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Effect of the Constitutive Nitric Oxide Synthase and Peroxynitrite in DNA Damage and Autophagy Response after UVB Irradiation on KeratinocytesBahamondes Lorca, Veronica Andrea 25 May 2021 (has links)
No description available.
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Reca Dynamics & the SOS Response in Escherichia Coli: Cellular Limitation of Inducing FilamentsMassoni, Shawn Christopher 01 February 2013 (has links)
During the course of normal DNA replication, replication forks are constantly encountering "housekeeping" types of routine damage to the DNA template that may cause the forks to stall or collapse. One product of this fork collapse is the induction of the SOS response, a coordinated global response to help pause the growth and replication of a cell while DNA damage is addressed and repaired. In E. coli, this response is activated by the formation of ssDNA, to which the RecA protein binds and forms a nucleoprotein filament, which acts as the activator for autocleavage of the LexA transcriptional repressor, which normally represses expression of SOS genes. Damage responses are crucial to maintaining genomic integrity, and are therefore essential to all forms of life, and this type of regulatory system is highly conserved. However, cells have mechanisms for tightly regulating induction of these responses, and can often repair routine damage to their chromosomes without the need to induce SOS. This is chiefly evidenced by the observation that more than 20% of cells in a population have RecA filaments, but less than 1% are induced for SOS. How cells make this decision to induce SOS is the subject of this work.
This dissertation describes three projects aimed at examining molecular mechanisms by which cells regulate RecA filaments, and therefore the decision to induce the SOS response. The first examines the disparity between the formation of RecA filaments, as evidenced by RecA-GFP foci, and the induction of SOS in the absence of damage, using a psulA-gfp reporter system. It is shown that there are three independent factors that repress SOS expression in undamaged E. coli cells. These are radA, the amount of recA in the cell, and in some circumstances recX. The first two limit SOS in wild type cells in the absence of external damage, while the third is an additional factor required in xthA mutants, likely due to the fact there are more RecA loading events in these mutants. These factors are thought to change the character and reduce the half-life and persistence of RecA filaments in the cell.
The second project shows that suppression of SOS through the use of recA4162 and uvrD303 mutants is substrate and situation-specific. This specificity is demonstrated by the fact that, while both recA4162 and uvrD303 can suppress SOS in the SOS constitutive mutant recA730, recA4162 can only suppress SOS when the signal occurs at replication forks and not at any other place on the chromosome, while uvrD303 appears to suppress SOS with less specificity, and can suppress after UV (shown previously), at induced DSBs, and other places not directly at the replication fork. Here mutants of different replication factors are used that uncouple the replisome and induce SOS to a high degree.
The third project determines the factors necessary for loading RecA filaments at the replication fork versus other locations on the chromosome when SOS is induced in the absence of damage, and helps elucidate further mechanisms for induction of SOS at these substrates. It is shown that the sbcB and recJ exonucleases assist in inappropriate RecA filament formation by substrate processing exclusively at replication forks, but not other substrates, likely through mechanisms that are reliant on the activities of the RecA loading factors RecBCD and RecFOR.
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Modelling the hair follicle dermal papilla using spheroid cell cultures.Schallreuter, Karin U., Salem, Mohamed M.A. 07 1900 (has links)
No / Vitiligo occurs in Northern Europe in one of 200 people. The disease can cause significant psychological stress for the affected individual. These patients generate and accumulate massive amounts of H2O2- and peroxynitrite in the epidermal compartment. Consequently many proteins are oxidized or nitrated, leading in turn to partial or complete loss of functionality. Moreover, presence of DNA damage in the skin as well as in plasma has been shown, while apoptosis is not enhanced. Induction of DNA repair is associated with up-regulated functioning p53 protein. Considering possible genetic predisposition and /or spontaneous mutations, autoimmune reactions in the disease are put forward in the context of oxidative stress. In addition a review of recent and novel treatment modalities including the role of oxidative stress reduction and combined climatotherapy at the Dead Sea in a group are discussed.
