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A study of mechanisms of genotoxicity in mammalian cells by retrovirus vectors intended for gene therapyReja, Safia January 2013 (has links)
Retrovirus gene therapy vectors can deliver therapeutic genes to mammalian cells in a permanent manner by integrating their genome into host chromosomes and therefore provide the potential for long term therapeutic gene expression. Retrovirus integration, however, can be oncogenic. Apart from insertional mutagenesis (IM) genotoxicity may be caused by other factors including DNA damage following infection and integration and epigenetic effects related to incoming viral particles. Thus, using retrovirus and lentivirus infected murine tumour tissue and infected cell lines in vitro this thesis was directed at investigating whether virus infection and integration could cause genotoxicity by alternative route(s) other than IM. Using clonally derived liver tumours that developed in mice, and normal liver and kidney tissues, following EIAV and HIV delivery in utero, comparative genome hybridisation methodology was used to examine for copy number variation. This showed amplification and deletions only in EIAV derived tumours. Real time Q-PCR analysis was then used to measure gene expression changes relating to genes contained within or near to amplifications observed in two tumours of individual mice. The STRING database was then used to find networks linking genes with differential expression profiles and genes in one of these tumours identified with provirus insertions that were also differentially expressed. These data provided preliminary data implicating a role for LV in Hepatocellular carcinoma (HCC). DNA damage is known to cause chromosomal instability that can lead to tumour development. The relationship between double strand breaks (DSB) and virus infection was also investigated in-vitro to find alternative routes to genotoxicity other than IM. Cell viability analysis demonstrated cells with a defective DNA damage response (DDR) have decreased cell viability compared with cells with intact DDR when infected with RV or LV vectors. DSB assays showed RV and LV infection to generate foci over a 6 hour period followed by DDR. Where no viral integrase is present, no DDR appears, however, where the vector is used with or without a genome to infect cells, DDR occurs as shown by the presence of 53BP1 foci indicative of DNA damage. The relationship between DNA damage and methylation was also investigated. Global methylation was found elevated in the genomic DNA of LV and RV infected cells and not in control uninfected cells. In contrast, methylation changes were not found in infected cells lacking the NHEJ repair pathway. These data suggest the DNA damage response is linked to genome methylation. The E2F transcription factor plays a key role in regulating expression of genes known to control oncogenesis and cancer, and E2F is regulated by methylation of its related target gene promoters. Taking into account all genes in the human genome the number of genes that bind E2F is 32.77%. However, using microarray to represent genes differentially expressed after infection, 59% of these were E2F targets. Overall, taking the data obtained in this thesis into account it may be suggested that RV and LV infection causes a number of potentially related changes to cells that include DNA damage and repair and methylation changes that could influence E2F that is an important factor involved in oncogenesis. Combining this with IM, attenuated RV and LV currently in use for gene therapy may cause genotoxicity to infected cells and increase the risk of oncogenesis especially where DNA damage is not correctly repaired. Further work is required to show in greater detail the extent of this genotoxicity, possible by whole genome sequencing of treated host genomes or cell transformation assays linked to the genotoxicity assays presented here. Collectively these data show that alternative factors to IM might exist that could act independently or synergistically to IM.
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Investigating benzene-initiated DNA double-strand breaks and recombination after acute and in utero exposure in miceLau, Annette Anling 22 August 2008 (has links)
Benzene is an ubiquitous pollutant and industrial solvent that has been identified as a human leukemogen. Early exposure to environmental carcinogens such as benzene has been postulated to play a role in the etiology of childhood leukemia, however the association remains controversial. Genotoxic agents such as benzene can cause an increase in the frequency of DNA double-strand breaks, which may remain unrepaired or result in the initiation of DNA recombinational repair mechanisms.
