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Homology searches in the Expressed Sequence Tag Database were performed using SPYGQ-rich regions as query sequences to find genes encoding protein regions similar to the N-terminal parts of the sarcoma-associated EWS and FUS proteins. Clone 22911 (T74973), encoding a SPYGQ-rich region in its 5' end, and several other clones that overlapped 22911 were selected. The combined data made it possible to assemble a full-length cDNA sequence. This cDNA sequence is 1677 bp, containing an initiation codon ATG, an open reading frame of 400 amino acids, a poly(A) signal, and a poly(A) tail. We found 100% identity between the 5' part of the consensus sequence and the 598-bp-long sequence named TFG. The TFG sequence is fused to the 3' end of NTRK1, generating the TRK-T3 fusion transcript found in papillary thyroid carcinoma. The cDNA therefore represents the full-length transcript of the TFG gene. TFG was localized to 3q11-q12 by fluorescence in situ hybridization. The 3' and the 5' ends of the TFG cDNA probe hybridized to a 2.2-kb band on Northern blot filters in all tissues examined.
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PMID:Characterization and chromosomal mapping of the human TFG gene involved in thyroid carcinoma. 916 29

Myxoid liposarcomas (MLS) carry a t(12;16) or, more rarely, a t(12;22) resulting in fusion of the transcription factor gene CHOP on chromosome 12 with TLS/FUS on chromosome 16 or EWS on chromosome 22. The chimeric TLS-CHOP or EWS-CHOP proteins most probably function as abnormal transcription factors, causing transcriptional de-regulation of several target genes and relaxation of functions critical for growth and differentiation control. A PCR-based subtractive hybridization technique was used to identify genes that are differentially expressed in TLS-CHOP-carrying MLS but not in normal fat tissue. Six myxoid-liposarcoma-associated transcripts, MLAT, were isolated. The genes identified as MLAT can be divided into 2 groups. MLAT1, 2 and 6 show high similarity to glia-derived nexin, neuronatin and the RET oncogene, respectively, all normally involved in development of tissues of neural origin. MLAT3 to MLAT5 represent new genes.
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PMID:Identification of genes differentially expressed in TLS-CHOP carrying myxoid liposarcomas. 1044 3

ZNF198 is fused with FGFR1 in an atypical myeloproliferative disease that results in constitutive activation of the kinase domain and mislocalization to the cytoplasm. We have used immunoprecipitation of a GFP-tagged ZNF198 combined with MALDI-TOF mass spectroscopy to identify interacting proteins. P splicing factor (PSF) was identified as one of the proteins and this interaction was confirmed by Western blotting. Other proteins identified were the spliceosomal components hnRNP A2/B1, hnRNP H3, and TLS/FUS. PSF is also known to interact with PTB, another member of the hnRNP family of proteins, and we further demonstrated that PTB interacts with ZNF198. The interaction between TLS/FUS and ZNF198 was confirmed using Western blot analysis. In 293 cells expressing the ZNF198/FGFR1 fusion protein, neither PSF nor PTB binds to the fusion protein, possibly because of their differential localization in the cell.
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PMID:Mass spectroscopy identifies the splicing-associated proteins, PSF, hnRNP H3, hnRNP A2/B1, and TLS/FUS as interacting partners of the ZNF198 protein associated with rearrangement in myeloproliferative disease. 1597 76

Soft tissue tumours represent a heterogeneous group of mesenchymal lesions and their classification continues to evolve as a result of incorporating advances in cytogenetic and molecular techniques. In the last decade traditional diagnostic approaches were supplemented with a significant number of reliable molecular diagnostic tools, detecting tumour type-specific genetic alterations. In addition, the successful application of some of these techniques to formalin-fixed paraffin-embedded tissue made it possible to subject a broader range of clinical material to molecular analysis. Thus, molecular genetics has already become an integral part of the work-up in some tumours, such as paediatric small blue round cell tumours, which demonstrate characteristic translocations. Several lines of evidence suggest that sarcomas can be divided into two major genetic groups: (i) sarcomas with specific genetic alterations and usually simple karyotypes, such as reciprocal chromosomal translocations (e.g. FUS-DDIT3 in myxoid liposarcoma) and specific oncogenic mutations (e.g. KIT mutation in gastrointestinal stromal tumours); and (i) sarcomas with non-specific genetic alterations and complex unbalanced karyotypes. Some of these genetic abnormalities, including chromosomal numerical changes, translocations, gene amplifications or large deletions can be apparent at the cytogenetic level (karyotyping, fluorescence in situ hybridization), while others, such as small deletions, insertions or point mutations, require molecular genetic techniques (polymerase chain reaction and sequence analysis). This review focuses on the applicability of genetic testing in the diagnosis and prognosis of soft tissue sarcomas, and gives a realistic appraisal of the ancillary role of molecular techniques, including its advantages and limitations.
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PMID:The role of genetic testing in soft tissue sarcoma. 1635 33

