Project description:Despite KRAS-G12V being the second most common KRAS mutation in cancer, there are no approved direct KRAS-G12V inhibitors. Difficulties with inhibiting oncogenes using conventional approaches have prompted the use of RNAi as a therapeutic approach. RNAi has faced numerous obstacles as a cancer therapeutic, including the lack of cancer-specific tissue targeting, rapid oligonucleotide nuclease degradation and clearance from the circulation. Recently, the use of targetable ligands conjugated to chemically modified siRNAs has shown remarkable promise in circumventing these barriers. We demonstrate that EFTX-G12V is highly selective for KRAS-G12V and has improved therapeutic activity over pan-KRAS targeting, including enhanced inhibition of several cancer hallmarks. With a novel RNAi delivery platform, we demonstrate tumor silencing of KRAS-G12V and significant anti-tumor activity across several cancer models. Our findings represent a technologic advance in oncogene targeting using RNAi and reveal new biologic insights in KRAS targeting that may have broad implications with regards to safety and efficacy. This dataset collects the RNA-Seq data for the SKCO1 cell line.

Project description:Despite KRAS-G12V being the second most common KRAS mutation in cancer, there are no approved direct KRAS-G12V inhibitors. Difficulties with inhibiting oncogenes using conventional approaches have prompted the use of RNAi as a therapeutic approach. RNAi has faced numerous obstacles as a cancer therapeutic, including the lack of cancer-specific tissue targeting, rapid oligonucleotide nuclease degradation and clearance from the circulation. Recently, the use of targetable ligands conjugated to chemically modified siRNAs has shown remarkable promise in circumventing these barriers. We demonstrate that EFTX-G12V is highly selective for KRAS-G12V and has improved therapeutic activity over pan-KRAS targeting, including enhanced inhibition of several cancer hallmarks. With a novel RNAi delivery platform, we demonstrate tumor silencing of KRAS-G12V and significant anti-tumor activity across several cancer models. Our findings represent a technologic advance in oncogene targeting using RNAi and reveal new biologic insights in KRAS targeting that may have broad implications with regards to safety and efficacy. This dataset collects the RNA-Seq data for the H727 cell line.

Project description:Despite KRAS-G12V being the second most common KRAS mutation in cancer, there are no approved direct KRAS-G12V inhibitors. Difficulties with inhibiting oncogenes using conventional approaches have prompted the use of RNAi as a therapeutic approach. RNAi has faced numerous obstacles as a cancer therapeutic, including the lack of cancer-specific tissue targeting, rapid oligonucleotide nuclease degradation and clearance from the circulation. Recently, the use of targetable ligands conjugated to chemically modified siRNAs has shown remarkable promise in circumventing these barriers. We demonstrate that EFTX-G12V is highly selective for KRAS-G12V and has improved therapeutic activity over pan-KRAS targeting, including enhanced inhibition of several cancer hallmarks. With a novel RNAi delivery platform, we demonstrate tumor silencing of KRAS-G12V and significant anti-tumor activity across several cancer models. Our findings represent a technologic advance in oncogene targeting using RNAi and reveal new biologic insights in KRAS targeting that may have broad implications with regards to safety and efficacy. This dataset collects the RNA-Seq data for the H441 cell line.

Project description:gen107_ptgs - gene profiling in silencing suppressor plants or in mirna mutants - What are the genes that are differentially regulated in various tissues derived from silencing suppressor plants or miRNA mutants? - HcPro, P15, P19, CHS-RNAi (control), were grown on MS solid medium, and tissues were harvested at different developmental stages. dcl1-9, hen1-1 and La-er (control) were grown on MS solid medium, and tissues harvested at different developmental stages. Keywords: gene knock in (transgenic),gene knock out 40 dye-swap - Chromochip Arabidopsis thaliana 21.7K CHROMO4_1

Project description:gen107_ptgs - gene profiling in silencing suppressor plants or in mirna mutants - What are the genes that are differentially regulated in various tissues derived from silencing suppressor plants or miRNA mutants? - HcPro, P15, P19, CHS-RNAi (control), were grown on MS solid medium, and tissues were harvested at different developmental stages. dcl1-9, hen1-1 and La-er (control) were grown on MS solid medium, and tissues harvested at different developmental stages. Keywords: gene knock in (transgenic),gene knock out 60 dye-swap - CATMA arrays

