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Ugene, a Newly Identified Protein that is Commonly Over-Expressed in Cancer, and that Binds to Uracil DNA-GlycosylaseGuo, Chunguang January 2009 (has links)
No description available.
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Targteing uracil exclusion mechanisms for development of anti-viral and anti-cancer therapiesStudebaker, Adam Wade 17 October 2003 (has links)
No description available.
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Dna Glycosylases Remove Oxidized Base Damages From G-Quadruplex Dna StructuresZhou, Jia 01 January 2015 (has links)
The G-quadruplex DNA is a four-stranded DNA structure that is highly susceptible to oxidation due to its G-rich sequence and its structure. Oxidative DNA base damages can be mutagenic or lethal to cells if they are left unrepaired. The base excision repair (BER) pathway is the predominant pathway for repair of oxidized DNA bases. DNA glycosylases are the first enzymes in BER and are responsible for removing base lesions from DNA. How DNA glycosylases remove base lesions from duplex and single-stranded DNA has been intensively studied, while how they act on G-quadruplex DNA remains to be explored.
In Chapter II of this dissertation, we studied the glycosylase activity of the five mammalian DNA glycosylases (OGG1, NTH1, NEIL1, NEIL2 and mouse Neil3) on G-quadruplex DNA formed by telomere sequences that contain a single base lesion. We found that telomeric sequences that contain thymine glycol (Tg), 8-oxo-7,8-dihydroguanine (8-oxoG), guanidinohydantoin (Gh) or spiroiminodihydantoin (Sp) all formed the basket form of an antiparallel G-quadruplex DNA structure in Na+ solution. We also showed that no glycosylase was able to remove 8-oxoG from quadruplex DNA, while its further oxidation products, Sp and Gh, were good substrates for mNeil3 and NEIL1 in quadruplex DNA. In addition, mNeil3 is the only enzyme that removes Tg from quadruplex DNA and the glycosylase strongly prefers Tg in the telomere sequence context in both single-stranded and double-stranded DNA.
In Chapter III, we extended our study to telomeric G-quadruplex DNA in K+ solution and we also studied quadruplex DNA formed by promoter sequences. We found that 8-oxoG, Gh and Sp reduce the thermostability and alter the folding of telomeric quadruplex DNA in a location-dependent manner. Also, the NEIL1 and NEIL3 DNA glycosylases are able to remove hydantoin lesions but none of the glycosylases, including OGG1, are able to remove 8-oxoG from telomeric quadruplex DNA in K+ solution. Interestingly, NEIL1 or NEIL3 do not efficiently remove hydantoin lesions at the site that is most prone to oxidation in quadruplex DNA. However, hydantoin lesions at the same site in quadruplex DNA are removed much more rapidly by NEIL1, NEIL2 and NEIL3, when an extra telomere TTAGGG repeat is added to the commonly studied four-repeat quadruplex DNA to make it a five-repeat telomere quadruplex DNA. We also show that APE1 cleaves furan in selected positions in Na+-coordinated telomeric quadruplex DNA structures. We use promoter sequences of the VEGF and c-MYC genes as models to study promoter G-quadruplex DNA structures, and show that the NEIL glycosylases primarily remove Gh from Na+-coordinated antiparallel quadruplex DNA but not from K+-coordinated parallel quadruplex DNA containing VEGF or c-MYC promoter sequences.
Taken together, our data show that the NEIL DNA glycosylases may be involved in both telomere maintenance and gene regulation.
