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Development of Real-Time PCR Based Methods for Detection of Viruses and Virus AntibodiesElfaitouri, Amal January 2006 (has links)
Quantitative real-time PCR (QPCR) technology has been very useful for diagnosis of viral diseases. QPCR has recently reached a level of sensitivity, simplicity, and reproducibility which allows a large number of samples to be screened rapidly, make it a suitable tool for the clinical virology diagnostics. In this thesis, broadly targeted and degenerated quantitative QPCR assays were used. A somewhat novel single-tube real-time reverse transcription-polymerase chain reaction (QRT-PCR), with takes advantage of ability of rTth DNA polymerase to reverse transcribe RNA in the presence of Mn2+ at elevated temperatures and includes protection against amplimer contamination by using thermolabile UNG, was developed. A new technique for diagnostic of recent viral infection by detection of viral immunoglobulin M (IgM) was also developed. In the first paper, a sensitive single-tube QRT-PCR for detection of enteroviral RNA in patients with aseptic meningitis was presented. In the second paper, a single-serum-dilution real-time PCR-based PIA (PCR-enhanced immunoassay), called quantitative PIA (QPIA), to detect enterovirus IgM for diagnosis of EV infection in patients with aseptic meningitis, was also developed. In the third paper, a broadly targeted, simple, single tube degenerated quantitative QPCR technique for detection of JCV, BKV and SV40 DNA was developed. A conserved region of the VP2 gene of JCV, BKV and SV40 was targeted. A false positive result due to contamination with commonly used SV40 T-antigen plasmids was therefore avoided. In manuscript four, the QPIA assay provide a rational strategy for detection of EV IgM, allows the use of viral antigens isolate from newly diagnosed Type 1 diabetes patients (T1D-EV-QPIA) to measured IgM against diabetogenic viruses in serum from newly diagnosed T1D children, siblings, and healthy children. To conclude, novel broadly targeted real-time PCR methods for diagnosis of entero- and polyoma viral infections were developed.
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Dynamics of the Bacterial Genome : Rates and Mechanisms of MutationKoskiniemi, Sanna January 2010 (has links)
Bacterial chromosomes are highly dynamic, continuously changing with respect to gene content and size via a number of processes, including deletions that result in gene loss. How deletions form and at what rates has been the focus of this thesis. In paper II we investigated how chromosomal location affects chromosomal deletion rates in S. typhimurium. Deletion rates varied more than 100-fold between different chromosomal locations and some large deletions significantly increased the exponential growth rate of the cells. Our results suggest that the chromosome is heterogeneous with respect to deletion rates and that deletions may be genetically fixed as a consequence of natural selection rather than by drift or mutational biases. In paper I we examined in a laboratory setting how rapidly reductive evolution, i.e. gene loss, could occur. Using a serial passage approach, we showed that extensive genome reduction potentially could occur on a very short evolutionary time scale. For most deletions we observed little or no homology at the deletion endpoints, indicating that spontaneous deletions often form through a RecA independent process. In paper III we examined further how large spontaneous deletions form and, unexpectedly, showed that 90% of all spontaneous chromosomal deletions required error-prone translesion DNA polymerases for their formation. We propose that the translesion polymerases stimulate deletion formation by allowing extension of misaligned single-strand DNA ends. In paper IV we investigated how the translesion DNA polymerase Pol IV, RpoS and different types of stresses affect mutation rates in bacteria. Derepression of the LexA regulon caused a small to moderate increase in mutation rates that was fully dependent on functional endonucleases but only partly dependent on translesion DNA polymerases. RpoS levels and growth stresses had only minor effects on mutation rates. Thus, mutation rates appear very robust and are only weakly affected by growth conditions and induction of translesion polymerases and RpoS.
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Structural determinants of murine leukemia virus reverse transcriptase that are important for template switching, fidelity, and drug-resistanceSvarovskaia, Evguenia S. January 2000 (has links)
Thesis (Ph. D.)--West Virginia University, 2000. / Title from document title page. Document formatted into pages; contains xi, 185 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references.