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DNA damage in lymphocytes from healthy individuals and respiratory disease patients, treated ex vivo/in vitro with aspirin and ibuprofen nanoparticles compared to their bulk formsAnderson, Diana, Najafzadeh, Mojgan, Ali, Aftab H.M., Jacobe, B., Isreb, Mohammad, Gopalan, Rajendran C., Shang, Lijun January 2014 (has links)
Yes / Conference abstract
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An evaluation of DNA damage in human lymphocytes and sperm exposed to methyl methanesulfonate involving the regulation pathways associated with apoptosisHabas, Khaled S.A., Najafzadeh, Mojgan, Baumgartner, Adolf, Brinkworth, Martin H., Anderson, Diana 23 June 2017 (has links)
Yes / Exposure to DNA-damaging agents produces a range of stress-related responses. These change the expression of genes leading to mutations that cause cell cycle arrest, induction of apoptosis and cancer. We have examined the contribution of haploid and diploid DNA damage and genes involved in the regulation of the apoptotic process associated with exposure, The Comet assay was used to detect DNA damage and quantitative RT-PCR analysis (qPCR) to detect gene expression changes in lymphocytes and sperm in response to methyl methanesulfonate. In the Comet assay, cells were administered 0–1.2 mM of MMS at 37 °C for 30 min for lymphocytes and 32 °C for 60 min for sperm to obtain optimal survival for both cell types. In the Comet assay a significant increase in Olive tail moment (OTM) and % tail DNA indicated DNA damage at increasing concentrations compared to the control group. In the qPCR study, cells were treated for 4 h, and RNA was isolated at the end of the treatment. qPCR analysis of genes associated with DNA stress responses showed that TP53 and CDKN1A are upregulated, while BCL2 is downregulated compared with the control. Thus, MMS caused DNA damage in lymphocytes at increasing concentrations, but appeared not to have the same effect in sperm at the low concentrations. These results indicate that exposure to MMS increased DNA damage and triggered the apoptotic response by activating TP53, CDKN1A and BCL2. These findings of the processing of DNA damage in human lymphocytes and sperm should be taken into account when genotoxic alterations in both cell types are produced when monitoring human exposure. / Libyan Government
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TiO2 NPs induce DNA damage in lymphocytes from healthy individuals and patients with respiratory diseases-An Ex vivo/In vitro StudyOsman, Ilham F., Najafzadeh, Mojgan, Sharma, Vyom, Shukla, Ritesh K, Jacob, B.K., Dhawan, A., Anderson, Diana 01 January 2018 (has links)
No / Nanotechnology has preceded nanotoxicology and little is known of the effects of nanoparticles in human systems, let alone in diseased individuals. Therefore, the effects of titanium dioxide (TiO2) nanoparticles in peripheral blood lymphocytes from patients with respiratory diseases [lung cancer, chronic obstructive pulmonary disease (COPD) and asthma] were compared with those in healthy Individuals, to determine differences in sensitivity to nanochemical insult. The Comet assay was performed according to recommended guidelines. The micronucleus assay and ras oncoprotein detection were conducted according to published standard methods. The results showed statistically significant concentration-dependent genotoxic effects of TiO2 NPs in both respiratory patient and control groups in the Comet assay. The TiO2 NPs caused DNA damage in a concentration dependent manner in both groups (respiratory and healthy controls) with the exception of the lowest TiO2 concentration (10 µg/ml) which did not induce significant damage in healthy controls (ns). When OTM data were used to compare the whole patient group and the control group, the patient group had more DNA damage (p > 0.001) with the exception of 10 µg/ml of TiO2 that caused less significant damage to patient lymphocytes (p < 0.05). Similarly, there was an increase in the pattern of cytogenetic damage measured in the MN assay without statistical significance except when compared to the negative control of healthy individuals. Furthermore, when modulation of ras p21 expression was investigated, regardless of TiO2 treatment, only lung cancer and COPD patients expressed measurable ras p21 levels. All results were achieved in the absence of cytotoxicity.
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Identification and Validation of ERK5 as a DNA Damage Modulating Drug Target in GlioblastomaCarmell, N., Rominiyi, O., Myers, K.N., McGarrity-Cottrell, C., Vanderlinden, A., Lad, N., Perroux-David, E., El-Khamisy, Sherif, Fernando, M., Finegan, K.G., Brown, S., Collis, S.J. 01 November 2023 (has links)
Yes / Brain tumours kill more children and adults under 40 than any other cancer, with approximately half of primary brain tumours being diagnosed as high-grade malignancies known as glioblastomas. Despite de-bulking surgery combined with chemo-/radiotherapy regimens, the mean survival for these patients is only around 15 months, with less than 10% surviving over 5 years. This dismal prognosis highlights the urgent need to develop novel agents to improve the treatment of these tumours. To address this need, we carried out a human kinome siRNA screen to identify potential drug targets that augment the effectiveness of temozolomide (TMZ)-the standard-of-care chemotherapeutic agent used to treat glioblastoma. From this we identified ERK5/MAPK7, which we subsequently validated using a range of siRNA and small molecule inhibitors within a panel of glioma cells. Mechanistically, we find that ERK5 promotes efficient repair of TMZ-induced DNA lesions to confer cell survival and clonogenic capacity. Finally, using several glioblastoma patient cohorts we provide target validation data for ERK5 as a novel drug target, revealing that heightened ERK5 expression at both the mRNA and protein level is associated with increased tumour grade and poorer patient survival. Collectively, these findings provide a foundation to develop clinically effective ERK5 targeting strategies in glioblastomas and establish much-needed enhancement of the therapeutic repertoire used to treat this currently incurable disease.
