Global ETD Search

191	Electrochemical control of reversible DNA hybridisation : for future use in nucleic acid amplification Syed, Shahida Nina January 2014 (has links) Denaturation and renaturation is indispensable for the biological function of nucleic acids in many cellular processes, such as for example transcription for the synthesis of RNA and DNA replication during cell division. However, the reversible hybridisation of complementary nucleic acids is equally crucial in nearly all molecular biology technologies, ranging from nucleic acid amplification technologies, such as the polymerase chain reaction, and DNA biosensors to next generation sequencing. For nucleic acid amplification technologies, controlled DNA denaturation and renaturation is particularly essential and achieved by cycling elevated temperatures. Although this is by far the most commonly used method, the management of rapid temperature changes requires bulky instrumentation and intense power supply. These factors so far precluded the development of true point-of-care tests for molecular diagnostics. This Thesis explored the possibility of using electrochemical means to control reversible DNA hybridisation by using electroactive intercalators. First, fluorescence-based melting curve analysis was employed to gain an in depth understanding of the reversible process of DNA hybridisation. Fundamental properties, such as stability of the double helix, were investigated by studying the effect of common denaturing agents, such as formamide and urea, pH and monovalent salt concentration. Thereafter, four different electroactive intercalators and their effect on the thermodynamic stability of duplex DNA were screened. The intercalators investigated were methylene blue, thionine, daunomycin and adriamycin. Absorbance-based melting curve analysis revealed a significant increase of the melting temperature of duplex DNA in the presence of oxidised daunomycin. This was not observed in the presence of chemically reduced daunomycin, which confirmed the hypothesis that switching of the redox-state of daunomycin altered its properties from DNA binding to non-binding. Accordingly this altered the thermodynamic stability of duplex DNA. The difference in the stability of duplex DNA, as a direct result of the redox-state of daunomycin, was exploited to drive cyclic electrochemically controlled DNA denaturation and renaturation under isothermal conditions. This proof-of-principle was demonstrated using complementary synthetic 20mer and 40mer DNA oligonucleotides. Analysis with in situ UV–vis and circular dichroism spectroelectrochemistry, as two independent techniques, indicated that up to 80 % of the duplex DNA was reversibly hybridised. Five cycles of DNA denaturation and renaturation were achieved and gel electrophoresis as well as NMR showed no degradation of DNA or daunomycin. As no extreme conditions were implicated, no covalent modification of DNA was required and isothermal conditions were kept, this finding has great potential to simplify future developments of miniaturised and portable bioanalytical systems for nucleic acid-based molecular diagnostics. 572.8
192	The role of Id-1 on the proliferation, motility and mitotic regulationof prostate epithelial cells Di, Kaijun., 狄凱軍. January 2007 (has links) published_or_final_version / abstract / Anatomy / Doctoral / Doctor of Philosophy Cell proliferation DNA-binding proteins. Epithelial cells. Mitosis. Prostate - Cancer - Genetic aspects. Carcinogenesis.
193	Investigating the molecular mechanisms of campomelic dysplasia in a mouse with a Sox9 gene mutation Au, Y. K., Tiffany. January 2007 (has links) published_or_final_version / abstract / Orthopaedics and Traumatology / Doctoral / Doctor of Philosophy Dysplasia. DNA-binding proteins. Gene expression. Molecular genetics. Mice as laboratory animals.