Sarcomas comprise some of the most aggressive solid tumours that, for the most part, respond poorly to chemo- and radiation therapy and are associated with a sombre prognosis when surgical removal cannot be performed or is incomplete. Partly because of their lower frequency, sarcomas have not been studied as intensively as carcinomas and haematopoietic malignancies, and the molecular mechanisms that underlie their pathogenesis are only beginning to be understood. Even more enigmatic is the identity of the primary cells from which these tumours originate. Over the past 25 years, however, several non-random chromosomal translocations have been found to be associated with defined sarcomas. Each of these translocations generates a fusion gene believed to be directly related to the pathogenesis of the sarcoma in which it is expressed. The corresponding fusion proteins provide a unique tool not only to study the process of sarcoma development, but also to identify cells that are permissive for their putative oncogenic properties. This is the first of two reviews that cover the mechanisms whereby specific fusion/mutant gene products participate in sarcoma development and the cellular context that may provide the necessary permissiveness for their expression and oncogenicity. Part 1 of the review focuses on sarcomas that express fusion genes containing TET gene family products, including EWSR1, TLS/FUS, and TAFII68. Part 2 (J Pathol 2007; DOI: 10.1002/path.2008) summarizes our current understanding of the genetic and cellular origins of sarcomas expressing fusion genes exclusive of TET family members; it also covers soft tissue malignancies harbouring specific mutations in RTK-encoding genes, the prototype of which are gastrointestinal stromal tumours (GIST).
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PMID:Sarcomas: genetics, signalling, and cellular origins. Part 1: The fellowship of TET. 1770 79

The molecular hallmark of angiomatoid fibrous histiocytoma (AFH) is not well defined, with only six cases with specific gene fusions reported to date, consisting of either FUS-ATF1 or EWSR1-ATF1. To address this, we investigated the presence of FUS-ATF1, EWSR1-ATF1, and the highly related EWSR1-CREB1 fusion in a group of nine AFHs. All cases were subjected to RT-PCR for EWSR1-ATF1 and EWSR1-CREB1. FISH for EWSR1 and FUS rearrangements was performed in most cases. Transcriptional profiling was performed in three tumors and their gene expression was compared to five clear cell sarcomas expressing either the EWSR1-ATF1 or EWSR1-CREB1 fusion. By RT-PCR, eight out of nine tumors showed the presence of the EWSR1-CREB1 fusion, while one had an EWSR1-ATF1 transcript. FISH showed evidence of EWSR1 rearrangement in seven out of eight cases. Karyotypic analysis performed in one tumor showed a t(2;22)(q33;q12). High transcript levels were noted for TFE3 in AFH tumors, while overexpression of genes involved in melanogenesis, such as MITF, GP100, and MET was noted in somatic clear cell sarcomas. We report for the first time the presence of EWSR1-CREB1 in AFH, which now appears to be the most frequent gene fusion in this tumor. EWSR1-CREB1 is a novel translocation recently described in clear cell sarcoma of the GI tract. EWSR1-ATF1, identified in some AFH cases, is the most common genetic abnormality in soft tissue clear cell sarcoma. Thus, identical fusions involving ATF1 and CREB1 are found in two distinct sarcomas, which may be able to transform two different types of mesenchymal precursor cells, unlike most other sarcoma gene fusions.
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PMID:EWSR1-CREB1 is the predominant gene fusion in angiomatoid fibrous histiocytoma. 1772 45

We previously performed SEREX (serological identification of antigens by recombinant expression cloning) using the sera of patients with esophageal squamous cell carcinoma (SCC), and isolated a variant clone (AK093616) of ubiquitin-conjugating enzyme E21 (UBE2I). This clone was tentatively designated as UBE2I-v5 and analyzed for biological function by transient transfection of the cDNA into activated Ha-ras-transformed NIH3T3 (ras-NIH) mouse fibroblasts. Chemosensitivity to 92 cytotoxic drugs was compared between UBE2I-v5-transfected cells and the parental ras-NIH cells. The UBE2I-v5-transfected cells were more sensitive than the parental cells to anticancer drugs such as vincristine (VCR), mitoxantrone (MIT) and etoposide (VP16). The regression analysis of the total chemosensitivity pattern of UBE2I-vS-transfected cells revealed that the function of UBE2I-v5 was positively related to RPA2 (replication protein A2), Rho-GDI (Rho guanine nucleotide dissociation inhibitor a), FUS (putative tumor suppressor) and TKT (transketolase) but negatively related to Per-1 (period-I), Ran (nuclear Ras-related protein), PTEN (phosphatase and tensin homolog), C/EBPalpha (CCAAT/enhancer binding protein a) and the tumor suppressor p53. Thus, it is possible that UBE21-v5 plays a role in carcinogenesis by suppressing the function of CIEBPa and/or p53 via RPA2-like activity.
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PMID:Sensitization against anticancer drugs by transfection with UBE2I variant gene into ras-NIH3H3 mouse fibroblasts. 1797 65