The first objective was to investigate the induction of DNA double-strand breaks following in utero treatment to 200 mg/kg and 400 mg/kg benzene i.p. using the phosphorylated histone γ-H2A.X as a marker. Using immunoblotting, treatment with benzene did not increase the formation of γ-H2A.X in bone marrow cells of adult C57Bl/6N male mice and in maternal bone marrow, fetal liver, and post-natal bone marrow cells following in utero exposure to 200 mg/kg or 400 mg/kg benzene throughout gestational days 7 to 15.
Secondly, the study investigated the induction of micronuclei following in utero exposure to benzene. Acute exposure to 400 mg/kg benzene resulted in a statistically significant increase in the percentage of micronucleated cells in adult male bone marrow cells. In utero exposure to 400 mg/kg benzene throughout gestational days 7 to 15 also caused a statistically significant increase in the percentage of micronucleated cells in maternal bone marrow and post-natal bone marrow cells. Fetal liver cells also demonstrated a statistically significant increase in the percentage of micronucleated cells following 200 mg/kg and 400 mg/kg benzene.
The third objective was to investigate the initiation of DNA recombination following in utero exposure to benzene using the pKZ1 mutagenesis mouse model as a surrogate marker for non-homologous end joining activity. Adult pKZ1 mouse tissue yielded no recombination events; however, post-natal bone marrow cells did contain detectable recombination frequencies.
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In utero benzene exposure did cause an increasing trend in recombination events, and upon analysis of only the samples containing detectable levels of recombination, in utero exposure to 400 mg/kg of benzene caused a statistically significant increase in recombination frequency within this group.
These results demonstrate that benzene does not increase the formation of γ-H2A.X after acute and in utero exposure, however, the induction of micronuclei following acute and in utero benzene exposure confirmed that benzene is a genotoxic agent causing chromosomal breaks. In utero benzene exposure increased the frequency of DNA recombination in bone marrow from post-natal day 9 pups exhibiting detectable levels of recombination. Further investigations into different types of DNA damage and repair pathways are warranted to fully elucidate the role of genotoxic mechanisms in the etiology of benzene-induced childhood leukemias. / Thesis (Master, Pharmacology & Toxicology) -- Queen's University, 2008-08-22 11:07:49.162
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Inibidor de histona deacetilase (HDACi) como possível radiosensibilizante em linhagens celulares de glioblastoma pediátrico / Histone inhibitor as a putative radiosensitizer in pediatric glioblastoma cell linesAndrade, Pamela Viani de 18 June 2015 (has links)
O glioblastoma (GBM) é considerado um dos tumores mais agressivos do sistema nervoso central (SNC). Mesmo com o uso de protocolos modernos de tratamento o prognóstico se mantém bastante reservado, sendo que crianças com GBM apresentam uma sobrevida média de 12 a 15 meses. Mecanismos epigenéticos podem interferir no processo de carcinogênese, sendo que a acetilação do DNA pode modular a expressão de genes que atuam no controle do ciclo celular, contribuindo assim para o desenvolvimento e progressão de neoplasias. Estudos clínicos demonstram que inibidores de histonas deacetilases (HDACs), em monoterapia ou combinados a outros agentes antineoplásicos, são clinicamente ativos e bem tolerados no tratamento de uma ampla variedade de tumores. Estes inibidores podem sensibilizar a resposta celular à irradiação ionizante, possibilitando uma redução nas doses-padrão utilizadas, minimizando os efeitos colaterais a curto e longo prazo. A radiação ionizante induz dano no DNA e é geralmente aceito que quebras da dupla-fita (DSBs) é o tipo de lesão mais severa relacionada à sobrevivência celular e preservação da integridade genômica. No presente estudo, avaliamos o potencial efeito radiosensibilizante do PCI-24781, um novo e potente pan-inibidor de HDAC nas linhagens celulares de GBM pediátrico SF188 e KNS42. Foram comparadas as taxas de proliferação celular, clonogenicidade e apoptose das linhagens SF188 e KNS42 com ou sem tratamento com PCI-24781. Também foram comparadas as taxas de clonogenicidade das linhagens SF188 e KNS42 que foram irradiadas com ou sem tratamento prévio com PCI-24781. Adicionalmente, foram avaliados os efeitos