Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.7.1.21 (thymidine kinase)
 7,561 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Normally, thyroid cancer is a disease with a good prognosis, but about 30% of the tumours dedifferentiate and may finally develop into highly malignant anaplastic thyroid carcinomas with a mean survival time of less than 8 months. Due to the loss of thyroid-specific functions associated with dedifferentiation, these tumours are inaccessible to standard therapeutic procedures such as radioiodide therapy and thyroxine-mediated thyrotrophin suppression. Medullary thyroid carcinomas are also highly aggressive. Here, therapy is limited to surgery, and no alternative is left if patients do not respond to this standard procedure. Obviously, new approaches would be desirable. Several novel approaches are currently being tested for the treatment of thyroid cancer. Many of them utilise methods of gene therapy, but follow different strategies: (1) reintroduction of the tumour suppressor p53 into a background lacking functional p53; (2) suicide gene therapy with ganciclovir and a transduced gene for herpes simplex virus thymidine kinase controlled by the thyroglobulin promoter; (3) strengthening of the antitumour immune response by expression of an adenovirus-delivered interleukin-2 (IL-2) gene; (4) induction of an immune response by DNA vaccination against the tumour marker calcitonin; (5) transduction of the thyroid sodium/iodide transporter gene to make tissues that do not accumulate iodide treatable by radioiodide therapy; (6) blocking of the expression of the oncogene c-myc by antisense oligonucleotides. While these approaches are still tested in vitro or in animal models, first results from pilot studies concerning other novel treatment modalities are available: (7) radioimmunotherapy exploits the carcinoembryonic antigen expressed on medullary thyroid carcinomas to target a radiolabelled antibody to the tumour; and (8) retinoic acid is used for a redifferentiation therapy in the case of thyroid cancer. Hopefully, one or the other of these novel strategies may probably extend after some time the current therapeutic repertoire for thyroid cancers and provide a perspective for otherwise untreatable patients.
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PMID:Innovative strategies for the treatment of thyroid cancer. 1087 26

Thyroid carcinoma accounts for the majority of deaths from endocrine cancers. Although effective therapies exist for well differentiated tumors, the treatment options for poorly differentiated and anaplastic tumors are much less effective. In the present study we demonstrate that the thyroglobulin (Tg) promoter can be used to direct specific expression of either luciferase or thymidine kinase in thyroid cancer cells. Furthermore, using a putative enhancer element for the Tg gene, the activity of the Tg promoter in and its specificity for thyroid cells were enhanced. In transient transfectants or in stably transfected thyroid carcinoma cells, treatment with the histone deacetylase inhibitors, depsipeptide (FR9012228) and sodium butyrate, alone or in combination with 8-bromo-cAMP, resulted in further enhancement. In experiments in which the herpes simplex virus thymidine kinase (HSV-TK) gene was driven by the Tg promoter and the putative enhancer, HSV-TK expression and ganciclovir sensitivity were augmented. Similar results were obtained in two cell lines derived from a follicular thyroid carcinoma and in two anaplastic thyroid carcinoma cell lines. In summary, we report the construction of a suicide HSV-TK vector with preferential toxicity for thyroid cells. The results in anaplastic thyroid carcinoma cells suggest that it may be of use in the full spectrum of thyroid malignancies.
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PMID:Construction of gene therapy vectors targeting thyroid cells: enhancement of activity and specificity with histone deacetylase inhibitors and agents modulating the cyclic adenosine 3',5'-monophosphate pathway and demonstration of activity in follicular and anaplastic thyroid carcinoma cells. 1115 54

We evaluated the effectiveness of a replication-defective adenovirus-transducing thymidine kinase (TK) gene under the control of the rat Tg (rTg) promoter (AdrTgtk) in therapy of a human Hurthle cancer (XTC-1 cell) in vitro and in vivo. The ganciclovir (GCV) sensitivity of infected XTC-1 cells was assessed in vitro by H(3)-thymidine incorporation assay and Trypan-blue exclusion, and by an in vivo tumor development assay. Proliferation was strongly inhibited by adding GCV into the culture medium of infected cells, but not uninfected cells, proving cell infection and expression of TK in the XTC-1 cells. AdrTgtk, and also viruses that have the noncell-specific cytomegalovirus (CMV) promoter-directing expression of TK (AdCMVtk), or luciferase (AdCMVLuc), were used to transduce XTC-1 cells to evaluate killing effects. After infection with AdCMVtk or AdrTgtk, followed by GCV treatment, 70% of infected cells were killed in the presence of GCV, compared with less than 20% of cells infected by AdCMVLuc and treated with GCV. In vivo toxicity was studied in BALB/c mice. When adenovirus is given iv, liver is the major organ infected. No significant changes of the serum transaminase levels and no histological abnormalities were found in animals treated with AdrTgtk/GCV given iv, compared with control animals. High levels of serum transaminases, lymphocyte infiltration, some Kupffer's cell prominence, and extensive single-cell hepatocyte death were found in AdCMVtk/GCV-treated animals, indicating severe liver damage induced, as expected, by the noncell-specific CMV promoter. XTL-1 cells (2 x 10(6)) were injected sc into BALB/c-severe combined immunodeficient mice (BALB/c-SCID), and the mice developed tumors after 3 wk. After intratumoral injection of AdrTgtk and treatment with GCV, tumors stabilized in 15 of 17 mice within 3 wk, 9 tumors remained stabilized after 5 wk of treatment, and 2 disappeared during observation. In AdCMVLuc/GCV-treated control mice, almost all tumors grew continuously. The average tumor size in AdrTgtk-treated mice was significantly smaller than that of control animals after 2 wk of treatment. Our data confirm the effectiveness and specificity of an adenovirus using rTg promoter to express TK, and support its future application to thyroid cancer gene therapy in humans.
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PMID:Cell-specific viral gene therapy of a Hurthle cell tumor. 1188 17

