Project description:Oncogenic KRAS mutations are prevalent in colorectal cancer (CRC) and are associated with poor prognosis and resistance to therapy. There is a substantial diversity of KRAS mutant alleles observed in CRC. Emerging clinical and experimental analysis of common KRAS mutations suggest that each mutation differently influences the clinical properties of a disease and response to therapy. Although there is some evidence to suggest biological differences between mutant KRAS alleles, these are yet to be fully elucidated. One approach to study allelic variation involves the use of isogenic cell lines that express different endogenous Kras mutants. Here, we generated Kras isogenic Apc-/- mouse colon epithelial cell lines using CRISPR-driven genome editing by altering the original G12D Kras allele to G12V, G12R, or G13D. We utilized these cell lines to perform transcriptomic and proteomic analysis to compare different signaling properties between these mutants. Both screens indicate significant differences in pathways relating to cholesterol and lipid regulation that we validated with targeted metabolomic measurements and isotope tracing. We found that these processes are upregulated in G12V lines through increased expression of nuclear SREBP1 and higher activation of mTORC1. G12V cells showed higher expression of ACSS2 and ACSS2 inhibition sensitized G12V cells to MEK inhibition. Finally, we found that ACSS2 plays a crucial role early in the development of G12V mutant tumors, in contrast to G12D mutant tumors. These observations highlight differences between KRAS mutant cell lines in their signaling properties. Further exploration of these pathways may prove to be valuable for understanding how specific KRAS mutants function, and identification of novel therapeutic opportunities in CRC.

Project description:The design of potent RAS inhibitors benefits from a molecular understanding of the dynamics in KRAS and NRAS and their oncogenic mutants. Here we characterize switch-1 dynamics in GTP-state KRAS and NRAS by 31P NMR, by 15N relaxation dispersion NMR, hydrogen-deuterium exchange mass spectrometry (HDX-MS), and molecular dynamics simulations. In GMPPNP-bound KRAS and NRAS, we see the co-existence of two conformational states, corresponding to an “inactive” state-1 and an “active” state-2, as previously reported. The KRAS oncogenic mutations G12D, G12C and G12V only slightly affect this equilibrium towards the “inactive” state-1, with rank order wt < G12C < G12D < G12V. In contrast, the NRAS Q61R oncogenic mutation shifts the equilibrium fully towards the “active” state-2. Our molecular dynamics simulations explain this by the observation of a transient hydrogen bond between the Arg61 side chain and the Thr35 backbone carbonyl oxygen. NMR relaxation dispersion experiments with GTP-bound KRAS Q61R confirm a drastic decrease in the population of state-1, but still detect a small residual population (1.8%) of this conformer. HDX-MS indicates that higher populations of state-1 correspond to increased hydrogen-deuterium exchange rates in some regions and increased flexibility, whereas low state-1 populations are associated with KRAS rigidification. We elucidated the mechanism of action of a potent KRAS G12D inhibitor, MRTX1133. Binding of this inhibitor to the switch-2 pocket causes a complete shift of KRAS G12D towards the “inactive” conformation and prevents binding of effector RAS-binding domain (RBD), by signaling through an allosteric network.

Project description:Oncogenic KRAS mutations are prevalent in colorectal cancer (CRC) and are associated with poor prognosis and resistance to therapy. There is a substantial diversity of KRAS mutant alleles observed in CRC. Emerging clinical and experimental analysis of common KRAS mutations suggest that each mutation differently influences the clinical properties of a disease and response to therapy. Although there is some evidence to suggest biological differences between mutant KRAS alleles, these are yet to be fully elucidated. One approach to study allelic variation involves the use of isogenic cell lines that express different endogenous Kras mutants. Here, we generated Kras isogenic Apc-/- mouse colon epithelial cell lines using CRISPR-driven genome editing by altering the original G12D Kras allele to G12V, G12R, or G13D. We utilized these cell lines to perform transcriptomic and proteomic analysis to compare different signaling properties between these mutants. Both screens indicate significant differences in pathways relating to cholesterol and lipid regulation that we validated with targeted metabolomic measurements and isotope tracing. We found that these processes are upregulated in G12V lines through increased expression of nuclear SREBP1 and higher activation of mTORC1. G12V cells showed higher expression of ACSS2 and ACSS2 inhibition sensitized G12V cells to MEK inhibition. Finally, we found that ACSS2 plays a crucial role early in the development of G12V mutant tumors, in contrast to G12D mutant tumors. These observations highlight differences between KRAS mutant cell lines in their signaling properties. Further exploration of these pathways may prove to be valuable for understanding how specific KRAS mutants function, and identification of novel therapeutic opportunities in CRC.

Project description:We have generated a novel Kras-LSL-Q61R allele. Here, we aim to evaluate the expression of the Kras isoforms and if the mutant Kras alleles (G12D and Q61R) express similar levels to one another and Kras WT.