do PCI-24781 na expressão de algumas das principais proteínas responsáveis pelo reparo de quebras da dupla-fita ocasionadas pela irradiação. Para os ensaios de proliferação celular foram utilizados os tempo de 24, 48, 72 e 96h, para apoptose, 48h e para capacidade clonogênica sem irradiação o tempo de 48h, em diferentes doses de PCI-24781 (0,25 - 16 M). O inibidor bloqueou significativamente a proliferação celular (p<0,05), induziu morte por apoptose (p<0,05) e reduziu a capacidade na formação de colônias (p<0,001) em ambas as linhagens. No ensaio para avaliação da radiosensibilidade, foram utilizadas as doses do IC30 11 de cada linhagem do ensaio clonogênico seguida de diferentes doses de irradiação. Ambas as linhagens apresentaram uma significativa (p<0,001) diminuição na formação de colônias em todas as doses de irradiação. A linhagem mais resistente à droga, SF188 foi escolhida para estudo do reparo de quebras da dupla-fita ocasionadas pela irradiação. As expressões da proteína Rad51, importante na via de reparo por recombinação homóloga (HR), e das proteínas DNA-PKcs, Ku70 e Ku86, importantes na via de reparo por união terminal não-homóloga (NHEJ) apresentaram uma maior diminuição quando a linhagem irradiada foi previamente tratada com PCI-24781 em comparação à radioterapia exclusiva. Estes achados demonstram que o inibidor de histona PCI-24781 apresenta um importante papel como agente radiosensibilizante, comprometendo o reparo das quebras de dupla-fita em células de GBM pediátrico tratadas com radioterapia. / Glioblastoma (GBM) is considered one of the most aggressive tumors to affect the central nervous system (CNS). Even employing modern treatment protocols the prognosis remains very poor, with children affected by GBM presenting a median survival rate of 12 to 15 months. Epigenetic mechanisms may interfere with the process of tumorigenesis, and DNA acetylation can modulate the expression of genes that contribute in cell cycle control and participate to the development and progression of cancer. Clinical studies demonstrate that histone deacetylase inhibitors (HDACs), alone or in combination with other antineoplastic agents, are clinically active and well tolerated in the treatment of a wide variety of tumors. These inhibitors may sensitize the cellular response to ionizing radiation, enabling the reduction in standard doses of radiation, ultimately minimizing both short and long-term side effects. Ionizing radiation induces DNA damage and it is generally accepted that the double-stranded breaks (DSBs) is the most severe type of injury related to cell survival and preservation of genomic integrity. In the present study, we evaluated the potential radiosensitizer effect of PCI-24781, a novel potent pan-HDAC inhibitor in the pediatric GBM cell lines SF188 and KNS42. We compared the cell proliferation rates, apoptosis of clonogenicity of KNS42 and SF188, with or without treatment with PCI-24781. Moreover, clonogenicity rates were compared between cell lines that were irradiated with or without prior treatment with PCI-24781 Additionally, we evaluated the effects of PCI-24781 in the expression of some of the major proteins responsible for the repair of double-stranded breaks caused by the irradiation. For the cell proliferation assays, the times of 24, 48, 72 and 96 hours were used, for apoptosis, the time of 48h and clonogenic capacity without irradiation, the time of 48h, and different doses of PCI-24781 (0,25 - 16 M). The inhibitor significantly blocked cell proliferation (p<0,05), inducing cell death by apoptosis (p<0,05) and reducing the colony forming ability (p<0,001) of both lineages. In the assays to evaluate the radiosensitivity , the IC30 doses of the clonogenic assays were used for each cell-line after different doses of irradiation. Both lineages showed a significant decrease (p<0,001) in colony formation at all doses of irradiation. The most resistant cell-line to the drug, SF188, was 13 chosen to study the double-strand breaks repair caused by irradiation. The Rad51 protein levels, critical for homologous recombination (HR), and the DNA-PKcs proteins Ku70 and Ku86, important for DNA repair through non-homologous end joining (NHEJ) showed significant decrease in expression when cell-line was treated with PCI-24781 prior to radiotherapy. These data demonstrates that the histone deacetylase inhibitor PCI-24781 plays an important role as a radiosensitizer agent, compromising the repair of double-strand breaks in pediatric GBM cells following irradiation.
