1 |
Évaluation du Statut télomérique : vers une thérapeutique personnalisée du glioblastome : application en Hadronthérapie par ions carbone / Telomere profiling : toward glioblastoma medicine : application to carbon ion hadrontherapyFerrandon, Sylvain 28 January 2013 (has links)
Le glioblastome, tumeur maligne des tissus astrocytaires, est de mauvais pronostic. Malgré un traitement standard invasif (chirurgie, radiochimiothérapie), la médiane de survie des patients n’excède pas 14 mois, essentiellement due à la récidive tumorale (radiorésistance des cellules résiduelles). L’hadronthérapie par ion carbone offre des atouts radiobiologiques importants : i) Balistique très précise (épargne les tissus sains), ii) Efficacité Biologique Relative (EBR) supérieure à la radiothérapie conventionnelle (augmentation de la dose possible), iii) Réponse indépendante de l’effet oxygène (tumeurs hypoxiques). L’hadronthérapie a montré des résultats prometteurs en traitement du glioblastome. Cependant, la rareté des centres offrant cette thérapeutique oblige les cliniciens à utiliser des marqueurs prédictifs de réponse à la radiothérapie conventionnelle afin de mieux orienter les patients diagnostiqués mauvais répondeur. L’homéostasie télomérique est connue pour moduler la radiosensibilité de différents types de cancer. Aussi, ce travail présente deux axes. D’une part, nous avons déterminé que la taille des télomères et l’expression de POT-1 (Protection Of Telomere1) peuvent être utilisées par les cliniciens pour diagnostiquer les patients mauvais répondeurs au traitement standard et ainsi les orienter vers l’hadronthérapie où leurs pronostics seraient meilleurs. D’autre part, nous avons montré qu’un traitement pharmacologique dirigé contre la télomérase (GRN163L, Geron Corp) pouvait améliorer les résultats de la radiothérapie conventionnelle sur un modèle in vivo de glioblastome humain chez la souris / Glioblastoma, high grade tumor of neuroepithelial tissue, is poor prognosis cancer. Despite an invasive standard treatment (surgery, radiochemotherapy), the overall survival of patients does not exceed 15 months, largely due to aggressive recurrence (radioresistance of residual cells). Hadrontherapy with Carbon ion beam have strong radiobiological arguments: i) high ballistic precision (save healthy tissues), ii) Relative Biological Efficiency (RBE) above conventional radiotherapy (dose escalation), iii) independent response of oxygen enhancement ratio (hypoxic tumors). Hadrontherapy have shown promising preliminary results in treatment of brain tumors. However, the rareness of health centers which purposed Handrontheray necessitates the use of predictive markers of resistance to conventional radiotherapy to address bad responder patient. Telomere homeostasis is also known to modulate radiosensitivity of different types of cancer. Thus, this work has two arms. On the one hand, we have shown that telomere length and POT1 (Protection Of Telomere1) level (RNA and protein) can be used by clinicians to diagnose bad responder of standard treatment and towards the hadrontherapy. On the other hand, we have shown that pharmacological treatment inhibitory of telomerase (GRN163L, Geron Corp) can improve the radiationinduced responses to conventional radiotherapy on human glioblastoma mice model
|
2 |
Investigations of the Telomerase Template Antagonist GRN163L and Implications for Augmenting Breast Cancer TherapyGoldblatt, Erin M. 18 March 2009 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Breast cancer is the second most common cancer among women in the US after skin cancer. While early detection and improved therapy has led to an overall decline in breast cancer mortality, metastatic disease remains largely incurable, indicating a need for improved therapeutic options for patients. Telomeres are repetitive (TTAGGG)n DNA sequences found at the end of chromosomes that protect the ends from recombination, end to end fusions, and recognition as damaged DNA. The enzyme telomerase acts to stabilize short telomeres, preventing apoptosis or senescence due to genomic instability. Telomerase is active in 85-90% of cancers, and inactive in most normal cells, making telomerase an attractive target for cancer therapy. Use of the telomerase-specific, lipidated oligonucleotide GRN163L can antagonize telomerase activity and telomere maintenance in cancer cells by preventing telomerase from binding to telomeres. GRN163L has been shown by our laboratory to inhibit breast cancer cell growth and metastasis in animal models. However, the mechanisms of cancer cell growth and metastatic inhibition via GRN163L are not completely understood. The overall goal of this research project was to further elucidate the role of telomerase in breast cancer cell survival by: 1) determining the effects of combining telomere dysfunction induced by GRN163L with a DNA damage inducer (irradiation); 2) elucidating the mechanisms underlying the cellular response to GRN163L and the effect of combination therapy with the mitotic inhibitor paclitaxel; and 3) testing the hypothesis that a telomerase inhibitor can augment the effects of trastuzumab in breast cancer cells with HER2 amplification. Results support the central hypothesis that the telomere dysfunction, structural and proliferative changes in breast cancer cells induced by GRN163L can synergize with irradiation, paclitaxel, and trastuzumab to inhibit the tumorigenicity of breast cancer cells both in vitro and in vivo. Furthermore, GRN163L can restore sensitivity of therapeutically resistant breast cancer cells to trastuzumab. These results provide insight into the role of telomerase in cancer cell growth. Additionally, implications of this research support GRN163L as an important part of therapeutic regimens for primary tumors, recurrence, and metastatic disease.
|
3 |
Gene therapy tools: oligonucleotides and peptidesEriksson, Jonas January 2016 (has links)
Genetic mutations can cause a wide range of diseases, e.g. cancer. Gene therapy has the potential to alleviate or even cure these diseases. One of the many gene therapies developed so far is RNA-cleaving deoxyribozymes, short DNA oligonucleotides that specifically bind to and cleave RNA. Since the development of these synthetic catalytic oligonucleotides, the main way of determining their cleavage kinetics has been through the use of a laborious and error prone gel assay to quantify substrate and product at different time-points. We have developed two new methods for this purpose. The first one includes a fluorescent intercalating dye, PicoGreen, which has an increased fluorescence upon binding double-stranded oligonucleotides; during the course of the reaction the fluorescence intensity will decrease as the RNA is cleaved and dissociates from the deoxyribozyme. A second method was developed based on the common denominator of all nucleases, each cleavage event exposes a single phosphate of the oligonucleotide phosphate backbone; the exposed phosphate can simultaneously be released by a phosphatase and directly quantified by a fluorescent phosphate sensor. This method allows for multiple turnover kinetics of diverse types of nucleases, including deoxyribozymes and protein nucleases. The main challenge of gene therapy is often the delivery into the cell. To bypass cellular defenses researchers have used a vast number of methods; one of these are cell-penetrating peptides which can be either covalently coupled to or non-covalently complexed with a cargo to deliver it into a cell. To further evolve cell-penetrating peptides and understand how they work we developed an assay to be able to quickly screen different conditions in a high-throughput manner. A luciferase up- and downregulation experiment was used together with a reduction of the experimental time by 1 day, upscaling from 24- to 96-well plates and the cost was reduced by 95% compared to commercially available assays. In the last paper we evaluated if cell-penetrating peptides could be used to improve the uptake of an LNA oligonucleotide mimic of GRN163L, a telomerase-inhibiting oligonucleotide. The combination of cell-penetrating peptides and our mimic oligonucleotide lead to an IC50 more than 20 times lower than that of GRN163L.
|
Page generated in 0.0282 seconds