Project description:Wilms tumor (nephroblastoma) is a pediatric kidney tumor that arises from renal progenitor cells. Since the blastemal type is associated with adverse prognosis, we characterized such Wilms tumors by exome and transcriptome analysis. We detected novel, recurrent somatic mutations affecting the SIX1/2 – SALL1 pathway implicated in kidney development, the DROSHA/DGCR8 microprocessor genes as well as alterations in MYCN and TP53, the latter being strongly associated with dismal outcome. The DROSHA mutations impair the RNase III domains, while DGCR8 exhibits stereotypic E518K mutations in the RNA binding domain - both may skew miRNA representation. SIX1 and SIX2 mutations affect a single hotspot (Q177R) in the homeodomain indicative of a dominant effect. In larger cohorts, these mutations cluster in blastemal and chemotherapy-induced regressive tumors that likely derive from blastemal cells and these are characterized by generally higher SIX1/2 expression. These findings broaden the spectrum of human cancer genes and may open new avenues for stratification and therapeutic leads for Wilms tumors. 53 Wilms tumor samples were selected for RNA extraction and hybridization on Affymetrix Affymetrix Human Genome U133 Plus 2.0 Arrays.

Project description:Wilms tumor (nephroblastoma) is a pediatric kidney tumor that arises from renal progenitor cells. Since the blastemal type is associated with adverse prognosis, we characterized such Wilms tumors by exome and transcriptome analysis. We detected novel, recurrent somatic mutations affecting the SIX1/2 – SALL1 pathway implicated in kidney development, the DROSHA/DGCR8 microprocessor genes as well as alterations in MYCN and TP53, the latter being strongly associated with dismal outcome. The DROSHA mutations impair the RNase III domains, while DGCR8 exhibits stereotypic E518K mutations in the RNA binding domain - both may skew miRNA representation. SIX1 and SIX2 mutations affect a single hotspot (Q177R) in the homeodomain indicative of a dominant effect. In larger cohorts, these mutations cluster in blastemal and chemotherapy-induced regressive tumors that likely derive from blastemal cells and these are characterized by generally higher SIX1/2 expression. These findings broaden the spectrum of human cancer genes and may open new avenues for stratification and therapeutic leads for Wilms tumors.

Project description:Wilms Tumor, the most common pediatric kidney cancer, evolves from the failure of terminal differentiation of the embryonic kidney. Here we show that over-expression of the heterochronic regulator Lin28 during kidney development in mice markedly expands nephrogenic progenitors by blocking their final wave of differentiation, ultimately resulting in pathology highly reminiscent of Wilms tumor.

Project description:Blastemal histology in chemotherapy-treated pediatric Wilms tumors (nephroblastoma) is associated with adverse prognosis. To uncover the underlying tumor biology and find novel therapeutic leads for this subgroup of patients, we analyzed 58 blastemal-type Wilms tumors by exome and transcriptome sequencing and validated our findings in a large independent replication cohort. Recurrent mutations identified either somatically or in the germline included a hotspot mutation (Q177R) in the homeodomain of SIX1 and SIX2 in tumors with high proliferative potential, mutations in microprocessor genes like DROSHA, DGCR8, DICER1 and DIS3L2, and alterations in IGF2, MYCN, and TP53, the latter being strongly associated with dismal outcome. DROSHA and DGCR8 mutations had a strong effect on miRNA expression patterns in tumors, which was functionally validated in cell lines transfected with mutant DROSHA. total samples analyzed are 16, each done as technical replicate