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Structural and biochemical basis for the high fidelity and processivity of DNA polymerase εGanai, Rais Ahmad January 2015 (has links)
DNA polymerase epsilon (Pol ε) is a multi-subunit B-family DNA polymerase that is involved in leading strand DNA replication in eukaryotes. DNA Pol ε in yeast consists of four subunits, Pol2, Dpb2, Dpb3, and Dpb4. Pol2 is the catalytic subunit and Dpb2, Dpb3, and Dpb4 are the accessory subunits. Pol2 can be further divided into an N-terminal catalytic core (Pol2core) containing both the polymerase and exonuclease active sites and a C-terminus domain. We determined the X-ray crystal structure of Pol2core at 2.2 Å bound to DNA and with an incoming dATP. Pol ε has typical fingers, palm, thumb, exonuclease, and N-terminal domains in common with all other B-family DNA polymerases. However, we also identified a seemingly novel domain we named the P-domain that only appears to be present in Pol ε. This domain partially encircles the nascent duplex DNA as it leaves the active site and contributes to the high intrinsic processivity of Pol ε. To ask if the crystal structure of Pol2core can serve as a model for catalysis by Pol ε, we investigated how the C-terminus of Pol2 and the accessory subunits of Pol ε influence the enzymatic mechanism by which Pol ε builds new DNA efficiently and with high fidelity. Pre-steady state kinetics revealed that the exonuclease and polymerization rates were comparable between Pol2core and Pol ε. However, a global fit of the data over five nucleotide-incorporation events revealed that Pol ε is slightly more processive than Pol2 core. The largest differences were observed when measuring the time for loading the polymerase onto a 3' primer-terminus and the subsequent incorporation of one nucleotide. We found that Pol ε needed less than a second to incorporate the first nucleotide, but it took several seconds for Pol2core to incorporate similar amounts of the first nucleotide. B-family polymerases have evolved an extended β-hairpin loop that is important for switching the primer terminus between the polymerase and exonuclease active sites. The high-resolution structure of Pol2core revealed that Pol ε does not possess an extended β-hairpin loop. Here, we show that Pol ε can processively transfer a mismatched 3' primer-terminus between the polymerase and exonuclease active sites despite the absence of a β-hairpin loop. Additionally we have characterized a series of amino acid substitutions in Pol ε that lead to altered partitioning of the 3'primer-terminus between the two active sites. In a final set of experiments, we investigated the ability of Pol ε to displace the downstream double-stranded DNA while carrying out DNA synthesis. Pol ε displaced only one base pair when encountering double-stranded DNA after filling a gap or a nick. However, exonuclease deficient Pol ε carries out robust strand displacement synthesis and can reach the end of the templates tested here. Similarly, an abasic site or a ribonucleotide on the 5'-end of the downstream primer was efficiently displaced but still only by one nucleotide. However, a flap on the 5'-end of the blocking primer resembling a D-loop inhibited Pol ε before it could reach the double-stranded junction. Our results are in agreement with the possible involvement of Pol ε in short-patch base excision repair and ribonucleotide excision repair but not in D-loop extension or long-patch base excision repair.
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Probing the dNTP Binding Region of <em>Bacillus subtilis</em>: DNA Polymerase III with Site-Directed Inhibitors: A DissertationButler, Michelle Marie 13 March 1992 (has links)
6-(p-Hydroxyphenylhydrazino) uracil (H2-HPUra) is a selective and potent inhibitor of the replication-specific DNA polymerase III (pol III) of Gram+ bacteria such as Bacillus subtilis. Although a pyrimidine, H2-HPUra derives its inhibitory activity from its specific capacity to mimic the purine nucleotide, dGTP. The project described in this thesis dissertation involves the use of H2-HPUra-like inhibitors to probe the structure and function of the pol III active site. It consists of two separate problems which are summarized below.
Production of a potent bona fide dGTP form of inhibitor. A method was devised to successfully convert the H2-HPUra inhibitor prototype to a bona fide purine, using N2-benzyl guanine as the basis. Structure-activity relationships of benzyl guanines carrying a variety of substituents on the aryl ring identified N2-(3,4-dichlorobenzyl) guanine (DCBG) as a compound equivalent to H2-HPUra with respect to potency and inhibitor mechanism. DCBdGTP, the 2'-deoxyribonucleoside 5'-triphosphate form of DCBG, was synthesized and characterized with respect to its action on wild-type and mutant forms of pol III. DCBdGTP acted on pol III by the characteristic inhibitor mechanism and formally occupied the dNTP binding site with a fit which permitted its polymerization. The latter experiment identified the site for the binding of the inhibitor's aryl moiety as a distinct site located at a distance of approximately 6-7 Å from the base-paired 2-NH group of a bound dGTP.
