Project description:The success of targeted therapies creates a need to discriminate tumors accurately by their histological and genetic characteristics. Here, we used cDNA microarray analysis to identify gene expression profiles and single markers that recapitulate the pathological and genetic background (i.e., BRAF, EGFR, KRAS, LKB1, PIK3CA, and TP53 gene alterations) of non-small cell lung cancer (NSCLC). Gene expression profiles were determined for 6 normal lung tissues and 69 lung tumors from patients diagnosed with NSCLC. We performed an unsupervised hierarchical clustering with the most variably expressed transcript to investigate whether there was evidence for natural grouping samples based on similarity in gene expression profiles. We examined the relationship between the clusters of tumors and patient and tumor characteristics such as gender, smoking status, histological type, degree of differentiation, tumor size, lymph node involvement and genetic background. We used a supervised analysis to identify the genes that are important for distinguishing subgroups of tumors defined by histological type. Moreover, we used this supervised approach to search for markers that characterize those tumors carrying EGFR, KRAS, PIK3CA and TP53 alterations. We identify several genes with characteristic patterns of expression in each tumor histological type (adenocarcinoma and squamous cell carcinoma) and we found that the presence of EGFR mutations result in a particular expression profile. Keywords: Transciption profiling of tumors with different histological and genetic background. We analyzed 69 NSCLC tumors. All the samples were characterized by histological type and by the presence of alterations at genes that are known to be involved in lung carcinogenesis. Mutational analysis of BRAF, EGFR, KRAS, and LKB1 is provided only for adenocarcinomas and analysis of alterations at PIK3CA gene (mutational analysis or gene amplification by FISH analysis) is provided only for 47 of the tumors. We analyzed gene expression profiles to identify those genes that are differentially expressed between two subgroups by t-test: 1) adenocarcinomas vs. squamous cell carcinomas; 2) tumors with mutation at EGFR gene vs. wild type tumors; 3) tumors with mutation at KRAS gene vs. wild type tumors; 4) tumors with mutation at TP53 gene vs. wild type tumors; 5) tumors with alterations (mutation or gene amplification) at PIK3CA gene vs. wild type tumors.

Project description:Purpose: The uncommonness of gallbladder cancer in the developed world has contributed to the generally poor understanding of the disease. The development of new and effective treatment has been and continues to be a major public health imperative. Methods: We report mutational and copy number analysis of 44 predominantly early-staged gallbladder tumors and 5-gallbladder cancer cell lines by a combination of directed and whole exome sequencing at an average coverage of 100X and above. Using gallbladder cancer cell lines and xenograft mouse models we performed phospho-proteome array profiling, followed by an in-depth functional characterization. Results: We describe recurrent activating ERBB2 somatic mutation in 6 of 44 gallbladder primary tumors with an overall mutation frequency of 13%, along with KRAS activating mutations in 3 of 44 samples. Consistent with whole exome findings, a phospho-proteomic array profile of 49-tyrosine kinase revealed constitutive phosphorylation of ERBB2 and EGFR that were found to heterodimerize. We demonstrate that treatment with ERBB2-specific, EGFR-specific shRNA or with covalent EGFR family inhibitor BIBW-2992 inhibits transformation, survival, migration, invasion, and tumor forming characteristics of gallbladder cancer cells harboring wild type or KRAS (G13D) but not KRAS (G12V) mutation. Furthermore, we show in vivo reduction in tumor size is paralleled by a reduction in the amounts of phospho-ERK in KRAS (G13D) but not in KRAS (G12V) xenografts, validating the in vitro findings Conclusion: Findings from this study implicate ERBB2 as an important therapeutic target in early stage gallbladder cancer. We also present the first evidence that the presence of KRAS (G12V), but not KRAS (G13D) mutation, may preclude gallbladder cancer patients to respond to anti-EGFR treatment, similar to the clinical algorithm commonly practiced to opt for anti-EGFR treatment in colorectal cancer.

Project description:INTRODUCTION: CDKN2A (p16) inactivation is common in lung cancer and occurs via homozygous deletions, methylation of promoter region, or point mutations. Although p16 promoter methylation has been linked to KRAS mutation and smoking, the associations between p16 inactivation mechanisms and other common genetic mutations and smoking status are still controversial or unknown. METHODS: We determined all three p16 inactivation mechanisms with the use of multiple methodologies for genomic status, methylation, RNA, and protein expression, and correlated them with EGFR, KRAS, STK11 mutations and smoking status in 40 cell lines and 45 tumor samples of primary non-small-cell lung carcinoma. We also performed meta-analyses to investigate the impact of smoke exposure on p16 inactivation. RESULTS: p16 inactivation was the major mechanism of RB pathway perturbation in non-small-cell lung carcinoma, with homozygous deletion being the most frequent method, followed by methylation and the rarer point mutations. Inactivating mechanisms were tightly correlated with loss of mRNA and protein expression. p16 inactivation occurred at comparable frequencies regardless of mutational status of EGFR, KRAS, and STK11, however, the major inactivation mechanism of p16 varied. p16 methylation was linked to KRAS mutation but was mutually exclusive with EGFR mutation. Cell lines and tumor samples demonstrated similar results. Our meta-analyses confirmed a modest positive association between p16 promoter methylation and smoking. CONCLUSION: Our results confirm that all the inactivation mechanisms are truly associated with loss of gene product and identify specific associations between p16 inactivation mechanisms and other genetic changes and smoking status. 40 NSCLC cell lines were profiled on Illumina WG6-V3 expression arrays. They consist of 4 groups of 10 cell lines each: non-smokers with EGFR mutation, non-smokers with EGFR wild-type, smokers with KRAS mutation, smokers with KRAS wild-type. Note that smoking status is not always clear.