Project description:Precise regulation of transduction signaling pathways genes is crucial for correct differentiation of kidney cells and perturbation may lead to tumor onset. Wilms tumors (WT), or nephroblastoma, originates from the metanephric blastema cells, which were unable to complete the differentiation, resulting in a triphasic tumor composed by distinct cell types, blastemal, epithelial and stromal, where the former harbor molecular characteristics similar to cells of the earliest stages of kidney development. In this study, to identify key early events involved in the disruption of correct cell signaling during kidney differentiation that can drive WT, we developed a cDNA platform containing genes from signaling transduction pathways. By using bioinformatics tools, we defined high conserved regions between human and mouse orthologous genes and assessed the gene modulation in blastemal cells captured from WT and differentiated kidneys (DK) in human and from four temporal stages of kidney differentiation in mouse. We found 18 genes, whose transcriptional level of the earliest phases of blastemal cell differentiation was recapitulated in WT. PAX2, FZD10, SHPK, WNT5B, FZD2, CRABP2, FRZB, GRK7, TESK1, HDGF and IGF2 were up- and MAPK9, PIK3CA, FRAT2, ITPR3, CDH6, HIPK1 and TIMP3 were down-regulated in WT respectively. Hierarchical clustering based on the expression of this gene set grouped DK from both species, human and mouse, and discriminated them from fetal kidney and WT in human, and the earliest kidney stages in mouse, validating the model proposed by this study and reveling a transduction signaling signature of WT. High robustness of this data was detected since expression level was tested by quantitative RT-PCR in the initial and independent sample set, with 75 and 56% of agreement. Agreement of 62% was also observed in protein level assessing blastemal component of an independent group of 137 WT. Protein expression of CRABP2, IGF2, GRK7, TESK1, HDGF, WNT5B, FZD2 and TIMP3 was also characterized in human fetal kidneys revealing interesting aspects of kidney differentiation. This study identified key genes modulated during kidney differentiation which may play a determinant role for WT onset. As far as we know, FZD10, FRZB, HDGF, MAPK9, FRAT2, SHPK, WNT5B, GRK7, TESK1, HDGF, PIK3CA, ITPR3, HIPK1 and TIMP3 were not previously associated to WT. The strong connection between nephrogenesis and WT highlights the importance of a detailed characterization of modulated genes belonged to signal transduction. Identification of gene expression involved in kidney differentiation arresting might be imperative to point out early alterations that drive WT onset and consequently are potential candidate as molecular marker. Here, we characterized expression pattern of genes belonged to transduction signaling pathways in blastemal cells during kidney development stages in mouse and WT in human. For that, we established a model of inter- and intra-specific hybridization to assess gene expression modulation to identify key events that drive WT onset. Dye-swap was performed for each sample as control for dye bias and used as replicate. In total, 24 frozen favorable histology WT and differentiated kidney samples were laser microdisscted for blastemal cells. Three kidneys from CD1 lineage from Mus Musculus were isolated from embryos (E) and postnatal animals (P) at ages E15.5, E17.5, P1.5 and P7.5 for laser microdissection of the blastemal cells in all stages of kidney differentiation. NA were purified with PicoPure™ RNA Isolation kit (Arcturus Engineering #KT0204) and treated with RNase-Free DNase Set (Qiagen #79254; Qiagen-Germantown MD USA).

Project description:Wilms Tumor, the most common pediatric kidney cancer, evolves from the failure of terminal differentiation of the embryonic kidney. Here we show that over-expression of the heterochronic regulator Lin28 during kidney development in mice markedly expands nephrogenic progenitors by blocking their final wave of differentiation, ultimately resulting in pathology highly reminiscent of Wilms tumor. Gene expression analysis was performed on a total of 8 kidneys samples, including 4 tumors samples from Lin28 transgenic mice and 4 control kidneys

Project description:Wilms tumors are pediatric cancers thought to arise from kidney-specific stem cells. In order to identify transcriptional and epigenetic mechanisms that drive these malignant cells, we compared genomewide chromatin profiles of Wilms tumors to embryonic stem (ES) cells and normal kidney. Data represent examination of genome-wide chromatin modifications in primary Wilms tumors, fetal and mature kidney.

Project description:The goal of this study was to find differences in the chromatin state (active promotor regions) between two Wilms tumor subtypes (blastemal and non-blastemal).

Project description:We show that oncogenesis in Wilms’ tumor - the most common pediatric renal cancer- is mediated by small non-coding RNAs miRNAs.Interestingly, several differentially expressed miRNAs target genes that are known to play important role in kidney development. miRNA profile of Wilm's tumor vs. normal kidney with two color microarray protocol

Project description:Blastemal histology in chemotherapy-treated pediatric Wilms tumors (nephroblastoma) is associated with adverse prognosis. To uncover the underlying tumor biology and find novel therapeutic leads for this subgroup of patients, we analyzed 58 blastemal-type Wilms tumors by exome and transcriptome sequencing and validated our findings in a large independent replication cohort. Recurrent mutations identified either somatically or in the germline included a hotspot mutation (Q177R) in the homeodomain of SIX1 and SIX2 in tumors with high proliferative potential, mutations in microprocessor genes like DROSHA, DGCR8, DICER1 and DIS3L2, and alterations in IGF2, MYCN, and TP53, the latter being strongly associated with dismal outcome. DROSHA and DGCR8 mutations had a strong effect on miRNA expression patterns in tumors, which was functionally validated in cell lines transfected with mutant DROSHA.