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The Ubiquitin Ligase \(CRL4^{Cdt2}\) Targets Thymine DNA Glycosylase for Destruction during DNA Replication and RepairSlenn, Tamara Jeannine 07 June 2014 (has links)
The E3 ubiquitin ligase \(CRL4^{Cdt2}\) targets proteins for destruction during DNA replication and following DNA damage (Havens and Walter, 2011). Its substrates contain "PIP degrons" that mediate substrate binding to the processivity factor PCNA at replication forks and damage sites. The resulting PCNA-PIP degron complex forms a docking site for \(CRL4^{Cdt2}\), which ubiquitylates the substrate on chromatin. Several \(CRL4^{Cdt2}\) substrates are known, including Cdt1, multiple CDK inhibitors, Drosophila E2f1, human Set8, S. pombe Spd1, and C. elegans \(Pol\eta\) (Havens and Walter, 2011). An emerging theme is that \(CRL4^{Cdt2}\) targets proteins whose presence in S phase is toxic. Here, I used Xenopus egg extract to characterize a new \(CRL4^{Cdt2}\) substrate, thymine DNA glycosylase (TDG). TDG is a base excision repair protein that targets G-U and G-T mispairs, which arise from cytosine and 5-methylcytosine deamination (Cortazar et al., 2007). Thus, TDG may function in epigenetic gene regulation via DNA demethylation, in addition to its canonical DNA repair function. A yet unknown E3 ubiquitin ligase triggers TDG destruction during S phase (Hardeland et al., 2007). Understanding TDG proteolysis in S phase is relevant to the regulation of DNA replication, DNA repair, and epigenetic control of gene expression. I discovered that TDG contains a variant of the "PIP degron" consensus and that TDG is ubiquitylated and destroyed in a PCNA-, Cdt2-, and degron-specific manner during DNA repair and DNA replication in Xenopus egg extract. I further characterized what features of TDG contribute to its proteolysis. Interestingly, I could not identify any defects during DNA replication or during Xenopus embryonic development in response to a non-degradable form of TDG. Additionally, I examined how interactions between \(CRL4^{Cdt2}\) and multiple subunits of the PCNA homotrimer contribute to \(CRL4^{Cdt2}\) function. In a popular model, PCNA functions as a "tool belt" on DNA, binding three separate proteins through its individual subunits to facilitate rapid exchange of DNA replication and repair proteins as they are needed on DNA. To address this model, I generated a single chain polypeptide with three PCNA subunits connected through flexible linker sequences. I used this tool to determine how multiple PCNA subunits contribute to \(CRL4^{Cdt2}\) function. I found that a single wildtype subunit is sufficient for modest destruction of the \(CRL4^{Cdt2}\) substrate Cdt1, but complete Cdt1 destruction requires two separate wildtype subunits. Additionally, a single subunit was sufficient for leading strand elongation, challenging the "tool belt" model during DNA replication. I also discuss implications and future use of the single-chain PCNA.
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INVESTIGATION OF THE ROLE OF OXIDATIVE DNA DAMAGE IN AFLATOXIN B1-INDUCED PULMONARY CARCINOGENESISGuindon, Katherine 16 December 2008 (has links)
Studies described in this thesis were aimed at characterizing the mechanism(s) of aflatoxin B1 (AFB1) pulmonary carcinogenesis by addressing the formation, prevention, and repair of AFB1-induced oxidative DNA damage.
The ability of AFB1 to cause oxidative DNA damage in different lung cell types of the A/J mouse was examined. The formation of 8-hydroxy-2’-deoxyguanosine (8-OHdG) in freshly isolated mouse lung alveolar macrophages, alveolar type II cells, and nonciliated bronchial epithelial (Clara) cells, was assessed by high performance liquid chromatography with electrochemical detection. An increase in 8-OHdG formation occurred in macrophage and Clara cell preparations isolated from A/J mice two hours following in vivo treatment with a single tumourigenic dose of AFB1. Prior treatment with polyethylene glycol-conjugated catalase (PEG-CAT) prevented the AFB1-induced increase in 8-OHdG levels in all mouse lung cell preparations. These results support the possibility that oxidative DNA damage in mouse lung cells contributes to AFB1 carcinogenicity.
Mouse lung tumourigenesis was assessed following treatment of A/J mice with PEG-CAT and/or AFB1. Unexpectedly, the mean number of tumours per mouse and tumour size in the PEG-CAT + AFB1 group were greater than those of the group treated with AFB1 alone. There was no difference in K-ras exon 1 mutation spectrum or in the histological diagnosis of tumours between treatment groups. In vitro incubation with mouse liver catalase (CAT) resulted in conversion of [3H]AFB1 into a DNA-binding species, a possible explanation for the results observed in vivo. These results demonstrate that PEG-CAT is not protective against AFB1 carcinogenicity in mouse lung despite preventing DNA oxidation.
