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Amélioration d'une enzyme hyperthermostable pour la dégradation des organophosphorés / Improvement of hyperthermostable enzyme for organophosphorus degradationJacquet, Pauline 19 December 2017 (has links)
Les organophosphorés (OPs) sont des composés neurotoxiques qui sont largement utilisés comme pesticides. Cette utilisation intensive a conduit à une importante pollution des sols et des effluents agricoles et sont retrouvés jusque dans les aliments. Ces pesticides sont responsables de 300 000 morts à travers le monde. Les OPs ont également été développés comme agents neurotoxiques de guerre tel que le sarin. Actuellement, il n’existe pas de méthode de décontamination externe satisfaisante pour dégrader les OPs, c’est pourquoi l’utilisation d’enzymes est une stratégie attractive. Parmi les enzymes capables de dégrader les OPs, les phosphotriestérases (PTEs) sont les plus actives mais sont peu stables ce qui limite leurs applications. Les enzymes hyperthermostables ont donc été considérées. Ainsi l’enzyme SsoPox, isolée de l’archée Sulfolobus solfataricus ayant une activité lactonase et une activité de promiscuité phosphotriestérase, a été plus particulièrement étudiée. SsoPox est extrêmement robuste mais son activité phosphotriestérase est en revanche plus faible. Une stratégie d’ingénierie protéique a été réalisée afin d’obtenir un compromis entre l’activité d'une PTE et la stabilité de SsoPox. En utilisant les similarités structurales entre ces deux enzymes, une base de données mutationnelle a été réalisée pour transférer le site actif hautement performant d’une PTE dans la structure hyperstable de SsoPox. Cette stratégie a permis d’obtenir des variants de SsoPox améliorés jusqu’à 2000 fois. L'efficacité de ces variants a été démontrée in vivo chez un modèle animal, la planaire, permettant d'améliorer la survie ainsi que la mobilité et la capacité de régénération. / Organophosphates (OPs) are neurotoxic compounds widely used as pesticides. Over the years, utilization of OP led to a considerable environmental contamination of soils and agricultural wastewaters, this pollution is furthermore a major health issue as these insecticides can be found in food. OP are highly toxic and are responsible for 300,000 deaths in the world every year. OPs were also developed as chemical warfare nerve agents such as sarin. Currently, no satisfying method for external decontamination is available, therefore bioremediation with enzymes is highly appealing. Among OP degrading enzymes, phosphotriesterases (PTEs) are the most active biocatalysts but are poorly stable what hinders their potential for bioremediation. Hyperthermostable enzymes from extreme environments were thus considered to circumvent this limitation. In particular, SsoPox isolated from the archaeon Sulfolobus solfataricus, displaying a lactonase activity and a promiscuous phosphotriesterase activity was deeply investigated. SsoPox is extremely robust but its activity for OP degradation is from far lower. A protein engineering strategy was started in order to reach a compromise between PTE activity and SsoPox robustness. Using structural similarities between PTEs and SsoPox, a mutational database was designed in order to transfer the highly performant active site of PTE into the hyperstable scaffold of SsoPox. This strategy led to variants displaying up to 2,000-fold increase against OPs as compared to wild-type enzyme. The variants efficiency was demonstrated in vivo using an original animal model planarian, allowed to enhance survival rate as well as mobility and regeneration capacity.
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Investigation of the Catalytic Mechanism and Biosensing Potential of PhosphotriesterasesLangley, Christopher R. 25 August 2011 (has links)
This thesis describes the characterization of SsoPox, a lactonase with promiscuous phosphotriesterase activity from the hyperthermophilic archaeon, Sulfolobus solfataricus, and the potential of the phosphotriesterase from Brevundimonas diminuta (PTEBd) to function as an organophosphate sensor. Arg-223 and Tyr-99 of SsoPox are not essential for lactonase activity, however substitution of a phenylalanine in place of Tyr-97 abolished lactonase activity while reducing paraoxonase activity by 20-fold. Substrate specificity of SsoPox can be modulated through the partial blockage of the hydrophobic binding tunnel adjacent to the active site. The specificity constant for N-(3-oxo-decanoyl)-L-homoserine lactone decreased 37-fold when a phenylalanine was introduced in place of Leu-226. PTEBd was expressed and purified from Pseudomonas putida and, like SsoPox, can be immobilized to Disruptor paper. The immobilized enzyme can be used to detect five organophosphates at concentrations as low as 50 μM. Incubation of PTEBd-immobilized sensors at different temperatures proved that the enzyme is stable for at least 40 days at 23.5 degrees Celsius without any detectable change in activity.
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