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CORM-3 induces DNA damage through Ru(II) binding to DNALyon, R.F., Southam, H.M., Trevitt, C.R., Liao, C., El-Khamisy, Sherif, Poole, R.K., Williamson, M.P. 01 November 2023 (has links)
Yes / When the 'CO-releasing molecule-3', CORM-3 (Ru(CO)3Cl(glycinate)), is dissolved in water it forms a range of ruthenium complexes. These are taken up by cells and bind to intracellular ligands, notably thiols such as cysteine and glutathione, where the Ru(II) reaches high intracellular concentrations. Here, we show that the Ru(II) ion also binds to DNA, at exposed guanosine N7 positions. It therefore has a similar cellular target to the anticancer drug cisplatin, but not identical, because Ru(II) shows no evidence of forming intramolecular crossbridges in the DNA. The reaction is slow, and with excess Ru, intermolecular DNA crossbridges are formed. The addition of CORM-3 to human colorectal cancer cells leads to strand breaks in the DNA, as assessed by the alkaline comet assay. DNA damage is inhibited by growth media containing amino acids, which bind to extracellular Ru and prevent its entry into cells. We conclude that the cytotoxicity of Ru(II) is different from that of platinum, making it a promising development target for cancer therapeutics.
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DNA damage responses to loss of telomere integrityCarlos, A. R. January 2013 (has links)
Linear genomes end in characteristic structures consisting of repetitive DNA and proteins: the telomeres. These play two critical roles: on one hand they avoid the of loss of genetic information due to the incomplete replication of the chromosome ends and on the other, they provide capping structures for chromosome termini, differentiating them from double strand breaks. Telomeres contain specialized proteins (the shelterin complex), as well as proteins present elsewhere on the chromosomes (chromatin remodelling, DNA damage repair and response factors). Interestingly, several DNA damage factors are required for proper telomere maintenance, drawing a thin line between telomere protection and their recognition as broken DNA ends. Loss of telomere integrity has severe consequences for the cell, namely it can induce replicative senescence and cellular aging, or it can contribute to tumorigenesis. How telomeres are capped and how they are perceived by the cell when they become dysfunctional is essential for our understanding of the contribution of loss of telomere integrity to aging and disease. In order to unravel new factors involved in telomere maintenance, siRNA screens were performed. The optimization process has confirmed both telomeric foci and telomere dysfunction-induced foci (TIFs) as suitable readouts and the screens performed generated a list of potential candidate genes involved in telomere biology. Although some of the candidate genes tested in this work failed the validation process, other genes deserve further analysis. In addition this work also studied the role of several DNA damage factors at uncapped telomeres. Furthermore, BRCA1, CtIP and EXO1 were found to be critical for the formation of end-to-end fusions generated after TRF2 inactivation. The requirement of this proteins in this process, suggests that not only that not only the classical non-homologous end joining (C-NHEJ) pathway is active at TRF2-depelted telomeres, but emphasises the multiplicity of mechanisms that act to repair dysfunctional telomeres.
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Hypoxia-induced chromatin changes and ATM signallingOlcina del Molino, Mónica January 2014 (has links)
The DNA damage response (DDR) is a complex signalling cascade triggered in response to stress, in an attempt to maintain genomic integrity. Components of this pathway, such as ATM-mediated signalling, have been proposed to act as a barrier in the early stages of tumourigenesis. Regions of low oxygen concentrations (hypoxia) occur in most solid tumours and are associated with a poor prognostic outcome. Here, we investigated the DDR induced following hypoxia-induced replication stress in an attempt to decipher the mechanism of ATM activation in response to physiological stresses that do not induce DNA damage. We hypothesized that hypoxia-mediated chromatin changes could impact on ATM signalling. We have characterised H3 methylation in response to hypoxia and found oxygen dependent changes in H3K9me3, including both global and replication fork associated increases in this histone modification. Importantly, we have found that decreases in H3K9me3 result in loss or attenuation of ATM activation. Notably, in a background of replication stress and increased H3K9me3, ATM inhibition or loss leads to accumulation of DNA damage and a significant decrease in replication rates in hypoxia. We propose that when replication stress occurs in the presence of hypoxia-induced chromatin changes, ATM activation is facilitated by the induction of H3K9me3. In this context, we propose a novel and stress specific role for ATM-mediated signalling in maintaining replication and preventing the generation of DNA breaks that may compromise genomic integrity. Moreover, the biological consequences of the hypoxia-induced chromatin context and in particular hypoxia-induced H3K9me3 include the repression of APAK, a negative regulator of p53. Activation of p53 is a key consequence of the hypoxia-induced DDR. Here we found that SETDB1, one of the H3 methyltransferases induced by hypoxia, mediates APAK repression. We propose that H3K9me3 plays a role in regulating APAK expression to allow optimal induction of p53 dependent apoptosis in hypoxic conditions suggesting a further role for H3K9me3 in facilitating DDR signalling in hypoxia. Together, these data suggest that the hypoxic chromatin context is critical for the role of the DDR as a barrier to tumourigenesis and predict that altering the chromatin landscape in combination with DNA damaging therapies would be efficacious in the treatment of hypoxic tumours.
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