194	Helicase-SSB Interactions In Recombination-Dependent DNA Repair and Replication Jordan, Christian 01 January 2014 (has links) Dda, one of three helicases encoded by bacteriophage T4, has been well- characterized biochemically but its biological role remains unclear. It is thought to be involved in origin-dependent replication, recombination-dependent replication, anti- recombination, recombination repair, as well as in replication fork progression past template-bound nucleosomes and RNA polymerase. One of the proteins that most strongly interacts with Dda, Gp32, is the only single-stranded DNA binding protein (SSB) encoded by T4, is essential for DNA replication, recombination, and repair. Previous studies have shown that Gp32 is essential for Dda stimulation of replication fork progression. Our studies show that interactions between Dda and Gp32 play a critical role in regulating replication fork restart during recombination repair. When the leading strand polymerase stalls at a site of ssDNA damage and the lagging strand machinery continues, Gp32 binds the resulting ssDNA gap ahead of the stalled leading strand polymerase. We found that a Gp32 cluster on leading strand ssDNA blocks Dda loading on the lagging strand ssDNA, blocks stimulation of fork progression by Dda, and stimulates Dda to displace the stalled polymerase and the 3' end of the daughter strand. This unwinding generates conditions necessary for polymerase template switching in order to regress the DNA damage-stalled replication fork. Helicase trafficking by Gp32 could play a role in preventing premature fork progression until the events required for error-free translesion DNA synthesis have taken place. Interestingly, we found that Dda helicase activity is strongly stimulated by the N-terminal deletion mutant Gp32-B, suggesting the N-terminal truncation to generate Gp32-B reveals a cryptic helicase stimulatory activity of Gp32 that may be revealed in the context of a moving polymerase, or through direct interactions of Gp32 with other replisome components. Additionally, our findings support a role for Dda-Gp32 interactions in double strand break (DSB) repair by homology-directed repair (HDR), which relies on homologous recombination and the formation of a displacement loop (D-loop) that can initiate DNA synthesis. We examined the D-loop unwinding activity of Dda, Gp41, and UvsW, the D-loop strand extension activity of Gp43 polymerase, and the effect of the helicases and their modulators on D-loop extension. Dda and UvsW, but not Gp41, catalyze D-loop invading strand by DNA unwinding. The relationship between Dda and Gp43 was modulated by the presence of Gp32. Dda D-loop unwinding competes with D- loop extension by Gp43 only in the presence of Gp32, resulting in a decreased frequency of invading strand extension when all three proteins are present. These data suggest Dda functions as an antirecombinase and negatively regulates the replicative extension of D- loops. Invading strand extension is observed in the presence of Dda, indicating that invading strand extension and unwinding can occur in a coordinated manner. The result is a translocating D-loop, called bubble migration synthesis, a hallmark of break-induced repair (BIR) and synthesis dependent strand annealing (SDSA). Gp41 did not unwind D- loops studied and may serve as a secondary helicase loaded subsequent to D-loop processing by Dda. Dda is proposed to be a mixed function helicase that can work both as an antirecombinase and to promote recombination-dependent DNA synthesis, consistent with the notion that Dda stimulates branch migration. These results have implications on the repair of ssDNA damage, DSB repair, and replication fork regulation, which are highly conserved processes sustained in all organisms. DNA helicase recombination repair replication single-stranded DNA binding protein Biochemistry Molecular Biology
195	Exploring the Methylation Status of RAI1 and the RAI1 Consensus Binding Sequence Kamura, Eri 20 July 2009 (has links) Smith Magenis Syndrome (SMS) is a multiple congenital anomalies/ mental retardation disorder caused by deletion or mutation of the RAI1 gene on chromosome 17p11.2. The majority of patients with SMS phenotypes have a deletion or mutation of RAI1. However, some patients have been observed with SMS-like phenotypes and yet have no deletions or mutations in the RAI1 gene. One possible explanation could be aberrant methylation of RAI1 since RAI1 is present and yet may be silenced. In order to study this possibility, patient cell lines were treated with 5-Aza-2’-deoxycytidine. RNA was extracted and real-time PCR was used to check the RAI1 expression status on the cells. RAI1 is thought to be a transcription factor, but the DNA binding sequence is still unknown. Sequences from ChIP-chip data were compared to identify a consensus sequence. One gene which contained this consensus sequence was the chemokine-like receptor-1 gene (CMKLR1), which was investigated by luciferase assay. CMKLR1 showed upregulation when co-transfected with RAI1. RAI1 SMS methylation DNA binding sequence Medical Genetics Medical Sciences Medicine and Health Sciences
