Global ETD Search

121	Vaccinia virus DNA polymerase and ribonucleotide reductase their role in replication, recombination and drug resistance / Gammon, Donald Brad. January 2010 (has links) Thesis (Ph.D.)--University of Alberta, 2010. / A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Virology, Medical Microbiology and Immunology. Title from pdf file main screen (viewed on January 10, 2010). Includes bibliographical references.
122	Genomic variation in recombination patterns : implications for disease and cancer Hussin, Julie 02 1900 (has links) Durant la méiose, il se produit des échanges réciproques entre fragments de chromosomes homologues par recombinaison génétique. Les chromosomes parentaux ainsi modifiés donnent naissance à des gamètes uniques. En redistribuant les mutations génétiques pour générer de nouvelles combinaisons, ce processus est à l’origine de la diversité haplotypique dans la population. Dans cette thèse, je présente des résultats décrivant l’implication de la recombinaison méiotique dans les maladies chez l’humain. Premièrement, l'analyse statistique de données de génotypage de familles québécoises démontre une importante hétérogénéité individuelle et sexe-spécifique des taux de recombinaisons. Pour la première fois chez l’humain, nous avons observé que le taux de recombinaison maternel diminue avec l'âge de la mère, un phénomène potentiellement impliqué dans la régulation du taux d’aneuploïdie associé à l’âge maternel. Ensuite, grâce à l’analyse de données de séquençage d’exomes de patients atteints de leucémie et de ceux de leurs parents, nous avons découvert une localisation anormale des évènements de recombinaison chez les enfants leucémiques. Le gène PRDM9, principal déterminant de la localisation des recombinaisons chez l’humain, présente des formes alléliques rares dans ces familles. Finalement, en utilisant un large spectre de variants génétiques identifiés dans les transcriptomes d’individus Canadiens Français, nous avons étudié et comparé le fardeau génétique présent dans les régions génomiques à haut et à faible taux de recombinaison. Le fardeau génétique est substantiellement plus élevé dans les régions à faible taux de recombinaison et nous démontrons qu’au niveau individuel, ce fardeau varie selon la population humaine. Grâce à l’utilisation de données génomiques de pointe pour étudier la recombinaison dans des cohortes populationnelles et médicales, ce travail démontre de quelle façon la recombinaison peut affecter la santé des individus. / The intergenerational mixing of DNA through meiotic recombination of homologous chromosomes is, along with mutation, a major mechanism generating diversity and driving the evolution of genomes. In this thesis, I use bioinformatics and statistical approaches to analyse modern genomic data in order to study the implication of meiotic recombination in human disease. First, using high-density genotyping data from French-Canadian families, we studied sex- and age-specific effects on recombination patterns. These analyses lead to the first observation of a significant decrease in recombination rates with advancing maternal age in humans, with potential implications for understanding trisomic conceptions. Second, using next-generation sequencing of exomes from families of children with leukemia, we discovered unusual distributions of recombination breakpoints in some leukemia patients, which implicates PRDM9, a protein involved in defining the location of recombination breakpoints, in leukemogenesis. Third, using single nucleotide polymorphisms (SNPs) called from RNA sequencing data, we present a detailed comparison of the mutational burden between high and low recombining regions in the human genome. We further show that the mutational load in regions of low recombination at the individual level varies among human populations. In analysing genomic data to study recombination in population and disease cohorts, this work improves our understanding of how recombination impacts human health. Furthermore, these results provide insights on how variation in recombination modulates the expression of phenotypes in humans. recombinaison génétique séquençage PRDM9 génétique des populations leucémie genetic recombination sequencing population genetics leukemia
123	Gene targeting at and distant from DNA breaks in yeast and human cells Stuckey, Samantha Anne 02 April 2013 (has links) Here we developed multiple genetic systems through which genetic modifications driven by DNA breaks caused by the I-SceI nuclease can be assayed in the yeast Saccharomyces cerevisiae and in human cells. Using the delitto perfetto approach for site-directed mutagenesis in yeast, we generated isogenic strains in which we could directly compare the recombination potential of different I-SceI variants. By genetic engineering procedures, we generated constructs in human cells for testing the recombination activity of the same I-SceI variants. Both in yeast and human cells we performed gene correction experiments using oligonucleotides (oligos) following modification and/or optimization of existing gene targeting protocols and development of new ones. We demonstrated that an I-SceI nicking enzyme can stimulate recombination on the chromosome in S. cerevisiae at multiple genomic loci. We also demonstrated in yeast that an I-SceI-driven nick can activate recombination 10 kb