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1	Avaliação dos efeitos antineoplásicos da Zebularina em meduloblastoma / Evaluation of antineoplastic effects of Zebularine in medulloblastoma Andrade, Augusto Faria 07 April 2016 (has links) O meduloblastoma (MB) é um câncer do sistema nervoso central, de origem embrionária, que surge no cerebelo. É o tumor maligno cerebral mais frequente na infância e corresponde a aproximadamente 20% de todos os tumores intracranianos pediátricos. Atualmente, o tratamento é realizado com cirurgia, quimioterapia e radioterapia e está relacionado com diversos efeitos colaterais em médio e longo prazo. Diversos fatores contribuem para o seu desenvolvimento e progressão, entre estes, alterações nas vias de sinalização, como a Sonic Hedgehog (SHH) e Wingless. As modificações nos padrões epigenéticos, como a metilação do DNA, tem também um papel central na biologia deste tumor. Tais alterações comprometem funções básicas da célula como o controle da proliferação, sobrevivência celular e apoptose. Drogas epigenéticas como os inibidores de DNA metiltransferases (DNMTs) têm demonstrado efeitos antineoplásicos e resultados promissores para terapia do câncer. A Zebularina é um inibidor de DNMTs, que consequentemente reduz a metilação do DNA, e tem se mostrado uma importante droga antitumoral, com baixa toxicidade e atividade adjuvante à quimioterapia em tumores quimio-resistentes. Diversos estudos têm descrito seus efeitos em diferentes tipos de neoplasias, entretanto, não há relatos da sua ação em MB. Sendo assim, o presente trabalho teve como objetivo analisar os potenciais efeitos antineoplásicos da Zebularina em quatro linhagens de MB pediátrico (DAOY, ONS-76, UW402 e UW473). Foi observado que o tratamento com a Zebularina promoveu inibição da proliferação celular e da capacidade clonogênica, aumentou o número de células apoptóticas e células na fase S do ciclo celular (p<0,05). Adicionalmente, o tratamento induziu um aumento na expressão proteica de p53, p21 e Bax e uma diminuição da ciclina A, Bcl-2 e Survivina. Além disso, quando combinada com o quimioterápico vincristina agiu de modo sinérgico; e de modo antagônico quando combinada com a cisplatina. Através de análises de expressão gênica em larga escala (plataforma Agilent de microarray), foi encontrada diferentes vias moduladas pela droga, incluindo a dos Receptores Toll-Like e o aumento dos genes SUFU e BATF2. Aqui, foi encontrado que a Zebularina pode modular a ativação da via SHH, reduzindo os níveis de SMO, de GLI1 e de um de seus alvos, o PTCH1; contudo sem alterar os níveis de SUFU. Confirmou-se que o gene BATF2 é induzido pela Zebularina e possui regiões ricamente metiladas. Além disso, a baixa expressão do gene BATF2 está associada à um pior prognóstico em MB. Todos esses dados sugerem que a Zebularina pode ser uma droga em potencial para o tratamento adjuvante do MB / Medulloblastoma (MB) is an embryonal cerebellum tumor. It is the most common brain malignancy in children and accounts for approximately 20% of all pediatric intracranial tumors. Currently, treatment consists of surgery, chemotherapy and radiation and is associated to medium- and long-term side effects. Several factors contribute to the development and progression of MB, for instance, alterations in signaling pathways, such as Sonic Hedgehog (SHH) and Wingless. Epigenetic changes in DNA methylation patterns also play a central role in the biology of this tumor. Such changes are able to alter basic cell functions, controlling cell proliferation, survival and apoptosis. Epigenetic drugs as DNA methyltransferases (DNMTs) inhibitors have shown anticancer effects and promising results for cancer therapy. Zebularine is a low toxicity DNMTs inhibitor that induces DNA demethylation and has been reported as an important antitumor drug with adjuvant activity to chemotherapy in chemoresistant tumors. Studies have described its effects on different types of cancer, however, there are not data concerning its action in MB. Therefore, this study aimed to analyze the potential anticancer effects of Zebularine in four pediatric MB lines (UW402, UW473, ONS- 76 and DAOY). It was observed that treatment with Zebularine promoted inhibition of cell proliferation and clonogenic capacity, increased the number of apoptosis rate and cells in S phase of the cycle (p <0.05). In addition, the treatment induced an increasing in the protein expression of p53, p21 and Bax and a decreasing in cyclin A, Survivin and Bcl-2. Also, when combined with the chemotherapeutic agent vincristine acted synergistically but resulted in antagonism when combined with cisplatin. Through large-scale gene expression analysis (Agilent microarray platform), it was found different pathways modulated by Zebularine, including the Toll-Like Receptors pathway and the overexpression of SUFU and BATF2 genes. Zebularine was able to modulate SHH pathway activation, by reducing levels of SMO, GLI1 and one of its targets, PTCH1, whereas there were no changes in SUFU levels. It was confirmed that the gene BATF2 is induced by Zebularine and contains regions richly methylated. In addition, BATF2 low expression is associated with a worse prognosis in MB. All these data suggest that Zebularine may be a potential drug for the adjuvant treatment of MB DNA methyltransferases DNA metiltransferases Epigenética Epigenetics Medulloblastoma Meduloblastoma Zebularina Zebularine