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Inibidor de histona deacetilase (HDACi) como possível radiosensibilizante em linhagens celulares de glioblastoma pediátrico / Histone inhibitor as a putative radiosensitizer in pediatric glioblastoma cell linesPamela Viani de Andrade 18 June 2015 (has links)
O glioblastoma (GBM) é considerado um dos tumores mais agressivos do sistema nervoso central (SNC). Mesmo com o uso de protocolos modernos de tratamento o prognóstico se mantém bastante reservado, sendo que crianças com GBM apresentam uma sobrevida média de 12 a 15 meses. Mecanismos epigenéticos podem interferir no processo de carcinogênese, sendo que a acetilação do DNA pode modular a expressão de genes que atuam no controle do ciclo celular, contribuindo assim para o desenvolvimento e progressão de neoplasias. Estudos clínicos demonstram que inibidores de histonas deacetilases (HDACs), em monoterapia ou combinados a outros agentes antineoplásicos, são clinicamente ativos e bem tolerados no tratamento de uma ampla variedade de tumores. Estes inibidores podem sensibilizar a resposta celular à irradiação ionizante, possibilitando uma redução nas doses-padrão utilizadas, minimizando os efeitos colaterais a curto e longo prazo. A radiação ionizante induz dano no DNA e é geralmente aceito que quebras da dupla-fita (DSBs) é o tipo de lesão mais severa relacionada à sobrevivência celular e preservação da integridade genômica. No presente estudo, avaliamos o potencial efeito radiosensibilizante do PCI-24781, um novo e potente pan-inibidor de HDAC nas linhagens celulares de GBM pediátrico SF188 e KNS42. Foram comparadas as taxas de proliferação celular, clonogenicidade e apoptose das linhagens SF188 e KNS42 com ou sem tratamento com PCI-24781. Também foram comparadas as taxas de clonogenicidade das linhagens SF188 e KNS42 que foram irradiadas com ou sem tratamento prévio com PCI-24781. Adicionalmente, foram avaliados os efeitos do PCI-24781 na expressão de algumas das principais proteínas responsáveis pelo reparo de quebras da dupla-fita ocasionadas pela irradiação. Para os ensaios de proliferação celular foram utilizados os tempo de 24, 48, 72 e 96h, para apoptose, 48h e para capacidade clonogênica sem irradiação o tempo de 48h, em diferentes doses de PCI-24781 (0,25 - 16 M). O inibidor bloqueou significativamente a proliferação celular (p<0,05), induziu morte por apoptose (p<0,05) e reduziu a capacidade na formação de colônias (p<0,001) em ambas as linhagens. No ensaio para avaliação da radiosensibilidade, foram utilizadas as doses do IC30 11 de cada linhagem do ensaio clonogênico seguida de diferentes doses de irradiação. Ambas as linhagens apresentaram uma significativa (p<0,001) diminuição na formação de colônias em todas as doses de irradiação. A linhagem mais resistente à droga, SF188 foi escolhida para estudo do reparo de quebras da dupla-fita ocasionadas pela irradiação. As expressões da proteína Rad51, importante na via de reparo por recombinação homóloga (HR), e das proteínas DNA-PKcs, Ku70 e Ku86, importantes na via de reparo por união terminal não-homóloga (NHEJ) apresentaram uma maior diminuição quando a linhagem irradiada foi previamente tratada com PCI-24781 em comparação à radioterapia