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)

In an extended phase I/II study we evaluated 36 prostate cancer patients with local recurrence after radiotherapy who received single or repeated cycles of replication-deficient adenoviral vector (ADV)-mediated herpes simplex virus-thymidine kinase (HSV-tk) plus ganciclovir (GCV) in situ gene therapy with respect to serum PSA levels, alterations in immune cells, and numbers of apoptotic cells in needle biopsies. An initial cycle of HSV-tk plus GCV gene therapy caused a significant prolongation of the mean serum PSA-doubling time (PSADT) from 15.9 to 42.5 months (p = 0.0271) and in 28 of the injected patients (77.8%) there was a mean PSA reduction (PSAR) of 28%. It took a mean of 8.5 months for the PSA to return to the initial PSA (TR-PSA) value. A repeated cycle of gene therapy failed to significantly extend PSADT but did result in significant increases in PSAR (29.4%) and TR-PSA (10.5 months). Moderately increased serum adenovirus antibody titers were generally observed 2 weeks after initial vector injection. Also at this time there was a statistically significant increase in the mean percent of CD8(+) T cells positive for the HLA-DR marker of activation in peripheral blood (p = 0.0088). Studies using prostate biopsies obtained at the same time point demonstrated that vector DNA was detectable by PCR in most samples yet all patients remained positive for prostate cancer in at least one biopsy core. Further analysis demonstrated a correlation between the level of CD8(+) cells and the number of apoptotic cells in biopsies containing cancer cells (p = 0.042). We conclude that repeated cycles of in situ HSV-tk plus GCV gene therapy can be administered to prostate cancer patients who failed radiotherapy and have a localized recurrence. Biological responses to this experimental therapy including increases in PSADT, PSAR, and TR-PSA, and activated CD8(+) T cells present in the peripheral blood, were demonstrated. Interestingly, the density of CD8(+) cells in posttreatment biopsies correlated with the number of apoptotic cells.
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PMID:Prostate-specific antigen response and systemic T cell activation after in situ gene therapy in prostate cancer patients failing radiotherapy. 1168 37

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

Enzyme pro-drug suicide gene therapy has been hindered by inefficient viral delivery and gene transduction. To further explore the potential of this approach, we have developed AdIU1, a prostate-restricted replicative adenovirus (PRRA) armed with the herpes simplex virus thymidine kinase (HSV-TK). In our previous Ad-OC-TK/ACV phase I clinical trial, we demonstrated safety and proof of principle with a tissue-specific promoter-based TK/pro-drug therapy using a replication-defective adenovirus for the treatment of prostate cancer metastases. In this study, we aimed to inhibit the growth of androgen-independent (AI), PSA/PSMA-positive prostate cancer cells by AdIU1. In vitro the viability of an AI- PSA/PSMA-expressing prostate cancer cell line, CWR22rv, was significantly inhibited by treatment with AdIU1 plus GCV (10 microg ml(-1)), compared with AdIU1 treatment alone and also cytotoxicity was observed following treatment with AdIU1 plus GCV only in PSA/PSMA-positive CWR22rv and C4-2 cells, but not in the PSA/PSMA-negative cell line, DU-145. In vivo assessment of AdIU1 plus GCV treatment revealed a stronger therapeutic effect against CWR22rv tumors in nude mice than treatment with AdIU1 alone, AdE4PSESE1a alone or in combination with GCV. Our results demonstrate the therapeutic potential of specific-oncolysis and suicide gene therapy for AI-PSA/PSMA-positive prostate cancer gene therapy.
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PMID:Enhanced combined tumor-specific oncolysis and suicide gene therapy for prostate cancer using M6 promoter. 1877 2

Gene therapy is a newly hatched field of biomedical research aimed at introducing therapeutically important genes into somatic cells of patients for the treatment of human disease. Whereas for inborn errors of metabolism transfer of a single gene can correct the disorder, cancer is a complex disease involving mutations in a number of protooncogenes and tumor suppressor genes as well as an imbalance and disarray in phosphorylation events and regulatory circuits of the cell cycle; transfer of the wild-type p53 or p21 tumor suppressor genes is a successful gene therapy approach leading to apoptotic death of cancer cells or in restrain of their chaotic growth. A different promising approach is transfer of the herpes simplex virus thymidine kinase (HSV-tk) gene (suicide gene) and systemic treatment with the prodrug ganciclovir which is converted by HSV-tk into a toxic drug killing dividing cells. Expression of suicide genes, p53, and other therapeutic genes preferentially in cancer cells can be achieved by regulatory elements from tumor-specific genes such as carcinoembryonic antigen, BRCA1, and PSA.
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PMID:Cancer gene therapy and immunotherapy (review). 2154