distant from the initial site of the chromosomal lesion. Moreover we demonstrated that an I-SceI nick can stimulate recombination at the site of the nick at episomal and chromosomal loci in human cells. We showed that an I-SceI double-strand break (DSB) could trigger recombination up to 2 kb distant from the break at an episomal target locus in human cells, though the same was not observed for the nick. Overall, we demonstrated the capacity for I-SceI nick-induced recombination in yeast and human cells. Importantly, our findings reveal that the nick stimulates gene correction by oligos differently from a DSB lesion, as determined by genetic and molecular analyses in yeast and human cells. This research illustrates the promise of targeted gene correction following generation of a nick. Single-strand break (SSB) Targeted gene correction Double-strand break (DSB) Yeast Gene targeting Mutagenesis Chromosomes Genetic recombination Genetic engineering
124	Population biology and invasion history of puccinia striformis F.SP. tritici at worldwide and local scale Sajid, Ali 10 September 2012 (has links) (PDF) Analyses of the large-scale population structure of pathogens enable the identification of migration patterns, diversity reservoirs or longevity of populations, the understanding of current evolutionary trajectories and the anticipation of future ones. A detailed analysis of populations in centre of diversity should enable to infer the adaptive capacity of the pathogen and identify potential sources for new invasions. Puccinia striiformis f.sp. tritici (PST) is the causal agent of wheat yellow/stripe rust, and despite a worldwide distribution, this fungus remains a model species for invasion studies, due to its long-distance migration capacity and recurrent local emergence of new strains. Little is known about the ancestral relationship of the worldwide PST population with unknown center of origin. We used multilocus microsatellite genotyping to infer the worldwide population structure of PST and the origin of new invasions, analysing a set of isolates representative of sampling performed over six continents. Bayesian and multivariate clustering methods partitioned the isolates into six distinct genetic groups, corresponding to distinct geographic areas. The assignment analysis confirmed the Middle East-Red Sea Area as the most likely source of newly spreading, high-temperature-adapted strains; Europe as the source of South American, North American and Australian populations; and Mediterranean-Central Asian populations as the origin of South African populations. The existence of strong population subdivision at worldwide level shows that major genetic groups are not markedly affected by recent dispersal events. However, the sources for recent invasions and the migration routes identified emphasize the importance of human activities on the recent long-distance spread of the disease. The analyses of linkage disequilibrium and genotypic diversity indicated a strong regional heterogeneity in levels of recombination, with clear signatures of recombination in the Himalayan (Nepal and Pakistan) and near-Himalayan (China) regions and a predominant clonal population structure in other regions. To explain the variability in diversity and recombination of worldwide PST populations, we assessed their sex ability in terms of telial production, the sex-specific structures that are obligatory for PST sexual cycle, in a set of 56 isolates representative of these worldwide geographical origins. We confirmed that the variability in genotypic diversity/ recombination was linked with the sex ability, pinpointing the Himalayan region as the possible center of origin of PST, from where it then spread worldwide. The reduced sex ability in clonal populations certainly reflects a loss of sexual function, associated to migration in areas where sexual alternate host is lacking, or not necessary for the completion of epidemic cycle. Approximate Bayesian computation analyses confirmed an out of Himalaya spread of PST, with Pakistan and China being the most ancestral population. A detailed analysis of Pakistani population at regional level revealed the existence of a strong population subdivision, a high genotypic diversity and the existence of recombination signature at each location reflecting the role of sexual recombination in the temporal maintenance at local level. A time spaced sampling of PST in the valley of Tianshui (China) inspired the development of a new estimator, allowing to quantify the relative contribution of sexual reproduction and effective population size on the basis of clonal resampling within and between years. A sexual reproduction rate of 74% (95% confidence interval [CI]: 38-95%) and effective population size of 1735 (95% CI: 675-2800) was quantified in Chinese PST population. The description of the origin and migration routes of PST populations worldwide and at its centre of diversity contributes to our understanding of PST evolutionary potential, and is helpful to build disease management strategies. Invasion history Fungal pathogen Population structure Genetic recombination Puccinia striiformis
125	Analysis of the response of nucleotide excision repair genes in Dictyostelium discoideum / Yu, Sung-Lim, January 1997 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 109-130). Also available on the Internet.