exclusiva. Estes achados demonstram que o inibidor de histona PCI-24781 apresenta um importante papel como agente radiosensibilizante, comprometendo o reparo das quebras de dupla-fita em células de GBM pediátrico tratadas com radioterapia. / Glioblastoma (GBM) is considered one of the most aggressive tumors to affect the central nervous system (CNS). Even employing modern treatment protocols the prognosis remains very poor, with children affected by GBM presenting a median survival rate of 12 to 15 months. Epigenetic mechanisms may interfere with the process of tumorigenesis, and DNA acetylation can modulate the expression of genes that contribute in cell cycle control and participate to the development and progression of cancer. Clinical studies demonstrate that histone deacetylase inhibitors (HDACs), alone or in combination with other antineoplastic agents, are clinically active and well tolerated in the treatment of a wide variety of tumors. These inhibitors may sensitize the cellular response to ionizing radiation, enabling the reduction in standard doses of radiation, ultimately minimizing both short and long-term side effects. Ionizing radiation induces DNA damage and it is generally accepted that the double-stranded breaks (DSBs) is the most severe type of injury related to cell survival and preservation of genomic integrity. In the present study, we evaluated the potential radiosensitizer effect of PCI-24781, a novel potent pan-HDAC inhibitor in the pediatric GBM cell lines SF188 and KNS42. We compared the cell proliferation rates, apoptosis of clonogenicity of KNS42 and SF188, with or without treatment with PCI-24781. Moreover, clonogenicity rates were compared between cell lines that were irradiated with or without prior treatment with PCI-24781 Additionally, we evaluated the effects of PCI-24781 in the expression of some of the major proteins responsible for the repair of double-stranded breaks caused by the irradiation. For the cell proliferation assays, the times of 24, 48, 72 and 96 hours were used, for apoptosis, the time of 48h and clonogenic capacity without irradiation, the time of 48h, and different doses of PCI-24781 (0,25 - 16 M). The inhibitor significantly blocked cell proliferation (p<0,05), inducing cell death by apoptosis (p<0,05) and reducing the colony forming ability (p<0,001) of both lineages. In the assays to evaluate the radiosensitivity , the IC30 doses of the clonogenic assays were used for each cell-line after different doses of irradiation. Both lineages showed a significant decrease (p<0,001) in colony formation at all doses of irradiation. The most resistant cell-line to the drug, SF188, was 13 chosen to study the double-strand breaks repair caused by irradiation. The Rad51 protein levels, critical for homologous recombination (HR), and the DNA-PKcs proteins Ku70 and Ku86, important for DNA repair through non-homologous end joining (NHEJ) showed significant decrease in expression when cell-line was treated with PCI-24781 prior to radiotherapy. These data demonstrates that the histone deacetylase inhibitor PCI-24781 plays an important role as a radiosensitizer agent, compromising the repair of double-strand breaks in pediatric GBM cells following irradiation.
