Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.10.1 (ERK)
 95,504 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Expression of the wild-type RET proto-oncogene has been observed in non-medullary, follicular cell-derived tumors (FCDT), but the relation with the histopathological features has not been fully demonstrated. To assess the expression of RET and protein products in relation to morphological types of FCDT, including follicular adenoma (FA), papillary carcinoma (PTC), follicular carcinoma (FTC) and anaplastic carcinoma (AnC), 58 non-neoplastic and neoplastic samples using pathological paraffin sections by immunohistochemistry (IHC), reverse transcriptase-polymerase chain reaction (RT-PCR) and laser capture microdissection (LCM) methods were analyzed. Expression of RET proto-oncogene was detected in 27.3% of FCDT by IHC and 25.5% by RT-PCR using a primer set at a regular break point. The present study also found higher expression ratios of RET in FA (50.0%) and the follicular variant of PTC (50.0%), in contrast to FTC (20.0%), ordinary PTC (20.0%) and poorly differentiated or AnC (14.3%) by RT-PCR. One patient with PTC showed a discrepancy in the results by RT-PCR using a different primer set at the C-terminus of RET. The study found that the RET proto-oncogene is often stimulated in FCDT, not only in PTC but also in follicular tumors (FA and FTC), and may contribute to tumorigenesis of these tumors.
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PMID:Expression of RET in follicular cell-derived tumors of the thyroid gland: prevalence and implication of morphological type. 1260 95

Thyroid papillary carcinomas are characterized by RET/PTC (rearranged in transformation/papillary thyroid carcinoma) rearrangements that result in fusion of the tyrosine kinase domain of the RET receptor to the N-terminal sequences encoded by heterologous genes. This thyroid-specific rearrangement causes aberrant expression of RET/PTC and results in constitutive ligand-independent activation of RET kinase. However, it is unclear how RET/PTC activates the specific signaling pathways for cellular transformation. In this study, we show that RET/PTC associates with signal transducer and activator of transcription 3 (STAT3) and activates it by the specific phosphorylation of the tyrosine 705 residue. Activation of STAT3 requires the intrinsic kinase activity of RET/PTC; Janus tyrosine kinase and c-Src kinase are not involved in the RET/PTC-mediated activation of STAT3. RET/PTC-induced activation of STAT3 induces the STAT3-responsive genes, vascular endothelial growth factor, cyclin D1, and intercellular adhesion molecule 1. In addition, RET/PTC-mediated cellular transformation and proliferation of transformed cells require tyrosine 705 phosphorylation of STAT3 in NIH3T3 cells. We conclude that STAT3 activation by the RET/PTC tyrosine kinase is one of the critical signaling pathways for the regulation of specific genes, such as cyclin D1, vascular endothelial growth factor, and intercellular adhesion molecule 1, and for cellular transformation.
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PMID:Activation of signal transducer and activator of transcription 3 by oncogenic RET/PTC (rearranged in transformation/papillary thyroid carcinoma) tyrosine kinase: roles in specific gene regulation and cellular transformation. 1263 86

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

Thyroid papillary cancers (PTCs) are associated with activating mutations of genes coding for RET or TRK tyrosine kinase receptors, as well as of RAS genes. Activating mutations of BRAF were reported recently in most melanomas and a small proportion of colorectal tumors. Here we show that a somatic mutation of BRAF, V599E, is the most common genetic change in PTCs (28 of 78; 35.8%). BRAF(V599E) mutations were unique to PTCs, and not found in any of the other types of differentiated follicular neoplasms arising from the same cell type (0 of 46). Moreover, there was no overlap between PTC with RET/PTC, BRAF, or RAS mutations, which altogether were present in 66% of cases. The lack of concordance for these mutations was highly unlikely to be a chance occurrence. Because these signaling proteins function along the same pathway in thyroid cells, this represents a unique paradigm of human tumorigenesis through mutation of three signaling effectors lying in tandem.
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PMID:High prevalence of BRAF mutations in thyroid cancer: genetic evidence for constitutive activation of the RET/PTC-RAS-BRAF signaling pathway in papillary thyroid carcinoma. 1267 Aug 89

