UMLS:C0178874 - FACTA Search

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Query: UMLS:C0178874 (tumor progression)
40,807 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The t(4;14) translocation occurs frequently in multiple myeloma (MM) and results in the simultaneous dysregulated expression of 2 potential oncogenes, FGFR3 (fibroblast growth factor receptor 3) from der(14) and multiple myeloma SET domain protein/Wolf-Hirschhorn syndrome candidate gene 1 from der(4). It is now shown that myeloma cells carrying a t(4;14) translocation express a functional FGFR3 that in some cases is constitutively activated by the same mutations that cause thanatophoric dysplasia. As with activating mutations of K-ras and N-ras, which are reported in approximately 40% of patients with MM, activating mutations of FGFR3 occur during tumor progression. However, the constitutive activation of ras and FGFR3 does not occur in the same myeloma cells. Thus the activated forms of these proteins appear to share an overlapping role in tumor progression, suggesting that they also share the signaling cascade. Consistent with this prediction, it is shown that activated FGFR3-when expressed at levels similar to those seen in t(4;14) myeloma-is an oncogene that acts through the MAP kinase pathway to transform NIH 3T3 cells, which can then generate tumors in nude mice. Thus, FGFR3, when overexpressed in MM, may be not only oncogenic when stimulated by FGF ligands in the bone marrow microenvironment, but is also a target for activating mutations that enable FGFR3 to play a ras-like role in tumor progression.
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PMID:Activated fibroblast growth factor receptor 3 is an oncogene that contributes to tumor progression in multiple myeloma. 1151 Apr 69

Multiple myeloma (MM), a malignant tumor of somatically mutated, isotype-switched plasma cells (PC), usually arises from a common benign PC tumor called Monoclonal Gammopathy of Undetermined Significance (MGUS). MM progresses within the bone marrow, and then to an extramedullary stage from which MM cell lines are generated. The incidence of IgH translocations increases with the stage of disease: 50% in MGUS, 60-65% in intramedullarly MM, 70-80% in extramedullary MM, and >90% in MM cell lines. Primary, simple reciprocal IgH translocations, which are present in both MGUS and MM, involve many partners and provide an early immortalizing event. Four chromosomal partners appear to account for the majority of primary IgH translocations: 11q13 (cyclin D1), 6p21 (cyclin D3), 4p16 (FGFR3 and MMSET), and 16q23 (c-maf). They are mediated primarily by errors in IgH switch recombination and less often by errors in somatic hypermutation, with the former dissociating the intronic and 3' enhancer(s), so that potential oncogenes can be dysregulated on each derivative chromosome (e.g., FGFR3 on der14 and MMSET on der4). Secondary translocations, which sometimes do not involve Ig loci, are more complex, and are not mediated by errors in B cell specific DNA modification mechanisms. They involve other chromosomal partners, notably 8q24 (c-myc), and are associated with tumor progression. Consistent with MM being the malignant counterpart of a long-lived PC, oncogenes dysregulated by primary IgH translocations in MM do not appear to confer an anti-apoptotic effect, but instead increase proliferation and/or inhibit differentiation. The fact that so many different primary transforming events give rise to tumors with the same phenotype suggests that there is only a single fate available for the transformed cell.
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PMID:Chromosome translocations in multiple myeloma. 1160 13

The work described in this review addresses the multifunctional roles of growth factors and their cognate receptors in normal development and in tumorigenesis. The concept of epithelial cell plasticity is described in the context of embryonic development during which frequent remodeling occurs in epithelial tissues. The critical role of one member of the FGF family of growth factors is demonstrated in lung branching morphogenesis. Several members of this family have been shown to induce an epithelial-mesenchymal transition in a bladder carcinoma line. In vivo the same factors act in an autocrine or paracrine mode to favor tumor progression. It is suggested that an EGFR-ligand autocrine loop exerts a positive role in tumor progression of human bladder carcinoma whereas FGFR2 acts as a phenotypic tumor suppressor gene. Unexpectedly, constitutive activating mutations in FGFR3 have been uncovered in the majority of the Ta superficial tumors which progress only very rarely to the invasive stages. In contrast, in situ carcinoma, which are considered to be associated with a strong malignant potential, do not carry the FGFR3 mutations. The presence or absence of the mutations defines two distinct oncogenic pathways in bladder carcinogenesis. The studies reveal the complexities in defining the putative functions of growth factors at different times and differentiation stages during development and in tumor progression. These results emphasize the need for caution in the interpretation of studies evaluating the potential of novel anti-cancer agents and for better designs of in vitro and in vivo biological assays.
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PMID:[Role of growth factor signaling in epithelial cell plasticity during development and in carcinogenesis]. 1197 24