196	Etude du mécanisme de régulation du gène et de l'importance biologique de la superoxyde dismutase à manganèse dans la croissance tumorale mammaire / Study of the regulation mechanism of manganese superoxide dismutase gene and its biological importance in the mammary tumoral growth Minig, Vanessa 27 March 2009 (has links) La superoxyde dismutase à Manganèse (SOD Mn ou SOD2) est une enzyme importante dans la défense antioxydante, qui semble jouer un rôle mal défini dans le développement des tumeurs selon l’expression constitutive de son gène. Cependant, les mécanismes de régulation de cette expression constitutive sont mal connus, en particulier dans les cellules tumorales mammaires. Ce travail a reposé sur la mise en évidence préalable d’une protéine, appelée la Damaged DNA Binding 2 (DDB2) protein, se fixant spécifiquement sur la région promotrice du gène SOD2. La DDB2 est connue pour sa participation dans la réparation de l’ADN par excision de nucléotides. Dans un 1er temps, nous avons caractérisé la séquence d’ADN spécifiquement reconnue dans la région proximale du promoteur du gène SOD2, sur laquelle la DDB2 s’y fixe sous la forme d’un monomère, pour réguler négativement la transcription constitutive de la SOD Mn dans les cellules tumorales mammaires non métastatiques de type MCF-7. Par ailleurs, la DDB2 n’est pas impliquée dans le mécanisme d’induction du gène SOD2, lorsque les cellules MCF-7 sont exposées à des substances inductrices. En revanche, nous avons montré que l’absence de la protéine DDB2, associée à celle du facteur de transcription AP-2?, déjà connu comme répresseur du gène SOD2, entraîne une expression constitutive élevée de la SOD Mn dans les cellules tumorales mammaires métastatiques n’exprimant pas le récepteur aux œstrogènes (ER-). De plus, cette expression constitutive élevée est principalement dépendante du facteur de transcription Sp1. Dans un 2ème temps, nous avons évalué la signification biologique de la régulation de l’expression constitutive de la SOD Mn par la DDB2 dans les cellules tumorales mammaires. Nos résultats montrent que la DDB2 active la prolifération des cellules tumorales mammaires ER+, en exerçant sa régulation négative sur l’expression de la SOD Mn. Dans un 3ème temps, nous avons cherché à montrer les conséquences sur la croissance des cellules tumorales mammaires ER-, qui surexpriment naturellement la SOD Mn. Nos résultats révèlent que l’enzyme antioxydante joue un rôle important dans les mécanismes moléculaires impliqués dans le pouvoir invasif des cellules tumorales mammaires ER-. La surexpression de la SOD Mn, associée à un taux faible des enzymes éliminant l’H2O2, entraînent une augmentation du pouvoir invasif déjà élevé des cellules tumorales mammaires ER-, associée une augmentation de l’activité de la métalloprotéinase 9. L’élimination, en présence d’antioxydants, de l’H2O2 libéré par l’activité de la SOD Mn surexprimée, entraîne une inhibition à la fois de la croissance et des capacités invasives des cellules tumorales mammaires ER-. L’ensemble de ce travail contribue à mieux comprendre l’importance de la SOD Mn et du mécanisme de régulation de son gène dans la croissance et l’invasion tumorales. Ainsi ce travail révèle également la SOD Mn et la DDB2 comme de potentiels facteurs prédictifs de la progression tumorale mammaire. Enfin, la découverte de la nouvelle activité biologique de la DDB2 ouvre un vaste champ de perspectives intéressantes en cancérologie mammaire. / Manganese superoxide dismutase (Mn SOD or SOD2) is an important enzyme in the antioxidizing defence, which seems to play an unclear role in the cancer development, according to the constitutive expression of its gene. However, the regulation of this constitutive expression is not totally known, particularly in the breast cancer cells. This work is based on a preliminary revealing that a protein, called Damaged DNA Binding 2 (DDB2), specifically binds the SOD2 gene promoter. The DDB2 is known for its involvement in the nucleotide excision repair. At first step, we characterized the specific DNA sequence recognized in the proximal area of the SOD2 gene promoter, on which a DDB2 monomer binds, in order to regulate negatively the Mn SOD transcription in the MCF-7 non metastatic breast cancer cells. Besides, DDB2 is not involved in the mechanism of SOD2 gene induction, when