EC:2.7.10.1 - FACTA Search

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Query: EC:2.7.10.1 (ERK)
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Benign and malignant thyroid tumors constitute a wide range of neoplasias showing recurrent chromosome abnormalities. Cytogenetic studies of thyroid hyperplasias and follicular adenomas revealed hyperdiplo d karyotypes with a characteristic sequence of trisomies (7, 5, 12, 14, 16, 17, 20 and 22) starting with trisomy 7. Comparative genomic hybridization (CGH) findings on thyroid oncocytic tumors showed similar chromosomal gains with no difference observed between adenomas and carcinomas. Follicular thyroid carcinomas exhibit losses of 3p25-pter predominantly or of 22,13 and 1p segments. Formation of fusion genes PAX8 - PPARgamma1 caused by a t(2;3)(q13;p25) has been observed in several cases of follicular carcinomas only. Loss of chromosome 22 has been found most frequently associated with widely invasive follicular carcinomas. Activation of the RET protooncogene through chromosome rearrangements involving subband 10q11.2 represent the most common and specific genetic alteration in papillary thyroid carcinoma. Several chimeric genes resulting in the fusion of the tyrosine kinase domain of RET with the 5' sequences of different genes have been described. Germline mutations in RET are associated with medullary thyroid carcinoma in multiple endocrine neoplasia type 2 (MEN2). Cytogenetics of thyroid tumors, using conventional and molecular methods (FISH, CGH) demonstrated that particular chromosome aberrations may be related to the clinical behavior of these tumors and may provide informations for their diagnosis or prognosis.
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PMID:[From the cytogenetics to the cytogenomics of thyroid tumors]. 1213 59

Tumors of thyroid follicular cells provide a very interesting model to understand the development of human cancer. It is becoming apparent that distinct molecular events are associated with specific stages in a multistep tumorigenic process with good genotype/ phenotype correlation. For instance, mutations of the gsp and thyroid-stimulating hormone receptor genes are associated with benign hyperfunctioning thyroid nodules and adenomas while alterations of other specific genes, such as oncogenic tyrosine kinase alterations (RET/PTC, TRK) in papillary carcinoma and the newly discovered PAX8/peroxisome proliferator-activated receptor gamma rearrangement, are distinctive features of cancer. Although activating RAS mutations occur at all stages of thyroid tumorigenesis, evidence is accumulating that they may also play an important role in tumor progression, a role that is well documented for p53. Environmental factors (iodine deficiency, ionizing radiations) have been shown to play a crucial role in promoting the development of thyroid cancer, influencing both its genotypic and phenotypic features. It is possible that the follicular thyroid cell has unique ways to respond to DNA damage. Similarly to leukemia or sarcomas (and unlike most epithelial cancers), numerous specific rearrangements are being discovered in thyroid cancer suggesting preferential activation of DNA repair instead of cell death programs after environmentally induced genetic alterations.
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PMID:Molecular pathobiology of thyroid neoplasms. 1266 46

Several genes control cell growth, differentiation and apoptosis. Any alteration in the sequence or expression of these genes can cause an uncontrolled growth of the tissue and produce a tumor. Quantitative and qualitative gene expression studies using genes as tumor markers are essential for the diagnosis and prognosis of the tumor and its behavior. Oncogenes are genes that stimulate cell growth and have an increased expression. On the contrary, tumor suppressor genes are genes that inhibit cell growth and have a decreased expression in tumor cells. To study these tumor markers we apply simple and random molecular biology techniques such as polymerase chain reaction (PCR), reverse transcription and genomic sequencing. In the case of thyroid epithelial neoplasia, tumor markers such as PTEN/MMAC1/TEP1, telomerase, RET/PTC, b-catenine, PAX8/PPAR(1, ciclooxygenase, thyroid stimulating hormonal receptor (TSHR), and thyro-globulin are being investigated. These markers are analyzed for somatic mutations in the genetic sequence, chromosomical rearrangements, alterations in the promoter zone that affect gene expression, regulation and studies of genes at mRNA level. A deeper study of these markers is deemed to help improve the accuracy of tumor diagnosis, behavior and prognosis. Hence, more effective therapeutic options will be adapted to each individual, eventually reducing hospital costs.
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PMID:[Thyroid carcinomas of the follicular epithelium: tumor markers and oncogenes]. 1297 39

Thyroid carcinomas represent only 1% of all human malignancies, but more than 90% of endocrine tumors. It can be histologically divided into papillary, follicular, anaplastic or medullary thyroid carcinomas. Here we report the genetic causes of the development of these tumors. For papillary thyroid carcinoma formation of fused genes of tyrosine kinases (RET proto-oncogene, NTRK1 proto-oncogene and met proto-oncogene) with other genes is typical. They can activate these kinases and induce mutation in BRAF gene. The presence of PAX8/PPARgamma fused gene and ras mutations are important in the development of follicular thyroid carcinoma. Anaplastic thyroid carcinoma derives from the dedifferentiation of papillary and follicular carcinomas as a consequence of mutation or loss of heterozygozity in p53 gene. Medullary thyroid carcinoma comes from parafollicular C-cells, where point somatic and germ-line mutations (in familial form of medullary thyroid carcinoma or in multiple endocrine neoplasia type 2) in the RET proto-oncogene determine its development. Identification of these specific genetic alternations for each type of carcinoma can contribute to precision of the diagnosis, explanation of the origin of carcinomas, establishment of prognosis of the disease or in future as a tool for the target gene therapy.
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PMID:[Genetic causes of the thyroid carcinomas]. 1558 14