126	Analysis of the response of nucleotide excision repair genes in Dictyostelium discoideum Yu, Sung-Lim, January 1997 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 109-130). Also available on the Internet.
127	Analysis of transactivation of the capsid gene promoter of MVM by the NS1 protein Pearson, James L. January 1999 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 1999. / Typescript. Vita. Includes bibliographical references (leaves 98-104). Also available on the Internet.
128	Caracterização biológica e molecular de recombinantes naturais de HIV-1. / Biological and molecular characterization of HIV-1 natural recombinants. Fernando Lucas de Melo 09 May 2011 (has links) A recombinação durante a transcrição reversa é um fator importante no aumento da diversidade genética e adaptação do HIV-1, permitindo que mutações vantajosas presentes em diferentes linhagens sejam combinadas em um mesmo genoma. No Brasil, vários recombinantes foram descritos e seis formas recombinantes circulantes (CRFs) já foram identificados, demonstrando a relevância destes recombinantes na epidemia brasileira. Portanto, um dos objetivos desta tese foi analisar os dados gerados pela Rede de Diversidade Genética Viral (VGDN) (sequências parciais de gag, pol e env), a fim de identificar recombinantes inter-subtipos de HIV-1 e avaliar a frequência e distribuição geográfica destes vírus. Utilizando diferentes técnicas foram identificados 152/1083 pacientes portadores de recombinantes BF. A frequência destes recombinantes foi maior em cidades como São Vicente (30%) e Sorocaba (22,6%), sendo que os recombinantes circulantes em São Vicente foram geralmente relacionados às CRF28 e CRF29, enquanto que os vírus presentes na região de Sorocaba comumente apresentam um envelope subtipo F1, independente do subtipo nos demais genes. Além disso, o gene da integrase de 159 pacientes foi amplificado e sequenciado. A análise deste gene revelou mais 10 pacientes infectados com recombinantes BF e nenhuma mutação de resistência primária aos inibidores da integrase foi encontrada. O segundo objetivo foi isolar e caracterizar recombinantes BF in vitro. O isolamento viral foi realizado por co-cultivo e ao final foram obtidos 10 isolados primários. O sequenciamento do genoma quase completo desses dez isolados primários revelou que três isolados primários pertencem ao grupo da CRF28_BF, três ao grupo da CRF29_BF e quatro foram classificados como formas recombinantes únicas (URFs). Ainda, o uso de correceptores desses isolados foi avaliado in vitro em ensaios com as células GHOST(3), e revelou três duplo-trópicos (X4/R5) vírus, quatro CXCR4 (X4) e três isolados utilizaram apenas CCR5 (R5). Em suma, uma alta frequência de URFs foi encontrada em algumas cidades do Estado de São Paulo, e também foi desenvolvido e caracterizado um painel de isolados primários representando as CRF28_BF, CRF29_BF e algumas URFs. / Recombination during reverse transcription is an important factor promoting HIV-1 diversity and adaptive change, allowing advantageous mutations arising on different genomes to undergo linkage in the same progeny recombinant genome more frequently than what would be expected under random mutation alone. In Brazil, several recombinant viruses were reported, and six circulating recombinant forms (CRFs) have already been identified. Therefore, the first objective of this Thesis was to analyze the data generated by the Viral Genetic Diversity Network (VGDN) (gag, pol and env partial sequences), in order to identify HIV-1 intersubtype recombinants and evaluate the frequency and geographical distribution of these viruses. Using different techniques we identified 152/1083 patients harboring BF recombinants. The frequency of these recombinants was higher in cities like São Vicente (30%) and Sorocaba (22.6 %). The recombinant viruses circulating in São Vicente were generally related to CRF28 and CRF29, while those viruses circulating in Sorocaba commonly presented an envelope region of subtype F1, irrespective the subtype composition on the remaining genes. Additionally, the integrase gene of HIV-1 from 159 patients was further amplified and sequenced. The analysis of this viral gene revealed ten more patients infected with BF recombinants and no primary mutations related to integrase inhibitor resistance were found. The second objective was to isolate and characterize BF recombinants in vitro, which resulted in ten primary HIV-1 isolates. The near full-length genomes of these ten primary isolates revealed that three were related to CRF28_BF, three to CRF29_BF and four were unique recombinant forms (URFs), according to their breakpoints profile determined with the jpHMM program. Additionally, the coreceptor usage of these isolate was investigated in vitro using GHOST assays, which revealed three dual-tropic (X4/R5) viruses, four CXCR4 (X4) viruses and three CCR5 (R5) viruses. In sum, we report a high frequency of URFs in some cities of São Paulo State, and also developed a well-characterized panel of viruses representing CRF28_BF, CRF29_BF and URFs. Diversidade genética Evolução molecular Filogenia Genomas HIV Recombinação genética Genetic diversity Genetic recombination Genomes HIV Molecular evolution Phylogeny