Many macrophage-specific promoters lack classical transcriptional start site elements such as TATA boxes and Sp1 sites. One example is the CSF-1 receptor (CSF-1R, CD115, c-fms), which is used as a model of the transcriptional regulation of macrophage genes. To understand the molecular basis of start site recognition in this gene, we identified cellular proteins binding specifically to the transcriptional start site (TSS) region. The mouse and human csf1r TSS were identified using cap analysis gene expression (CAGE) data. Conserved elements flanking the TSS cluster were analyzed using EMSAs to identify discrete DNA-binding factors in primary bone marrow macrophages as candidate transcriptional regulators. Two complexes were identified that bind in a highly sequence-specific manner to the mouse and human TSS proximal region and also to high-affinity sites recognized by myeloid zinc finger protein 1 (Mzf1). The murine proteins were purified by DNA affinity isolation from the RAW264.7 macrophage cell line and identified by mass spectrometry as EWS and FUS/TLS, closely related DNA and RNA-binding proteins. Chromatin immunoprecipitation experiments in bone marrow macrophages confirmed that EWS, but not FUS/TLS, was present in vivo on the CSF-1R proximal promoter in unstimulated primary macrophages. Transfection assays suggest that EWS does not act as a conventional transcriptional activator or repressor. We hypothesize that EWS contributes to start site recognition in TATA-less mammalian promoters.
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PMID:The Ewing sarcoma protein (EWS) binds directly to the proximal elements of the macrophage-specific promoter of the CSF-1 receptor (csf1r) gene. 1845 93

Our goal of this study was to reconstruct a "genome-scale co-expression network" and find important modules in lung adenocarcinoma so that we could identify the genes involved in lung adenocarcinoma. We integrated gene mutation, GWAS, CGH, array-CGH and SNP array data in order to identify important genes and loci in genome-scale. Afterwards, on the basis of the identified genes a co-expression network was reconstructed from the co-expression data. The reconstructed network was named "genome-scale co-expression network". As the next step, 23 key modules were disclosed through clustering. In this study a number of genes have been identified for the first time to be implicated in lung adenocarcinoma by analyzing the modules. The genes EGFR, PIK3CA, TAF15, XIAP, VAPB, Appl1, Rab5a, ARF4, CLPTM1L, SP4, ZNF124, LPP, FOXP1, SOX18, MSX2, NFE2L2, SMARCC1, TRA2B, CBX3, PRPF6, ATP6V1C1, MYBBP1A, MACF1, GRM2, TBXA2R, PRKAR2A, PTK2, PGF and MYO10 are among the genes that belong to modules 1 and 22. All these genes, being implicated in at least one of the phenomena, namely cell survival, proliferation and metastasis, have an over-expression pattern similar to that of EGFR. In few modules, the genes such as CCNA2 (Cyclin A2), CCNB2 (Cyclin B2), CDK1, CDK5, CDC27, CDCA5, CDCA8, ASPM, BUB1, KIF15, KIF2C, NEK2, NUSAP1, PRC1, SMC4, SYCE2, TFDP1, CDC42 and ARHGEF9 are present that play a crucial role in cell cycle progression. In addition to the mentioned genes, there are some other genes (i.e. DLGAP5, BIRC5, PSMD2, Src, TTK, SENP2, PSMD2, DOK2, FUS and etc.) in the modules.
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PMID:Reconstruction of an integrated genome-scale co-expression network reveals key modules involved in lung adenocarcinoma. 2387 28

Corticobasal syndrome (CBS) is associated with different pathologies including FTLD-tau (corticobasal degeneration; CBD, progressive supranuclear palsy, and Pick disease), FTLD-TDP, Alzheimer disease, Creutzfeldt-Jakob disease, and Parkinson disease/dementia with Lewy bodies. Genetic causes of CBS are also various reflecting diverse pathology. In familial and sporadic FTLD, MAPT, GRN and C9ORF72 mutations are three major causes of the disease. A part of patients harboring these mutations could exhibit CBS. In addition, the patients with TARDBP, FUS, LRRK2 or CSF1R mutations also have potential to exhibit CBS. In sporadic cases, H1 haplotype of MAPT is known to be associated with FTLD-tau, including CBS/CBD. Despite major advances in recent years, the majority of familial and sporadic CBS cases are genetically unsolved. In particular, little is known about both familial and sporadic cases of CBS in Japanese. Further studies are needed to unveil the genetic background of CBS.
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PMID:[Genetic background of corticobasal syndrome]. 2429 68

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