Project description:Darinaparsin (DPS) is an arsenic cytotoxin with a more favorable toxicity profile than the established anti-leukemic drug, arsenic trioxide (ATO). Here we report effects of DPS on a variety of solid tumor cell lines under normoxia as well as hypoxia, the latter an important characteristic of the tumor microenvironment. Using MTT and clonogenic assays, we demonstrated that DPS had potent cytotoxic activities under both normoxia and hypoxia, with IC50??s ~ 2- to 3-fold lower than ATO. Xenograft studies using tumor cell lines as well as patient-derived tumor tissues implanted under the renal capsule in mice confirmed the anti-tumor activity of DPS in vivo. DPS was also a more potent radiosensitizer under hypoxia than ATO in vitro, and sensitized solid tumors to radiation in vivo at doses that had no systemic toxicities. Interestingly, in contrast to previous reports of DPS effects on leukemic cells under normoxia, DPS-induced killing of hypoxic solid tumor cells was not dependent on ROS generation and oxidative damage. Instead, cDNA microarray analysis suggested that DPS inhibited oncogene- (such as RAS and MYC) associated gene expression. In fact, compared to normal mouse embryonic fibroblasts (MEFs), oncogene (RAS/E1A) transformed MEFs were markedly more sensitive to DPS-induced apoptosis under both normoxia and hypoxia. Altogether, these results demonstrate that DPS has significant and preferential cytotoxicity against solid tumor as compared with normal cells, and is an effective radiosensitizer. Since DPS is in early clinical development as a single agent, these findings have near term translational potential. time_series_design

Project description:Extrachromosomal DNA (ecDNA) amplification enhances intercellular oncogene dosage variability and accelerates tumor evolution by violating foundational principles of genetic inheritance through its asymmetric mitotic segregation. Spotlighting high-risk neuroblastoma we demonstrate how ecDNA amplification undermines the clinical efficacy of current therapies in cancers with extrachromosomal MYCN amplification. Integrating theoretical models of oncogene copy number-dependent fitness with single-cell ecDNA quantification and phenotype analyses, we reveal that ecDNA copy number heterogeneity drives phenotypic diversity and determines treatment sensitivity through mechanisms unattainable by chromosomal oncogene amplification. We demonstrate that ecDNA copy number directly influences critical cell fate decisions in cancer cell lines, patient-derived xenografts and primary neuroblastomas, illustrating how extrachromosomal oncogene dosage-driven phenotypic diversity offers a strong evolutionary advantage under therapeutic pressure. Furthermore, we identify senescent ecDNA-containing cells with reduced copy numbers in neuroblastomas and other MYC-amplified cancers as a source of treatment resistance and outline a strategy for their targeted elimination to improve the poor outcome of patients with MYCN-amplified cancers.

Project description:Darinaparsin (DPS) is an arsenic cytotoxin with a more favorable toxicity profile than the established anti-leukemic drug, arsenic trioxide (ATO). Here we report effects of DPS on a variety of solid tumor cell lines under normoxia as well as hypoxia, the latter an important characteristic of the tumor microenvironment. Using MTT and clonogenic assays, we demonstrated that DPS had potent cytotoxic activities under both normoxia and hypoxia, with IC50??s ~ 2- to 3-fold lower than ATO. Xenograft studies using tumor cell lines as well as patient-derived tumor tissues implanted under the renal capsule in mice confirmed the anti-tumor activity of DPS in vivo. DPS was also a more potent radiosensitizer under hypoxia than ATO in vitro, and sensitized solid tumors to radiation in vivo at doses that had no systemic toxicities. Interestingly, in contrast to previous reports of DPS effects on leukemic cells under normoxia, DPS-induced killing of hypoxic solid tumor cells was not dependent on ROS generation and oxidative damage. Instead, cDNA microarray analysis suggested that DPS inhibited oncogene- (such as RAS and MYC) associated gene expression. In fact, compared to normal mouse embryonic fibroblasts (MEFs), oncogene (RAS/E1A) transformed MEFs were markedly more sensitive to DPS-induced apoptosis under both normoxia and hypoxia. Altogether, these results demonstrate that DPS has significant and preferential cytotoxicity against solid tumor as compared with normal cells, and is an effective radiosensitizer. Since DPS is in early clinical development as a single agent, these findings have near term translational potential.

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:While small interfering RNAs (siRNAs) have been rapidly appreciated to induce gene silencing, efficient vectors for primary cells and for systemic in vivo delivery are lacking. We here present a novel chemically modified cell-penetrating peptide named PepFect6 (PF6) for efficient delivery of siRNAs into various types of cells including e.g. lymphocyte suspension cells and primary embryonic stem cells. Stable PF6/siRNA nano- particles rapidly enter entire cell populations resulting in strong and persistent RNAi responses, without associated transcriptomic or proteomic changes. In contrast to the majority of chemical reagents, PF6-mediated delivery is independent of cell confluence and, in most cases, not significantly hampered by the presence of serum. Finally, strong RNAi responses are observed in two different in vivo models following systemic delivery of PF6/siRNA in mice. Taken together, PF6 is an efficient siRNA delivery vector with superior delivery properties as compared to other tested transfection reagents.