2	Prebiotic Synthesis of Pyrimidine Nucleosides Collins, James P. 28 November 2005 (has links) The problem of forming a glycosidic bond between ribose and the free nucleoside bases to produce beta-nucleosides under plausible prebiotic conditions is commonly referred to in origin of life research as The Nucleoside Problem. The lack of a general solution to this problem currently represents one of the largest stumbling blocks to the RNA world hypothesis and many other theories regarding the origin of life. Over thirty years ago the purine nucleosides were successfully synthesized by drying the fully-formed bases and ribose together in the presence of divalent metal ion salts. However, glycosidic bond formation by the pyrimidine bases has never been achieved under similar reaction conditions. This thesis describes the first plausible prebiotic synthesis of a pyrimidine nucleoside, demonstrated with the pyrimidine base analogue 2-pyrimidinone. Information provided by nucleoside-formation reaction involving 2-pyrimidinone and related pyrimidine bases should provide valuable insights into the possible mechanism by which glycosidic bond formation was accomplished on the prebiotic Earth. Glycosidic bond 2-pyrimidinone Nucleosides Pyrimidine Prebiotic Zebularine RNA world
3	Avaliação dos efeitos antineoplásicos da Zebularina em meduloblastoma / Evaluation of antineoplastic effects of Zebularine in medulloblastoma Augusto Faria Andrade 07 April 2016 (has links) O meduloblastoma (MB) é um câncer do sistema nervoso central, de origem embrionária, que surge no cerebelo. É o tumor maligno cerebral mais frequente na infância e corresponde a aproximadamente 20% de todos os tumores intracranianos pediátricos. Atualmente, o tratamento é realizado com cirurgia, quimioterapia e radioterapia e está relacionado com diversos efeitos colaterais em médio e longo prazo. Diversos fatores contribuem para o seu desenvolvimento e progressão, entre estes, alterações nas vias de sinalização, como a Sonic Hedgehog (SHH) e Wingless. As modificações nos padrões epigenéticos, como a metilação do DNA, tem também um papel central na biologia deste tumor. Tais alterações comprometem funções básicas da célula como o controle da proliferação, sobrevivência celular e apoptose. Drogas epigenéticas como os inibidores de DNA metiltransferases (DNMTs) têm demonstrado efeitos antineoplásicos e resultados promissores para terapia do câncer. A Zebularina é um inibidor de DNMTs, que consequentemente reduz a metilação do DNA, e tem se mostrado uma importante droga antitumoral, com baixa toxicidade e atividade adjuvante à quimioterapia em tumores quimio-resistentes. Diversos estudos têm descrito seus efeitos em diferentes tipos de neoplasias, entretanto, não há relatos da sua ação em MB. Sendo assim, o presente trabalho teve como objetivo analisar os potenciais efeitos antineoplásicos da Zebularina em quatro linhagens de MB pediátrico (DAOY, ONS-76, UW402 e UW473). Foi observado que o tratamento com a Zebularina promoveu inibição da proliferação celular e da capacidade clonogênica, aumentou o número de células apoptóticas e células na fase S do ciclo celular (p<0,05). Adicionalmente, o tratamento induziu um aumento na expressão proteica de p53, p21 e Bax e uma diminuição da ciclina A, Bcl-2 e Survivina. Além disso, quando combinada com o quimioterápico vincristina agiu de modo sinérgico; e de modo antagônico quando combinada com a cisplatina. Através de análises de expressão gênica em larga escala (plataforma Agilent de microarray), foi encontrada diferentes vias moduladas pela droga, incluindo a dos Receptores Toll-Like e o aumento dos genes SUFU e BATF2. Aqui, foi encontrado que a Zebularina pode modular a ativação da via SHH, reduzindo os níveis de SMO, de GLI1 e de um de seus alvos, o PTCH1; contudo sem alterar os níveis de SUFU. Confirmou-se que o gene BATF2 é induzido pela Zebularina e possui regiões ricamente metiladas. Além disso, a baixa expressão do gene BATF2 está associada à um pior prognóstico em MB. Todos esses dados sugerem que a Zebularina pode ser uma droga em potencial para o tratamento adjuvante do MB / Medulloblastoma (MB) is an embryonal cerebellum tumor. It is the most common brain malignancy in children and accounts for approximately 20% of all pediatric intracranial tumors. Currently, treatment consists of surgery, chemotherapy and radiation and is associated to medium- and long-term side effects. Several factors contribute to the development and progression of MB, for instance, alterations in signaling pathways, such as Sonic Hedgehog (SHH) and Wingless. Epigenetic changes in DNA methylation patterns also play a central role in the biology of this tumor. Such changes are able to alter basic cell functions, controlling cell proliferation, survival and apoptosis. Epigenetic drugs as DNA methyltransferases (DNMTs) inhibitors have shown anticancer effects and promising results for cancer therapy. Zebularine is a low toxicity DNMTs inhibitor that induces DNA demethylation and has been reported as an important antitumor drug with adjuvant activity to chemotherapy in chemoresistant tumors. Studies have described its effects on different types of cancer, however, there are not data concerning its action in MB. Therefore, this study aimed to analyze the potential anticancer effects of Zebularine in four pediatric MB lines (UW402, UW473, ONS- 