The t(4;14)(p16.3;q32) translocation that occurs uniquely in a subset of multiple myeloma tumors results in ectopic expression of wild-type FGFR3 and enhanced expression of MMSET, a gene that is homologous to the MLL gene that is involved in acute myeloid leukemias. Wild-type FGFR3 appears to be weakly transforming in a hematopoietic murine model, whereas FGFR3 that contains kinase-activating mutations is strongly transforming in NIH3T3 cells and the hematopoietic model. The subsequent acquisition of FGFR3 kinase-activating mutations in some tumors with t(4;14) translocations confirms a role for FGFR3 in tumor progression. However, it remains to be proven if and how dysregulation of FGFR3 or MMSET mediates an early oncogenic process in multiple myeloma.
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PMID:The enigma of ectopic expression of FGFR3 in multiple myeloma: a critical initiating event or just a target for mutational activation during tumor progression. 1204 2

Homeostasis of normal prostate and two-compartment nonmalignant prostate tumors is dependent on two-way communication between epithelial and stromal compartments. Independence of epithelial cells on controlling instructions from stroma is a hallmark of extremely malignant epithelial cell tumors. To better understand the evolution of stromal independence during malignant progression, we performed a clonal analysis of stromal cells derived from a well-defined model of two-way stromal-epithelial cell communication that loses response to stroma during prostate tumor progression. Directionally specific signaling from stroma to epithelium contributes to homeostasis between the two compartments. Stromal cells were characterized in respect to expression and activity of isotypes of the fibroblast growth factor (FGF) family of ligands and receptors in addition to morphology and cytoskeletal markers. One stromal subtype (DTS1) exhibited a fibroblast-like morphology and did not display smooth muscle cell (SMC) alpha-actin. The other (DTS2) exhibited SMC alpha-actin and an SMC-like morphology in vitro. Both subtypes expressed FGF7 and equally low levels of FGFR2IIIc mRNA, whereas fibroblast growth factor receptor (FGFR) 1 predominated in DTS1 cells. DTS1 cells also expressed FGF10 and no detectable FGFR3, whereas the absence of FGF10 and presence of FGFR3 distinguished DTS2 cells. Epithelial cell-derived FGF9 bound to FGFR and stimulated growth of specifically FGFR3-positive DTS2 cells, not the FGFR3-negative DTS1 cells. These results demonstrate stromal cell heterogeneity in signal reception of FGF from epithelium. This correlated with potential heterogeneity in the response back to epithelial cells. Epithelium-dependent control of a stromal cell phenotype within a tumor may be a determinant of whether tumors remain in nonmalignant homeostasis or progress to malignancy.
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PMID:Stromal cell heterogeneity in fibroblast growth factor-mediated stromal-epithelial cell cross-talk in premalignant prostate tumors. 1294 18

Although arbutin is a natural product and widely used as an ingredient in skin care products, its effect on the gene expression level of human skin with malignant melanoma cells is rarely reported. We aim to investigate the genotoxic effect of arbutin on the differential gene expression profiling in A375 human malignant melanoma cells through its effect on tumorigenesis and related side-effect. The DNA microarray analysis provided the differential gene expression pattern of arbutin-treated A375 cells with the significant changes of 324 differentially expressed genes, containing 88 up-regulated genes and 236 down-regulated genes. The gene ontology of differentially expressed genes was classified as belonging to cellular component, molecular function and biological process. In addition, four down-regulated genes of AKT1, CLECSF7, FGFR3, and LRP6 served as candidate genes and correlated to suppress the biological processes in the cell cycle of cancer progression and in the downstream signaling pathways of malignancy of melanocytic tumorigenesis.
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PMID:Toxicogenomics of A375 human malignant melanoma cells treated with arbutin. 1710 32

Bladder cancer is the fifth most commonly diagnosed non-cutaneous solid malignancy, and the second most commonly diagnosed genitourinary malignancy amongst people living in the United States, where it is estimated that more than 61,000 new cases of bladder cancer will be diagnosed in the year 2008. Approximately 90% of malignant tumors arising in the urinary bladder are of epithelial origin, the majority being transitional cell carcinomas. Early stage bladder tumors have been classified into two groups with distinct behavior and unique molecular profiles: low grade tumors (always papillary and usually superficial), and high-grade tumors (either papillary or non-papillary, and often invasive). Clinically, superficial bladder tumors (stages Ta and Tis) account for 75% to 85% of neoplasms, while the remaining 15% to 25% are invasive (T1, T2-T4) or metastatic lesions at the time of initial presentation. Studies from the author's group and others have revealed that distinct genotypic and phenotypic patterns are associated with early versus late stages of bladder cancer. Most importantly, early superficial diseases appear to segregate into two main pathways. Superficial papillary bladder tumors are characterized by gain-of-function mutations, mainly affecting classical oncogenes such as RAS and FGFR3. Deletions of chromosome 9, mainly allelic losses on the long arm (9q) are also frequent events in these tumors. Such genetic alterations are observed in most if not all superficial papillary non-invasive tumors (Ta), but only in a small subset of invasive bladder neoplasms. Flat carcinoma in situ (Tis) and invasive tumors are characterized by loss-of-function mutations, affecting the prototype tumor suppressor genes, including p53, RB and PTEN. These alterations are absent or very rare in the Ta tumors analyzed, but have been frequently identified in invasive bladder carcinomas. Based on these data, a novel model for bladder tumor progression has been proposed in which two separate genetic pathways characterize the evolution of superficial bladder neoplasms. Numerous individual molecular markers have been identified in the tissue specimens that correlate to some extent with tumor stage, and possibly with prognosis in bladder cancer. However, these molecular prognosticators do not play a role in the clinical routine management of patients with bladder tumors, mainly due to lack of large prospective validation studies. Thus, the need for development of specific tissue and serum tumor markers for prognostic stratification remains. The advent of high-throughput microarrays technologies allows comprehensive discovery of targets relevant in bladder cancer progression, which could be translated into new approaches for drug and biomarker development. Further investigation is warranted to define novel biomarkers specific for bladder cancer patients based on the molecular alterations of tumor progression, and multiplexed strategies for clinical management.
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PMID:Molecular alterations associated with bladder cancer initiation and progression. 1881 30

