Implication des levures du genre Candida et des amibes libres dans le risque infectieux lié à l'eau – contexte des soins dentaires / Involvement of Candida yeasts and free-living amoebae in infectious risk associated with water – dental unit context

Barbot, Vanessa

30 October 2012

La contamination microbienne des units de soins dentaires (USD) est connue depuis les années 60. L'eau circule à l'intérieur des USD dans des conditions favorables au développement d'un biofilm (faible débit, nature des surfaces, stagnation). Ce biofilm, réservoir de micro-organismes potentiellement pathogènes, peut représenter un risque infectieux pour les patients et le personnel dentaire exposés à l'eau et aux aérosols générés lors des soins dentaires, en particulier s'ils sont immunodéprimés.Des micro-organismes provenant de l'eau, tels que les amibes libres, peuvent être retrouvés dans ce biofilm. Des protozoaires ubiquitaires de l'environnement du genre Acanthamoeba ou Hartmannella, connus comme pathogènes opportunistes chez l'Homme (kératites, méningo-encéphalites) et ayant la capacité de servir d'hôte pour le développement intracellulaire de certains microorganismes pathogènes (ex : Legionella pneumophila), ont en effet été isolés dans l'eau des USD.D'autre part, des micro-organismes provenant de la cavité buccale d'un patient peuvent également se retrouver dans le système d'eau des USD, en même temps que des traces de salive et/ou de sang, suite à un dysfonctionnement ou un mauvais entretien des valves anti-reflux des porte-instruments rotatifs. Les levures du genre Candida sont des commensaux du tube digestif humain, pathogènes opportunistes notamment responsables d'infections oro-pharyngées, et parfois retrouvées dans les USD.Ce travail a consisté d'une part en l'étude de la capacité de deux amibes libres : A. castellanii et H. vermiformis, ainsi que de trois espèces de Candida : C. albicans, C. glabrata et C. parapsilosis, à survivre dans l'eau, en présence ou non de salive. Les résultats montrent une influence dose-dépendante et espèce-dépendante de la salive sur la survie des trois levures, et aucun effet sur la viabilité des amibes. Des interactions ont pu être mises en évidence entre amibes libres et levures : A. castellanii est capable d'internaliser puis de digérer les trois espèces de levures, induisant leur élimination rapide, indépendamment de la présence de salive. En revanche, H. vermiformis permet la survie et la prolifération de Candida spp. dans l'eau, même en l'absence de salive.Enfin, dans une démarche de prévention et de lutte contre le risque infectieux lié à l'eau des USD, l'efficacité de différents traitements chimiques communément utilisés : le chlore (NaOCl), le peroxyde d'hydrogène (H2O2) et l'Oxygenal 6©, a été étudiée sur les différentes espèces de Candida et d'amibes libres. Ces traitements montrent une efficacité variable : le chlore requiert l'utilisation de concentrations élevées (>26 ppm) et peu compatibles avec l'usage courant des USD. Le H2O2 ne présente pas d'activité significative dans les conditions testées (de 0.07% à 0.9% v/v). En revanche, l'Oxygenal 6© apparaît le plus efficace pour l'éradication des levures du genre Candida et des amibes libres dans l'eau (dès 0.05%). / Microbial contamination of dental unit waterlines (DUW) is known since the 60's. Water circulates throughout DUW with environmental conditions encouraging biofilm development (low flow, surface material, stagnation). This biofilm, which is a reservoir of potentially pathogenic micro-organisms, may represent an infectious risk for patients and dental staff exposed to water and aerosols generated during dental cares, in particular for immunocompromised persons. Micro-organisms coming from water, such as free-living amoebae (FLA), may be isolated in this biofilm. Protozoa belonging to Acanthamoeba or Hartmannella genera are ubiquitous in the environment; they are known to be opportunistic pathogens for Human (keratitis, meningo-encephalitis), to encourage intracellular development of some pathogenic micro-organisms (for example: Legionella pneumophila), and they have already been isolated in DUW.On the other hand, micro-organisms coming from the oral cavity of an infected patient may also be isolated in DUW water, mixed with saliva traces and/or blood, mainly because of the dysfunction or the poor maintenance of anti-retraction valves. Candida yeasts colonize human's oral cavity and digestive tract as commensals or opportunistic pathogens, thus implicated in oro-pharyngeal infections; they are sometimes isolated in DUW.This work focused first on the study of the survival capacity of two species of FLA: A. castellanii and H. vermiformis, and three species of yeasts: C. albicans, C. glabrata and C. parapsilosis, in water, with or without saliva. Results showed that the addition of saliva permitted both survival and proliferation of all three tested Candida species whereas no effect was observed on FLA growth. Then, interactions have been demonstrated between FLA and yeasts: A. castellanii were able to internalize and then digest the three tested yeasts species, inducing their rapid degradation, independently of saliva presence. Conversely, H. vermiformis were able to promote Candida survival and proliferation in water, with or without saliva.Finally, in order to prevent and fight against infectious risk associated with DUW water, the efficacy of commonly used chemical treatments: chlorine (NaOCl), hydrogen peroxide (H2O2) and Oxygenal 6©, was studied against the three species of Candida and the two species of FLA. These treatments showed a variable efficacy: chlorine was effective only using the highest tested concentrations (> 14 ppm), which are not compatibles with DUW use. H2O2 displayed no significant activity in the experimental conditions (0.07% to 0.9% v/v). Oxygenal 6© seemed to be the more effective for eradication of Candida yeasts and FLA, in water (even with 0.05% v/v).