76 and DAOY). It was observed that treatment with Zebularine promoted inhibition of cell proliferation and clonogenic capacity, increased the number of apoptosis rate and cells in S phase of the cycle (p <0.05). In addition, the treatment induced an increasing in the protein expression of p53, p21 and Bax and a decreasing in cyclin A, Survivin and Bcl-2. Also, when combined with the chemotherapeutic agent vincristine acted synergistically but resulted in antagonism when combined with cisplatin. Through large-scale gene expression analysis (Agilent microarray platform), it was found different pathways modulated by Zebularine, including the Toll-Like Receptors pathway and the overexpression of SUFU and BATF2 genes. Zebularine was able to modulate SHH pathway activation, by reducing levels of SMO, GLI1 and one of its targets, PTCH1, whereas there were no changes in SUFU levels. It was confirmed that the gene BATF2 is induced by Zebularine and contains regions richly methylated. In addition, BATF2 low expression is associated with a worse prognosis in MB. All these data suggest that Zebularine may be a potential drug for the adjuvant treatment of MB DNA metiltransferases Epigenética Meduloblastoma Zebularina DNA methyltransferases Epigenetics Medulloblastoma Zebularine
4	Estudo da Expressão dos Genes DNMT1, DNMT3A, DNMT3B, MGMT e Efeitos da Zebularina em Glioblastoma / Estudo da Expressão dos Genes DNMT1, DNMT3A, DNMT3B, MGMT e Efeitos da Zebularina em Glioblastoma Moreno, Daniel Antunes 24 August 2012 (has links) Os gliomas são tumores que surgem a partir de células da glia e são considerados os mais comuns do sistema nervoso central. São subdivididos em quatro grupos: astrocitoma pilocítico (grau I), astrocitoma difuso (grau II), astrocitoma anaplásico (grau III) e glioblastoma (grau IV ou GBM). Entre esses, o GBM é o tumor mais agressivo e mais freqüente. Apesar de ser encontrado em qualquer faixa etária, esse tumor é raro em crianças. Atualmente a cirurgia seguida de radioterapia e quimioterapia com temozolomida (TMZ) tem sido utilizado como protocolo de tratamento padrão para a maioria dos pacientes e mesmo assim a sobrevida se mantem extremamente baixa. Além disso, grande parte dos pacientes não respondem ao tratamento com TMZ indicando a necessidade de agentes quimioterápicos alternativos. A zebularina (ZB) é um agente inibidor de DNA metiltransferases (iDNMTs) estável, pouco tóxico, que promove radiosensibilização e tem mostrado efeitos promissores em diversos tipos de neoplasias, entretanto pouco se sabe a respeito dos efeitos da ZB em glioblastoma. Os objetivos deste trabalho foram analisar a expressão dos genes DNMT1, DNMT3A, DNMT3B, MGMT em 5 amostras de substâncias brancas (SB), 6 linhagens de GBM e 33 amostras de gliomas (13 grau I, 2 grau II e 18 grau IV), correlacionar a expressão desses genes com os diferentes graus de gliomas e analisar os efeitos da ZB combinada ou não com TMZ em linhagens de GBM irradiadas e não irradiadas. Para análise da expressão gênica foi realizada a técnica de PCR em tempo Real. Os ensaios de proliferação celular, clonogênico, radiação e apoptose foram realizados em 3 linhagens de GBM (U251, SF188 e T98G) e uma de fibroblastos (MRC5). Também foi realizado o ensaio de proliferação celular em 5 culturas primárias de GBM tratadas com zebularina. Os genes DNMT3A e MGMT mostraram expressão maior nas amostras de SB comparando-se com gliomas e linhagens de GBM. O gene DNMT3B foi mais expresso nas linhagens de GBM comparando-se com as SB. O gene DNMT1 não mostrou diferenças significativas entre as amostras analisadas. Os ensaios de proliferação celular mostraram diminuição na proliferação com doses a partir de 50-100µM de ZB e de 250-500µM de TMZ nas linhagens e a partir de 50µM de ZB para as culturas primárias de GBM. As combinações de ZB com TMZ não mostraram sinergia na grande maioria das doses testadas. A ZB aumenta a apoptose nas 3 linhagens com doses a partir de 100µM. A ZB e TMZ mostraram diminuição na formação de colônias com as doses de 100µM e 10µM nas linhagens U251 e SF188 não irradiadas e irradiadas com 2, 4 e 6 Gy. A linhagem T98G expressa o gene MGMT, mostrou resistência a 10µM de TMZ e respondeu ao tratamento com 100µM de ZB. Também foi observado que 10µM de TMZ é mais citotóxico do que 100µM de ZB em fibroblastos não irradiados e irradiados (2Gy). Os resultados obtidos neste estudo mostram que a ZB pode representar um alvo terapêutico interessante para o estudo em glioblastoma. / Gliomas arise from glial cells and are the most common central nervous system tumors. They are divided in four groups: pilocytic astrocytoma (grade I), difuse astrocytoma (grade II), anaplastic astrocytoma (grade III) and glioblastoma (grade IV or GBM). GBM is the most frequent and aggressive glioma. This type of tumor can occur in any age but its rare in children. Actually, surgery, radiotherapy and temozolomide (TMZ) adjuvant/concomitant chemotherapy has been the standard treatment protocol but the survival is extremely poor. In addition most patients do not respond to TMZ indicating the need for alternative chemotherapeutic agents. Zebularine (ZB) is a DNA metiltransferase inhibitor (DNMTi) stable, slight toxic that has been showed promise effects in cancer including radiosensitivity but little is known about ZB in glioblastoma. The objectives of this study were analyze DNMT1, DNMT3A, DNMT3B, MGMT gene expression