The successful use of tissue- or tumor-selective promoters in targeted gene therapy for cancer depends on high and selective activity. Tg is a thyroid-specific protein that is expressed in the normal thyroid and a majority of thyroid tumors. In the present study, we show, using a luciferase reporter assay, that a construct containing the putative Tg promoter and enhancer is active in 4 thyroid carcinoma cell lines (including 2 anaplastic thyroid carcinoma cell lines) and not in 5 cancer cell lines arising from nonthyroid tissues. Furthermore, both the activity and the specificity of this construct were increased by pretreatment with 8-Br-cAMP and the histone deacetylase inhibitor depsipeptide (FR901228). Expression of thymidine kinase in thyroid cancer cells infected with a recombinant adenovirus (Ad) carrying a Tg enhancer/promoter-thymidine kinase expression cassette (AdTg enhancer/promoter-TK) correlated with the level of Tg enhancer/promoter activity in these cells. Under similar conditions, TK expression was not observed in cancer cell lines arising from nonthyroid tissues. Cells infected with AdTg enhancer/promoter-TK demonstrated preferential GCV sensitivity, with up to a 100,000-fold increase in GCV sensitivity in thyroid cancer cell lines compared to cancer cell lines of nonthyroid origin. The construct described herein can be used to selectively target thyroid cancer cells, and its expression can be modulated to further increase its specificity and selectivity, especially in anaplastic thyroid carcinoma cells, using 8-Br-cAMP and depsipeptide.
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PMID:Adenovirus HSV-TK construct with thyroid-specific promoter: enhancement of activity and specificity with histone deacetylase inhibitors and agents modulating the camp pathway. 1199 17

Medullary thyroid carcinoma (MTC), a neoplasm of thyroid C-cells, is characterized by dominant activating mutations in the RET proto-oncogene. Currently therapy is restricted to surgical removal of all neoplastic tissue lacking alternative forms of treatment such as chemotherapy or radiotherapy. Therefore MTC is a particularly attractive target for gene therapeutic approaches. Many promising gene therapy strategies have been used in various animal models of MTC, showing enhanced antitumoral efficacy, and these will hopefully extend our current standard of care in the future. These approaches can tentatively be subdivided into four groups: (a) Inhibition of oncogenic RET signaling, (b) suicide gene therapy, (c) immunotherapy, and (d) combination of immunotherapy and suicide approaches. To block oncogenic signal transduction dominant-negative RET mutants were delivered into tumor cells and found to possess strong antineoplastic activity, including tumor growth suppression and increased animal survival. Suicide gene therapeutic approaches applied to MTC treatment featured either gene transfer of herpes simplex virus thymidine kinase with concomitant application of ganciclovir or delivery of nitric oxide synthase II. Here antitumor effects were attributed to the occurrence of substantial bystander activities. Immunotherapy approaches comprised stimulation of immune response by delivery of interleukin 2 or 12. Finally, treatment with herpes simplex virus thymidine kinase/ganciclovir in combination with interleukin 2 was found to be superior over either treatment alone. This review discusses the various gene therapeutic approaches applied to MTC treatment in detail, gives an overview on the diverse vector systems used to achieve efficient transduction of thyroid cancer cells, and points out the strategies employed to accomplish target cell selective gene expression thereby contributing to enhanced safety of gene therapy for MTC
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PMID:Gene therapeutic approaches for medullary thyroid carcinoma treatment. 1281 13

Despite multimodality treatment for thyroid cancer, including surgical resection, radioiodine therapy, thyrotropin (TSH)-suppressive thyroxine treatment, and chemotherapy/radiotherapy, survival rates have not improved over the last decades. Therefore, development and evaluation of novel treatment strategies, including gene therapy, are urgently needed. A variety of gene therapy approaches have been evaluated for the treatment of follicular cell-derived and medullary thyroid cancer, including corrective gene therapy (p53 restoration, expression of a dominant negative RET mutant), cytoreductive gene therapy (suicide gene/prodrug strategy herpes simplex virus-thymidine kinase [HSV-tk]/ganciclovir, antiangiogenic therapy with endostatin) and immunomodulatory gene therapy (expression of interleukin (IL)-2 and IL-12). Furthermore, cloning of the sodium iodide symporter (NIS) gene has paved the way for the development of a novel cytoreductive gene therapy strategy based on NIS gene transfer followed by the application of radioiodine therapy ((131)I). NIS gene delivery into medullary and follicular cell-derived thyroid cancer cells has been shown to be capable of establishing or restoring radioiodine accumulation and might therefore represent an effective therapy for medullary and dedifferentiated thyroid tumors that lack iodide accumulating activity. The data summarized in this review article clearly demonstrate that the currently available strategies represent potentially curative novel therapeutic approaches for future gene therapy of thyroid cancer. The combination of different therapeutic genes has been demonstrated to be very useful to enhance therapeutic efficacy and seems to have a promising role at least as part of a multimodality approach for advanced thyroid cancer.
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PMID:Gene therapy for thyroid cancer: current status and future prospects. 1524 69