Attempt to covalently label amino acid residue 1175, a putative participant in inhibitor binding. Azp-12, a point mutation of serine 1175, yields a form of pol III whose inhibitior sensitivity varies specifically as a function of the composition of the para substituent of the inhibitor's aryl ring. On the basis of the latter behavior, residue 1175 was hypothesized to be a residue directly involved in the binding of the inhibitor's aryl moiety. To test this hypothesis, residue 1175 was specifically mutated to either cysteine or lysine, each of which presents a side chain amenable to covalent bond formation with appropriately reactive inhibitor forms. Of the two mutant pol III forms, only the cysteine form (pol III-cys) was catalytically active. The kinetic properties and inhibitor sensitivity profile of pol III-cys identified it as a target suitable for potentially irreversible inhibitor forms containing the following groups in the meta position of the aryl ring: -CH2Br, -CH2C1, and -CH2SH. None of the several inhibitors tested selectively or irreversibly inactivated pol III-cys. Possible bases for the failure of this group of inhibitors and for the redesign of more useful covalently reactive inhibitor forms are considered.
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Etude de l'effondrement rapide des fourches de réplication lors d'un stress réplicatif / Identification and study of rapid replication fork collapse during replicative stressGoullet de Rugy, Théo 27 September 2016 (has links)
Le Stress Réplicatif est caractérisé par une accumulation de fourches bloquées et est connu pour être une source majeure d'instabilité génétique dans les cellules humaines. Le Stress Réplicatif et l'instabilité génétique sont des marqueurs précoces de la tumorigenèse. Il est connu que les fourches de réplication bloquées peuvent dégénérer en cassures double brin. En effet, après un stress réplicatif prolongé (24h) induit par l'hydroxyurée (HU), l'endonucléase MUS81-EME1 peut promouvoir l'effondrement des fourches de réplication. Cette endonucléase prévient l'accumulation de régions sous-répliquées en G2 et des défauts de ségrégation chromosomique en mitose. Dans cette étude, en suivant l'apparition de cassures double brin (CDB) par les techniques sensibles d'essai comète neutre et de QIBC (Quantitative Image-Based Cytometry), nous avons pu mettre en évidence que l'effondrement des fourches est un événement qui peut être visualisé rapidement suite au stress réplicatif (dès 2h après HU). Nous avons pu caractériser cet effondrement rapide comme étant un mécanisme indépendant de MUS81, sous unité catalytique du complexe MUS81-EME1. De plus, en réalisant des extinctions de l'expression de gènes par siARN, nous avons identifié deux nucléases, Artémis et XPF, comme étant impliquées dans ce mécanisme d'effondrement rapide des fourches de réplication. Nos résultats suggèrent un rôle de ce mécanisme d'effondrement rapide dans la prévention d'intermédiaires mitotiques et de la transmission de lésions aux cellules filles. Nous avons également identifié l'ADN polymérase alternative, Pol theta comme étant un facteur impliqué dans la prévention de la mort cellulaire induite par ce mécanisme. L'exploration de données de qPCR sur des prélèvements de tissus cancéreux nous a permis d'identifier la surexpression de Pol theta comme étant corrélée à des gènes de la HR. Ceci suggère un potentiel mécanisme d'adaptation pour prévenir de l'accumulation de fourches effondrées dans les cellules cancéreuses. L'ensemble de ces données révèle que les cellules humaines ont acquis au cours de l'évolution la capacité de cliver rapidement des fourches bloquées qui pourrait s'avérer importante pour la stabilité du génome, notamment en contexte de stress réplicatif. / Replicative stress is characterized by an accumulation of stalled replication forks and is known to be a major source of genetic instability in human cells. Replicative stress and genetic instability are early markers of tumorigenesis. It is known that stalled replication forks can degenerate into double strand breaks (DSB), a process called replication fork collapse. Indeed, after an extended replicative stress (24h) induced by hydroxyurea (HU), the endonuclease MUS81-EME1 can promote the collapse of replication forks. This endonuclease prevents accumulation of under replicated regions in G2 and mitotic segregation defects. Here, by monitoring DSB with sensitive neutral comet assay and QIBC (Quantitative Image-Based Cytometry) approaches, we found that replication forks can also collapse rapidly after replicative stress (as early as 2 hours after HU). We characterised this rapid replication fork collapse as a MUS81-independent mechanism. Moreover, by performing siRNA based knock down, we identified two nucleases, Artemis and XPF, involved in rapid replication fork collapse mechanism. Our results point toward a role of this rapid collapse mechanism in preventing mitotic intermediates and lesion transmission to daughter cells. Also, we identified the role of an alternative DNA polymerase Pol theta as a molecular factor involved in preventing this mechanism to induce cell death. Data mining of expression data from tumour samples allowed us to identify Pol theta verexpression as correlated with HR genes, underpinning a potential adaptation mechanism to prevent collapsed fork accumulation in cancer cells. Collectively, these data reveal that human cells have evolved a quick cleavage response to stalled forks that might be important for genome stability notably in cells undergoing replicative stress.
