Project description:Papillary thyroid cancer (PTC) is the most common type of endocrine malignancy. From a set of PTC patients whose tumor did not harbour any BRAF or RAS mutations, a 35 years old male patient’s normal, primary tumor and lymph node (LN) metastatic tissues were subjected to genomics and proteomics analysis. By RNA-seq analysis, we identified a novel RET rearrangement involving exons 1-4 from the 5’ end of the Trk fused Gene (TFG) fused to the 3’ end of RET tyrosine kinase leading to a TFG-RET fusion which transforms immortalized human thyroid cells in a kinase-dependent manner. Further, TFG-RET oncogene oligomerises in a PB1 domain-dependent manner and consistently, mutation of the oligomerisation interface led to the inhibition of RET-mediated oncogenic transformation. Quantitative proteomic analysis of the same samples revealed the upregulation of proteins involved in the ubiquitination machinery including E3 Ubiquitin ligase HUWE1 and DUBs like USP9X and UBP7 in both tumor and LN metastatic lesions. We further identified that expression of TFG-RET led to the upregulation of HUWE1. Further, in a cohort of PTC patients, we observed higher expression of HUWE1, USP9X and USP7 in the tumor and metastatic lesions, when compared to the matched normal tissue. Transient knockdown of HUWE1, USP9X and USP7 affected viability and proliferation of TFG-RET transformed cells. Consistently, inhibition of RET, HUWE1 and DUBs by small molecule inhibitors significantly reduced RET-mediated oncogenesis. Apart from unveiling a novel oncogenic RET fusion in PTCs, our data may open a novel avenue of targeting ubiquitin signaling machinery in human PTCs.

Project description:Papillary thyroid cancer (PTC) is the most common type of endocrine malignancy. From a set of PTC patients whose tumor did not harbour any BRAF or RAS mutations, a 35 years old male patient’s normal, primary tumor and lymph node (LN) metastatic tissues was subjected to genomics and proteomics analysis. By RNA-seq analysis, we identified a novel RET rearrangement involving exons 1-4 from the 5’ end of the Trk fused Gene (TFG) fused to the 3’ end of RET tyrosine kinase leading to a TFG-RET fusion which transforms immortalized human thyroid cells in a kinase dependent manner. Further, TFG-RET oncogene oligomerises in a PB1 domain dependent manner and consistently, mutation of the oligomerisation interface led to the inhibition of RET-mediated oncogenic transformation. Quantitative proteomic analysis of the same samples revealed the upregulation of proteins involved in the ubiquitination machinery including HECT carrying E3 Ubiquitin ligase HUWE1 and DUBs like USP9X and UBP7 in the tumor and LN metastatic lesions. We further identify that expression of TFG-RET led to the upregulation of HUWE1. Further, in a cohort of PTC patients, we observed higher expression of HUWE1, USP9X and USP7 in the tumor and metastatic lesions, when compared to the matched normal tissue. Transient knockdown of HUWE1, USP9X and USP7 affected viability and proliferation of TFG-RET transformed cells. Consistently, inhibition of RET, HUWE1 and DUBs by small molecule inhibitors significantly reduced RET-mediated oncogenesis. Apart from unveiling a novel oncogenic RET fusion in PTCs, our data may open a novel avenue of targeting ubiquitin signaling machinery in human PTCs.

Project description:Poorly differentiated thyroid carcinomas (PDTC) represent a heterogeneous, aggressive entity, presenting features that suggest a progression from well-differentiated carcinomas. To elucidate the mechanisms underlying such progression and identify novel therapeutical targets, we assessed the genome-wide expression in normal thyroid tissues, well-differentiated thyroid carcinomas and PDTC. RNA were extracted from 2 normal thyroid tissues taken from the opposite lobe of thyroid tumors, and 24 thyroid carcinomas: 5 PDTC, 7 classic papillary thyroid carcinomas (cPTC), 8 follicular variants of PTC (fvPTC) and 4 follicular thyroid carcinomas (FTC). All samples were obtained at time of surgery and immediately frozen in liquid nitrogen. We also hybridized a commercial pool of human thyroid total RNA (BD Bioscience). PTC were screened for BRAF mutations and rearrangements of RET/PTC and, in addition, follicular variants were also analyzed for RAS mutations and PAX8-PPARG rearrangements. FTC were screened for RAS and PAX8-PPARG rearrangements. PDTC were analyzed for BRAF, RAS and PAX8-PPARG genes.