Risque infectieux

Candida

Amibes libres

Interactions microbiennes

Salive

Units de soins dentaires

Eau

Infectious risk

Candida

Free-living amoebae

Microbial interactions

Saliva

Dental units

Water

579

Interaction of Actinides with the Predominant Indigenous Bacteria in Äspö Aquifer - Interactions of Selected Actinides U(VI), Cm(III), Np(V) and Pu(VI) with Desulfovibrio äspöensis

Bernhard, Gert, Selenska-Pobell, Sonja, Geipel, Gerhard, Rossberg, Andre, Merroun, Mohamed, Moll, Henry, Stumpf, Thorsten

January 2005

Sulfate-reducing bacteria (SRB) frequently occur in the deep granitic rock aquifers at the Äspö Hard Rock Laboratory (Äspö HRL), Sweden. The new SRB strain Desulfovibrio äspöensis could be iso-lated. The objective of this project was to explore the basic interaction mechanisms of uranium, curium, neptunium and plutonium with cells of D. äspöensis DSM 10631T. The cells of D. äspöensis were successfully cultivated under anaerobic conditions as well in an optimized bicarbonate-buffered mineral medium as on solid medium at 22 °C. To study the interaction of D. äspöensis with the actinides, the cells were grown to the mid-exponential phase (four days). The collected biomass was usually 1.0±0.2 gdry weight/L. The purity of the used bacterial cultures was verified using microscopic techniques and by applying the Amplified Ribosomal DNA Restriction Enzyme Analysis (ARDREA). The interaction experiments with the actinides showed that the cells are able to remove all four actinides from the surrounding solution. The amount of removed actinide and the interaction mechanism varied among the different actinides. The main U(VI) removal occurred after the first 24 h. The contact time, pH and [U(VI)]initial influence the U removal efficiency. The presence of uranium caused a damaging of the cell membranes. TEM revealed an accumulation of U inside the bacterial cell. D. äspöensis are able to form U(IV). A complex interaction mechanism takes place consisting of biosorption, bioreduction and bioaccumulation. Neptunium interacts in a similar way. The experimental findings are indicating a stronger interaction with uranium compared to neptunium. The results obtained with 242Pu indicate the ability of the cells of D. äspöensis to accumulate and to reduce Pu(VI) from a solution containing Pu(VI) and Pu(IV)-polymers. In the case of curium at a much lower metal concentration of 3x10-7 M, a pure biosorption of Cm(III) on the cell envelope forming an inner-sphere surface complex most likely with organic phosphate groups was detected. To summarize, the strength of the interaction of D. äspöensis with the selected actinides at pH 5 and actinide concentrations ≥10 mg/L ([Cm] 0.07 mg/L) follows the pattern: Cm > U > Pu >> Np.

Microbial Diversity in Opalinus Clay and Interaction of Dominant Microbial Strains with Actinides (Final Report BMWi Project No.: 02 E 10618)

Moll, Henry, Lütke, Laura, Bachvarova, Velina, Steudner, Robin, Geißler, Andrea, Krawczyk-Bärsch, Evely, Selenska-Pobell, Sonja, Bernhardt, Gert

