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The Effects of Workload Transitions in a Multitasking EnvironmentBowers, Margaret Anna 30 August 2013 (has links)
No description available.
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Towards preparative in vitro enzymatic synthesis of new polyketide metabolitesHughes, Amanda Jane 18 October 2013 (has links)
Modular polyketide synthases (PKSs) are the largest enzymes known to man and are responsible for synthesizing some of the most important human medicines. Their ability to construct stereochemically-rich carbon chains containing diverse substituents has inspired the biosynthetic community to engineer these factories for the in vitro synthesis of a small library of polyketide compounds. New complex polyketides are discovered every year, yet the lack of compound prohibits characterization and testing of these new compounds for medicinal properties. Smaller polyketide compounds generated in vitro could be organically manipulated to generate larger, more complex polyketide natural products and natural product analogs. Chemoenzymatic approaches like this would be extremely beneficial to the scientific community; however, there are still obstacles that must be overcome before the use of PKS for the preparative synthesis of an in vitro generated polyketide library would prove fruitful: purchasing substrates such as methylmalonyl-CoA is cost-prohibitive, PKSs are often difficult to express and purify, and the products generated are typically nonchromophoric. The use of a malonyl-CoA ligase from Streptomyces coelicolor (MatB) was investigated for the enzymatic synthesis of polyketide extender units such as methylmalonyl-CoA (Chapter 2). MatB synthesized a total of 5 CoA-linked extender units in vitro: malonyl-, methylmalonyl-, ethylmalonyl-, hydroxymalonyl- and methoxymalonyl-CoA. Two ternary complex structures of MatB with bound product and leaving group were also solved to sub-2Å resolution. MatB generated extender units were employed in the module-catalyzed synthesis of a triketide pyrone. The selectivity of a PKS module to incorporate a variety of side chains into triketide pyrones was also investigated (Chapter 3). A total of 10 triketide pyrone compounds were synthesized, 5 produced via modular "stuttering" and one possessing a terminal alkyne chemical handle. Lastly, nonchromphoric polyketide products were made visible upon copper(I)-catalyzed azide alkyne cycloaddition (CuAAC) with fluorescent sulforhodamine B azide revealing insights into in vitro reactivites of a PKS module (Chapter 4). The work described in this dissertation has helped advance the scientific community towards procuring an in vitro synthesized polyketide library for future synthetic applications. / text
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Application of the human-machine interaction model to Multiple Attribute Task Battery (MATB): Task component interaction and the strategy paradigmWalters, Craig M. 19 September 2012 (has links)
No description available.
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In vitro polyketide biocatalysis : triketide building-blocks and enzymologyHarper, Andrew David 08 October 2013 (has links)
Polyketide products are useful compounds to research and industry but can be difficult to access due to their richness in stereogenic centers. Type I polyketide synthases offer unique engineering opportunities to access natural stereocontrol and resultant complex compounds. The development of a controlled in vitro platform based around type I polyketide synthases is described. It has been used to produce a small library of polyketide fragments on an unprecedented and synthetically-relevant scale and explore polyketide synthase enzymology. / text
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