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Izolace DNA v kvalitě pro PCR z mléčných výrobků pro dětskou výživu / Isolation of PCR-ready DNA from dairy products for baby nutritionMantlová, Jana January 2013 (has links)
The work was focused on isolation of PCR-ready DNA and the identification of probiotic lactic acid bacteria that were isolated from five milk product for infant nutrition. DNA was isolated from crude cell-lysates of the products by magnetic P(HEMA-co-GMA) microspheres. DNAs isolated from crude cell lysates of control strains using phenol extraction method were used as positive controls. Using PCRs DNA of genera Bifidobacterium and species B. animalis, B. bifidum, B. breve, B. infantis, B. longum and Streptococcus thermophilus species were identified in products. The results obtained are consistent with the data declared by the manufacturers.
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Využití magnetických částic při izolaci DNA z vybraných tepelně zpracovaných výrobků rostlinného původu / The application of magnetic particles for DNA isolation from thermally processed food productsHronová, Aneta January 2017 (has links)
The thesis has been focused on testing of micromethod of DNA isolation using magnetic particles from thermic-managed food products in a quality suitable for polymerase chain reaction (PCR). Currant jams were selected for the analysis. These were homogenized using plastic copist and stomacher in lysis buffer with cetyltrimethylammonium bromide (CTAB). The effect of chloroform-octanol and isopropanol in the preparation of homogenates was tested. Homogenates were used for DNA isolation by magnetic particles. Rough fraction of DNA was purified by binding on the magnetic particles after centrifugation of the CTAB complexes with proteins, polyphenols and polysaccharides. Two types of magnetic particles were tested: microparticles of poly(hydroxyethylmethacrylate-co-glycidylmethacrylate) - P(HEMA-co-GMA) and nanoparticles of iron oxides covered by poly(L-lysine) - PLL. Isolated DNA was analyzed spectrophotometrically - it was assessed its concentration and contamination by polyphenols and proteins. After that, amplification of the DNA was tested in PCR. Primers specific for plant ribosomal DNA were used. PCR products of expected length 700 bp were detected by agarose gel electrophoresis. It was shown that DNA isolated from currant jams using magnetic particles was in PCR-ready quality.
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Interactions Between the Organellar Pol1A, Pol1B, and Twinkle DNA Replication Proteins and Their Role in Plant Organelle DNA ReplicationMorley, Stewart Anthony 01 March 2019 (has links)
Plants maintain organelle genomes that are descended from ancient microbes. Ages ago, these ancient microbes were engulfed by larger cells, beginning a process of co-evolution we now call the endo-symbiotic theory. Over time, DNA from the engulfed microbe was transferred to the genome of the larger engulfing cell, eventually losing the ability to be free-living, and establishing a permanent residency in the larger cell. Similarly, the larger cell came to rely so much on the microbe it had engulfed, that it too lost its ability to survive without it. Thus, mitochondria and plastids were born. Nearly all multicellular eukaryotes possess mitochondria; however, different evolutionary pressures have created drastically different genomes in plants versus animals. For one, animals have very compact, efficient mitochondrial genomes, with about 97% of the DNA coding for genes. These genomes are very consistent in size across different animal species. Plants, on the other hand, have mitochondrial genomes 10 to more than 100 times as large as animal mitochondrial genomes. Plants also use a variety of mechanisms to replicate and maintain their DNA. Central to these mechanisms are nuclear-encoded, organelle targeted replication proteins. To date, there are two DNA polymerases that have been identified in plant mitochondria and chloroplasts, Pol1A and Pol1B. There is also a DNA helicase-primase that localizes to mitochondria and chloroplasts called Twinkle, which has similarities to the gp4 protein from T7 phage. In this dissertation, we discuss the roles of the polymerases and the effects of mutating the Pol1A and Pol1B genes respectively. We show that organelle genome copy number decreases slightly and over time but with little effect on plant development. We also detail the interactions between Twinkle and Pol1A or Pol1B. Plants possess the same organellar proteins found in animal mitochondria, which are homologs to T7 phage DNA replication proteins. We show that similar to animals and some phage, plants utilize the same proteins in similar interactions to form the basis of a DNA replisome. However, we also show that plants mutated for Twinkle protein show no discernable growth defects, suggesting there are alternative replication mechanisms available to plant mitochondria that are not accessible in animals.
