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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Fluorescence in situ Hybridization of Symbiotic Chemoautotrophic Sulfur-Oxidizing Bacteria of the Sponge, Cinachyra australiensis

Lu, Der-Kang 28 February 2004 (has links)
Symbiosis is commonly present in marine invertebrates. Many corals and sponges have symbiotic algae or bacteria. In the previous studies of the sponge Cinachyra australiensis, 85% of the bacteria associated with the sponge have high similarity (88.65%) with the symbiotic chemoautotrophic sulfur-oxidizing bacteria of the deep-sea hydrothermal vent mussel, Solemya reidi. This study aims to investigate the localization of the chemoautotrophic sulfur-oxidizing bacteria associated with Cinachyra australiensis. The Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase (RubisCO) large-subunit genes for autotrophic organisms were amplified by polymerase chain reaction from the sponge samples. The phylogenetic relationship of the RubisCO large subunit genes was analyzed. A total of 26 clones were selected and sequenced. They could be divided into two groups. One (9 clones) belongs to form I type IB (cynobacteria and green algae). The other (17 clones) belongs to form II type IA (chemoautotrophic symbiotic bacteria). The location of the sulfur-oxidizing chemoautotrophic bacteria was shown to be intracellular symbiosis within the mesoglial cells by fluorescence in situ hybridization.
2

Microbial colonization and dissolution of mercury sulfide minerals

Vazquez Rodriguez, Adiari Iraida 01 January 2016 (has links)
Mercury (Hg) is a toxic heavy metal that poses significant human and environmental health risks. Mineral-associated Hg is the largest reservoir of Hg in the environment where it can account for nearly 60% of the global Hg mass inventory. A large fraction of this pool is comprised of mercury sulfide (HgS) minerals, including metacinnabar (beta-HgS). HgS minerals have long been considered insignificant sources of Hg to aqueous or atmospheric pools in all but severely acidic environments due to their low solubility and slow abiotic dissolution kinetics. Little previous work has been conducted investigating the bacterial colonization of HgS minerals and the potential role of these mineral-associated communities in impacting the mobility of mineral-hosted Hg. To address this gap in knowledge, the studies within this dissertation employed a combination of field- and laboratory-based methods. Using culture-independent techniques, this work revealed that sulfur-oxidizing bacteria can extensively colonize metacinnabar within aerobic, near neutral pH, creek sediments, suggesting a potential role for chemolithotrophic bacteria in metacinnabar weathering. Within laboratory incubations, the dominant bacterial colonizer (Thiobacillus thioparus), induced extensive release and volatilization of metacinnabar-hosted Hg. These findings expose a new pathway for metacinnabar dissolution and point to mineral-hosted Hg as an underappreciated source of elemental Hg that may contribute to global atmospheric Hg budgets. In addition, this work elucidates the importance of thiosulfate, a major intermediate sulfur species in the environment, in stimulating metacinnabar dissolution. Therefore, the work within this dissertation shows that authigenic HgS minerals are not merely a sink for Hg within non-acidic natural environments and instead are a source of dissolved and gaseous Hg. This work provides critical information for predicting the transport of Hg in the environment and for developing appropriate management and remediation strategies for Hg-contaminated systems. / Engineering and Applied Sciences
3

Caractérisation du rôle de l'aluminium dans les interactions entre les microorganismes et les matériaux cimentaires dans le cadre des réseaux d'assainissement / Characterization of the role of aluminium in the interactions between microorganisms and cementitious material in sewer networks context

Buvignier, Amaury 28 June 2018 (has links)
Une part importante de la détérioration des réseaux d’assainissement en matériau cimentaire est d’origine biologique. Dans ce contexte, les matériaux à base de ciment alumineux ont montré une meilleure durabilité que ceux à base de ciment Portland ordinaire, couramment utilisés. Les hypothèses de la littérature qui expliqueraient cette meilleure résistance sont centré sur l’aluminium (présent à plus de 50% dans les ciments alumineux pour seulement 5% dans les ciments Portland). L’objectif de cette thèse est de caractériser et hiérarchiser les mécanismes de résistance des matériaux cimentaires lors de la biodétérioration. Cela permettra de comprendre le rôle de l’aluminium dans les interactions entre les microorganismes et les matériaux cimentaires. Après des études en réacteur et des tests de biodétérioration de pâte de ciments en laboratoire, il semblerait que la principale cause de résistance est due à la réactivité des matrices cimentaires plus qu’à un effet inhibiteur de l’aluminium ou du matériau sur les microorganismes. / An important part of the deterioration observed in concrete sewer networks is due to biological activity. In this context, calcium aluminate cement (CAC) based material has shown a better durability than ordinary Portland cement, usually used in such context. In literature, hypothesis explaining the better resistance are focused on aluminium. The aim of the project is to characterize the role of aluminium in the interactions between cementitious material and microorganisms. Reactor study and Lab scale aggressive biodeterioration protocol of cementitious material revealed that the better resistance of CAC is due to their lower reactivity and not to a bacteriostatic effect of the material on the microorganisms.
4