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Rôle du complexe de cohésion sur la ligature d'extrémités d'ADN non homologues et la stabilité du génome / The cohesin complex protects against genome rearrangements by preventing the end-joining of distal DNA double-strand-endsGelot, Camille 10 September 2014 (has links)
Au cours de la réplication, la réparation des cassures double brin (CDB) par recombinaison homologue (RH), basée sur la synthèse d’ADN à partir de la chromatide sœur, permet le maintien de la stabilité du génome. La religature d’extrémités (EJ) éloignées de CDB peut quant à elle générer des réarrangements menaçant son intégrité. Nous avons étudié le mécanisme de réparation par EJ en fonction de la distance séparant deux cassures double brin. En utilisant des substrats intra-chromosomiques permettant la mesure de l’efficacité et de la fidélité du EJ après ligature d’extrémités éloignées ou proximales, nous avons mis en évidence l’implication du complexe de cohésion dans l’inhibition du EJ d’extrémités distales. Le complexe de cohésion joue donc un rôle central dans l’interface réplication/réparation ; la cohésion des chromatides sœurs favorise la réparation par RH et permet l’inhibition spécifique du EJ d’extrémités éloignées, probablement en limitant la mobilité de la chromatine endommagée et la formation d’une synapse propice au rapprochement des extrémités. La religature d’extrémités éloignées est également nécessaire aux mécanismes de diversification des gènes des immunoglobulines tels que la recombinaison V(D)J et la commutation de classe. L’étude de souris Rad21+/- a également démontré une implication du complexe de cohésion dans ces mécanismes essentiels à la diversité de l’information génétique. Le complexe de cohésion étant impliqué dans ces mécanismes et dans l’inhibition des réarrangements complexes tels que les translocations et insertions il est un acteur essentiel de la diversité et de la stabilité génomique. / DNA double-strand breaks (DSBs) repair is essential for genome stability/diversity, but can also generate genome rearrangements. Although non-homologous end-joining (NHEJ) is required for genome stability maintenance, the joining of distant double strand ends (DSE) should inexorably lead to genetic rearrangements. We analyzed the efficiency and accurency of close or distal EJ repair. Our data show that global end-joining is more efficient on close ends (34bp) compared to distal ends (3200bp) and that C-NHEJ is favored on close ends, resulting in more accurate outcome, compared to distal ends where more mutagenic A-EJ events takes place. In addition, the joining of distal ends favors the insertion/capture of DNA sequences. These data show only few kb distances between two DSEs are sufficient to jeopardize DSB repair efficiency and accuracy, leading to complex scars at the re-sealed junctions, and cell response is sufficiently sensitive to differently process such distal ends. We next addressed the question of the mechanisms preventing the joining of distant DSE. We show that depletion of the cohesin complex proteins specifically stimulates the end-joining of I-SceI-induced DSBs distant of 3200bp, while the joining of close DSEs (34bp) remained unaffected. Consistently, exome sequencing and cytogenetic analysis revealed that RAD21 ablation generates large chromosome rearrangements and a strong induction of replication stress-induced chromosome fusions. These data reveal a role for the cohesin complex in the protection against profound genome rearrangements arising through ligation of distant DSEs.
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Stochastic modeling of the cell killing effect for low- and high-LET radiationPartouche, Julien 17 February 2005 (has links)
Theoretical modeling of biological response to radiation describes qualitatively and quantitatively the results of radiobiological effects at the molecular, chromosomal, and cellular level. The repair-misrepair (RMR) model is the radiobiological model chosen for our study. It models deoxyribonucleic acid (DNA) damage formation and lesion repair through linear and quadratic processes.
Double strand breaks (DSB) are a critical lesion in DNA. With increasing LET, the number of DSB per track traversing the cell nucleus increases. Using a compound Poisson process (CPP), we describe DNA damage formation. Three models were considered: a simple CPP using constant LET, a CPP using a chord length distribution, and a CPP using specific energy distribution. In the two first cases, and for low LET radiation the initial distribution of DSB was well approximated by a Poisson distribution, while for high LET radiation the initial distribution of DSB deviated slightly from a Poisson distribution. In the last case, DSB distribution was much broader than a pure Poisson distribution.
Datasets from the literature for seven human cell lines, exhibiting various sensitivities to radiation were analyzed.
We compared stochastic, CPP, and CPP using chord length distribution, with deterministic RMR models. For low LET radiation and at high dose rates the stochastic survival results agree well with the deterministic survival results. Also the stochastic model allows for non-linearity at low doses due to the accumulation of sub-lethal damage. At low dose rates deterministic results overestimate the surviving fraction compared to stochastic results. For high LET radiation stochastic and deterministic survival results agree. Stochastic survival results using specific energy distribution diverged from deterministic results by underestimating the surviving fraction at low and high LET radiation.
The dose rate sparing curve, representing surviving fraction at a dose of 10Gy vs. dose rate shows that deterministic survival results are consistent with stochastic survival results, using CPP, or CPP with chord length distribution, for low and high dose rate values. Compared to deterministic aspects of DNA damage formation we concluded that stochastic aspects of DNA damage formation and repair using CPP or CPP with chord length distribution are not as prominent as reported in the earlier studies.