MCF-7 cells are exposed to induced substances. However, we showed that the lack of the DDB2 protein, associated with the lack of the AP-2a transcription factor, already known as a repressor of the SOD2 gene, lead to a high Mn SOD constitutive expression in the metastatic breast cancer cells. Furthermore, this high constitutive expression is mainly dependent of the Sp1 transcription factor. Secondly, we estimated the biological meaning of the regulation of the Mn SOD constitutive expression by the DDB2 in the breast cancer cells. Our results show that the DDB2 activates the positive ER breast cancer cell proliferation, by exercising its negative regulation on the Mn SOD expression. Thirdly, we tried to show the consequences on the negative ER breast cancer cell growth, which naturally and highly express the Mn SOD. Our results reveal that the antioxidizing enzyme plays an important role in the molecular mechanisms involved in the invasive capacities of the negative ER breast cancer cells. The high Mn SOD expression, associated in a decrease of the H2O2 detoxifying enzymes expression, enhance the negative ER breast cancer cell invasion and an increase of the matrix metallopeptidase-9 activity. The H2O2 elimination, with specific antioxidants, decreases both negative ER breast cancer cell growth and invasive capacities. This whole work contributes to better understand the Mn SOD importance and the mechanism of its gene regulation, in the tumoral growth and invasion. This work also reveals the Mn SOD and DDB2 as potential predictive factors of the breast cancer progress. Finally, the discovery of this new DDB2 biological activity opens a huge field of interesting perspectives in breast cancer research. Damaged-DNA binding 2 (DDB2) Espèces actives de l’oxygène (EAO)
197	The role of STAT1-cooperative DNA binding in myocardial infarction Doudin, Asmma 06 August 2019 (has links) No description available. 610 STAT1 Sterile inflammation Myocardial infarction RNA-seq Cooperative DNA-binding Medizin (PPN619874732)
198	Homologous Recombinational DNA Repair: from Prokaryotes to Eukaryotes: a Dissertation Forget, Anthony L. 17 April 2004 (has links) The error free repair of DNA double strand breaks through the homologous recombinational repair pathway is essential for organisms of all types to sustain life. A detailed structural and mechanistic understanding of this pathway has been the target of intense study since the identification of bacterial recA, the gene whose product is responsible for the catalysis of DNA strand exchange, in 1965. The work presented here began with defining residues that are important for the assembly and stability of the RecA filament, and progressed to the identification of residues critical for the transfer of ATP-mediated allosteric information between subunits in the protein's helical filament structure. My work then evolved to investigate similar mechanistic details concerning the role of ATP in the human RecA homolog, Rad51. Results from non-conservative mutagenesis studies of the N-terminal region of one subunit and the corresponding interacting surface on the neighboring subunit within the RecA protein, led to the identification of residues critical for the formation of the inactive RecA filament but not the active nucleoprotein filament. Through the use of specifically engineered cysteine substitutions we observed an ATP-induced change in the efficiency of cross subunit disulfide bond formation and concluded that the position of residues in this region as defined by the current crystal structure may not accurately reflect the active form of the protein. These ATP induced changes in positioning led to the further investigation of the allosteric mechanism resulting in the identification of residue Phe217 as the key mediator for ATP-induced information transfer from one subunit to the next. In transitioning to investigate homologous mechanisms in the human pathway I designed a system whereby we can now analyze mutant human proteins in human cells. This was accomplished through the use of RNA interference, fluorescent transgenes, confocal microscopy and measurements of DNA repair. In the process of establishing the system, I made the first reported observation of the cellular localization of one of the Rad51 paralogs, Xrcc3, before and after DNA damage. In addition we found that a damage induced reorganization of the protein does not require the presence of Rad51 and the localization to DNA breaks occurs within 10 minutes. In efforts to characterize the role of ATP in human Rad51 mediated homologous repair of double strand breaks we analyzed two mutations in Rad51 specifically affecting ATP hydrolysis, K133A and K133R. Data presented here suggests that, in the case of human cells, ATP hydrolysis and therefore binding, by Rad51 is essential for successful repair of induced damage. DNA-Binding Proteins DNA Repair Rec A Recombinases Recombinant Proteins Amino Acids, Peptides, and Proteins Genetic Phenomena
