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Functions of TRF2: From Telomere Protection to DNA Damage Signaling and Vascular RemodelingKhan, Sheik Jamaludin 18 June 2008 (has links)
TTAGGG repeat factor 2 (TRF2) is a protein that plays an important role in capping telomere ends from DNA damage responses. Telomere DNA consists of double strand repeats of the TTAGGG sequence ending with a 3'single-stranded overhang of the guanine strand (the G-strand overhang). TRF2 protects telomeres from being recognized as double-stranded breaks. It is thought that this protection is performed through the formation of T-loop structures and recruitment of proteins into a complex called shelterin. The exact mechanism of T-loop formation is unknown. I show with in vitro biochemical studies that TRF2 specifically interacts with telomeric ss/ds DNA junctions and binding is sensitive to the sequence of the G-strand overhang and double-stranded DNA sequence at the junction. Binding assays with TRF2 truncation mutants suggest that TRF2 interacts with both the double-stranded DNA through the C-terminal DNA binding domain and the G-strand overhang through the N-terminus. Mobility shifts and atomic force microscopy with truncation mutants bound to telomeric DNA also show that a previously uncharacterized "linker" region within TRF2 is involved in DNA-specific TRF2 oligomerization. From these observations, I suggest that TRF2 forms protective loops by oligomerizing through both a previously characterized dimerization domain and the linker region. I propose that loop formation involving the telomere ends is accomplished through direct interactions between TRF2 and the G-strand overhang. In addition to DNA protection, a new role has emerged for TRF2 in sensing DNA damage. TRF2 can be phosphorylated within its dimerization domain by ATM and recruited to DNA damage foci in cells. The inhibition of TRF2 function alone has been shown to induce senescence and apoptosis in vascular endothelial cells. Since the common stimuli for a senescence phenotype is activation of a DNA damage response, I studied the relationship between DNA damage and TRF2 phosphorylation. Ex-vivo characterization of DNA damage-induced changes in vascular smooth muscle cells (VSMC) was undertaken. VSMC treated with H202 induced an increase in reactive oxygen species (ROS), and 8-oxo-guanine accumulation resulting in cell cycle arrest, chromatin condensation and a senescent phenotype. Interestingly phosphorylated TRF2 and ATM were also up regulated. Balloon injury was used to test the connection between phosphorylated TRF2 and senescence during vascular remodeling in rat arteries. Vascular remodeling as judged by neointima formation was associated with accumulation of 8-oxo-guanine, DNA damage signaling, including phosphorylated TRF2, an increase in cell cycle inhibitors and senescence. These events were exaggerated in aged animals and are consistent with a role in telomere dysfunction, and age related diseases.
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Cave and cliff swallows as indicators of exposure and effects of environmental contaminants on birds from the Rio Grande, TexasMusquiz, Daniel 15 November 2004 (has links)
Cave (Petrochelidon fulva) and cliff swallows (Petrochelidon pyrrhonota) were collected along the Rio Grande and evaluated as potential indicators of environmental contamination. The Rio Grande receives toxic substances from agricultural, industrial, municipal, and non-point sources; consequently, high levels of contaminants have been detected in birds, mammals, fishes and sediments. Swallows were obtained from 8 sites between Brownsville and El Paso, as well as from a reference site in Burleson County, 320 miles north of the nearest site of the Rio Grande. Blood samples were analyzed by flow cytometry, a technique that allows the detection of DNA damage in blood and other tissues. Plasma samples were analyzed for thyroid hormones using a radioimmunoassay technique. Organochlorines and trace metal analysis was limited to a few samples. DDE and PCB levels were below levels known to cause reduced hatching, embryo mortality, and deformities, Hg, Pb, and As were below detection, and Se, Ni and Cr concentrations were lower than levels known to cause harm in birds. Neither species showed sex-related differences in chromosome damage. Cave swallows from the Del Rio area had the highest levels of DNA variation, which may be indicative of DNA damage, possibly from PAHs exposure. Previous studies indicate that sediment samples from tributaries near Del Rio have high levels of chromium compared to other sites along the Rio Grande. A significant increase in DNA variation between sampling years was detected in cave swallows from Llano Grande Lake. Wildlife samples collected from Llano Grande Lake have recorded high levels of DDE and PCBs; in addition, this urban/agricultural contaminant sink appears to be affected by PAH exposure. T3 levels were below the detection limit of the radioimmunoassay. There were no gender related differences in T4 levels in cave swallows. Cave swallows sampled from Laredo had significantly higher T4 levels than those from birds at other sites during 1999. It was not possible to determine thyroid hormone disruption in plasma samples. Thyroid hormone and flow cytometry data were useful in establishing baseline data. Areas of concern based on genotoxic data include Llano Grande Lake, Del Rio, and El Paso.