Recent molecular studies have provided new insights into thyroid carcinogenesis. In thyroid papillary carcinomas at least three initiating events may occur, which are point mutations in the BRAF and RAS genes and RET/PTC rearrangements. Tumors harboring mutant BRAF and RAS are prone to progression to poorly differentiated and anaplastic carcinoma, but most likely require additional mutations to trigger this process. In thyroid follicular carcinomas, two known initiating events are RAS mutations and PAX8-PPARgamma rearrangements, and RAS predisposes to dedifferentiation of follicular carcinomas. p53 and beta-catenin mutations, found with increasing incidence in poorly differentiated and anaplastic carcinomas but not in well-differentiated tumors, may serve as a direct molecular trigger of tumor dedifferentiation. Additional evidence for progression from a preexisting well-differentiated carcinoma to poorly differentiated and anaplastic carcinoma comes from the studies of loss of heterozygosity and comparative genomic hybridization. Molecular studies, although limited by the lack of uniform histologic criteria for poorly differentiated carcinomas, revealed no genetic mutations or chromosomal abnormalities that are unique for poorly differentiated carcinoma and not present in well-differentiated or anaplastic carcinomas. This suggests that poorly differentiated carcinoma, as a group, represents a distinct step in the evolution from well-differentiated to anaplastic thyroid carcinoma, rather than an entirely separate type of thyroid malignancy.
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PMID:Genetic alterations involved in the transition from well-differentiated to poorly differentiated and anaplastic thyroid carcinomas. 1568 56

Papillary thyroid carcinomas are characterized in 70% of cases by the presence of either a RET/PTC rearrangement, or an activating point mutation of RAS or BRAF genes that induce a constitutive activation of the MAP kinase pathway. Follicular carcinomas are characterized by the presence of a RAS mutation or of a PAX8-PPARgamma rearrangement. Inactivating mutations of the p53 gene are found only in anaplastic thyroid carcinomas.
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PMID:[Oncogenes and thyroid tumors]. 1568 24

Knowledge of the molecular events that govern human thyroid tumorigenesis has grown considerably in the past ten years. Key genetic alterations and new oncogenic pathways have been identified. Molecular genetic aberrations in thyroid carcinomas bear noteworthy resemblance to those in acute myelogenous leukemias. Thyroid carcinomas and myeloid leukemias both possess transcription factor gene rearrangements-PPARgamma-related translocations in thyroid carcinoma and RARalpha-related and CBF-related translocations (amongst others) in myeloid leukemia. PPARgamma and RARalpha are closely related members ofthe same nuclear receptor subfamily, and the PML-RARalpha and PAX8-PPARgamma fusion proteins both function as dominant negative inhibitors of their wild-type parent proteins. Thyroid carcinomas and myeloid leukemias also both harbor NRAS mutations (15-25% of both cancers) and receptor tyrosine kinase mutations--RET mutations in thyroid carcinomas and FLT3 mutations in myeloid leukemias. The NRAS and tyrosine receptor kinase mutations are not observed in the same thyroid carcinoma or leukemia patients, suggesting that multiple initiating pathways exist in both. Lastly, thyroid carcinomas and myeloid leukemias possess p53 mutations at relatively low frequency (10-15%) in patients who tend to be older and have more aggressive, therapy resistant disease. Such parallels are unlikely to occur by chance alone and argue that common mechanisms underlie these diverse epithelial and hematologic cancers. The comparison of thyroid carcinomas and myeloid leukemias may highlight areas of thyroid cancer investigation worthy of further focus. For example, few collaborating mutations have been defined in thyroid carcinomas even though they play a clear role in myeloid leukemias, as exemplified by RARalpha rearrangements and FLT3 mutations that together dictate the promyleocytic leukemia phenotype. Functional interactions between collaborating mutations are possible at multiple levels, and it is tempting to speculate that some thyroid carcinomas might develop through an unique combination or co-activation of RET and RAS and/or RET and PPARgamma (and/or other) signaling systems. In fact, the ELE1-RET (PTC3) fusion protein contains the ELE1 nuclear receptor co-activator domain and it appears to physically associate with and inhibit wild-type PPARgamma in some papillary carcinomas. The similarities of the fusion proteins in thyroid carcinoma and myeloid leukemia suggest that a more directed search for fusion genes in non-thyroid carcinomas is warranted. In fact, novel fusion genes have been identified recently in aggressive midline, secretory breast, and renal cell carcinomas, although the epithelial nature of the latter is not well-documented. Interestingly, these cancers all tend to present more frequently in adolescence and young adulthood in a manner similar to thyroid and myeloid malignancies that have fusion genes. The analyses of cancers that present earlier in life may enhance fusion gene recognition in other carcinoma types. Definition and biologic characterization of the precursor cells that give rise to thyroid carcinoma will also be important. Myeloid leukemias are thought to arise from stem/progenitor cells that acquire disturbed self-renewal and differentiation capacities but retain characteristics of the myeloid lineages. Although the presence of comparable stem/progenitor cells in the thyroid are not defined, distinct thyroid cancer lineages and patterns of differentiation exist and candidate stem/progenitor cells such as the p63-immunoreactive solid cell nests are apparent. A last important area is development of molecular-based therapies for thyroid carcinoma patients resistant to standard radio-iodine treatment. Treatments for such cancers are limited and pathways defined by thyroid cancer mutations are prime targets for pharmacologic interventions with molecular inhibitors. Tyrosine kinase inhibitors and nuclear receptor ligands have proven dramatically effective in some myeloid leukemia patients. Various molecular inhibitors are being investigated now in thyroid cancer models. Such developments predict that the thyroid cancer model will continue to provide biologic insights into human carcinoma biology and that improved pathologic diagnosis and treatment for thyroid cancer patients sit on the not too distant horizon.
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PMID:Molecular events in follicular thyroid tumors. 1620 39