199	Role of peroxisome proliferator-activated receptors in diabetic vascular dysfunction. / CUHK electronic theses & dissertations collection January 2011 (has links) Aside from an indirect effect of PPARgamma activation to reduce insulin resistance and to facilitate adiponectin release, PPARgamma agonist could also exert direct effects on blood vessels. I provided a first line of experimental evidence demonstrating that PPARgamma agonist rosiglitazone up-regulates the endothelin B receptor (ETBR) expression in mouse aortas and attenuates endothelin-1-induced vasoconstriction through an endothelial ET BR-dependent NO-related mechanism. ETBR up-regulation inhibits endothelin-1-induced endothelin A receptor (ETAR)-mediated constriction in aortas and mesenteric resistance arteries, while selective ETBR agonist produces endothelium-dependent relaxations in mesenteric resistance arteries. Chronic treatment with rosiglitazone in vivo or acute exposure to rosiglitazone in vitro up-regulate the ETsR expression without affecting ETAR expression. These results support a significant role of ETBR in contributing to the increased nitric oxide generation upon stimulation with PPARgamma agonist. This study provides additional explanation for how PPARgamma activation improves endothelial function. / Firstly, I demonstrated that adipocyte-derived adiponectin serves as a key link in PPARgamma-mediated amelioration of endothelial dysfunction in diabetes. Results from ex vivo fat explant culture with isolated arteries showed that PPARgamma expression and adiponectin synthesis in adipose tissues correlate with the degree of improvement of endothelium-dependent relaxation in aortas from diabetic db/db mice. PPARgamma agonist rosiglitazone elevates the adiponectin release and restores the impaired endothelium-dependent relaxation ex vivo and in vivo, in arteries from both genetic and diet-induced diabetic mice. The effect of PPARgamma activation on endothelial function that is mediated through the adiponectin- AMP-activated protein kinase (AMPK) cascade is confirmed with the use of selective pharmacological inhibitors and adiponectin -/- or PPARgamma+/- mice. In addition, the benefit of PPARgamma activation in vivo can be transferred by transplanting subcutaneous adipose tissue from rosiglitazone-treated diabetic mouse to control diabetic mouse. I also revealed a direct effect of adiponectin to rescue endothelium-dependent relaxation in diabetic mouse aortas, which involves both AMPK and cyclic AMP-dependent protein kinase signaling pathways to enhance nitric oxide formation accompanied with inhibition of oxidative stress. These novel findings clearly demonstrate that adipocyte-derived adiponectin is prerequisite for PPARgamma-mediated improvement of endothelial function in diabetes, and thus highlight the prospective of subcutaneous adipose tissue as a potentially important intervention target for newly developed PPARgamma agonists in the alleviation of diabetic vasculopathy. / To summarize, the present investigation has provided a few lines of novel mechanistic evidence in support for the positive roles of PPARgamma and PPARdelta activation as potentially therapeutic targets to combat against diabetic vasculopathy. / Type 2 diabetes mellitus and obesity represent a global health problem worldwide. Most diabetics die of cardiovascular and renal causes, thus increasing the urgency in developing effective strategies for improving cardiovascular outcomes, particularly in obesity-related diabetes. Recent evidence highlights the therapeutic potential of peroxisome proliferators activated receptor (PPAR) agonists in improving insulin sensitivity in diabetes. / While agonists of PPARalpha and PPARgamma are clinically used, PPARdelta is the remaining subtype that is yet to be a target for current therapeutic drugs. Little is available in literature about the role of PPARdelta in the regulation of cardiovascular function. The third part of my thesis focused on elucidating cellular mechanisms underlying the beneficial effect of PPARdelta activation in the modulation of endothelial function in diabetes. PPARdelta agonists restore the impaired endothelium-dependent relaxation in high glucose-treated aortas and in aortas from diabetic db/db mice through activation of a cascade involving PPARdelta, phosphatidylinositol 3-kinase, and Akt. PPARdelta activation increases Akt and endothelial nitric oxide synthase and nitric oxide production in endothelial cells. The crucial role of Akt