profile in 5 samples of normal brain, 6 GBM cell lines and 33 glioma samples (13 grade I, 2 grade II e 18 grade IV), correlate with different gliomas grades and analyze the effects of ZB isolate and in combination with TMZ in irradiated and non irradiated GBM cell lines. Gene expression assays was made using Real Time PCR. Proliferation, clonogenic, radiation and apoptosis assays were realized in three GBM cell lines (U251, SF88, T98G) and one fibroblast cell line (MRC5). We also made proliferation assays in 5 primary cultures of samples of GMB. MGMT and DNMT3A genes showed higher expression in normal brain compared to gliomas and GBM cell lines. DNMT3B gene showed higher expression in GBM cell lines compared with normal brain and DNMT1 showed no significant differences among samples analyzed. We observed decrease of cell proliferation from 50-100µM of ZB and 250-500µM of TMZ on GBM cell lines and from 50µM of ZB for primary GBM samples. It was not observed synergy in the most combinations doses of ZB and TMZ (Calcusyn software). It was observed that 100µM of ZB and 10µM of TMZ decrease colony formation on U251 and SF188 cell lines non irradiated and irradiated with 2, 4, and 6Gy. T98G that express MGMT, did not respond to TMZ but showed response to ZB. It was also observed that 10µM of TMZ is more cytotoxic than 100µM of ZB in fibroblast cell line non irradiated and irradiated with 2Gy. ZB increase apoptosis from 100µM on the three GBM cell lines. Results obtained in this study can indicate that ZB may be an interestig therapeutic target for future studies in glioblastoma. DNA metil-transferases DNA metil-transferases Glioblastoma Glioblastoma Radiação Radiation Temozolomida Temozolomide Zebularina Zebularine
5	Avaliação dos Efeitos Antineoplásicos da Zebularina em Linhagens Pediátricas de Leucemia Linfoide Aguda. / Evaluation of Antineoplastic Effects of Zebularine on Childhood Acute Lymphoblastic Leukemia Cell Lines. Andrade, Augusto Faria 26 March 2012 (has links) A leucemia linfóide aguda (LLA) é a neoplasia hematológica mais comum na infância e representa uma doença heterogênea em relação à biologia e ao prognóstico e seu tratamento consiste principalmente em quimioterapia. Apesar dos avanços no tratamento, cerca de 20% dos pacientes apresentam recaída da doença e/ou óbito indicando a necessidade de terapias diferenciadas para esse grupo. Recentemente, drogas epigenéticas como inibidores de DNA metiltransferases (iDNMTs) tem mostrado efeitos anti-neoplásicos promissores para o tratamento de diversos tipos de neoplasias incluindo a LLA. Nos tumores, a hipermetilação gênica é encontrada em vários genes, incluindo genes de reparo do DNA, reguladores do ciclo celular e apoptose. Sendo assim, drogas desmetilantes estão sendo apontadas como promissores agentes para o tratamento do câncer. A Zebularina (ZB) é um iDNMT análogo de citidina que inibe a metilação do DNA. Esta droga tem mostrado resultados animadores para o tratamento de diversas neoplasias, incluindo glioblastoma, leucemia mielóide aguda, câncer de mama, próstata e outros. O objetivo deste trabalho foi avaliar os efeitos do tratamento com a ZB, associada ou não à quimioterápicos, em linhagens celulares pediátricas de LLA, por meio de ensaios funcionais como proliferação celular, capacidade clonogênica, apoptose e ciclo celular. Além disso, foi analisada a capacidade desmetilante da droga e a expressão dos genes DNMT1, DNMT3a e DNMT3b após o tratamento com a ZB. A ZB inibiu a proliferação celular de maneira dose e tempo-dependente e agiu sinergicamente quando combinada com o MTX em ambas as linhagens. Ela também diminuiu a capacidade clonogênica e aumentou a taxa de apoptose nas duas linhagens estudadas. Além disso, o tratamento com ZB causou uma parada na fase S do ciclo celular na linhagem ReH. A ZB foi capaz de desmetilar parcialmente o gene AhR e reduzir a expressão dos genes DNMT1, DNMT3a e DNMT3b. Todos os dados encontrados no presente trabalho sugerem que as drogas desmetilantes podem ser interessantes agentes para o tratamento da LLA pediátrica. / Acute lymphoblastic leukemia (ALL) is the most common hematologic malignancy in childhood and represents a heterogeneous disease regarding its biology and prognosis. Its treatment consists mainly of chemotherapy. Despite advances in treatment, about 20% of patients experience disease recurrence and/or death indicating the need for differentiated therapies for this group. Recently, epigenetic drugs such as DNA methyltransferases inhibitors (iDNMTs) has shown antineoplastic and promising results for several types of tumors including ALL. Gene hypermethylation is found in several genes in tumors cells, including genes responsible for DNA repair, cell cycle and apoptosis regulators. Therefore, demethylating agents may be promising agents for cancer treatment. Zebularine (ZB) an iDNMT is a cytidine analogue that inhibits DNA methylation. This drug has shown promising results for the treatment of many cancers, including glioblastoma, acute myeloid leukemia, breast and prostate cancer and others. The aim of this study was to evaluate the effects of ZB treatment, associated or not with chemotherapeutic agents, in childhood ALL cell lines through functional tests such as cell proliferation, clonogenic capacity, apoptosis and cell cycle. In addition, we examined the demethylating ability of ZB and the expression of DNMT1, DNMT3a and DNMT3b genes after treatment with this agent. ZB inhibited cell proliferation in a dose- and time-dependent manner and showed synergistic effects when combined with MTX in both cell lines. ZB treatment also reduced clonogenic capacity and increased the number of apoptotic cells in both cell lines studied. Furthermore, treatment with ZB caused an S phase cell cycle arrest in ReH cell line. ZB was able to partially demethylate AhR gene and reduce the expression of genes DNMT1, DNMT3a and DNMT3b. These results suggest that demethylating drugs may be interesting agents for the treatment of childhood ALL. Acute lymphoblastic leukemia Combinação de Drogas Drug combination Epigenética Epigenetics Leucemia Linfóide Aguda Methylation Metilação Zebularina Zebularine