Production et élimination des sulfures produits lors de la biométhanisation de boues de station de traitement des eaux usées domestiques : Procédés biologiques de sulfooxydation par des thiobacilles anaérobies facultatifs (projet SULFOX) / Production and removal of sulfides produced during biomethanation of from domestic wastewater treatment plant sludge : Biological sulfooxidation processes using facultative anaerobic thiobacilli (SULFOX project)

El Houari, Abdelaziz 30 August 2018 (has links)
Reconnu par leur effet toxique, inhibiteur et corrosif, les sulfures (S2-, SH-, SH2) sont un sous-produit indésirable de la digestion anaérobie des boues de station de traitement des eaux domestiques de la ville de Marrakech, Maroc (STEP). Ils proviennent essentiellement de la réduction "dissimilatrice" des composés soufrés (SO4 2-, SO3 2-, S2O4 2- ..) contenus dans ces boues. Ce processus est réalisé par un groupe bactérien anaérobie appelé bactéries sulfatoréductrices (BSR). Une fois dans le biogaz, les sulfures sous forme gazeuse réduisent en plus la durée de vie des installations et des équipements de la STEP. Elle est ainsi dotée d’installations biologiques et physico-chimiques lui permettant d’éliminer ces sulfures avant la transformation du biogaz en énergie électrique. Cependant, ces procédés sont onéreuses et grandes consommatrices d’énergies. D’où l’idée de minimiser la production des sulfures au sein même des digesteurs anaérobies. Pour cela, il était nécessaire d’abord de connaître les microorganismes à l'origine de la production des sulfures (BSR), ceux potentiellement impliqués dans leur élimination (bactéries sulfo-oxydantes), et d’un groupe de microorganismes fermentaires (Synergistetes) intervenant dans le bon fonctionnement de la digestion anaérobie. Ces études ont été menées à la fois sur des d'approches moléculaires et culturales. Les résultats obtenus, ont permis de comprendre comment ces groupes bactériens, d’intérêts écologique et économique importants, interviennent dans la digestion anaérobie des boues de la STEP permettant à la fois d’accélérer les processus d’oxydation de la matière organique combinée à la réduction des composés soufrés et de minimiser la concentration des en sulfure dans le biogaz. / Recognized by their toxic, inhibitory and corrosive effect, sulfides (S2-, SH-, H2S) are an undesirable by-product of the anaerobic digestion of from domestic wastewater treatment plants sludge in the city of Marrakech, Morocco (WWTP). They produced mainly by the dissimilatory reduction of sulfur compounds (SO42-, SO32-, S2O42-) contained in these sludges. This process is performed by an anaerobic bacterial group called sulfate reducing bacteria (SRB). Once in the biogas, the sulfides in gaseous form shorten in addition the lifetime of the installations and equipments of the WWTP. It is thus equipped with biological and physicochemical installations allowing it to eliminate these sulfides before the transformation of biogas into electrical energy. However, these processes are expensive and consume large amounts of energy. Hence the idea of minimizing the production of sulfides within anaerobic digesters. For this, it was first necessary to know the microorganisms originating of the production of sulfides (SRB), those potentially involved in their elimination (sulfur oxidizing bacteria), and a group of fermentative microorganisms (Synergistetes) involved in the good functioning of the anaerobic digestion. These studies were conducted on both molecular and cultural approaches. The results obtained allowed to understand how these bacterial groups, of great ecological and economic interest, are involved in the anaerobic digestion of sludge from the WWTP, which both accelerates the oxidation processes of the organic matter combined with the reduction of sulfur compounds and to minimize the concentration of sulfide in biogas.

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