the KRAS G12D allele in the genome of mouse somatic cells. Heterozygous mutant cells displayed a constitutively active Kras protein, marked morphologic changes, increased proliferation and motility but were not transformed. On the contrary, mouse cells in which we overexpressed the corresponding KRAS cDNA were readily transformed. The levels of Kras activation in knock-in cells were comparable with those present in human cancer cells carrying the corresponding mutation. KRAS-mutated cells were compared with their wild-type counterparts by gene expression profiling, leading to the definition of a "mutated KRAS-KI signature" of 345 genes. This signature was capable of classifying mouse and human cancers according to their KRAS mutational status, with an accuracy similar or better than published Ras signatures. The isogenic cells that we have developed recapitulate the oncogenic activation of Kras occurring in cancer and represent new models for studying Kras-mediated transformation. Our results have implications for the identification of human tumors in which the oncogenic KRAS transcriptional response is activated and suggest new strategies to build mouse models of tumor progression. Keywords: Genetic modification by homologous recombination in somatic cells

Project description:Mutations of the proto-oncogene KRas, together with the inactivation of the onco-suppressor genes APC and TP53, are considered to have an important role both in the carcinogenesis and in the colorectal tumor progression. The oncogene K-ras has activating mutations, especially in codon 12, in about 40% to 50% of colorectal carcinomas (Andreyev et al., 1998). The mechanism by which oncogenic K-ras alone contribuites to tumor progression in colon cancer is largely unknown. To this end, we have developed a model system where the colorectal adenocarcinoma cell line Colo741 has been stably trasfected with the Kras-G12V or Kras-G12D mutated oncogenes. Our results demonstrate how expression profiling data can be used to interpret changes in cellular characteristics induced by transfection and hence provide some clues as to the mechanisms by which different activated K-Ras impair processes mediated by endogenous wild-type KRas proteins.

Project description:Lo A, Holmes K, Mundt F, Moorthi S, Fung I, Fereshetian S, Watson J, Carr SA, Mertins P, Berger A. Aberrant activation of RAS oncogenes is a prevalent event in lung adenocarcinoma, with somatic mutation of KRAS occurring in ~30% of tumors. Recently, we identified somatic mutation of the RAS-family GTPase RIT1 in lung adenocarcinoma, but relatively little is known about the biological pathways regulated by RIT1 and how these relate to the oncogenic KRAS network. Here we present quantitative proteomic and transcriptomic profiles from KRAS-mutant and RIT1-mutant isogenic lung epithelial cells and globally characterize the signaling networks regulated by each oncogene. We find that both mutant KRAS and mutant RIT1 promote S6 kinase, AKT, and RAF/MEK signaling, and promote epithelial-to-mesenchymal transition and immune evasion via HLA protein loss. However, KRAS and RIT1 diverge in regulation of phosphoproteins including EGFR, USO1, and AHNAK proteins. The majority of the proteome changes are related to altered transcriptional regulation, but a small subset of proteins are differentially regulated at the post-transcriptional level, including intermediate filament proteins, metallothioneins, and MHC Class I proteins, which are profoundly suppressed by oncogenic KRAS and RIT1 variants. These data provide the first global, unbiased characterization of oncogenic RIT1 network and identify the shared and divergent functions of oncogenic RIT1 and KRAS GTPases in lung cancer.

Project description:Cancer treatment decisions are increasingly guided by which specific genes are mutated within each patient’s tumor. For example, agents inhibiting the epidermal growth factor receptor (EGFR) benefit many colorectal cancer (CRC) patients, with the general exception of those whose tumor includes a KRAS mutation. However, among the various KRAS mutations, the G13D mutation behaves differently; for unknown reasons, CRC patients with the KRAS G13D mutation (also written KRASG13D) appear to benefit from the EGFR-blocking antibody cetuximab. Controversy surrounds this observation, because it appears to contradict the well-established mechanisms of EGFR signaling and of RAS mutations. Here, we identified a systems-level, mechanistic basis that explains why KRASG13D cancers respond to EGFR inhibition. We first investigated the problem with a computational model of RAS signaling, which unexpectedly revealed that the known biophysical differences between the three most common KRAS mutant proteins are sufficient to generate different sensitivities to inhibition. Computation and experimentation together revealed a non-intuitive, mutant-specific dependency of wild-type RAS activation by EGFR that is determined by the interaction strength between KRAS and the tumor suppressor neurofibromin (NF1). KRAS mutants that strongly interact with NF1 drive wild-type RAS activation in an EGFR independent manner through competitive inhibition of NF1, whereas KRAS G13D cells remain dependent upon EGFR for wild-type Ras activation because they cannot competitively inhibit NF1 due to a weak interaction between these two proteins. Overall, our work demonstrates how systems approaches enable mechanism-based inference in genomic medicine and can help identify patients for selective therapeutic strategies.