is confirmed by selective pharmacological inhibitors and transient transfection of dominant negative Akt plasmid in these cells. Treatment with PPARdelta agonist GW501516 in vivo augments endothelial function in diabetic db/db and diet-induced obese mice. The specificity of GW501516 for PPARdelta is proven with the loss of its effect against high glucose-induced impairment of endothelium-dependent relaxation in aortas from PPARdelta knockout mice. In addition, oral administration of GW501516 in vivo fails to improve endothelial function in diet-induced obese PPARdelta deficient mice. / Tian, Xiaoyu. / Adviser: Huang Yu. / Source: Dissertation Abstracts International, Volume: 73-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2011. / Includes bibliographical references (leaves 132-165). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. Diabetic angiopathies--Treatment DNA-binding proteins Diabetic Angiopathies--therapy
200	Dissecting the oncogenic function of a novel androgen receptor-dependent direct target, cell cycle-related kinase (ccrk), in hepatocellular carcinoma. / CUHK electronic theses & dissertations collection January 2011 (has links) Hepatocellular carcmoma (HCC) is the third most common cause of cancer-related deaths worldwide, with a gender prevalence observed in men. Recent studies have suggested that elevated activity of the androgen axis is one major host factor underlying this disparity between genders. The androgen receptor (AR) mediates function of androgen in vital developmental and oncogenic pathways by binding to genomic androgen response elements, which influence the transcription of downstream target genes. AR is overexpressed in 60-80% of human HCCs. Genetic studies further established the pivotal role ofAR in hepatocarcinogenesis, where liver-specific knockout of AR significantly reduced tumorigenicity in carcinogen- and HBV-induced HCC mouse models. However, AR-inducedhepatocarcinogenesis is far from fully understood, in part because little is known about the identity and role of direct AR-dependent targeted genes in hepatocytes. / In this study, we used genome-wide location and functional analyses to identify a critical mediator of AR signaling, cell cycle-related kinase (CCRK), in driving beta-cateninl T-cell factor (TCF)-dependent hepatocarcinogenesis. Using chromatin immunoprecipitation followed by promoter array analysis of AR-overexpressing HCC cell lines, we found a number of cell cycle-related genes that are likely under the direct modulation of AR. Cell cycle-related kinase (CCRK), previously shown to promote glioblastoma tumorigenesis, was found to be the most significantly-bound AR target ( p<0.0001). CCRK was directly up-regulated by ligand-activated AR through promoter binding and required for AR-induced G1-S cell cycle progression because (1) CCRK overexpression attenuated cell cycle blockage by AR knockdown and (2) CCRK inhibition counteracted AR-mediated cell cycle progression. Ectopic CCRK expression induced immortalized liver cell proliferation, malignant transformation and tumor formation in immunodeficient mice, whereas CCRK inhibition decreased HCC cell growth in vitro and in vivo. These functional assays demonstrated that CCRK is a potential oncogene in HCC. Mechanistically, CCRK activated beta-catenin/TCF-dependent transcription through phosphorylation of glycogen synthase kinase-3beta and induced the expressions of beta-catenin target genes, cyclin D1 (CCND1) and epidermal growth factor receptor (EGFR). Inhibition of beta-catenin/TCF signaling attenuated CCRK-induced cell cycle progression, colony formation and tumorigenicity. Conversely, HCC cell growth inhibition by CCRK knockdown was rescued by constitutively active beta-catenin or TCF. In agreement with these findings, activation of the AR/CCRK/beta-catenin axis was frequently observed in primary HCCs. More importantly, CCRK over-expression was correlated with tumor staging and poor overall survival in a cohort ofhuman HCC tissues. / Together, our data reveal a new cascade for AR function in hepatocarcinogenesis via the activation of beta-catenin/TCF signaling. This study also reveals that CCRK is a novel focal link between two prominent signaling pathways vital for HCC growth and thus represents a new therapeutic target for HCC treatment. / Feng, Hai. / Adviser: Sung Jao Yiu. / Source: Dissertation Abstracts International, Volume: 73-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2011. / Includes bibliographical references (leaves 161-177). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. DNA-binding proteins Liver--Cancer Protein kinases Carcinoma, Hepatocellular Cyclin-Dependent Kinases Receptors, Androgen

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