Project description:MALT lymphoma is characterized by t(11;18)(q21;q21)/API2-MALT1, t(1;14)(p22;q32)/BCL10-IGH and t(14;18)(q32;q21)/IGH-MALT1, which commonly activate the NF-κB pathway. Gastric MALT lymphomas harboring such translocation do not respond to H. pylori eradication, while those without translocation can be cured by antibiotics. To understand the molecular mechanism of these different MALT lymphoma subgroups, we performed gene expression profiling analysis of 24 MALT lymphomas (15 translocation-positive, 9 translocation-negative). Gene set enrichment analysis (GSEA) of the NF-κB target genes and 4394 additional gene sets covering various cellular pathways, biological processes and molecular functions showed that translocation-positive MALT lymphomas are characterized by an enhanced expression of NF-κB target genes, particularly TLR6, CCR2, CD69 and BCL2, while translocation-negative cases were featured by active inflammatory and immune responses, such as IL8, CD86, CD28 and ICOS. Separate analyses of the genes differentially expressed between translocation-positive and negative cases and measurement of gene ontology term in these differentially expressed genes by hypergeometric test reinforced the above findings by GSEA. Finally, expression of TLR6, in the presence of TLR2, enhanced both API2-MALT1 and BCL10 mediated NF-κB activation in vitro. Our findings provide novel insights into the molecular mechanism of MALT lymphomas with and without translocation, potentially explaining their different clinical behaviors. This study compares MALT with other lymphomas namely follicular and mantle cell lymphomas, and investigates the molecular mechanisms of the lymphomagenesis between translocation positive versus negative MALT lymphoma cases in order to derive the pathways leading to MALT lymphoma pathogenesis using GSEA, GO, dynamic pathway analysis as well as other bioinformatics analysis. Samples were run on the Affymetrix HG-U133A and HG-U133 plus2 GeneChips.

Project description:MALT lymphoma is characterized by t(11;18)(q21;q21)/API2-MALT1, t(1;14)(p22;q32)/BCL10-IGH and t(14;18)(q32;q21)/IGH-MALT1, which commonly activate the NF-κB pathway. Gastric MALT lymphomas harboring such translocation do not respond to H. pylori eradication, while those without translocation can be cured by antibiotics. To understand the molecular mechanism of these different MALT lymphoma subgroups, we performed gene expression profiling analysis of 24 MALT lymphomas (15 translocation-positive, 9 translocation-negative). Gene set enrichment analysis (GSEA) of the NF-κB target genes and 4394 additional gene sets covering various cellular pathways, biological processes and molecular functions showed that translocation-positive MALT lymphomas are characterized by an enhanced expression of NF-κB target genes, particularly TLR6, CCR2, CD69 and BCL2, while translocation-negative cases were featured by active inflammatory and immune responses, such as IL8, CD86, CD28 and ICOS. Separate analyses of the genes differentially expressed between translocation-positive and negative cases and measurement of gene ontology term in these differentially expressed genes by hypergeometric test reinforced the above findings by GSEA. Finally, expression of TLR6, in the presence of TLR2, enhanced both API2-MALT1 and BCL10 mediated NF-κB activation in vitro. Our findings provide novel insights into the molecular mechanism of MALT lymphomas with and without translocation, potentially explaining their different clinical behaviors.

Project description:L. lactis NIAI712 carries five different plasmids, including an 8.7-kb plasmid designated pAG6. In this study, genome-wide expression profiles of the pAG6-cured variant was compared to the wild-type strain. Two samples of total RNA recovered from a wild-type culture of L. lactis NIAI712 and a pAG6-cured variant were examined

Project description:ERCC6L2 suppresses chromosome translocation

Project description:Transgenic mouse models of osteosarcoma originate from osteoblast cells with a baseline deletion of Tp53 and Rb1; however, the model is not 100% penetrant in osteosarcomagenesis and demonstrates no visible evidence of the metastatic disease. To enhance the current model, a fourth allele was added so that Arid1a, Tp53, and Rb1 are all conditionally deleted in osteoblast cells upon tamoxifen-induced, CreERT2-mediated recombination. Mice from both cohorts, with and without Arid1a were compared at the transcriptional level to identify the consequences of Arid1a deletion and the pathways associated with the more aggressive and metastatic mouse model without Arid1a.