Differentiated thyroid cancers (papillary--PTC and follicular--FTC) are the most common endocrine malignancies. The recent progresses in the understanding of PTC and FTC pathogenesis are summarized in this review. In PTC, a single mutation of BRAF (the gene for the B-type Raf kinase) (V600E) is responsible for the disease in 40-50% of patients, especially in older people and is associated with a poorer clinicopathological outcome. Due to these characteristics, its use as a specific diagnostic and prognostic marker for PTC in cytological specimens is being implemented. Another important cause of PTC is rearrangements of the RET tyrosine kinase receptor (RET/PTC), which represent a recombination of the promoter and N-terminal domain of a partner gene with the C-terminal region of the RET gene, resulting in a chimeric gene with a protein product containing a constitutively activated RET tyrosine kinase, responsible for 20-30% patients, specially the younger or after radiation. The pathogenesis of FTC is less understood. A chromosomal translocation between the transcription factor PAX8 and the peroxisome proliferator-activated receptorgamma (PPARgamma) occurs in 30-50% of patients; however, the presence of PAX8-PPARgamma is also demonstrated in follicular adenomas. Therefore, there is no complete evidence that PAX8-PPARgamma is the cause of FTC. Another finding in FTC is mutations on the RAS gene, which excludes PAX8-PPARgamma rearrangements. Several genes, as TRgamma, PTEN, PKAR1A, DDIT3, ARG2, ITM1 and C1orf24--some discovered by techniques of differential gene expression--, have been recently implicated in the pathogenesis of FTC.
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PMID:[Pathogenesis of differentiated thyroid cancer (papillary and follicular)]. 1644 51

Tumors of the thyroid with a follicular growth pattern are controversial and can be diagnostically challenging for the pathologist. This group of tumors includes both follicular derived lesions (adenomas and carcinomas) and papillary carcinoma (follicular variant of papillary carcinoma). H&E morphology has classically been the gold standard for diagnosis. In the past several decades, however, several important molecular markers have been identified that may be unique to different types of thyroid carcinomas. These include the translocations RET/PTC and PAX8-PPARgamma and point mutations in the BRAF and RAS genes. Other molecular events in tumor suppressor genes may be useful for diagnosis of these tumors as well. None of the mutational markers are very sensitive, and there is some question regarding specificity for malignancy, because mutations have also been described in histologically benign tumors. However, with increasing availability of molecular testing for the general pathologist, a molecular testing panel used in conjunction with the H&E morphology and immunohistochemical stains may become useful in the clinical setting for the diagnosis of thyroid tumors.
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PMID:Understanding the genotype of follicular thyroid tumors. 1662 18

Epithelial tumors of the thyroid are cytogenetically well-investigated tumors. So far, the main cytogenetic subgroups, characterized by trisomy 7 and by rearrangements of either 19q13 or 2p21, respectively, have been described. Recently, we have been able to describe the involvement of a novel gene called THADA in benign thyroid lesions with 2p21 rearrangements. Other fusion genes found in thyroid lesions are RET/PTC and PAX8/PPAR(gamma). The latter occurs in follicular thyroid carcinomas with a t(2;3)(q13;p25). Here we present molecular-cytogenetic and cytogenetic investigations on a follicular thyroid adenoma with a t(2;20;3)(p21;q11.2; p25). In this case, an intronic sequence of PPAR(gamma) is fused to exon 28 of THADA. We used BAC clones containing the genomic sequence of PPARgamma for fluorescence in situ hybridization to confirm the localization of the breakpoint within intron 2 of PPAR(gamma) . Our findings suggest that the close surrounding of PPAR(gamma) is a breakpoint hot spot region, leading to recurrent alterations of this gene in thyroid tumors of follicular origin including carcinomas as well as adenomas with or without involvement of PAX8.
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PMID:Evidence for a 3p25 breakpoint hot spot region in thyroid tumors of follicular origin. 1712 35

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