The effect of in vivo treatment of mice with AFB1 on pulmonary and hepatic base excision repair (BER) activities and levels of 8-oxoguanine DNA glycosylase (OGG1) was investigated. AFB1 treatment increased 8-OHdG levels and BER activity in mouse lung, but did not significantly affect either in liver. Levels of OGG1 immunoreactive protein were increased in both mouse lung and liver. These results indicate that oxidative DNA damage may be an important mechanism in the carcinogenicity of AFB1. However, BER activity is increased by AFB1 treatment, possibly representing a compensatory response to the production of oxidative DNA damage. / Thesis (Ph.D, Pharmacology & Toxicology) -- Queen's University, 2008-12-12 10:00:44.81
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Determinants of silver nanoparticle toxicityPromtong, Pawika January 2015 (has links)
Silver nanoparticles (AgNPs) containing consumer products have increasingly emerged in the market because of their potential antibacterial property, which might result in increased human exposure and environmental contamination. AgNPs are toxic to mammalian and other cells but the determinants of this toxicity remain to be fully characterised and the potential impact of DNA repair systems has been poorly explored. This study, therefore, examined to what extent the size and shape of synthesised AgNPs determined AgNP toxicity in DNA repair proficient and deficient (8-oxoguanine DNAglycosylase; WT and OGG1-/-, respectively) mouse embryonic fibroblasts (MEFs) as well as a well-known human cell line used in the toxicity testing, HepG2 cells. Citrate-stabilised spherical- and triangular-shaped AgNPs (S-AgNPs andT-AgNPs, respectively) were synthesised chemically from AgNO3 using combinations of NaBH4 and sodium citrate as a reducing and stabilising agent, respectively, and purified by dialysis. Three different sized S-AgNPs were prepared with diameters of 7.6 ± 1.2, 14.3 ± 4.2, and 52.5 ± 17.9 nm as measured using transmission electron microscope (TEM), and their zeta potentials were -36.1±2.7, -39.5±2.7 and -36.7±4.1 mV, respectively. T-AgNPs had an edge length and thickness of 71.4 ± 11.1 nm and 5.7 ± 0.8 nm, respectively. The size and zeta potential of the purified AgNPs were constant in distilled water for at least 6 months. The uptake of both S- and T-AgNPs by cells resulted in a time and dose-dependent increase in the number of cellular AgNPs and the amount of Ag+ released intracellularly. These increases were associated with a decrease in cell viability (as measured using the MTT assay) and cell survival (the clonogenic assay), and an induction in ROS generation (the DCF assay) and DNA damage(the alkaline Comet assay) for all three cell lines. AgNPs were observed in cells using TEM, suggesting the uptake of AgNPs via an endocytosis pathway. Results suggested that an increase in cellular AgNP level and intracellular released Ag+ content were associated with a time and dose-dependent toxicity. Interestingly, cellular AgNP level and intracellular released Ag+ content might play an important role in size-dependent AgNP toxicity, in which exposure to the smaller S-AgNP sizes (7nm and 14nm) resulted in higher levels of both cellular AgNPs and Ag+ released intracellularly, and then to increased toxicity when compared with the larger S-AgNP size (50nm). Moreover, different shaped AgNPs might induce toxicity by different mechanisms: ROS-mediated toxicity might be induced by both 70nm T-AgNPs and 50nm S-AgNPs and 70nm T-AgNPs might also induce cell membrane damage. AgNP-induced toxicity was different in different cell lines with HepG2 cells being more sensitive to AgNPs particularly using the clonogenic assay, and this toxicity was associated with higher DNA damage observed in HepG2 cells after 24 h. OGG1-/- MEFs were more sensitive to intracellular released Ag+, leading to higher ROS formation and DNA damage in OGG1-/- MEFs than that observed in WT MEFs. In summary, this study strongly suggests that AgNPs induce toxicity via a Trojan-horse type mechanism, and not only Ag+ released intracellularly but also cellular AgNPs take part in this toxicity, and will eventually result in the biological responses of the cells.
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Inhibition of Human Melonoma Cell Proliferation Using Small Molecule Uracil-DNA Glycosylase InhibitorsXiao, Mei, Zhu, Bi Ke, Yu, Lin Jiang 01 March 2008 (has links)
Four known small molecule uracil-DNA glycosylase (UNG) inhibitors were synthesized and tested against human melanoma cells, IgR3 and MM200. They were found to be effective against cell proliferation at micromolar concentrations and to operate through a nonapoptotic mechanism. Thus, small molecules that target UNG may be useful as potential chemotherapeutic agents against human melanoma.
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Elucidating a role for uracil DNA glycosylase (UNG)-initiated DNA base excision repair in the cellular sensitivity to the antifolate, pemetrexedWeeks, Lachelle Dawn 21 February 2014 (has links)
No description available.