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Studies of DNA repair strategies in response to complex DNA damagesBajinskis, Ainars January 2012 (has links)
The main aim of this thesis was to study the role of the indirect actions of γ-rays and α-particles on the complexity of primary DNA damages and the repair fidelity of major DNA repair pathways: non-homologous end joining (NHEJ), homologous recombination repair (HRR) and base excision repair (BER). The complexity of radiation-induced damages increases and the proximity between damages decreases with increasing LET due to formation of ionization clusters along the particle track. The complexity of damages formed can be modified by the free radical scavenger dimethyl sulfoxide (DMSO). In addition, the effects of low doses of low dose rate γ-radiation on cellular response in terms of differentiation were investigated. Paper I investigates the role of the indirect effect of radiation on repair fidelity of HRR, NHEJ and BER when damages of different complexity were induced by radiation or by potassium bromate. We found that potassium bromate induces complex DNA damages through processing of base modifications and that the indirect effect of radiation has a high impact on the NHEJ pathway. Results in paper II confirmed our conclusions in paper I that the indirect effect from both γ-rays and α-particles has an impact on all three repair pathways studied and NHEJ benefits the most when the indirect effect of radiation is removed. In paper III we investigated the effects of low dose/dose rate γ-radiation on the developmental process of neural cells by using cell models for neurons and astrocytes. Our results suggest that low dose/dose rate γ-radiation attenuates differentiation and down-regulates proteins involved in the differentiation process of neural cells by an epigenetic rather than cytotoxic mechanism. / <p>At the time of doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p>
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Transcriptional Dynamics of the Eukaryotic CellBatenchuk, Cory 27 January 2011 (has links)
Gene regulatory networks are dynamic and continuously remodelled in response to internal and external stimuli. To understand how these networks alter cellular phenotype in response towards specific challenges, my first project sought to develop a methodology to explore how the strength of genetic interactions changes according to environmental context. Defined as sensitivity-based epistasis, the results obtained using this methodology were compared to those generated under the conventional fitness-based approach. By integrating this information with gene expression profiles and physical interaction datasets, we demonstrate that sensitivity-based epistasis specifically highlights genetic interactions with a dynamic component.
Having investigated how an external stimulus regulates network dynamics, we next sought to understand of how genome positioning impacts transcription kinetics. This feat was accomplished by cloning two gene-reporter constructs, representing contrasting promoter architectures, across 128 loci along chromosome III in S.Cerevisiae. By comparing expression and noise measurements for promoters with “covered” and “open” chromatin structures against a stochastic model for eukaryotic gene expression, we demonstrate that while promoter structure regulates burst frequency (the rate of promoter activation), positional effects in turn appear to primarily modulate burst size (the number of mRNA produced per gene activation event). By integrating these datasets with information describing global chromatin structure, we suggest that the acetylation state of chromatin regulates burst size across the genome. Interestingly, this hypothesis is further supported by nicotinamide-mediated inhibition of Sir2 which would appear to modulate burst size globally across the genome.