129	Mycobacterium Smegmatis RecA And SSB : Structure-Function Relationships, Interaction With Cofactors And Accessory Proteins Manjunath, G P 10 1900 (has links) Homologous genetic recombination, because of its fundamental roles in the maintenance of genome stability and evolution, is an essential cellular function common to all organisms. This process also plays important roles in the repair of damaged DNA molecules, generation of genetic diversity and proper segregation of chromosomes. The genetic exchange is a highly orchestrated process that entails a plethora of control mechanisms and a large number of proteins, of which RecA and SSB are two proteins that have been chosen for further investigation(s) in the present study. In addition, we have also investigated the interaction between SSB and UvrD1, which plays an important role in DNA repair pathways, especially nucleotide excision repair (NER) and mismatch repair as well as DNA replication and recombination. Chapter 1 reviews the literature regarding various aspects of homologous recombination, with an emphasis on the biochemical and the biophysical aspects of RecA and SSB proteins. In addition, it provides an overview of the study of DNA repair and recombination in mycobacteria. RecA protein is ubiquitous and well conserved among bacterial species. Many archaeal species possess two RecA homologues (RadA and RadB) and eukarya possess multiple homologues of RecA including, Rad51, Rad51B, Rad51C, Rad51D, DMC1, XRCC2, or XRCC3. RecA or its homologues function as polymers, consisting of hundreds of monomers that cooperatively polymerize on single-stranded DNA to form a nucleoprotein filament. E. coli RecA protein participates in Trans Lesion Synthesis (TLS) of DNA and forms the minimal mutasome in association with DNA polymerase V (UmuD’2C). The fundamental mechanism underlying HR, i.e. DNA strand exchange, is one of the most fascinating examples of molecular recognition and exchange between biological macromolecules. Since the isolation of E. coli recA gene and the subsequent purification of its gene product and also from other organisms, RecA protein has been studied extensively for more than three decades. E. coli RecA protein has pivotal roles in DNA recombination and repair, and binding to DNA in the presence of ATP, is a fundamental property of RecA protein resulting in the formation of a nucleoprotein filament. This is the slow step of the HR process, and is considerably faster on ssDNA than on duplex DNA. Binding of RecA to dsDNA is slower at physiological pH, is accelerated at acidic pH, and the lag in binding at the higher pH values is due to slow nucleation. The ATP and the DNA binding functions of RecA display allosteric interaction such that ATP- binding leads to an increase in affinity to ssDNA-binding and vice-versa. X-ray structures of E. coli RecA complexed with nucleotide cofactors have implicated a highly conserved Gln196 in Mycobacterium smegmatis RecA in the coupling of ATP and the DNA binding domains. The carboxyamide group of Gln196 makes an H-bond with the γ-phosphate group of ATP and the side chain of this residue is observed to move by approximately 2Å towards the ATP, relative to the other residues involved in ATP binding. In addition, a highly conserved Arg198 has also been postulated to interact with the γ-phosphate group of bound ATP and position it for a nucleophilic attack by a conserved residue-Glu96 leading to ATP hydrolyses. To elucidate the role of Gln196 and Arg198 in the allosteric modulation of RecA functions, we generated MsRecA variant proteins, where in Gln196 was substituted with alanine, asparagine or glutamate; Arg198 was mutated to a lysine. The biochemical characterization of MsRecA and its variant proteins with the objective of defining the allosteric interaction between the ATP- and the DNA-binding sites has been described with in Chapter 2. We observed that while the mutant MsRecA proteins were proficient in ATP-binding they were deficient in