Project description:Reovirus propagates with high efficiency in KRAS mutated colorectal cancer (CRC). About 45-50% of CRC patients possess KRAS mutation. Oncolytic reovirus treatment in combination with chemotherapy was tested in patient samples possessing KRAS mutated metastatic CRC. This is the raw data from the peripheral mononuclear cell (PBMC) samples at 4 timepoints (pre treatment, 48 hours, day 8, and day 15).
Project description:PurposeReovirus propagates with high efficiency in KRAS mutated colorectal cancer (CRC). About 45-50% of CRC patients possess a KRAS mutation. Oncolytic reovirus treatment in combination with chemotherapy was tested in patients possessing KRAS mutated metastatic CRC. This study evaluates the biological responses to reovirus treatment by determining the gene expression patterns in RAS-related signaling pathways.MethodsReovirus was administered as a 60-min intravenous infusion for 5 consecutive days every 28 days, at a tissue culture infective dose (TCID50) of 3×1010. Peripheral blood mononuclear cells (PBMCs) were isolated from whole-blood pre- and post-reovirus administration at 48 hr, day-8, and day-15. Clariom_D_Human_Assay was used to determine the expression of vital genes compared to pre-reovirus treatment by RNA sequencing. Using exported sample signals, ΔΔCt method was used to analyze the fold changes of genes within seven gene pathways. Significance was calculated by students-two-tail-t-test. Hierarchical clustering dendrogram was constructed by calculating Pearson's correlation coefficients.ResultsAs compared to the control, SOS1[48 hr; 2.49X], RRAS [48 hr; 2.24X], PIK3CB [D8, D15; 2.27X, 3.16X], MIR 16-2 [D15; 1.70X], CHORDC1 [48 hr, D15; 1.89X, 4.54X], RTN4 [48 hr; 4.66X], FAM96A [48 hr; 4.54X], NFKB [D8, D15; 19.0X, 1.42X], CASP8 [D8, D15; 2.11X, 1.77X], and CASP9 [D8; 1.45X] are upregulated post-reovirus. NOS3 [D15; 0.61X], SYNE1 [D8, D15; 0.78X, 0.71X], ANGPT1 [D8; 0.62X], VEGFB [48 hr, D8, D15; 0.44X, 0.28X, 0.28X], JUN [D15; 0.69X], and IGF2 [D8; 0.73X] are downregulated post-reovirus. Fold change values were significant [p<0.05].ConclusionThis study highlights reovirus as a novel treatment option for KRAS mutated CRC and showcases its effect on the expression of crucial genes.
Project description:PurposeTo explore the effects of pelareorep on autophagy in multiple models of colorectal cancer, including patient-derived peripheral blood mononuclear cells (PBMCs).Experimental designHCT116 [KRAS mutant (mut)] and Hke3 [KRAS wild-type (WT)] cells were treated with pelareorep (multiplicity of infection, 5) and harvested at 6 and 9 hours. LC3 A/B expression was determined by immunofluorescence and flow cytometry; five autophagic proteins were analyzed by Western blotting. The expression of 88 autophagy genes was determined by qRT-PCR. Syngeneic mouse models, CT26/Balb-C (KRAS mut) and MC38/C57B6 (KRAS WT), were developed and treated with pelareorep (10 × 106 plaque-forming unit/day) intraperitoneally. Protein and RNA were extracted from harvested tumor tissues. PBMCs from five experimental and three control patients were sampled at 0 (pre) and 48 hours, and on days 8 and 15. The gene expression normalized to "pre" was determined using 2-ΔΔC t method.ResultsPelareorep induced significant upregulation of LC3 A/B in HCT116 as compared with Hke3 cells by immunofluorescence (3.24 × and 8.67 ×), flow cytometry (2.37 × and 2.58 ×), and autophagosome formation (2.02 × and 1.57 ×), at 6 and 9 hours, respectively; all P < 0.05. Western blot analysis showed an increase in LC3 A/B (2.38 × and 6.82 ×) and Beclin1 (1.17 × and 1.24 ×) at 6 and 9 hours, ATG5 (2.4 ×) and P-62 (1.52 ×) at 6 hours, and VPS-34 (1.39 ×) at 9 hours (all P < 0.05). Induction of 13 transcripts in cell lines (>4 ×; 6 and 9 hours; P < 0.05), 12 transcripts in CT26 (qRT-PCR), and 14 transcripts in human PBMCs (P < 0.05) was observed. LC3 A/B, RICTOR, and RASD1 expression was upregulated in all three model systems.ConclusionsPelareorep hijacks host autophagic machinery in KRAS-mut conditions to augment its propagation and preferential oncolysis of the cancer cells.
Project description:KRAS mutation is a common driver in solid tumors, and KRAS-mutated tumors are relatively resistant to radiotherapy. Therefore, we investigated the combined effect of radiation and KRAS-MEK inhibitors (AMG510 and trametinib) in KRAS-mutated tumors.
Project description:KRAS mutation is a common driver in solid tumors, and KRAS-mutated tumors are relatively resistant to radiotherapy. Therefore, we investigated the combined effect of radiation and KRAS-MEK inhibitors (AMG510 and trametinib) in KRAS-mutated tumors.
Project description:We studied the KRAS and NRAS mutational status in pediatric MLL-AF4+ leukemia patients by means of ultra deep amplicon sequencing. The gene expression profiles of RAS wild type and RAS mutated patients were investigated by gene expression analysis. We showed that mutated patients were characterized by a RAS related expression signature.
Project description:The goal for this study was to determine the effects of ethanol on pancreas cells and examine how ethanol influences protein expression in non-transformed and mutant KRAS cells. We performed TMT-labeled proteomics of non-transformed (hTERT-HPNE E6/E7) and KRAS mutated (hTERT-HPNE E6/E7/K-RasG12D) human pancreas cell lines following 6 months of 100 mM ethanol treatment.
Project description:By silencing of RALA, a downstream member of the RAS signal transduction pathway, we aimed to determine whether genes downstream of a mutated KRAS (codon 12 or 13) or a mutated BRAF can have significant functions in colorectal cancer carcinogenesis.
Project description:By silencing of RALA, a downstream member of the RAS signal transduction pathway, we aimed to determine whether genes downstream of a mutated KRAS (codon 12 or 13) or a mutated BRAF can have significant functions in colorectal cancer carcinogenesis. RALA was silenced in three colorectal cancer cell lines (SW480, HCT116 and HT29). Effects were normalized to mock-transfected cells and the effects of scramble siRNA were excluded. SW480, HCT116 and HT29 cell lines were treated with the PI3K inhibitor LY294002 or DMSO.
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