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Exploring DNA Damage Induced Foci and their Role in Coordinating the DNA Damage ResponseYeung, ManTek 31 August 2012 (has links)
DNA damage represents a major challenge to the faithful replication and transmission of genetic information from one generation to the next. Cells utilize a highly integrated network of pathways to detect and accurately repair DNA damage. Mutations arise when DNA damage persists undetected, unrepaired, or repaired improperly. Mutations are a driving force of carcinogenesis and therefore many of the DNA damage surveillance and repair mechanisms guard against the transformation of normal cells into cancer cells. Central to the detection and repair of DNA damage is the relocalization of DNA damage surveillance proteins to DNA damage where they assemble into subnuclear foci and are capable to producing a signal that the cell interprets to induce cellular modifications such as cycle arrest and DNA repair which are important DNA damage tolerance. In this work, I describe my quest to understand the mechanisms underlying the assembly, maintenance, and disassembly of these DNA damage-induced foci and how they affect DNA damage signaling in Saccharomyces cerevisiae. First, I describe phenotypic characterization of a novel mutation that impairs assembly of the 9-1-1 checkpoint clamp complex into foci. Second, I describe my work to further understand the roles of the histone phosphatase Pph3 and phosphorylated histone H2A in modulating DNA damage signaling. Third, I include my work to uncover the possible mechanism by which the helicase Srs2 works to enable termination of DNA damage signaling. In summary, this thesis documents my efforts to understand the cellular and molecular nature of DNA damage signaling and how signaling is turned off in coordination with DNA damage repair.
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DNA damage tolerance in mammalian cellsAndersen, Parker Lyng 17 September 2009
DNA is susceptible to both exogenous and endogenous damaging agents. Damage is constantly reversed by a wide range of DNA repair pathways. Lesions which escape such repair may cause nucleotide mis-pairing and stalled replication, resulting in mutagenesis and cell death, respectively if left unresolved. Stalled replication is particularly dangerous because replication fork collapse can lead to double-strand breaks (DSBs) and chromosome rearrangement, a hallmark of cancer. DNA damage tolerance (DDT) is defined as a mechanism that allows DNA synthesis to occur in the presence of replication-blocking lesions.<p>
DDT, also known as post-replication repair (PRR) in yeast, has been well characterized in the lower eukaryotic model Saccharomyces cerevisiae to consist of error-free and error-prone (mutagenic) pathways. Mono-ubiquitination of proliferating cell nuclear antigen (PCNA) by the Rad6-Rad18 complex promotes mutagenesis by recruiting low fidelity translesion synthesis (TLS) polymerases, while continual Lys63-linked poly-ubiquitination of PCNA by the Mms2-Ubc13-Rad5 complex promotes error-free lesion bypass. Since most of the genes involved in DNA metabolism are conserved within eukaryotes, from yeast to human, I tested the hypothesis that mammalian cells also possess two-pathway DDT in response to DNA damage. Namely, the error-free pathway is dependent on the Ubc13-Mms2 complex, while the error-prone pathway utilizes the TLS polymerases, such as Rev3.<p>
By utilizing cultured mammalain cells and producing antibodies against human Ubc13, Mms2 and Rev3, I was able to show that all three proteins associate with PCNA in S-phase cells, and that this association is enhanced following DNA damage. Ubc13-Mms2 association with PCNA was enhanced in response to DSBs. Furthermore, suppression of Ubc13 or Mms2 using interfering RNA technology resulted in increased spontaneous DSBs. In response to UV exposure, Rev3 co-localized with PCNA and two other TLS polymerases, Rev1 and Pol-Ø, at the damage site. UV-induced Rev3 nuclear focus formation was dependent on Rev1 but independent of Pol-£b. Surprisingly, over-expression of Pol-£b was sufficient to induce spontaneous Rev3 nuclear foci. It was further demonstrated that Rev1 and Pol-Ø were independently recruited to the damage site and did not require Rev3. These observations support and extend the polymerase switch model which regulates the activity of the replicative and TLS polymerases. Finally, simultaneous suppression of Rev3 along with Ubc13 or Mms2 resulted in a synergistic sensitivity to UV, whereas simultaneous suppression of Ubc13 and Pol-Ø resulted in an additive effect. These results are consistent with those in yeast cells, implying a comparable mammalian two-pathway DDT model.<p>
Additional interesting observations were made. Firstly, Ubc13 interacts with Uev1A, a close homolog of Mms2, which is involved in the NF-£eB signaling pathway independent of DNA damage. Secondly, Rev3 appears to be excluded from the nucleus in a fraction of low passage normal non-S-phase cells, whereas in tumor derived cell lines, Rev3 is consistently enriched in the nucleus independent of cell cycle stage. Finally, Rev3 is elevated during mitosis and associates with condensed chromosomes, suggesting a possible novel role in mitosis. Consistent with this notion, chronic ablation of Rev3 resulted in cell death with inappropriate chromosome segregations. The above preliminary observations require further investigation.