Project description:Papillary thyroid carcinoma (PTC) is the most common malignancy amongst adolescent and young adult women. Clinical and genomic features of PTC in children differ from those in adults. Historically, a substantial proportion (~50%) of pediatric PTC (PPTC) lack any of the common driver mutations typical of adult PTC. Thus, molecular diagnostics developed for adults may not be valid in children. We applied novel bioinformatic pipelines to RNASeq analysis of pediatric thyroid tumors to identify known and novel fusion oncogenes as drivers of tumorigenesis and to define gene expression patterns among tumors. Analysis of 38 samples resulted in identification of 16 previously reported oncogenic fusions and three novel candidate fusions. In conducting these analyses, we reduced the proportion of cancers with unknown drivers from approximately 50% to 6%. Gene expression analysis identified three distinct categories of tumors. These studies represent the first unbiased genomic approach to childhood PTC. Novel bioinformatic pipeline. GEC Identified 3 distinct classes. DICER1, PTEN segregated with benign tumors. >90% of PPTC carry identifiable ongognic driver variants, however, the landscape differs from that in adults and existing tools for tumor genotyping in adults may not be applicable to pediatric tumors. BACKGROUND: Papillary thyroid carcinoma demonstrates clinically distinct behaviour in pediatric patients when compared to adults, with increased regional and distal metastases, more frequent recurrence, yet overall highly favourable prognosis. Recent tumor genotyping has demonstrated that in pediatric tumors, ***-*** do not carry the most common genomic variants found in adult PTC, leaving a substantial proportion of driver-unknown or “dark matter†tumors. METHODS: We established a cohort of 52 pediatric PTC and performed quantitative-PCR genotyping followed in a subset by whole exome and whole transcriptome (RNASeq) sequencing using a novel, robust bioinformatic pipeline to identify oncogenic fusion transcripts. Gene expression analysis was used to derive distinct clusters. RESULTS: In 52 pediatric PTC, genotyping identified BRAFV600E(21%), NRASQ61R(2%), RET/PTC1 (21%), RET/PTC3 (17%) or PAX8-PPARï§ in 33 (63%) of tumors. Among the remaining 19 tumors, oncogenic variants were identified in /19 (%). The variants included SNVs in DICER1, ETV6-NTRK3, PTEN and 9 additional oncogenic fusions including two previously-undescribed fusion transcripts, *** and ***. CONCLUSIONS: The genomic landscape of PTC differs between children and adults. In children, there is a substantial fraction of tumors that are unexplained by variants typical of adult PTC. This discrepancy is explained largely by uncommon oncogenic fusions which can be identified by whole-transcriptome analysis.

Project description:Apart from alterations in the RET/PTC-RAS-BRAF pathway, comparatively little is known about the genetics of papillary thyroid carcinoma (PTC). We show that numerous miRNAs are transcriptionally up-regulated in PTC tumors compared with unaffected thyroid tissue. A set of 5 miRNAs including the 3 most upregulated ones (miRs 221, 222, 146) distinguished unequivocally between PTC and normal thyroid. Additionally, miR-221 was upregulated in unaffected thyroid tissue in several PTC patients, presumably an early event in carcinogenesis. Tumors in which the upregulation (11-19 fold) of miRs 221, 222 and 146 was strongest showed dramatic loss of KIT transcript and Kit protein. In five of 10 such cases this was associated with germline single nucleotide changes in the two recognition sequences in KIT for these miRNAs. We conclude that upregulation of several miRs and down regulation of KIT are involved in PTC pathogenesis, and that sequence changes in genes targeted by miRNAs can contribute to their downregulation.