Bladder cancer is the fifth most common human malignancy and the second most frequently diagnosed genitourinary tumor after prostate cancer. The majority of malignant tumors arising in the urinary bladder are urothelial carcinomas. Clinically, superficial bladder tumors (stages Ta and Tis) account for 75% to 85% of neoplasms, while the remaining 15% to 25% are invasive (T1, T2-T4) or metastatic lesions at the time of initial presentation. Several studies have revealed that distinct genotypic and phenotypic patterns are associated with early vs. late stages of bladder cancer. Early superficial disease appears to segregate into 2 main pathways: (1) superficial papillary bladder tumors, which are characterized by gain-of-function mutations affecting oncogenes such as H-RAS, FGFR3, and PI3K, and deletions of the long arm of chromosome 9 (9q); (2) Carcinoma in situ, a "flat" high grade lesion considered to be a precursor of invasive cancer, is characterized by loss-of-function mutations affecting tumor suppressor genes, such as p53, RB, and PTEN. Based on these data, a model for bladder tumor progression has been proposed in which 2 separate genetic pathways characterize the evolution of early bladder neoplasms. Several molecular markers have been correlated with tumor stage, but the rationale for these 2 well-defined genetic pathways still remains unclear. Normal urothelium is a pseudo-stratified epithelium that coats the bladder, composed of 3 cell types: basal, intermediate, and superficial ("umbrella") cells. We have identified a series of markers that are differently expressed in these distinct cells types, and postulated a novel model for urothelium development and configuration. Briefly, it is our working hypothesis that 2 distinct progenitor cells are responsible for basal/intermediate cells and "umbrella" cells, respectively. Basal and intermediate cells are characterized by a p63 positive phenotype, as well as expression of high molecular weight cytokeratins (CKs), such as CK5, CK10, and CK14. On the contrary, "umbrella" cells display a p63 negative phenotype and are characterized by expression of 2 specific low molecular weight CKs: CK18 and CK20. Neither urothelial stem cells nor bladder cancer stem cells have been identified to date. In this review, we will further expand on the issues discussed above.
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PMID:Molecular pathways of urothelial development and bladder tumorigenesis. 2061 Feb 78

Fusion genes are chromosomal aberrations that are found in many cancers and can be used as prognostic markers and drug targets in clinical practice. Fusions can lead to production of oncogenic fusion proteins or to enhanced expression of oncogenes. Several recent studies have reported that some fusion genes can escape microRNA regulation via 3'-untranslated region (3'-UTR) deletion. We performed whole transcriptome sequencing to identify fusion genes in glioma and discovered FGFR3-TACC3 fusions in 4 of 48 glioblastoma samples from patients both of mixed European and of Asian descent, but not in any of 43 low-grade glioma samples tested. The fusion, caused by tandem duplication on 4p16.3, led to the loss of the 3'-UTR of FGFR3, blocking gene regulation of miR-99a and enhancing expression of the fusion gene. The fusion gene was mutually exclusive with EGFR, PDGFR, or MET amplification. Using cultured glioblastoma cells and a mouse xenograft model, we found that fusion protein expression promoted cell proliferation and tumor progression, while WT FGFR3 protein was not tumorigenic, even under forced overexpression. These results demonstrated that the FGFR3-TACC3 gene fusion is expressed in human cancer and generates an oncogenic protein that promotes tumorigenesis in glioblastoma.
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PMID:The tumorigenic FGFR3-TACC3 gene fusion escapes miR-99a regulation in glioblastoma. 2329 39

RNA sequencing facilitates the discovery of novel gene fusions in cancer. In this issue of the JCI, Parker et al. identify an FGFR3-TACC3 fusion oncogene in glioblastoma and demonstrate a novel mechanism of pathogenicity. A miR-99a binding site within the 3'-untranslated region (3'-UTR) of FGFR3 is lost, releasing FGFR3 signaling from miR-99a-dependent inhibition and greatly enhancing tumor progression relative to WT FGFR3. These results provide compelling insight into the pathogenicity of a novel fusion oncogene and suggest new therapeutic approaches for a subset of glioblastomas.
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PMID:Multiple functions of a glioblastoma fusion oncogene. 2329 36

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