Chromosomal rearrangements linking the promoter(s) and N-terminal domain of unrelated gene(s) to the C terminus of RET result in constitutively activated chimeric forms of the receptor in thyroid cells (RET/PTC). RET/PTC rearrangements are thought to be tumor-initiating events; however, the early biological consequences of RET/PTC activation are unknown. To explore this, we generated clonal lines derived from well-differentiated rat thyroid PCCL3 cells with doxycycline-inducible expression of either RET/PTC1 or RET/PTC3. As previously shown in other cell types, RET/PTC1 and RET/PTC3 oligomerized and displayed constitutive tyrosine kinase activity. Neither RET/PTC1 nor RET/PTC3 conferred cells with the ability to grow in the absence of TSH, likely because of concomitant stimulation of both DNA synthesis and apoptosis, resulting in no net growth in the cell population. Effects of RET/PTC on DNA synthesis and apoptosis did not require direct interaction of the oncoprotein with either Shc or phospholipase Cgamma. Acute expression of the oncoprotein decreased TSH-mediated growth stimulation due to interference of TSH signaling by RET/PTC at multiple levels. Taken together, these data indicate that RET/PTC is a weak tumor-initiating event and that TSH action is disrupted by this oncoprotein at several points, and also predict that secondary genetic or epigenetic changes are required for clonal expansion.
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PMID:Conditional expression of RET/PTC induces a weak oncogenic drive in thyroid PCCL3 cells and inhibits thyrotropin action at multiple levels. 1269 93

Thyroid cancers are a leading cause of death due to endocrine malignancies. RET/PTC (rearranged in transformation/papillary thyroid carcinomas) gene rearrangements are the most frequent genetic alterations identified in papillary thyroid carcinoma. Although the oncogenic potential of RET/PTC is related to intrinsic tyrosine kinase activity, the substrates for this enzyme are yet to be identified. In this report, we show that phosphoinositide-dependent kinase 1 (PDK1), a pivotal serine/threonine kinase in growth factor-signaling pathways, is a target of RET/PTC. RET/PTC and PDK1 colocalize in the cytoplasm. RET/PTC phosphorylates a specific tyrosine (Y9) residue located in the N-terminal region of PDK1. Y9 phosphorylation of PDK1 by RET/PTC requires an intact catalytic kinase domain. The short (iso 9) and long forms (iso 51) of the RET/PTC kinases (RET/PTC1 and RET/PTC3) induce Y9 phosphorylation of PDK1. Moreover, Y9 phosphorylation of PDK1 by RET/PTC does not require phosphatidylinositol 3-kinase or Src activity. RET/PTC-induced phosphorylation of the Y9 residue results in increased PDK1 activity, decrease of cellular p53 levels, and repression of p53-dependent transactivation. In conclusion, RET/PTC-induced tyrosine phosphorylation of PDK1 may be one of the mechanisms by which it acts as an oncogenic tyrosine kinase in thyroid carcinogenesis.
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PMID:RET/PTC (rearranged in transformation/papillary thyroid carcinomas) tyrosine kinase phosphorylates and activates phosphoinositide-dependent kinase 1 (PDK1): an alternative phosphatidylinositol 3-kinase-independent pathway to activate PDK1. 1273 63