ATP hydrolyses. We assayed for the ability of these proteins to bind ssDNA using either nitrocellulose filter binding or Surface Plasmon Resonance (SPR). While we did not detect any ssDNA-binding by the mutant MsRecA proteins in the filter binding assay, we observed only ten-fold reduction in the affinity for ssDNA as compared to wild type MsRecA protein in MsRecAQ196A, Q196N and R198K in the SPR assay. MsRecA Q196E did not show any binding to ssDNA, in both nitrocellulose filter-binding as well as SPR assays. We assayed for the ability of the mutant RecA proteins for their ability to promote DNA-pairing as well as DNA strand exchange. While we observed limited pairing promoted by the mutant proteins relative to the wild-type MsRecA, we observed a complete abrogation of strand exchange in the case of mutant proteins. In addition, we assayed for the co-protease function of MsRecA, by monitoring the cleavage of MtLexA. We observed that only the wild-type MsRecA protein was able to cleave MtLexA, while none of the mutant RecA proteins were able to do so. In order to understand the differences observed between the wild -type and the mutant MsRecA proteins, we analyzed the conformational state of MsRecA and its variant proteins by circular dichroism spectroscopy upon ATP-binding. We observed that while MsRecA and MsRecAQ196N displayed a reduction in the absorbance at 220 nm upon ATP binding, we did not observe any such structural transitions in the other mutant MsRecA proteins that we tested. Based on our observations and the crystal structure of E. coli RecA bound to ssDNA, in Chapter 2, we propose a dual role for the Gln196 and Arg198 in modulating RecA activities. In the presynaptic filament Gln196 and Arg198 sense the presence of the nucleotide in the nucleotide binding pocket and initiate a series of conformation changes that culminate in the transition to an active RecA nucleoprotein filament. In the active RecA nucleoprotein filament these residues are repositioned such that they now form a part of the protomer-protomer interface. As such they perform two vital functions; they stabilize the protomer-protomer interface by participating in the formation of hydrogen bonds that span the interface as well transmit the wave of ATP hydrolysis across the interface leading to a coordinated hydrolyses of ATP essential for the heteroduplex extension phase of strand exchange reaction. The members of the super family of single stranded DNA binding proteins (SSB) play an important role in all aspects of DNA metabolism including DNA replication, repair, transcription and recombination. Prokaryotic SSBs bind ssDNA with high affinity and generally with positive cooperativity. Several lines of evidence suggest that prokaryotic SSBs are modularly organized into three distinct domains: the N-terminal DNA binding domain and acidic C-terminal domain are linked by a flexible spacer. Studies from our laboratory have revealed that M. smegmatis SSB plays a concerted role in recombination-like activities promoted by the cognate RecA. The C- terminal of SSB is known to be involved in its ability to interact with other proteins. We have previously reported that the C-terminal domain of M. smegmatis SSB, which is not essential for interaction with DNA, is the site for the binding of cognate RecA. The data in Chapter 3 describes the characterization of the SSB C-terminus with the objective of delineating the elements responsible for mediating protein-protein interaction, as well as to define the mechanism by which SSB is able to modulate the activities of RecA. To map the RecA interaction domain of SSB we created deletion mutants in MsSSB lacking 5, 10, 15 or 20 residues from the C-terminal. The truncated SSB proteins were expressed with a His- tag at the N- terminus and purified to homogeneity using a Ni-NTA affinity matrix. We observed unlike MsSSB, MsSSB∆C5 and MsSSB∆C10, MsSSB∆C15 and MsSSB∆C20 were unable to support three-strand exchange catalyzed by MsRecA. Based on the observation that interaction with SSB is essential for MsRecA to catalyze the strand Exchange reaction, we postulate that the RecA interacting domain of SSB is situated between the 15th and the 20th residue from the C-terminal. Further, the C-terminal of MsSSB modulates the transitions between DNA binding modes. Unlike the case with EcSSB where deletion of the last 8 residues from the C-terminal stabilizes the (SSB)35 mode of ssDNA binding, we observe that in case of MsSSB the deletion of C-terminal seems to destabilize the (SSB)35. In addition, the transition from the low density binding mode to a high density mode