Project description:Identification of genes up-regulated in ALK-positive and EGFR/KRAS/ALK-negative lung adenocarcinomas. To elucidate molecular characteristics of lung adenocarcinomas (ADCs) with ALK mutations and those without EGFR, KRAS and ALK mutations, 226 primary lung ADCs of pathological stage I-II, examined for the status of EGFR, KRAS and ALK mutations, were subjected to genome-wide expression profiling, and genes up-regulated in lung ADCs with ALK mutations and those without EGFR, KRAS and ALK mutations were identified. One hundred and seventy-four genes, including ALK, were selected as being up-regulated specifically in 79 lung ADCs without EGFR and KRAS mutations. These 79 cases were divided into: 11 cases of ALK-positive ADCs, 36 cases of group A triple-negative ADCs, and 32 cases of group B triple-negative ADCs, by unsupervised clustering according to the expression of the 174 genes. In ALK-positive ADCs, 30 genes, including ALK itself and GRIN2A, were significantly overexpressed. Group A triple-negative ADC cases showed significantly worse prognoses for relapse and death than ADC cases with EGFR, KRAS or ALK mutations and group B triple-negative ADC cases. Nine genes were identified as being significantly up-regulated in group A triple-negative ADC cases and critical for predicting their prognosis. The nine genes included DEPDC1, which had been identified as a candidate diagnostic and therapeutic target in bladder and breast cancers. Genes discriminating this group of ADCs will be useful for selection of patients who will benefit from adjuvant chemotherapy after surgical resection of stage I-II triple-negative ADCs and also informative for the development of molecular targeting therapies for these patients. Expression profiles in of 226 lung adenocarcinomas (127 with EGFR mutation, 20 with KRAS mutation, 11 with EML4-ALK fusion and 68 triple negative cases).

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.

Project description:RAS is one of the most frequently mutated proto-oncogenes in human malignancies, with mutation sites and subtypes exhibiting tumor-type dependent distribution. Oncogenic RAS mutations will maintain continuously GTP-bound activation states that leading to dysregulation of downstream signaling, ultimately disrupting cellular homeostasis to induce malignant transformation of cells. In this study, we employed TurboID proximity-labeling technology integrated with quantitative proteomics LC-MS/MS to systematically characterize the proximal binding proteins of wild-type KRAS and three high-frequency oncogenic mutant subtypes G12C, G12D and G12V. Through comprehensive bioinformatic analysis of mutation-specific interaction networks and distinct metabolic pathways, we identified significant enrichment of mutant KRAS binding proteins in insulin signaling pathway, reactive oxygen species related pathways, glucose and lipid metabolism and so on. Metabolic reprogramming pathways in KRAS G12 mutations collectively fuel tumor proliferation and immune evasion. In addition, we also comparatively analyzed the proximal binding proteins similarity in three G12 mutants. Notably, we observed that the KRAS E3 ubiquitin ligase adaptor LZTR1 diminished binding with mutations, and the mTORC1 important regulatory protein LAMTOR1 was enhanced recruitment by mutations. This multi-dimensional profiling delineates a comprehensive mapping of KRAS WT and G12 mutant interactomes and unveils the metabolic reprogramming pathways associated with KRAS activating mutations. Our analysis result provides potential therapeutic targets for KRAS-driven tumorigenesis while establishing a mechanistic framework for developing KRAS mutation-specific therapeutic strategies.

Project description:Sarcomas are a biologically complex group of tumors of mesenchymal origin. By using gene expression microarray analysis, we aimed to find clues into the cellular differentiation and oncogenic pathways active in these tumors as well as potential biomarkers and therapeutic targets. We examined 181 tumors representing 16 classes of human bone and soft tissue sarcomas on a 12,601-feature cDNA microarray. Remarkably, 2,766 probes differentially expressed across this sample set clearly delineated the various tumor classes. Several genes of potential biological and therapeutic interest were associated with each sarcoma type, including specific tyrosine kinases, transcription factors, and homeobox genes. We also identified subgroups of tumors within the liposarcomas, leiomyosarcomas, and malignant fibrous histiocytomas. We found significant gene ontology correlates for each tumor group and identified similarity to normal tissues by Gene Set Enrichment Analysis. Mutation analysis done on 275 tumor samples revealed that the high expression of epidermal growth factor receptor (EGFR) in certain tumors was not associated with gene mutations. Finally, to further the investigation of human sarcoma biology, we have created an online, publicly available, searchable database housing the data from the gene expression profiles of these tumors (http://watson.nhgri.nih.gov/sarcoma), allowing the user to interactively explore this data set in depth. Keywords = sarcoma Keywords = cDNA Keywords = tumor profiling Common reference, multiclass gene profiling