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Etude d’un réseau génétique intégrant métabolisme central carboné et réplication de l’ADN chez la bactérie Bacillus subtilis / A genetic network integrating central carbon metabolism and DNA replication in Bacillus subtilisNouri, Hamid 18 June 2013 (has links)
La réplication de l’ADN est une fonction cellulaire responsable de la duplication du matériel génétique. Elle est assurée par un complexe protéique appelé réplisome. Ce processus est hautement régulé en fonction des conditions de croissance cellulaire. Durant cette thèse je me suis intéressé principalement au contrôle de la réplication par le Métabolisme Central Carboné (MCC) et, dans une moindre mesure, au fonctionnement du réplisome chez la bactérie modèle Bacillus subtilis. J’ai analysé la réplication de l’ADN dans des mutants métaboliques, par deux techniques ; la QPCR et la cytométrie en flux. Mes analyses révèlent que la réplication de l’ADN est dérégulée dans des cellules mutées dans les cinq dernières réactions de la glycolyse et dans celles affectées dans des réactions connectant cette petite région du métabolisme aux autres réactions du MCC (haut de la glycolyse, voie des pentoses phosphate et cycle de Krebs) et au milieu extérieur (voies overflow qui éliminent les métabolites du MCC produits en excès). J’ai constaté que dans ces mutants la réplication commence plutôt et dure plus longtemps que dans une souche sauvage. L’ensemble de ces résultats montre que les réactions situées au cœur du MCC sont importantes pour assurer un bon contrôle temporel de la réplication. J’ai aussi établi que le ppGpp, une petite molécule fonctionnant comme une alarmone de l’état nutritionnelle des cellules, ne joue pas un rôle déterminant dans le contrôle de la réplication par le métabolisme dans des cellules à l’état d’équilibre. L’ensemble de nos connaissances actuelles sur les réplisomes repose essentiellement sur les données accumulées à partir de la dissection du réplisome de la bactérie modèle Escherichia coli et des phages T4 et T7. Chez Bacillus subtilis, deuxième modèle bactérien le mieux connu et représentant des Gram+ à faible GC%, il existe deux ADN polymérases essentielles à la réplication : PolC et DnaE. Nous avons montré que DnaE, comme PolC, fait partie du réplisome. Nos études fournissent une explication moléculaire à la spécialisation de DnaE dans la synthèse du brin d’ADN discontinu. En conclusion, nos résultats montrent que les réplisomes bactériens ont beaucoup plus évolué qu’attendu tant dans leur composition protéique que dans leur organisation et leur fonctionnement. Ils montrent également, et pour la première fois, que le contrôle temporel de la réplication dépend de réactions situées au cœur du MCC chez B. subtilis. Ces données et d’autres de la littérature suggèrent que cette propriété pourrait être universelle et pourrait jouer un rôle important dans la carcinogenèse. / DNA replication is a central cellular function for the duplication of the genetic material. A protein complex that is called replisome carries out this function. The process of replication is highly regulated with respect to cell growth conditions. During my thesis I was primarily interested in the control of replication by the central carbon metabolism (CCM) and to a lesser extent, to the functioning of the replisome in the bacterium Bacillus subtilis. The thesis studied the DNA replication in metabolic mutants by employing two techniques; QPCR and flow cytometry. The analyses showed that DNA replication is deregulated in cells that carry the following mutations: First, cells with mutations in the last 5 reactions of glycolysis. Second, cells with mutations in the reactions that connect the last part of glycolysis to the other parts of CCM (upper part of glycolysis pathway, pentose phosphate and Krebs cycle). Third, cells mutated in the overflow genes (channels that eliminate overflow metabolites produced in excess in CCM). The results demonstrate that in these mutants the replication begins and lasts longer than in the wild strain. All of these results show that the reactions that are centrally located to the CCM are important to ensure a correct control of replication timing. I also found that the ppGpp, a small molecule that functions as an alarmone of nutritional state in the cells, does not play a decisive role in the control of replication by metabolism in cells in steady state. The current knowledge of replisomes is mainly based on accumulated data from the dissection of the replisome of the model bacterium Escherichia coli and the phages T4 and T7. Bacillus subtilis is the second well studied bacterial model, a representative of Gram+ low GC%, it carries –unlike E. coli- two essential DNA polymerases for replication: PolC and DnaE. The thesis showed that DnaE as PolC form a part of the replisome in B. subtilis and provide a molecular explanation to the specialization of DnaE in the synthesis of the DNA lagging strand. In conclusion, the results show that there is much more diversity in the protein composition, organization and functioning of replisomes in bacteria than it is expected. In addition, the thesis concluded for the first time that the temporal control of replication depends on reactions located in the heart of CCM in B. subtilis. This property, in combination with other data from the literature, suggests that it could be universal and play an important role in carcinogenesis.
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