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Exploring DNA Damage Induced Foci and their Role in Coordinating the DNA Damage ResponseYeung, ManTek 31 August 2012 (has links)
DNA damage represents a major challenge to the faithful replication and transmission of genetic information from one generation to the next. Cells utilize a highly integrated network of pathways to detect and accurately repair DNA damage. Mutations arise when DNA damage persists undetected, unrepaired, or repaired improperly. Mutations are a driving force of carcinogenesis and therefore many of the DNA damage surveillance and repair mechanisms guard against the transformation of normal cells into cancer cells. Central to the detection and repair of DNA damage is the relocalization of DNA damage surveillance proteins to DNA damage where they assemble into subnuclear foci and are capable to producing a signal that the cell interprets to induce cellular modifications such as cycle arrest and DNA repair which are important DNA damage tolerance. In this work, I describe my quest to understand the mechanisms underlying the assembly, maintenance, and disassembly of these DNA damage-induced foci and how they affect DNA damage signaling in Saccharomyces cerevisiae. First, I describe phenotypic characterization of a novel mutation that impairs assembly of the 9-1-1 checkpoint clamp complex into foci. Second, I describe my work to further understand the roles of the histone phosphatase Pph3 and phosphorylated histone H2A in modulating DNA damage signaling. Third, I include my work to uncover the possible mechanism by which the helicase Srs2 works to enable termination of DNA damage signaling. In summary, this thesis documents my efforts to understand the cellular and molecular nature of DNA damage signaling and how signaling is turned off in coordination with DNA damage repair.
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Transcriptional Dynamics of the Eukaryotic CellBatenchuk, Cory 27 January 2011 (has links)
Gene regulatory networks are dynamic and continuously remodelled in response to internal and external stimuli. To understand how these networks alter cellular phenotype in response towards specific challenges, my first project sought to develop a methodology to explore how the strength of genetic interactions changes according to environmental context. Defined as sensitivity-based epistasis, the results obtained using this methodology were compared to those generated under the conventional fitness-based approach. By integrating this information with gene expression profiles and physical interaction datasets, we demonstrate that sensitivity-based epistasis specifically highlights genetic interactions with a dynamic component.
Having investigated how an external stimulus regulates network dynamics, we next sought to understand of how genome positioning impacts transcription kinetics. This feat was accomplished by cloning two gene-reporter constructs, representing contrasting promoter architectures, across 128 loci along chromosome III in S.Cerevisiae. By comparing expression and noise measurements for promoters with “covered” and “open” chromatin structures against a stochastic model for eukaryotic gene expression, we demonstrate that while promoter structure regulates burst frequency (the rate of promoter activation), positional effects in turn appear to primarily modulate burst size (the number of mRNA produced per gene activation event). By integrating these datasets with information describing global chromatin structure, we suggest that the acetylation state of chromatin regulates burst size across the genome. Interestingly, this hypothesis is further supported by nicotinamide-mediated inhibition of Sir2 which would appear to modulate burst size globally across the genome.
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DNA damage tolerance in mammalian cellsAndersen, Parker Lyng 17 September 2009 (has links)
DNA is susceptible to both exogenous and endogenous damaging agents. Damage is constantly reversed by a wide range of DNA repair pathways. Lesions which escape such repair may cause nucleotide mis-pairing and stalled replication, resulting in mutagenesis and cell death, respectively if left unresolved. Stalled replication is particularly dangerous because replication fork collapse can lead to double-strand breaks (DSBs) and chromosome rearrangement, a hallmark of cancer. DNA damage tolerance (DDT) is defined as a mechanism that allows DNA synthesis to occur in the presence of replication-blocking lesions.<p>