involves the formation of several intermediates when the C-terminal residues are deleted. With the objective of understanding the functions to the C-terminal of SSB independent of its DNA-binding domain in modulating RecA functions, we employed a peptide corresponding to the 35 residues from the C-terminal of the MsSSB. We observed that the C-terminal region alone is capable of interacting with RecA. In addition we also observed that the C-terminal domain of SSB stimulates RecA functions independent of its DNA binding domain. To address the question, whether the stimulatory effect of the C-terminal domain of SSB in the absence of its DNA-binding domain is restricted to RecA or is a generalized phenomenon associated with all SSB interacting proteins; we tested the effect of C-terminal domain of SSB on UvrD which is known to interact with SSB. UvrD participates in several pathways of DNA metabolism, which include the nucleotide excision repair (NER) and mismatch repair pathway, replication and recombination. Genetic evidence suggests that UvrD and SSB interact in vivo. We tested the effect of mycobacterial SSB on M. tuberculosis UvrD1 (MtUvrD1) functions in vitro. We observe that MtUvrd1 physically interacts with SSB. Further, presence of SSB has an inhibitory effect on the helicase activity of MtUvrD1 and that this effect is dependent on the C-terminal region as the deletion of residues from the C-terminal of SSB abrogates the inhibitory effect of SSB. However, unlike RecA, the C-terminal region of SSB alone had no effect on the helicase activity of UvrD1. We also observed that MsSSB has opposing effects on the ATPase activity of MtUvrD1. In the presence of low concentrations of SSB the ATPase activity is enhanced, while we observed an inhibition when the concentration of MsSSB is high. The precise mechanistic details of how SSB is able to act as an accessory protein to RecA, in context of homologous recombination and stimulates its biochemical activities have been a subject of debate. Whereas research from some groups has shown that the stimulatory effect SSB is mediated through its ability to melt DNA secondary structure, thereby allowing RecA to overcome the kinetic barrier imposed by the presence of secondary structure in ssDNA, others postulate that SSB plays a direct role in the stabilization of RecA nucleoprotein filament and prevents its dissociation. Chapter 3 discusses the experimental evidence in favor of the aforesaid models and based on the results of our experiments; we propose that the accessory functions of SSB may be mediated by a mechanism that involves elements of both models. While interaction with SSB can bring about a conformational change in RecA that is reflected in the enhanced levels of strand exchange and co-protease activity, the helix destabilizing function of SSB is essential during heteroduplex extension and to sequester the displaced strand such that it does not participate in any further pairing reactions. The novel finding that we present in Chapter 3 is that the interaction of SSB C-terminal alone has a stimulatory effect upon RecA activities. Furthermore, we observed that M. tuberculosis UvrD1 is a weak interaction partner of SSB. The physical and functional interactions between MsSSB with RecA on the one hand, and MsSSB and UvrD1 on the other highlight different types of cross-talk between the components of HR and DNA repair pathways. In contrast to the results of earlier studies, our results indicate that protein-protein interactions alone between SSB and RecA may modulate the RecA mediated processes of presynapsis, homologous pairing and strand exchange between homologous DNA molecules as well as modulate its co-protease activity. In addition, our studies indicate that a direct protein-protein interaction is responsible for the modulation of UvrD1 activities by SSB. Bacteria - Proteins Mycobacterium Smegmatis Homologous Genetic Recombination Recombinase A Protein DNA Repair Mycobacteria - DNA Repair Mycobacteria - DNA Recombination DNA Replication Recombinant DNA RecA Protein SSB Protein Biochemistry
130	Protein processing strategies by adeno-associated virus type 5 (AAV5) and the effects of the adenovirus E4orf6/E1b-55k/Cullin 5 E3 ubiquitin ligase complex on AAV protein stability Farris, Kerry David, Pintel, David J. January 2008 (has links) The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from PDF of title page (University of Missouri--Columbia, viewed on March 10, 2010). Vita. Thesis advisor: David Pintel "August 2008" Includes bibliographical references

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