6	Aberrant epigenetics in the molecular pathogenesis of human acute myeloid leukemia Scott, Stuart Alexander 30 May 2005 Promoter hypermethylation mediated gene silencing is a frequent epigenetic finding in many cancers that affects genes known to have important roles in several aspects of cell biology. Hematological malignancies have been reported to harbor multiple genes aberrantly silenced by promoter hypermethylation and as a result, cytosine analogs known to inhibit the DNA methylation machinery are currently being evaluated in clinical trials. As such, the general goal of this thesis was to identify genes silenced by promoter hypermethylation in human acute myeloid leukemia (AML) and to study the mechanism of promoter hypermethylation mediated gene silencing. Interestingly, the cyclin dependent kinase inhibitor p15 was found to be methylated at a high frequency in AML patients and cell lines in association with a lack of detectable p15 mRNA. Treatment with the cytosine analog 5-Aza-2-deoxycytidine (5-Aza-dC) in vitro resulted in promoter demethylation and p15 mRNA re-expression, which was associated with a release of a transcriptionally repressive complex at the p15 promoter. Importantly, 5-Aza-dC treatment also reversed specific histone amino-terminal modifications at the p15 promoter which are normally associated with transcriptionally inactive chromatin regions, implicating chromatin remodeling in promoter hypermethylation mediated gene silencing. The recently discovered DNA methylation inhibitor, zebularine considered more stable than 5-Aza-dC was also able to reconstitute p15 mRNA in vitro in association with promoter demethylation, regional enrichment of histone acetylation, and growth inhibition. To identify novel genes silenced by promoter hypermethylation in AML, cDNA microarray analysis was employed following in vitro pharmacological inhibition of DNA methylation and histone deacetylation. Of note, four genes from the metallothionein family of cysteine rich small molecules were consistently upregulated following drug treatment and further evaluation identified the gene MT1H to be hypermethylated at a high frequency in AML patients and cell lines. Taken together, the data suggests that aberrant promoter hypermethylation mediated gene silencing occurs in multiple genes from different gene families during the molecular pathogenesis of human AML. Furthermore, the mechanism of promoter methylation mediated transcriptional silencing acts in concert with specific histone modifications which, importantly, can be reversed by treatment with pharmacological inhibitors of DNA methylation. histone modification p15INK4B 5-Aza-2'-deoxycytidine zebularine cDNA microarray metallothionein promoter hypermethylation
7	Aberrant epigenetics in the molecular pathogenesis of human acute myeloid leukemia Scott, Stuart Alexander 30 May 2005 (has links) Promoter hypermethylation mediated gene silencing is a frequent epigenetic finding in many cancers that affects genes known to have important roles in several aspects of cell biology. Hematological malignancies have been reported to harbor multiple genes aberrantly silenced by promoter hypermethylation and as a result, cytosine analogs known to inhibit the DNA methylation machinery are currently being evaluated in clinical trials. As such, the general goal of this thesis was to identify genes silenced by promoter hypermethylation in human acute myeloid leukemia (AML) and to study the mechanism of promoter hypermethylation mediated gene silencing. Interestingly, the cyclin dependent kinase inhibitor p15 was found to be methylated at a high frequency in AML patients and cell lines in association with a lack of detectable p15 mRNA. Treatment with the cytosine analog 5-Aza-2-deoxycytidine (5-Aza-dC) in vitro resulted in promoter demethylation and p15 mRNA re-expression, which was associated with a release of a transcriptionally repressive complex at the p15 promoter. Importantly, 5-Aza-dC treatment also reversed specific histone amino-terminal modifications at the p15 promoter which are normally associated with transcriptionally inactive chromatin regions, implicating chromatin remodeling in promoter hypermethylation mediated gene silencing. The recently discovered DNA methylation inhibitor, zebularine considered more stable than 5-Aza-dC was also able to reconstitute p15 mRNA in vitro in association with promoter demethylation, regional enrichment of histone acetylation, and growth inhibition. To identify novel genes silenced by promoter hypermethylation in AML, cDNA microarray analysis was employed following in vitro pharmacological inhibition