Project description:That mutational activation of Kras and inactivation of p16 are two signature genetic alterations required for development of PDAC. To elucidate the downstream pathways activated by oncogenic Kras and inactivated p16 in human pancreatic tumorigenesis, we profiled gene expression in HPNE/Kras/shp16 and HPNE/Kras cells using cDNA microarray analysis.

Project description:We report the RNAseq data from uterine tissues obtained from mice that over-express KRAS-G12D or KRAS-G12V oncogenes in a Ahmr2-Cre Pten null genetic background.

Project description:To explore the distinct mechanism of KRAS G12V and G12D mutation. We used microarray to explore the distinct differences in gene expression profiles of H838 KRAS mutation isogenic cell lines

Project description:KRAS is a proto-oncogene encoding a small GTPase. Mutations contribute up to 30% of human solid tumours including lung adenocarcinoma, pancreatic and colorectal carcinomas. Most KRAS activating mutations interfere with GTP hydrolysis, essential for its role as a molecular switch, leading to alterations in their molecular environment and oncogenic signalling. Here, APEX-2 proximity labelling was used to profile the molecular environment of wild type and G12D, G13D and Q61H activating mutants of KRAS under both, starvation and stimulation conditions. We demonstrate by quantitative proteomics the presence of known interactors of KRAS including a-RAF and LZTR1, which varied in abundance with wildtype and KRAS mutants. Notably, the KRAS mutations G12D, G13D and Q61H abrogate association with LZTR1. Wildtype KRAS and LZTR1, as part of the CUL3 ubiquitin E3 ligase complex, affect each other’s protein stability.

Project description:Inflammation in the context of pancreatic injury drives acinar-to-ductal metaplasia (ADM), a cell state that can be hijacked by mutant Kras to drive the formation of pancreatic cancer. ADM has been described alternatively to bear progenitor features, but the extent to which lineage reversion is a broad feature of the response to injury and early tumorigenesis – particularlyacross the different mutant Kras alleles – remains poorly understood. Herein we implement novel Ptf1a-tdTomato mice to characterize early and late pancreatic progenitors to serve as benchmarks that define cell fate decisions in the context of inflammatory injury and initiation. In so doing, we define ADM as a mixed-lineage transcriptomic and epigenetic state, harboring ductal features but also featuring a lineage reversion to a late progenitor program. By contrast, while inducible mutant Kras alone is able to induce oncogenic gene expression, it does little to alter chromatin in the absence of injury. The most frequent Kras mutant alleles – G12D, G12V, and G12R – display differential cooptation of the injury-induced mixed-lineage state, with mutant KrasG12D able to form ADM and PanIN more robustly than either KrasG12V or KrasG12R. In particular, KrasG12R fails to promote phenotypic transformation on its own or even in concert with inflammatory injury. Whereas KrasG12Dand injury induce enhancer reprogramming at AP-1 chromatin and a lineage reversion to resemble early progenitors, KrasG12Rcan initiate but not sustain the key cell-intrinsic transcriptional and epigenetic programs characteristic of neoplasia. In KrasG12R we identify a decrease in Rac1 signaling, not AKT activation, as the key molecular defect. Together, these data demonstrate that the PDAC-associated Kras variants are not functionally equivalent and distinctly drive lineage reversion and epigenetic reprogramming, such that allele-specific approaches will be essential to therapeutic targeting in pancreatic cancer.

Project description:Inflammation in the context of pancreatic injury drives acinar-to-ductal metaplasia (ADM), a cell state that can be hijacked by mutant Kras to drive the formation of pancreatic cancer. ADM has been described alternatively to bear progenitor features, but the extent to which lineage reversion is a broad feature of the response to injury and early tumorigenesis – particularlyacross the different mutant Kras alleles – remains poorly understood. Herein we implement novel Ptf1a-tdTomato mice to characterize early and late pancreatic progenitors to serve as benchmarks that define cell fate decisions in the context of inflammatory injury and initiation. In so doing, we define ADM as a mixed-lineage transcriptomic and epigenetic state, harboring ductal features but also featuring a lineage reversion to a late progenitor program. By contrast, while inducible mutant Kras alone is able to induce oncogenic gene expression, it does little to alter chromatin in the absence of injury. The most frequent Kras mutant alleles – G12D, G12V, and G12R – display differential cooptation of the injury-induced mixed-lineage state, with mutant KrasG12D able to form ADM and PanIN more robustly than either KrasG12V or KrasG12R. In particular, KrasG12R fails to promote phenotypic transformation on its own or even in concert with inflammatory injury. Whereas KrasG12Dand injury induce enhancer reprogramming at AP-1 chromatin and a lineage reversion to resemble early progenitors, KrasG12Rcan initiate but not sustain the key cell-intrinsic transcriptional and epigenetic programs characteristic of neoplasia. In KrasG12R we identify a decrease in Rac1 signaling, not AKT activation, as the key molecular defect. Together, these data demonstrate that the PDAC-associated Kras variants are not functionally equivalent and distinctly drive lineage reversion and epigenetic reprogramming, such that allele-specific approaches will be essential to therapeutic targeting in pancreatic cancer.