Project description:Conventioal cytogenetic on 2 sinonasal sarcoma (SNS) cases showed t(2;4)(q37.1;q31.3) translocation previously. The aim of this whole transcriptome analysis is to determine potential candidate genes involved in this translocation. Total RNA extracted from frozen cultured primary tumor cells from a SNS characterized at the cytogenetics level was subjected to Illumina whole transcriptome RNA-sequencing anslysis.

Project description:Analysis of the immunopeptidome of Human Leukocyte Antigen(HLA)class I of SaOS-2 osteosarcoma cells transfected with pBR322 vector only, and 2 mutants of TP53 protein namely R175H and R273H.

Project description:Osteosarcoma, derived from mesenchymal stem cells or osteoblasts, is the most common malignant bone tumor and the highly metastatic malignant phenotypes often with poor prognosis are related to modulation of TP53- and cell cycle-related pathways. MYC, which regulates the transcription of cell-cycle modulating genes, e.g. CCNE1, is used as a representative prognostic marker. MYCN, a member of MYC oncoprotein family, is highly expressed in a subset of osteosarcoma, however, its roles in osteosarcoma have not been elucidated extensively. Here, we attempted to make an in vitro tumorigenesis model by using hiPSCs derived neural crest cells, which is a precursor cell of mesenchymal stem cells, by MYCN overexpression in the background of heterozygousTP53 hotspot mutation (c.733G>A; p.G245S). MYCN-expressing transformed clones with TP53 mutation were isolated by soft agar colony formation, and injected subcutaneously and into periadrenal adipose tissue of immune-deficient mice, resulted in development of chondroblastic osteosarcoma. MYCN suppression decreased proliferation in MYCN-induced osteosarcoma cells, suggesting that MYCN seems to be one of the targets of osteosarcoma treatment. Further, comprehensive analysis of gene expression and exome sequencing of the MYCN-induced transformed clones indicated molecular context of osteosarcoma-specific feature such as activation of TGF-β signaling and DNA copy number amplification of GLI1. The model of MYCN-expressing chondroblastic osteosarcoma was developed from hiPSC-based neural crest cells, allowing us to provide useful tool for development of new tumor models using hiPSC-derived progenitor cells with gene modification and in vitro transformation.

Project description:End-stage breast cancers are clonally heterogeneous and harbor many poorly-understood treatment resistance mechanisms. We therefore established multiple Patient-Derived-Xenograft (PDX) models to study genomic events driving advanced disease. Comparative whole-genome sequencing of paired primary tumors and their PDX models demonstrated that PDX retain the vast majority of the structural variations and copy number aberrations seen within the originating tumor, and with high fidelity. Variant allele fractions (VAF) were preserved, even for rare mutations. Clonal representation is therefore a transplantable phenotype, indicating that genomic heterogeneity can be regulated in a tumor-autonomous mechanism, indifferent to host immune status. Mutations and gene rearrangements were documented in the ESR1 gene in three of five sequenced luminal PDX/progenitor tumor pairs (amplification, point mutation and translocation), and were associated with clinical endocrine response phenotypes, differential PDX estradiol responsiveness and all induced estradiol-independent growth in standard cell lines. PDX models are therefore a significant new tool for fundamental studies on the molecular basis for resistance to endocrine treatment in advanced breast cancer. reference x sample

Project description:Comprehensive proteogenomic analysis of Microphthalmia Transcription Factor (MiT) family translocation renal cell carcinoma (tRCC) tumor and normal adjacent tissues was performed to elucidate the molecular landscape of these tumors.