of DNA methylation and histone deacetylation. Of note, four genes from the metallothionein family of cysteine rich small molecules were consistently upregulated following drug treatment and further evaluation identified the gene MT1H to be hypermethylated at a high frequency in AML patients and cell lines. Taken together, the data suggests that aberrant promoter hypermethylation mediated gene silencing occurs in multiple genes from different gene families during the molecular pathogenesis of human AML. Furthermore, the mechanism of promoter methylation mediated transcriptional silencing acts in concert with specific histone modifications which, importantly, can be reversed by treatment with pharmacological inhibitors of DNA methylation. histone modification p15INK4B 5-Aza-2'-deoxycytidine zebularine cDNA microarray metallothionein promoter hypermethylation
8	Avaliação dos Efeitos Antineoplásicos da Zebularina em Linhagens Pediátricas de Leucemia Linfoide Aguda. / Evaluation of Antineoplastic Effects of Zebularine on Childhood Acute Lymphoblastic Leukemia Cell Lines. Augusto Faria Andrade 26 March 2012 (has links) A leucemia linfóide aguda (LLA) é a neoplasia hematológica mais comum na infância e representa uma doença heterogênea em relação à biologia e ao prognóstico e seu tratamento consiste principalmente em quimioterapia. Apesar dos avanços no tratamento, cerca de 20% dos pacientes apresentam recaída da doença e/ou óbito indicando a necessidade de terapias diferenciadas para esse grupo. Recentemente, drogas epigenéticas como inibidores de DNA metiltransferases (iDNMTs) tem mostrado efeitos anti-neoplásicos promissores para o tratamento de diversos tipos de neoplasias incluindo a LLA. Nos tumores, a hipermetilação gênica é encontrada em vários genes, incluindo genes de reparo do DNA, reguladores do ciclo celular e apoptose. Sendo assim, drogas desmetilantes estão sendo apontadas como promissores agentes para o tratamento do câncer. A Zebularina (ZB) é um iDNMT análogo de citidina que inibe a metilação do DNA. Esta droga tem mostrado resultados animadores para o tratamento de diversas neoplasias, incluindo glioblastoma, leucemia mielóide aguda, câncer de mama, próstata e outros. O objetivo deste trabalho foi avaliar os efeitos do tratamento com a ZB, associada ou não à quimioterápicos, em linhagens celulares pediátricas de LLA, por meio de ensaios funcionais como proliferação celular, capacidade clonogênica, apoptose e ciclo celular. Além disso, foi analisada a capacidade desmetilante da droga e a expressão dos genes DNMT1, DNMT3a e DNMT3b após o tratamento com a ZB. A ZB inibiu a proliferação celular de maneira dose e tempo-dependente e agiu sinergicamente quando combinada com o MTX em ambas as linhagens. Ela também diminuiu a capacidade clonogênica e aumentou a taxa de apoptose nas duas linhagens estudadas. Além disso, o tratamento com ZB causou uma parada na fase S do ciclo celular na linhagem ReH. A ZB foi capaz de desmetilar parcialmente o gene AhR e reduzir a expressão dos genes DNMT1, DNMT3a e DNMT3b. Todos os dados encontrados no presente trabalho sugerem que as drogas desmetilantes podem ser interessantes agentes para o tratamento da LLA pediátrica. / Acute lymphoblastic leukemia (ALL) is the most common hematologic malignancy in childhood and represents a heterogeneous disease regarding its biology and prognosis. Its treatment consists mainly of chemotherapy. Despite advances in treatment, about 20% of patients experience disease recurrence and/or death indicating the need for differentiated therapies for this group. Recently, epigenetic drugs such as DNA methyltransferases inhibitors (iDNMTs) has shown antineoplastic and promising results for several types of tumors including ALL. Gene hypermethylation is found in several genes in tumors cells, including genes responsible for DNA repair, cell cycle and apoptosis regulators. Therefore, demethylating agents may be promising agents for cancer treatment. Zebularine (ZB) an iDNMT is a cytidine analogue that inhibits DNA methylation. This drug has shown promising results for the treatment of many cancers, including glioblastoma, acute myeloid leukemia, breast and prostate cancer and others. The aim of this study was to evaluate the effects of ZB treatment, associated or not with chemotherapeutic agents, in childhood ALL cell lines through functional tests such as cell proliferation, clonogenic capacity, apoptosis and cell cycle. In addition, we examined the demethylating ability of ZB and the expression of DNMT1, DNMT3a and DNMT3b genes after treatment with this agent. ZB inhibited cell proliferation in a dose- and time-dependent manner and showed synergistic effects when combined with MTX in both cell lines. ZB treatment also reduced clonogenic capacity and increased the number of apoptotic cells in both cell lines studied. Furthermore, treatment with ZB caused an S phase cell cycle arrest in ReH cell line. ZB was able to partially demethylate AhR gene and reduce the expression of genes DNMT1, DNMT3a and DNMT3b. These results suggest that demethylating drugs may be interesting agents for the treatment of childhood ALL. Combinação de Drogas Epigenética Leucemia Linfóide Aguda Metilação Zebularina Acute lymphoblastic leukemia Drug combination Epigenetics Methylation Zebularine