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Contribution de la forme nucléaire de l'uracile DNA glycosylase aux étapes précoces du cycle de réplication du virus de l'immunodéficience humaine de type 1 / Contribution of the nuclear form of the uracil DNA glycosylase during early steps of HIV-1 replication cycleHérate, Cécile 06 July 2015 (has links)
La protéine auxiliaire Vpr du VIH-1 est exprimée tardivement au cours de la réplication virale. Toutefois, du fait de son encapsidation dans les particules virales, elle joue un rôle important dès les étapes initiales du cycle de réplication viral. Cette protéine de 96 acides aminés intervient en effet au cours de la rétrotranscription du génome viral puis de la translocation de l’ADN viral vers le noyau de la cellule hôte. Parallèlement, elle provoque un arrêt du cycle cellulaire et l’apoptose des lymphocytes T infectés. Alors qu’il a été établi que Vpr participait au contrôle de la fidélité de la rétrotranscription via le recrutement au sein des particules virales de l’uracile DNA glycosylase 2 (UNG2), enzyme impliquée dans les processus de réparation de l’ADN, certaines études ont ensuite remis en question l’impact positif de l’encapsidation de l’UNG2 sur la réplication virale. Les travaux présentés ici permettent de confirmer le rôle de l’UNG2 dans le contrôle du taux de mutations au sein de l’ADN synthétisé à partir de l'ARN viral par un mécanisme indépendant de son activité enzymatique, mais lié à des déterminants situés dans la partie N-terminale de la protéine engagée dans le recrutement de la sous-unité p32 du complexe RPA (Replication protein A) (RPA32). Nous avons montré, dans un premier temps, que la production de virus dans des cellules dont les niveaux d'expression de l'UNG2 et de RPA32 étaient diminués se traduisait par une réduction significative du pouvoir infectieux des particules virales et de la synthèse de l’ADN viral. Nous avons ensuite montré que la protéine Vpr est capable de former un complexe tri-moléculaire avec les protéines UNG2 et RPA32, et confirmé l’importance de ces deux protéines cellulaires pour permettre une réplication virale optimale aussi bien dans des lignées cellulaires T que dans les cellules primaires cibles du VIH-1. Même si les macrophages et les PBMCs (cellules mononucléaires du sang périphérique), cellules cibles du VIH-1, expriment des niveaux faibles d’UNG2 et de RPA32, ces protéines cellulaires semblent requises pour permettre une synthèse d'ADN virale suffisante à la réplication optimale du virus dans ces cellules primaires. L’ensemble de ces résultats suggère que le contrôle de la rétrotranscription par Vpr a lieu via le recrutement de deux protéines cellulaires UNG2 et RPA32 permettant la dissémination efficace du VIH-1 dans les cellules cibles primaires. / The HIV-1 auxiliary protein Vpr is expressed during the late steps of the viral replication. However, Vpr is incorporated into HIV-1 viral particles and plays a key role during the initial steps of the viral replication cycle. This 96 amino acids protein is involved in viral genome reverse transcription as well as in viral DNA translocation into the nucleus of the host cell. In parallel, Vpr provokes cell cycle arrest and apoptosis of infected T cells. Previously, it has been well established that Vpr participates in the control of the fidelity of the reverse transcription through the recruitment of the Uracil DNA Glycosylase 2 (UNG2) into the viral particles. UNG2 is an enzyme involved in different DNA repair pathway. However some studies have challenged the positive impact of UNG2 encapsidation for HIV-1 replication. Here, our studies confirm the important role of UNG2 for the control of the mutation rate in the newly synthesized viral DNA by a mechanism independent of its enzymatic activity but dependent to determinants located in the N-terminal domain that is involved in the recruitment of the p32 subunit of the RPA (Replication Protein A) complex (RPA32). First we showed that viruses produced in UNG2 or RPA32 depleted cells present a defect of infectivity and that the reverse transcription step is impaired during the course of infection of these viruses. Then we reported that the Vpr protein is able to form a trimolecular complex with UNG2 and RPA32 and we confirmed the importance of both UNG2 and RPA32 for optimal virus replication in a T cell line as well as in HIV-1 primary target cells. Even though macrophages and PBMCs (Peripheral Blood Mononuclear Cells), target cells of HIV-1, express low level of UNG2 and RPA32, these cellular proteins seem to be required for an efficient viral DNA synthesis leading to an optimal virus replication in primary cells. All these results suggest that Vpr controls the reverse transcription step through the recruitment of two cellular proteins UNG2 and RPA32 which allow the efficient dissemination of HIV-1 in the primary target cells.