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Cooperative nuclease activity of the Mre11/Rad50/Xrs2 complex and Sae2 during DNA double-strand break repairLengsfeld, Bettina Marie 12 March 2014 (has links)
DNA double-strand breaks (DSBs) are lethal in eukaryotic cells if left unrepaired. In Saccharomyces cerevisiae the Mre11/Rad50/Xrs2 (MRX) complex is required for repair of DSBs through homologous recombination and nonhomologous end joining. Although Mre11 complexes exhibit 3'[rightwards arrow]5' exonuclease activity and endonuclease activity on DNA hairpin and single-stranded DNA overhang substrates in vitro, the role of the MRX complex in homologous recombination in vivo is not well understood. It has been shown to be specifically required for the processing of protein-conjugated DNA ends at DSBs during meiosis and hairpin-capped DSBs in mitotic cells and has been suggested that the Mre11 nuclease functions to remove damaged DNA ends. Recently, the Sae2 protein has been demonstrated to be involved in hairpin-capped DSBs and DNA end processing along with MRX in vivo. However, the Sae2 protein has no known homologs outside of fungi and no obvious motifs to suggest the function(s) of the Sae2 protein. We have purified recombinant Sae2 and MRX and report that the Sae2 protein itself is a single-stranded DNA endonuclease. The Sae2 protein stimulates the 3[rightwards arrow]5' exonuclease activity of the MRX complex. Also, the MRX complex can stimulate Sae2 nuclease activity to cleave ssDNA adjacent to DNA hairpin structures. The Sae2 protein also binds independently to double-stranded DNA and forms higher order protein-DNA complexes with MRX. These results provide biochemical evidence for functional cooperatively between MRX and Sae2 on DSBs and hairpin-capped DNA ends. / text
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Characterization of Mre11/Rad50/Xrs2, Sae2, and Exo1 in DNA end resectionNicolette, Matthew Lawrence 28 April 2015 (has links)
Eukaryotic cells repair DNA double-strand breaks (DSBs) through both non-homologous and homologous recombination pathways. The initiation of homologous recombination requires the generation of 3' overhangs, which are essential for the formation of Rad51 protein-DNA filaments that catalyze subsequent steps of strand invasion. Experiments in budding yeast show that resection of the 5' strand at a DSB is delayed in strains lacking any components of the Mre11/Rad50/Xrs2 (MRX) complex¹ . In meiosis, a specific class of hypomorphic mutants of mre11 and rad50 (Rad50S) are completely deficient in 5' resection and leave Spo11 covalently attached to the 5' strands of DNA breaks². Similar to mre11S and rad50S mutants, sae2 deletion strains fail to resect 5' strands at meiotic DSBs and accumulate covalent Spo11 adducts³;⁴. In addition, Sae2 and MRX were also found to function cooperatively to process hairpin-capped DNA ends in vivo in yeast. sae2 and mrx null strains show a severe defect in processing these structures and accumulate hairpin-capped DNA ends⁵;⁶. The Longhese laboratory has also shown that Sae2 deletion strains show a delay in 5' strand resection, similar to rad50S strains⁷. Recently, Bettina Lengsfeld in our laboratory demonstrated that Sae2 itself possesses nuclease activity and that MRX and Sae2 act cooperatively to cleave single-stranded DNA adjacent to DNA hairpin structures⁸. In vitro characterization of Sae2 showed that the central and N-terminal domains are required for MRX-independent nuclease activity and that the C-terminus is required for cooperative activities with MRX. Sae2 also acts independently of MRX as a 5' flap endonuclease on branched structures in vitro. Our studies investigate whether MRX, Sae2, and Exo1 function cooperatively in DNA resection using recombinant, purified proteins in vitro. We developed assays utilizing strand-specific Southern blot analysis to visualize DNA end processing of model DNA substrates using recombinant proteins in vitro. Our results demonstrate that MRX and Sae2 cooperatively resect the 5' end of a DNA duplex together with the Exo1 enzyme, supporting a role for these factors in the early stages of homologous recombination and repair. / text