9	Estudo da Expressão dos Genes DNMT1, DNMT3A, DNMT3B, MGMT e Efeitos da Zebularina em Glioblastoma / Estudo da Expressão dos Genes DNMT1, DNMT3A, DNMT3B, MGMT e Efeitos da Zebularina em Glioblastoma Daniel Antunes Moreno 24 August 2012 (has links) Os gliomas são tumores que surgem a partir de células da glia e são considerados os mais comuns do sistema nervoso central. São subdivididos em quatro grupos: astrocitoma pilocítico (grau I), astrocitoma difuso (grau II), astrocitoma anaplásico (grau III) e glioblastoma (grau IV ou GBM). Entre esses, o GBM é o tumor mais agressivo e mais freqüente. Apesar de ser encontrado em qualquer faixa etária, esse tumor é raro em crianças. Atualmente a cirurgia seguida de radioterapia e quimioterapia com temozolomida (TMZ) tem sido utilizado como protocolo de tratamento padrão para a maioria dos pacientes e mesmo assim a sobrevida se mantem extremamente baixa. Além disso, grande parte dos pacientes não respondem ao tratamento com TMZ indicando a necessidade de agentes quimioterápicos alternativos. A zebularina (ZB) é um agente inibidor de DNA metiltransferases (iDNMTs) estável, pouco tóxico, que promove radiosensibilização e tem mostrado efeitos promissores em diversos tipos de neoplasias, entretanto pouco se sabe a respeito dos efeitos da ZB em glioblastoma. Os objetivos deste trabalho foram analisar a expressão dos genes DNMT1, DNMT3A, DNMT3B, MGMT em 5 amostras de substâncias brancas (SB), 6 linhagens de GBM e 33 amostras de gliomas (13 grau I, 2 grau II e 18 grau IV), correlacionar a expressão desses genes com os diferentes graus de gliomas e analisar os efeitos da ZB combinada ou não com TMZ em linhagens de GBM irradiadas e não irradiadas. Para análise da expressão gênica foi realizada a técnica de PCR em tempo Real. Os ensaios de proliferação celular, clonogênico, radiação e apoptose foram realizados em 3 linhagens de GBM (U251, SF188 e T98G) e uma de fibroblastos (MRC5). Também foi realizado o ensaio de proliferação celular em 5 culturas primárias de GBM tratadas com zebularina. Os genes DNMT3A e MGMT mostraram expressão maior nas amostras de SB comparando-se com gliomas e linhagens de GBM. O gene DNMT3B foi mais expresso nas linhagens de GBM comparando-se com as SB. O gene DNMT1 não mostrou diferenças significativas entre as amostras analisadas. Os ensaios de proliferação celular mostraram diminuição na proliferação com doses a partir de 50-100µM de ZB e de 250-500µM de TMZ nas linhagens e a partir de 50µM de ZB para as culturas primárias de GBM. As combinações de ZB com TMZ não mostraram sinergia na grande maioria das doses testadas. A ZB aumenta a apoptose nas 3 linhagens com doses a partir de 100µM. A ZB e TMZ mostraram diminuição na formação de colônias com as doses de 100µM e 10µM nas linhagens U251 e SF188 não irradiadas e irradiadas com 2, 4 e 6 Gy. A linhagem T98G expressa o gene MGMT, mostrou resistência a 10µM de TMZ e respondeu ao tratamento com 100µM de ZB. Também foi observado que 10µM de TMZ é mais citotóxico do que 100µM de ZB em fibroblastos não irradiados e irradiados (2Gy). Os resultados obtidos neste estudo mostram que a ZB pode representar um alvo terapêutico interessante para o estudo em glioblastoma. / Gliomas arise from glial cells and are the most common central nervous system tumors. They are divided in four groups: pilocytic astrocytoma (grade I), difuse astrocytoma (grade II), anaplastic astrocytoma (grade III) and glioblastoma (grade IV or GBM). GBM is the most frequent and aggressive glioma. This type of tumor can occur in any age but its rare in children. Actually, surgery, radiotherapy and temozolomide (TMZ) adjuvant/concomitant chemotherapy has been the standard treatment protocol but the survival is extremely poor. In addition most patients do not respond to TMZ indicating the need for alternative chemotherapeutic agents. Zebularine (ZB) is a DNA metiltransferase inhibitor (DNMTi) stable, slight toxic that has been showed promise effects in cancer including radiosensitivity but little is known about ZB in glioblastoma. The objectives of this study were analyze DNMT1, DNMT3A, DNMT3B, MGMT gene expression profile in 5 samples of normal brain, 6 GBM cell lines and 33 glioma samples (13 grade I, 2 grade II e 18 grade IV), correlate with different gliomas grades and analyze the effects of ZB isolate and in combination with TMZ in irradiated and non irradiated GBM cell lines. Gene expression assays was made using Real Time PCR. Proliferation, clonogenic, radiation and apoptosis assays were realized in three GBM cell lines (U251, SF88, T98G) and one fibroblast cell line (MRC5). We also made proliferation assays in 5 primary cultures of samples of GMB. MGMT and DNMT3A genes showed higher expression in normal brain compared to gliomas and GBM cell lines. DNMT3B gene showed higher expression in GBM cell lines compared with normal brain and DNMT1 showed no significant differences among samples analyzed. We observed decrease of cell proliferation from 50-100µM of ZB and 250-500µM of TMZ on GBM cell lines and from 50µM of ZB for primary GBM samples. It was not observed synergy in the most combinations doses of ZB and TMZ (Calcusyn software). It was observed that 100µM of ZB and 10µM of TMZ decrease colony formation on U251 and SF188 cell lines non irradiated and irradiated with 2, 4, and 6Gy. T98G that express MGMT, did not respond to TMZ but showed response to ZB. It was also observed that 10µM of TMZ is more cytotoxic than 100µM of ZB in fibroblast cell line non irradiated and irradiated with 2Gy. ZB increase apoptosis from 100µM on the three GBM cell lines. Results obtained in this study can indicate that ZB may be an interestig therapeutic target for future studies in glioblastoma. DNA metil-transferases Glioblastoma Radiação Temozolomida Zebularina DNA metil-transferases Glioblastoma Radiation Temozolomide Zebularine