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Contribution de la forme nucléaire de l'uracile DNA glycosylase aux étapes précoces du cycle de réplication du virus de l'immunodéficience humaine de type 1 / Contribution of the nuclear form of the uracil DNA glycosylase during early steps of HIV-1 replication cycleHérate, Cécile 06 July 2015 (has links)
La protéine auxiliaire Vpr du VIH-1 est exprimée tardivement au cours de la réplication virale. Toutefois, du fait de son encapsidation dans les particules virales, elle joue un rôle important dès les étapes initiales du cycle de réplication viral. Cette protéine de 96 acides aminés intervient en effet au cours de la rétrotranscription du génome viral puis de la translocation de l’ADN viral vers le noyau de la cellule hôte. Parallèlement, elle provoque un arrêt du cycle cellulaire et l’apoptose des lymphocytes T infectés. Alors qu’il a été établi que Vpr participait au contrôle de la fidélité de la rétrotranscription via le recrutement au sein des particules virales de l’uracile DNA glycosylase 2 (UNG2), enzyme impliquée dans les processus de réparation de l’ADN, certaines études ont ensuite remis en question l’impact positif de l’encapsidation de l’UNG2 sur la réplication virale. Les travaux présentés ici permettent de confirmer le rôle de l’UNG2 dans le contrôle du taux de mutations au sein de l’ADN synthétisé à partir de l'ARN viral par un mécanisme indépendant de son activité enzymatique, mais lié à des déterminants situés dans la partie N-terminale de la protéine engagée dans le recrutement de la sous-unité p32 du complexe RPA (Replication protein A) (RPA32). Nous avons montré, dans un premier temps, que la production de virus dans des cellules dont les niveaux d'expression de l'UNG2 et de RPA32 étaient diminués se traduisait par une réduction significative du pouvoir infectieux des particules virales et de la synthèse de l’ADN viral. Nous avons ensuite montré que la protéine Vpr est capable de former un complexe tri-moléculaire avec les protéines UNG2 et RPA32, et confirmé l’importance de ces deux protéines cellulaires pour permettre une réplication virale optimale aussi bien dans des lignées cellulaires T que dans les cellules primaires cibles du VIH-1. Même si les macrophages et les PBMCs (cellules mononucléaires du sang périphérique), cellules cibles du VIH-1, expriment des niveaux faibles d’UNG2 et de RPA32, ces protéines cellulaires semblent requises pour permettre une synthèse d'ADN virale suffisante à la réplication optimale du virus dans ces cellules primaires. L’ensemble de ces résultats suggère que le contrôle de la rétrotranscription par Vpr a lieu via le recrutement de deux protéines cellulaires UNG2 et RPA32 permettant la dissémination efficace du VIH-1 dans les cellules cibles primaires. / The HIV-1 auxiliary protein Vpr is expressed during the late steps of the viral replication. However, Vpr is incorporated into HIV-1 viral particles and plays a key role during the initial steps of the viral replication cycle. This 96 amino acids protein is involved in viral genome reverse transcription as well as in viral DNA translocation into the nucleus of the host cell. In parallel, Vpr provokes cell cycle arrest and apoptosis of infected T cells. Previously, it has been well established that Vpr participates in the control of the fidelity of the reverse transcription through the recruitment of the Uracil DNA Glycosylase 2 (UNG2) into the viral particles. UNG2 is an enzyme involved in different DNA repair pathway. However some studies have challenged the positive impact of UNG2 encapsidation for HIV-1 replication. Here, our studies confirm the important role of UNG2 for the control of the mutation rate in the newly synthesized viral DNA by a mechanism independent of its enzymatic activity but dependent to determinants located in the N-terminal domain that is involved in the recruitment of the p32 subunit of the RPA (Replication Protein A) complex (RPA32). First we showed that viruses produced in UNG2 or RPA32 depleted cells present a defect of infectivity and that the reverse transcription step is impaired during the course of infection of these viruses. Then we reported that the Vpr protein is able to form a trimolecular complex with UNG2 and RPA32 and we confirmed the importance of both UNG2 and RPA32 for optimal virus replication in a T cell line as well as in HIV-1 primary target cells. Even though macrophages and PBMCs (Peripheral Blood Mononuclear Cells), target cells of HIV-1, express low level of UNG2 and RPA32, these cellular proteins seem to be required for an efficient viral DNA synthesis leading to an optimal virus replication in primary cells. All these results suggest that Vpr controls the reverse transcription step through the recruitment of two cellular proteins UNG2 and RPA32 which allow the efficient dissemination of HIV-1 in the primary target cells.
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