January 2013

For the first time microbial tDNA could be isolated from 50 g unperturbed Mont Terri Opalinus Clay. Based on the analysis of the tDNA the bacterial diversity of the unperturbed clay is dominated by representatives of Firmicutes, Betaproteobacteria, and Bacteriodetes. Firmicutes also dominate after treatment of the clay with R2A medium. Bacteria isolated from Mont Terri Opalinus Clay on R2A medium were related to Sporomusa spp., Paenibacillus spp., and Clostridium spp.. All further investigations are concentrated on the unique isolates Sporomusa sp. MT-2 and Paenibacillus sp. MT-2. Cells of the type Sporomusa sp. MT-2 and Paenibacillus sp. MT-2 were comprehensively analyzed in terms of growing, morphology, functional groups of the cell envelope, and cell membrane structure. Strong actinide(An)/lanthanide(Ln)-interactions with the Opalinus Clay isolates and the Äspö-strain Pseudomonas fluorescens (CCUG 32456) could be determined within a broad pH range (2-8). The metals bind as a function of pH on protonated phosphoryl, carboxyl and deprotonated phosphoryl sites of the respective cell membrane. The thermodynamic surface complexation constants of bacterial An/Ln-species were determined and can be used in modeling programs. Depending on the used An different interaction mechanisms were found (U(VI): biosorption, partly biomineralisation; Cm(III): biosorption, indications for embedded Cm(III); Pu: biosorption, bioreduction and indications for embedded Pu). Different strategies of coping with U(VI) were observed comparing P. fluorescens planktonic cells and biofilms under the chosen experimental conditions. An enhanced capability of the biofilm to form meta-autunite in comparison to the planktonic cells was proven. Conclusively, the P. fluorescens biofilm is more efficient in U(VI) detoxification. In conclusion, Mont Terri Opalinus Clay contains bacterial communities, that may influence the speciation and hence the migration behavior of selected An/Ln under environmental conditions.

info:eu-repo/classification/ddc/540

ddc:540

Understanding the relationship between bacterial community composition and the morphology of bloom-forming <i>Microcystis</i>

Akins, Leighannah

30 November 2018

No description available.

Biology

Aquatic Sciences

Ecology

Environmental Science

Microbiology

Diatom interactions in the open ocean : from the global patterns to the single cell / Interactions des diatomées dans l’océan : de l’échelle globale à la cellule unique

Vincent, Flora

21 November 2016

Les diatomées sont des micro-algues unicellulaires, qui jouent un rôle primordial dans l’eco-système marin. En effet, elles sont responsables de 20% de l’activité photosynthétique sur Terre, et sont à la base de la chaîne alimentaire marine, toujours plus menacée par le changement climatique. Les diatomées établissent diverses interactions microbiennes avec des organismes issus de l’ensemble de l’arbre du vivant, à travers des méchanismes complexes tels que la symbiose, le parasitisme ou la compétition. L’objectif de ma thèse a été de comprendre comment ces interactions structurent la communauté du plancton, à grande échelle spatiale. Pour ce faire, j’ai développé de nouvelles approches basées sur le jeu de données inédit de Tara Océans, une expédition mondiale qui a exploré la diversité et les fonctions des microbes marins, en récoltant plus de 40.000 échantillons à travers 210 sites autour du monde. Grâce à l’analyse de réseaux de co-occurrence microbiens, je montre d’une part que les diatomées agissent comme des « ségrégateurs répulsifs » à l’échelle globale, en particulier envers les organismes potentiellement dangeureux tels que les prédateurs et les parasites, et d’autre part que la co-occurrence des espèces ne s’explique qu’en minorité par les facteurs environnementaux. Grâce à la richesse des données Tara Océans, j’ai par ailleurs permis la charactérisation d’une interaction biotique impliquant une diatomée et un cilié hétérotrophe à l’échelle de l’eco-système, illustrant de surcroît le succès des approches dirigées par les données. Dans l’ensemble, ma thèse contribue à notre compréhension des interactions biotiques impliquant les diatomées, de l’échelle globale à la cellule unique. / Diatoms are unicellular photosynthetic microeukaryotes that play a critical role in the functioning of marine ecosystems. They are responsible for 20% of global photosynthesis on Earth and lie at the base of marine food webs, ever more threatened by climate change.Diatoms establish microbial interactions with numerous organisms across the whole tree of life, through complex mechanisms including symbiosis, parasitism and competition. The goal of my thesis was to understand how those biotic interactions structure the planktonic community at large spatial scales, by using new approaches based on the unprecedented Tara Oceans dataset, a unique and worldwide circumnavigation that collected over 40.000 samples across 210 sites to explore the diversity and functions of marine microbes. Through the analysis of microbial association networks, I show that diatoms act as repulsive segregators in the ocean, in particular towards potentially harmful organisms such as predators as well as parasites, and that species co-occurrence is driven by environmental factors in a minority of cases. By leveraging the singularity of the Tara Oceans data, I provide a comprehensive characterization of a prevalent biotic interaction between a diatom and heterotrophic ciliates at large spatial scale, illustrating the success of data-driven research. Overall, my thesis contributes to our understanding of diatom biotic interactions, from the global patterns to the single cell.

Plancton

Diatomées

Biodiversité marine

Interactions microbiennes

Réseaux de corrélation microbiens

Structure des communautés

Cellule unique

Biologie écosystémique

Plankton

Diatoms

Marine biodiversity

Microbial interactions

Microbial correlation networks

Community structure

Single cell

Ecosystem biology

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