10	Action anti-leucémique des inhibiteurs de la méthylation de l’ADN et de la déacétylation des histones Lemaire, Maryse 04 1900 (has links) Les gènes suppresseurs de tumeurs (TSGs) contrôlent la prolifération cellulaire et leur inactivation joue un rôle important dans la leucémogénèse. Deux mécanismes épigénétiques majeurs sont impliqués dans la répression des TSGs: 1- la méthylation de l’ADN et 2- la déacétylation des histones des chromosomes. On les dit épigénétiques car ils n’affectent pas la séquence de l’ADN. Ces phénomènes sont réversibles, faisant donc d’eux des cibles thérapeutiques de choix. Dans le cadre de cette thèse, nous avons évalué le potentiel chimiothérapeutique de différents agents qui visent ces mécanismes épigénétiques et nous les avons administrés seuls et en combinaison dans le but d’améliorer leur efficacité. La 5-aza-2’-désoxycytidine (5-Aza-CdR) est un inhibiteur de la méthylation de l’ADN qui permet la ré-expression des TSGs. Cet agent s’est avéré efficace contre certaines maladies hématologiques et est d’ailleurs approuvé aux États-Unis dans le traitement du syndrome myélodysplasique depuis 2006. Cependant, le protocole d’administration optimal de cet agent, en termes de doses et de durée, n’est toujours pas établi. Nos recherches suggèrent que le celui-ci devrait être plus intensif que ce que rapporte la littérature. Les inhibiteurs des déacétylases des histones (HDACi) ont également montré une activité antinéoplasique intéressante. De récentes recherches ont montré que la combinaison d’agents ciblant à la fois la méthylation de l’ADN et la déacétylation des histones produit une réactivation synergique des TSGs, ce à quoi nous nous sommes intéressé. Nous avons observé que la co-administration d’un HDACi avec la 5-Aza-CdR potentialise son action anti-leucémique. Il est aussi possible d’augmenter l’activité de la 5-Aza-CdR en inhibant sa dégradation par l’enzyme cytidine (CR) désaminase. Nous avons observé que la co-administration du zebularine, un inhibiteur de la CR désaminase, avec la 5-Aza-CdR accroît son efficacité. Le zebularine est aussi un inhibiteur de la méthylation de l’ADN, ce qui pourrait contribuer à la potentialisation de la réponse anti-leucémique observée lors de la co-administration de ces deux agents. En résumé, il est possible d’augmenter l’efficacité anti-leucémique de la 5-Aza-CdR en : 1- intensifiant son protocole d’administration, en termes de doses et de durée, 2- la combinant avec un HDACi, et 3- diminuant sa dégradation par la CR désaminase. L’utilisation de ces résultats précliniques dans l’élaboration de protocoles cliniques pourrait être bénéfique à beaucoup de patients. / The silencing of tumor suppressor genes (TSG) that normally regulate cells proliferation plays an important role in leukemogenesis. Two major mechanisms are involved in TSG’s silencing: DNA methylation and histones deacetylation. Because those phenomenons are reversible, it makes them interesting therapeutic targets for chemotherapeutic agents. We evaluated the antineoplastic potential of different agents that target those events and we administered them alone or in combination with the goal of improving their efficiency. 5-aza-2’-deoxycytidine (5-Aza-CdR) is a DNA methylation inhibitor that can re-express TSGs that are silenced by methylations. This agent demonstrated its efficacy against hematological malignancies. Therefore, 5-Aza-CdR is used since 2006 in United States of America against myelodysplastic syndrome; but its optimal dose-schedule still needs to be established. Our researches suggest that the dose-schedule of 5-Aza-CdR should be more intensive than what is reported from the literature. Inhibitors of histones deacetylation (HDACi) also demonstrated some interesting antineoplastic activity. Recently, observations showed that combination of chemotherapeutic agent that targets both DNA methylation and histones deacetylation lead to a synergic reactivation of silenced TSG. This finding allowed us to observe that the co-administration of an HDACi with 5-Aza-CdR improve its antileukemic potential. Moreover, it is possible to increase the activity of 5-Aza-CdR by preventing its degradation by cytidine (CR) deaminase. We demonstrated that the co-administration of zebularine, an inhibitor of CR deaminase, with 5-Aza-CdR increases its activity. Zebularine is also an inhibitor of DNA methylation, which may contribute to the enhancement of the antileukemic action of this combination. In summary, our preclinical data indicate that the antileukemic activity of 5-Aza-CdR can be enhanced by: 1- increasing his dosage, 2- combining it with HDACi, and 3- preventing its inactivation by CR deaminase. The translation of those preclinical observations into clinical protocols may be effective in patients with advanced leukemia. Leucémie Cancer 5-Aza-2'-désoxycytidine Zebularine Phénylbutyrate SAHA LAQ824 Cytidine désaminase Leukemia Cancer 5-Aza-2'-deoxycytidine Zebularine Phenylbutyrate SAHA LAQ824 Cytidine deaminase

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