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Organizing the Ubiquitin-dependent Response to DNA Double-Strand BreaksPanier, Stephanie 14 January 2014 (has links)
DNA double-strand breaks (DSBs) are highly cytolethal DNA lesions. To protect genomic integrity and ensure cellular homeostasis, cells initiate a complex signaling-based response that activates cell cycle checkpoints, coordinates DNA repair, regulates gene expression and, if necessary, induces apoptosis. The spatio-temporal control of this signaling pathway relies on a large number of post-translational modifications, including phosphorylation and regulatory ubiquitylation. In this thesis, I describe the discovery and characterization of the E3 ubiquitin ligase RNF168, which cooperates with the upstream E3 ubiquitin ligase RNF8 to form a cascade of regulatory ubiquitylation at damaged chromatin. One of the main functions of RNF8/RNF168-dependent chromatin ubiquitylation is to generate a molecular landing platform for the ubiquitin-dependent accumulation of checkpoint and DNA repair proteins such as 53BP1, the breast-cancer associated protein BRCA1 and the RNF168-paralog RNF169. I present evidence that the hierarchical recruitment of these proteins to DSB sites is, in large part, organized through the use of tandem protein interaction modules. These modules are composed of a ubiquitin-binding domain and an adjacent targeting motif called LRM, which specifies the recognition of RNF8- and RNF168-ubiquitylation substrates at damaged chromatin. I conclude that the LRM-based selection of ligands is a parsimonious means to build a highly discrete ubiquitin-based signaling pathway such as the chromatin-based response to DSBs.
Collectively, my results indicate that RNF168-mediated chromatin ubiquitylation is critical for the physiological response to DSBs in human cells. The importance of the ubiquitin-based response to DSBs is underscored by the finding that RIDDLE syndrome, an immunodeficiency and radiosensitivity disorder, is caused by mutations in the RNF168 gene.
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Organizing the Ubiquitin-dependent Response to DNA Double-Strand BreaksPanier, Stephanie 14 January 2014 (has links)
DNA double-strand breaks (DSBs) are highly cytolethal DNA lesions. To protect genomic integrity and ensure cellular homeostasis, cells initiate a complex signaling-based response that activates cell cycle checkpoints, coordinates DNA repair, regulates gene expression and, if necessary, induces apoptosis. The spatio-temporal control of this signaling pathway relies on a large number of post-translational modifications, including phosphorylation and regulatory ubiquitylation. In this thesis, I describe the discovery and characterization of the E3 ubiquitin ligase RNF168, which cooperates with the upstream E3 ubiquitin ligase RNF8 to form a cascade of regulatory ubiquitylation at damaged chromatin. One of the main functions of RNF8/RNF168-dependent chromatin ubiquitylation is to generate a molecular landing platform for the ubiquitin-dependent accumulation of checkpoint and DNA repair proteins such as 53BP1, the breast-cancer associated protein BRCA1 and the RNF168-paralog RNF169. I present evidence that the hierarchical recruitment of these proteins to DSB sites is, in large part, organized through the use of tandem protein interaction modules. These modules are composed of a ubiquitin-binding domain and an adjacent targeting motif called LRM, which specifies the recognition of RNF8- and RNF168-ubiquitylation substrates at damaged chromatin. I conclude that the LRM-based selection of ligands is a parsimonious means to build a highly discrete ubiquitin-based signaling pathway such as the chromatin-based response to DSBs.
Collectively, my results indicate that RNF168-mediated chromatin ubiquitylation is critical for the physiological response to DSBs in human cells. The importance of the ubiquitin-based response to DSBs is underscored by the finding that RIDDLE syndrome, an immunodeficiency and radiosensitivity disorder, is caused by mutations in the RNF168 gene.
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