DDT, also known as post-replication repair (PRR) in yeast, has been well characterized in the lower eukaryotic model Saccharomyces cerevisiae to consist of error-free and error-prone (mutagenic) pathways. Mono-ubiquitination of proliferating cell nuclear antigen (PCNA) by the Rad6-Rad18 complex promotes mutagenesis by recruiting low fidelity translesion synthesis (TLS) polymerases, while continual Lys63-linked poly-ubiquitination of PCNA by the Mms2-Ubc13-Rad5 complex promotes error-free lesion bypass. Since most of the genes involved in DNA metabolism are conserved within eukaryotes, from yeast to human, I tested the hypothesis that mammalian cells also possess two-pathway DDT in response to DNA damage. Namely, the error-free pathway is dependent on the Ubc13-Mms2 complex, while the error-prone pathway utilizes the TLS polymerases, such as Rev3.<p>
By utilizing cultured mammalain cells and producing antibodies against human Ubc13, Mms2 and Rev3, I was able to show that all three proteins associate with PCNA in S-phase cells, and that this association is enhanced following DNA damage. Ubc13-Mms2 association with PCNA was enhanced in response to DSBs. Furthermore, suppression of Ubc13 or Mms2 using interfering RNA technology resulted in increased spontaneous DSBs. In response to UV exposure, Rev3 co-localized with PCNA and two other TLS polymerases, Rev1 and Pol-Ø, at the damage site. UV-induced Rev3 nuclear focus formation was dependent on Rev1 but independent of Pol-£b. Surprisingly, over-expression of Pol-£b was sufficient to induce spontaneous Rev3 nuclear foci. It was further demonstrated that Rev1 and Pol-Ø were independently recruited to the damage site and did not require Rev3. These observations support and extend the polymerase switch model which regulates the activity of the replicative and TLS polymerases. Finally, simultaneous suppression of Rev3 along with Ubc13 or Mms2 resulted in a synergistic sensitivity to UV, whereas simultaneous suppression of Ubc13 and Pol-Ø resulted in an additive effect. These results are consistent with those in yeast cells, implying a comparable mammalian two-pathway DDT model.<p>
Additional interesting observations were made. Firstly, Ubc13 interacts with Uev1A, a close homolog of Mms2, which is involved in the NF-£eB signaling pathway independent of DNA damage. Secondly, Rev3 appears to be excluded from the nucleus in a fraction of low passage normal non-S-phase cells, whereas in tumor derived cell lines, Rev3 is consistently enriched in the nucleus independent of cell cycle stage. Finally, Rev3 is elevated during mitosis and associates with condensed chromosomes, suggesting a possible novel role in mitosis. Consistent with this notion, chronic ablation of Rev3 resulted in cell death with inappropriate chromosome segregations. The above preliminary observations require further investigation.
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Cave and cliff swallows as indicators of exposure and effects of environmental contaminants on birds from the Rio Grande, TexasMusquiz, Daniel 15 November 2004 (has links)
Cave (Petrochelidon fulva) and cliff swallows (Petrochelidon pyrrhonota) were collected along the Rio Grande and evaluated as potential indicators of environmental contamination. The Rio Grande receives toxic substances from agricultural, industrial, municipal, and non-point sources; consequently, high levels of contaminants have been detected in birds, mammals, fishes and sediments. Swallows were obtained from 8 sites between Brownsville and El Paso, as well as from a reference site in Burleson County, 320 miles north of the nearest site of the Rio Grande. Blood samples were analyzed by flow cytometry, a technique that allows the detection of DNA damage in blood and other tissues. Plasma samples were analyzed for thyroid hormones using a radioimmunoassay technique. Organochlorines and trace metal analysis was limited to a few samples. DDE and PCB levels were below levels known to cause reduced hatching, embryo mortality, and deformities, Hg, Pb, and As were below detection, and Se, Ni and Cr concentrations were lower than levels known to cause harm in birds. Neither species showed sex-related differences in chromosome damage. Cave swallows from the Del Rio area had the highest levels of DNA variation, which may be indicative of DNA damage, possibly from PAHs exposure. Previous studies indicate that sediment samples from tributaries near Del Rio have high levels of chromium compared to other sites along the Rio Grande. A significant increase in DNA variation between sampling years was detected in cave swallows from Llano Grande Lake. Wildlife samples collected from Llano Grande Lake have recorded high levels of DDE and PCBs; in addition, this urban/agricultural contaminant sink appears to be affected by PAH exposure. T3 levels were below the detection limit of the radioimmunoassay. There were no gender related differences in T4 levels in cave swallows. Cave swallows sampled from Laredo had significantly higher T4 levels than those from birds at other sites during 1999. It was not possible to determine thyroid hormone disruption in plasma samples. Thyroid hormone and flow cytometry data were useful in establishing baseline data. Areas of concern based on genotoxic data include Llano Grande Lake, Del Rio, and El Paso.
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