Project description:To obtain a PTC cell model, primary human thyrocytes have been infected with a retrovirus expressing RET/PTC1 oncogene, using parental thyrocytes as control. The obtained RET/PTC-dependent differential miRNA expression profile, representing the effects of RET/PTC1 oncogene present in about one third of papillary thyroid carcinoma (PTC), models the early event of thyrocytes transformation ending to PTC. miRNA expression profiles of thyrocytes expressing RET/PTC1 oncogene and parental thyrocytes were compared. Biological replicates could not be generated.

Project description:To obtain a PTC cell model, primary human thyrocytes have been infected with a retrovirus expressing RET/PTC1 oncogene, using parental thyrocytes as control. The obtained RET/PTC-dependent differential miRNA expression profile, representing the effects of RET/PTC1 oncogene present in about one third of papillary thyroid carcinoma (PTC), models the early event of thyrocytes transformation ending to PTC.

Project description:The RET/PTC3 (RP3) fusion gene is the most frequent mutation found in radiation-induced papillary thyroid cancers (PTC). Several studies suggest that the RET/PTC rearrangement is an initiating event in tumorigenesis. E7 is an oncoprotein derived from the Human Papilllomavirus 16 (HPV16) responsible for most cervical carcinoma in women. We studied here the sequence of events leading to thyroid cancer in Tg-RP3 and Tg-E7 mice expressing the transgene exclusively in the thyroid under the control of thyroglobulin (Tg) promoter. Both transgenic mice develop thyroid hyperplasia followed by solid differentiated carcinoma in older animals. To understand the different steps leading to carcinoma, we analyzed thyroid gene expression in both strains at different ages (2, 6, 10 months) by microarray technology. Important biological processes were differentially regulated in the two tumor types. In E7 thyroids cell cycle was the most upregulated process; observation consistent with the huge size of these tumors. In RP3 thyroids immunity was the most significantly regulated process, as previously observed in microarray data on human PTC. Interestingly, other human PTC characteristics were also observed in RP3 but not in E7 mouse tumors: similar regulation of several human PTC markers, upregulation of many EGF-like growth factors and finally significant regulation of angiogenesis and extracellular matrix remodeling-related genes. In summary we showed that RP3 contrary to E7 mouse tumors share several important genotypic characteristics with human PTC, observation reinforcing the validity of this model to study human thyroid tumorigenesis. Keywords: time course, genetic modification, disease state, cancer

Project description:BRAFV600E mutation is the most frequent molecular event in papillary thyroid carcinoma. The relation of this genetic alteration with the factors od poor prognosis has been reported as well as its influence on PTC gene signature. However human material disables distinction of cancer causes from its effect. We used our transgenic mouse model of papillary thyroid carcinoma induced by the BRAFV600E mutation to select BRAFV600E-specifi gene signature which was than compared to human material The human microarray data were obtained for: 27 papillary thyroid carcinomas including 18 BRAF(+), 8 RET(+), 1 RAS(+); 18 apparently healthy thyroids. In order to find BRAFV600E-specific gene signature data obtained from our transgenic mouse model of PTC were compared to human material. The analyses were performed taking into account not only the BRAF mutation but also other PTC initiating events including RET rearrangements and RAS poin mutations. Morover the microarray data were validated with the QPCR reaction.

Project description:Our goal was to search for new molecular markers of the mitochondrial implication in the thyroid tumorigenesis. Using a DNA microarray (Cancerochip), we explored a collection of thyroid samples representing 4 classes of thyroid tumors. 45 thyroid tumoral and paired control tissues representing 4 classes (benign follicular tumors [FTA], oncocytic variants of follicular tumors [OT], papillary thyroid carcinomas [PTC] and tumors of uncertain malignancy potential [TUMP]) of thyroid tumors were explored for the expression of 6866 genes.