Thyroid cancers are of special interest in gene therapy, since it is possible to direct gene expression specifically to the thyroid derived cells by using promoters with limited expression, and secondly, because destruction of the normal tissue by introduction of a toxic gene would have no important adverse effect. A variety of methods for gene delivery are available. Adenovirus is a well studied and widely used vector and is useful for targeting genes because it infects many cell types, including differentiated thyroid cancer and medullary thyroid cancer cells. Strategies that have been employed successfully in animal models include adenoviral mediated expression of thymidine kinase under control of a thyroglobulin promoter, similarly expression of the cytokine IL-2, and perhaps most effectively, expression of IL-12. Combinations of vectors expressing thymidine kinase and IL-12 under control of a strong but non-tissue specific CMV promoter effectively destroy a model anaplastic thyroid tumor in Wistar rats. Replicating adenoviruses, in contrast to the non-replicating form commonly used, have also been used to infect tumor cells and express P-53 protein, leading to apoptosis of tumor cells. Medullary thyroid cancer provides a target much like differentiated thyroid cancer because it is possible to address gene expression specifically to the medullary thyroid cells by the use of a modified calcitonin promoter. Animal models of this tumor are available in a mouse and Wag/Rij rat model. In the latter system, treatment with adenoviruses expressing genes under control of the modified calcitonin promoter and expressing thymidine kinase or IL-12 leads to destruction of growing medullary thyroid cancer tumors, destroy distant tumors after injection in one tumor, and cause induction of long lasting immunity to subsequent tumor development in the animals. There are many ongoing studies of gene therapy in humans using various genes such as thymidine kinase, IL-2, and now IL-12. Although none of these trials to date shows complete eradication of metastatic tumors in humans, there are reports showing distinctly that the viral mediated gene therapy approach can effectively destroy human tumors after in vivo administration. Tumors that have been treated include melanomas, glioblastomas, breast tumors, and prostate carcinomas. In the latter studies, it has been possible to show objective responses documented by a fall in serum PSA levels of 50% or more that are sustained for prolonged periods. Gene therapy using the adenoviral vectors appears to be safe in studies reported so far. A problem is prior or induced immunity to adenoviral proteins, but direct injection of the vector into a tumor nodule largely circumvents this problem. New genes and new vectors under development will certainly lead to the established use of these methods in the therapy of human thyroid carcinomas in the near future.
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PMID:Viral mediated gene therapy for the management of metastatic thyroid carcinoma. 1537 25

Patients with advanced thyroid carcinoma have poor prognosis with low overall survival. Unfortunately, the underlying mechanisms of thyroid carcinoma progression remain unclear. The elevated expression of thymidine kinase 1 (TK1) has been implicated in the progression of thyroid carcinoma, while the role of TK1 in thyroid carcinoma progression has not been explored. The present study aimed to determine the role TK1 in the progression of thyroid cancer and to explore the underlying molecular mechanisms. In this study, it was found that serum TK1 levels were markedly increased in the patients with thyroid nodules. Further online data mining showed that TK1 expression was upregulated in thyroid carcinoma tissues, and higher expression of TK1 was correlated with shorter disease-free survival of patients with thyroid carcinoma. Silencing of TK1 suppressed cell proliferation, invasion, migration, and epithelial-mesenchymal transition, and also induced cell apoptosis in the thyroid carcinoma cell lines. Animal studies showed that TK1 knockdown inhibited in vivo tumor growth of thyroid carcinoma cells. Importantly, miR-34a-5p was found to be downregulated in the thyroid carcinoma cells. Furthermore, miR-34a-5p targeted the 3' untranslated region of TK1 and suppressed the expression of TK1 in thyroid carcinoma cell lines. In summary, first, these results demonstrated the upregulation of TK1 in thyroid nodules and thyroid carcinoma tissues; second, TK1 promoted thyroid carcinoma cell proliferation, invasion, and migration; lastly, TK1 was negatively regulated by miR-34a-5p. Our study may provide novel insights into the role of TK1 in regulating thyroid carcinoma progression.
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PMID:Knockdown of Thymidine Kinase 1 Suppresses Cell Proliferation, Invasion, Migration, and Epithelial-Mesenchymal Transition in Thyroid Carcinoma Cells. 3206 35