Project description:Colorectal cancer (CRC) is still one of the most common causes of cancer-related death worldwide (World Health Organization, Fact sheet NM-BM-0297, October 2011). Though, therapeutic options improved over the past years, the prognosis of metastatic colorectal cancer (mCRC) remains poor with a median survival of 18-21 months. Monoclonal antibodies targeting the epidermal growth factor receptor (EGFR) are used for the palliative treatment of metastatic colorectal cancer (mCRC) carrying a KRAS-wildtype. Among the tumors with a KRAS-wildtype, only 35% respond, and alterations of other signaling molecules and pathways modulate therapeutic response. In this study we analyzed the effect of KRAS-mutations on intracellular signaling cascades to find new therapeutic approaches for patients with mCRC. Reverse-phase protein array and gene array technology was applied to sixteen adenocarcinomas of the sigmoid colon carrying either wildtype (n=8) or mutant (n=8) KRAS. Differential expression was validated on 49 sigmoid cancers by RT-PCR, Western blot and immunohistochemistry. In a screening for members of signaling pathways known to have a high impact on tumor development in colon cancer, we found 14 proteins downregulated in tumors with mutated KRAS. Subsequently, we compared the data of the protein arrays with the results of gene expression arrays performed with the same samples. We confirmed the differential expression of eight genes as a function of the KRAS genotype of the tumor. To further validate the differential expression of these candidates, we performed quantitative expression analysis and immunohistochemical staining of an independent validation series comprising 49 CRC patient samples. It was clearly demonstrated that the expression of EGFR is decreased in colorectal carcinomas with a mutant KRAS genotype. mRNA was obtained from 16 patients with colorectal cancer (8 with and 8 without KRAS-mutation). mRNA was extracted from neoplastic and non-neoplastic colon mucosa and analyzed separately by Affymetrix Human Gene 1.1 ST GeneChips finally generating 32 separate data sets.

Project description:A Cartes d'Identite des Tumeurs (CIT) project from the French National League Against Cancer (http://cit.ligue-cancer.net ) : 165 lung adenocarcinomas without prior chemotherapy, hybridized on Illumina SNP HumanCNV370 and Affymetrix HGU133Plus2 arrays. Project leader : Prof. Pierre FOURET (pierre.fouret@igr.fr). Note: Bronchiolo-alveolarComponent : a non invasive tumor component shown in well differentiated tumor cells. EGFR Gene Mutation Status: Gene mutation status of epidermal growth factor receptor (erythroblastic leukemia viral (v; -erb-b) ; oncogene homolog, avian) ; HGNC:3236 ; Approved Symbol:EGFR; Chromosome:7p12 ; UniProt ; ID:P00533 ; OMIMID:131550 ; EntrezGeneID:1956 ; ; RefSeq:NM_201283 ; M=mutated ; WT=non mutated=wild type. KRAS Gene Mutation Status: Gene mutation status of v-Ki-ras2 Kirsten rat ; sarcoma viral oncogene homolog ; HGNC:6407 ; Approved Symbol:KRAS ; Chromosome:12p12.1 ; UniProtID:P01116; OMIM ID:190070 ; EntrezGeneID:3845 ; ;RefSeq:NM_033360 ; M=yes=mutated ; WT=non mutated.

Project description:While mutations in the KRAS oncogene are amongst the most prevalent in human cancer, there are few successful treatments to target these tumors. It is also likely that heterogeneity in KRAS-mutant tumor biology significantly contributes to the response to therapy. We hypothesized that presence of commonly co-occurring mutations in STK11 and TP53 tumor suppressors may represent a significant source of heterogeneity in KRAS-mutant tumors. To address this, we utilized a large cohort of resected tumors from 442 lung adenocarcinoma patients with data including annotation of prevalent driver mutations (KRAS, EGFR) and tumor suppressor mutations (STK11 and TP53), microarray-based gene expression and clinical covariates including overall survival (OS). Specifically, we determined impact of STK11 and TP53 mutations on a new KRAS mutation-associated gene expression signature as well as previously defined signatures of tumor cell proliferation and immune surveillance responses. Interestingly, STK11, but not TP53 mutations, were associated with highly elevated expression of KRAS mutation-associated genes. Mutations in TP53 and STK11 also impacted tumor biology regardless of KRAS status, with TP53 strongly associated with enhanced proliferation and STK11 with suppression of immune surveillance. These findings illustrate the remarkably distinct ways through which tumor suppressor mutations may contribute to heterogeneity in KRAS-mutant tumor biology. In addition, these studies point to novel associations between gene mutations and immune surveillance that could impact the response to immunotherapy.