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Molecular epidemiological typing of Salmonella with the DNA insertion sequence IS200Baquar, Namoos January 1995 (has links)
No description available.
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Role of DNA methylation and intron structure in genetic evolutionTang, Sze-man, January 2006 (has links)
Thesis (M. Phil.)--University of Hong Kong, 2006. / Title proper from title frame. Also available in printed format.
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Phylogenetic aspects of oral bacterial microbiomeParahitiyawa, Nipuna Bandara. January 2009 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 176-213). Also available in print.
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Lysis time, optimality, and the genetics of evolution in a T7 phage model systemHeineman, Richard Hugh, 1978- 28 August 2008 (has links)
The ability of traits to adapt in response to change is one of the most fundamental aspects of evolution. Optimality models used to predict adaptation frequently make simplifying assumptions about the ability of traits to evolve freely within simple tradeoffs. However, we frequently have little understanding of genomic mechanisms underlying phenotypic evolution. Genetic constraints clearly limit phenotypic change, but the extent to which they do so is unclear. I will explore molecular and phenotypic responses to genomic and environmental perturbations through experimental evolution in T7 bacteriophage. First, I studied evolutionary robustness of the lysis time phenotype when lysin gene lysozyme was deleted. This deletion profoundly delayed lysis and thus decreased fitness. Evolved phages recovered much of the lost fitness and mostly restored lysis timing. The recovery was mediated by changes in a tail fiber gene (gene 16) with muralytic activity that is generally used in genome entry. Next, I extended the work on lysozyme to observe the effect of increasing constraint on evolutionary recovery. The effects of various combinations of deletions of lysozyme, 17.5 (which plays a role in lysis) and 16 suggested that another gene played a role similar to 17.5 in lysis. The phage defective in both lysozyme and 16 did not lyse hosts thoroughly even after long periods of infection, suggesting that these were the only effective lysin genes. Adaptation of this phage on cells expressing the essential gp16 constrained the primary adaptive pathway of recovery from lysozyme deletion. A mutually exclusive alternative pathway involving a variety of different genes evolved. The line recovered the ability to lyse normal hosts, by a mechanism involving multiple mutations. Finally, I tested the ability of T7 to adapt to an optimum lysis time. Based on empirical results from other phages, mature phage virions accumulate linearly inside the cell over time. This assumption underlies a model suggesting that availability of hosts determines optimal lysis time. While adaptation to different host densities caused the expected qualitative evolutionary changes, adaptation to conditions expected to select for slow lysis did not lead to the quantitative optimum. This is probably due to nonlinear virion accumulation.
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Detecting evolutionary dynamics of genotype-phenotype associationsO'Connor, Timothy January 2010 (has links)
No description available.
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Lysis time, optimality, and the genetics of evolution in a T7 phage model systemHeineman, Richard Hugh, January 1900 (has links)
Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.
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Use of ValRS-IleRS interparalog distance for the analysis of the phylogenetic relationships between methanopyrus isolates from the atlantic, pacific and indian oceans /Yu, Zhiliang. January 2007 (has links)
Thesis (Ph.D.)--Hong Kong University of Science and Technology, 2007. / Includes bibliographical references. Also available in electronic version.
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Patterns of evolutionary diversification through lineages, morphology, and mechanicsBanbury, Barbara Lee. January 2010 (has links) (PDF)
Thesis (Ph. D.)--Washington State University, May 2010. / Title from PDF title page (viewed on June 11, 2010). "Department of Biological Sciences." Includes bibliographical references.
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Phenotypic plasticity of metabolic rate in an afrotropical bird species (Euplectes orix) across a temperature gradientVan de Ven, Tanja Maria Francisca Nicole January 2012 (has links)
Avian species are known to have the capacity to respond to environmental changes through physiological adjustments. The process whereby organisms adjust their phenotype without genetic change is termed phenotypic plasticity and it is mostly observed to be a phenotypic improvement to ecological challenges. Metabolic rate (MR), which is the rate of energy expenditure in a species, is a highly flexible physiological parameter which results in a great diversity of avian standardised metabolic rates. Like birds from high latitudes, Afrotropical bird species are expected to have the capacity to adjust their energy expenditure to match the availability of resources. Previous studies on the flexibility of physiological parameters in birds have focused on the magnitude of change of physiological adjustments and the cues inducing these changes. Comparative research has furthermore investigated metabolic rates across aridity, altitude, latitude and temperature gradients. Recently, a clear dichotomy has become evident with elevated metabolic rates observed in high latitude birds in winter and a down-regulation of metabolic rates observed in birds exposed to low latitude mild winters. In this study, the shape of the reaction norm, the magnitude, the reversibility, the direction and the rate of change of two physiological parameters, basal metabolic rate (BMR) and summit metabolic rate (Msum), were investigated in a coastal and an inland population of Southern Red Bishops (Euplectes orix) through seasonal acclimatisation and laboratory acclimation. Summer and winter basal metabolic rates as well as body mass, were highly flexible traits in free-ranging coastal and inland Red Bishops. Birds acclimatised to a mild coastal climate in winter exhibited reduced basal and summit metabolic rates, whereas birds originating from a more variable inland climate increased basal metabolic rate in winter, but did not show increases of Msum in winter. Red Bishops responded to short term thermal acclimation under laboratory conditions by gradually changing body mass. Acclimation periods of 21 days revealed a negative relationship between body mass and acclimation air temperature. Peak responses of basal metabolic rate to ambient temperature change were observed in both coastal and inland birds between two and eight days after the change in acclimation air temperature. The influences of seasonal acclimatisation on energy expenditure differed between coastal and inland birds, however, during laboratory acclimation individuals from the two populations showed no difference in response. Within the individuals of the coastal and inland Southern Red Bishops, phenotypic flexibility is observed in body mass, basal metabolic rate and summit metabolic rate as a response to environmental changes. This flexibility is thought to increase thermoregulatory capacities of the Southern Red Bishop in different habitats and climates.
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Role of DNA methylation and intron structure in genetic evolutionTang, Sze-man, 鄧詩敏 January 2006 (has links)
published_or_final_version / abstract / Medicine / Master / Master of Philosophy
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