Constitutive activation of the RET proto-oncogene in papillary thyroid carcinomas results from rearrangements linking the promoter(s) and N-terminal domains of unrelated genes to the C-terminus of RET tyrosine kinase (RET/PTC). RET/PTC expression has been demonstrated to inhibit transcription of thyroid-specific genes. To study the signal transduction pathways responsible for this, we generated PCCL3 thyroid cells with doxycycline-inducible expression of RET/PTC3, RET/PTC3(Y541F), or PTC2/PDZ. Acute expression of RET/PTC(Y541F) appropriately interacted with Shc, an intermediate in the activation of the Ras pathway, but failed to activate PLCgamma. By contrast, PTC2/PDZ failed to bind Shc, but interacted normally with PLCgamma. Acute expression of RET/PTC3 or RET/PTC3(Y541F), but not PTC2/PDZ, inhibited TSH-induced Tg and NIS expression, suggesting that activation of Shc-Ras, but not PLCgamma, is required for RET/PTC-induced dedifferentiation. Accordingly, acute expression of H-Ras(V12) or of a constitutively active MEK1 also blocked TSH-induced expression of Tg and NIS. Moreover, MEK inhibitors restored Tg and NIS levels. In conclusion, activation of the Ras/Raf/MEK/MAPK pathway through Shc mediates RET/PTC-induced thyroid cell dedifferentiation. This suggests that inhibition of this pathway may promote redifferentiation in poorly differentiated thyroid carcinomas with constitutive activation of either Ras or RET/PTC.
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PMID:RET/PTC-induced dedifferentiation of thyroid cells is mediated through Y1062 signaling through SHC-RAS-MAP kinase. 1285 77

Nuclear envelope (NE) irregularity is an important diagnostic feature of cancer, and its molecular basis is not understood. One possible cause is abnormal postmitotic NE re-assembly, such that a rounded contour is never achieved before the next mitosis. Alternatively, dynamic forces could deform the NE during interphase following an otherwise normal postmitotic NE re-assembly. To distinguish these possibilities, normal human thyroid epithelial cells were microinjected with the papillary thyroid carcinoma oncogene (RET/PTC1 short isoform, known to induce NE irregularity), an attenuated version of RET/PTC1 lacking the leucine zipper dimerization domain (RET/PTC1 Deltazip), H (V-12) RAS, and labeled dextran. Cells were fixed at 6 or 18 to 24 hours, stained for lamins and the products of microinjected plasmids, and scored blindly using previously defined criteria for NE irregularity. 6.5% of non-injected thyrocytes showed NE irregularity. Neither dextran nor RAS microinjections increased NE irregularity. In contrast, RET/PTC1 microinjection induced NE irregularity in 27% of cells at 6 hours and 37% of cells at 18 to 24 hours. RET/PTC1 Deltazip induced significantly less irregularity. Since irregularity develops quickly, and since no mitoses and only rare possible postmitotic cells were scored, postmitotic NE re-assembly does not appear necessary for RET/PTC signaling to induce an irregular NE contour.
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PMID:Nuclear envelope irregularity is induced by RET/PTC during interphase. 1293 50

Different techniques of molecular biology have been used to screen for RET rearrangements. More recently, immunohistochemistry has been used, assuming that RET is not expressed in normal thyroid follicular cells. The present study was designed to define the prevalence of RET expression in patients with papillary thyroid carcinoma, by immunohistochemistry and by RT-PCR; to search specifically for RET/PTC-1; -2; -3 rearrangements using RT-PCR, and to compare results obtained by immunohistochemistry with those obtained by RT-PCR. Immunohistochemistry was performed using a polyclonal antibody against tyrosine kinase domain of Ret protein. Screening for RET/PTC1-3 was performed using RT-PCR and specific primers for each rearrangement; complementarily, a subset of cases were tested using RET exon 10/11 primers designed to detect the expression of the wild-type RET. Positive staining was observed in 30 of 39 (77%) tumours. RET/PTC1-3 rearrangements were detected in 8 of 32 (25%) cases. Ten of 15 (67%) cases expressed the wild-type RET. Two tumours characterised by positive immunostaining, absence of RET 5' expression and absence of RET/PTC1-3 expression were considered as expressing a RET rearrangement different from RET/PTC-1, -2, or -3. In 3 of 10 tumours, expression of the wild-type RET coexisted with the expression of a RET rearrangement. Positive staining does not necessarily mean the presence of a rearrangement; it may correspond to the expression of the wild-type RET, RET rearrangement or both. On the contrary, positive staining without evidence for the expression of the extracellular domain of RET is highly suggestive of a RET rearrangement independently of the type. Refinement of diagnosis depends on RT-PCR with specific primers.
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PMID:Immunostaining and RT-PCR: different approaches to search for RET rearrangements in patients with papillary thyroid carcinoma. 1296 82

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


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