Soilborne disease suppressiveness / conduciveness : analysis of microbial community dynamics / by Johannes Hendrikus Habig

Habig, Johannes Hendrikus

January 2003

Take-all is the name given to the disease caused by a soilborne fungus Gaeumannomyces graminis (Sacc.) von Arx and Olivier var. tritici Walker (Ggt), an ascomycete of the family Magnaportheaceae (Cook, 2003). This fungus is an aggressive soil-borne pathogen causing root rot of wheat (primary host), barley and rye crops (secondary host). The flowering, seedling, and vegetative growth stages can be affected by the infection of the whole plant, leaves, roots, and stems. Infections of roots result in losses in crop yield and quality primarily due to a lowering in nutrient uptake. Take-all is most common in regions where wheat is cultivated without adequate crop rotation. Crop rotation allows time between the planting dates of susceptible crops, which causes a decrease in the inoculum potential of soilborne plant pathogens to levels below an economic threshold by resident antagonistic soil microbial communities. Soilborne disease suppressiveness is an inherent characteristic of the physical, chemical, and/or biological structure of a particular soil which might be induced by agricultural practices and activities such as the cultivation of crops, or the addition of organisms or nutritional amendments, causing a change in the microfloral environment. Disturbances of soil ecosystems that impact on the normal functioning of microbial communities are potentially detrimental to soil formation, energy transfers, nutrient cycling, and long-term stability. In this regard, an overview of soil properties and processes indicated that the use of microbiological and biochemical soil properties, such as microbial biomass, the analysis of microbial functional diversity and microbial structural diversity by the quantification of community level physiological profiles and signature lipid biomarkers are useful as indicators of soil ecological stress or restoration properties because they are more responsive to small changes than physical and chemical characteristics. In this study, the relationship between physico-chemical characteristics, and different biological indicators of soil quality of agricultural soils conducive, suppressive, and neutral with respect to take-all disease of wheat as caused by the soilborne fungus Gaeumannomyces graminis var. tritici (Ggt), were investigated using various techniques. The effect of crop rotation on the functional and structural diversity of soils conducive to take-all disease was also investigated. Through the integration of quantitative and qualitative biological data as well as the physico-chemical characteristics of the various soils, the functional and structural diversity of microbial IV communities in the soils during different stadia of take-all disease of wheat were characterised. All results were evaluated statistically and the predominant physical and chemical characteristics that influenced the microbiological and biochemical properties of the agricultural soils during different stadia of take-all disease of wheat were identified using multivariate analyses. Although no significant difference @ > 0.05) could be observed between the various soils using conventional microbiological enumeration techniques, the incidence of Gliocladium spp. in suppressive soils was increased. Significant differences @ < 0.05) were observed between agricultural soils during different stadia of take-all disease of wheat. Although no clear distinction could be made between soils suppressive and neutral to take-all disease of wheat, soils suppressive and conducive to take-all disease of wheat differed substantially in their community level physiological profiles (CLPPs). Soils suppressive / neutral to take-all disease were characterised by enhanced utilisation of carboxylic acids, amino acids, and carbohydrates, while conducive soils were characterised by enhanced utilisation of carbohydrates. Shifts in the functional diversity of the associated microbial communities were possibly caused by the presence of Ggt and associated antagonistic fungal and bacterial populations in the various soils. It was evident that the relationships amongst the functionality of the microbial communities within the various soils had undergone changes through the different stages of development of take-all disease of wheat, thus implying different substrate utilisation capabilities of present soil microbial communities. Diversity indices were calculated as Shannon's diversity index (H') and substrate equitability (J) and were overall within the higher diversity range of 3.6 and 0.8, respectively, indicating the achievement of very high substrate diversity values in the various soils. A substantial percentage of the carbon sources were utilised, which contributed to the very high Shannon-Weaver substrate utilisation indices. Obtained substrate evenness (equitability) (J) indices indicated an existing high functional diversity. The functional diversity as observed during crop rotation, differed significantly (p < 0.05) from each other, implying different substrate utilisation capabilities of present soil microbial communities, which could possibly be ascribed to the excretion of root exudates by sunflowers and soybeans. Using the Sorenson's index, a clear distinction could be made between the degrees of substrate utilisation between microbial populations in soils conducive, suppressive, and neutral to take-all disease of wheat, as well as during crop rotation. Furthermore, the various soils could also be differentiated on the basis of the microbial community structure as determined by phospholipid fatty acid (PLFA) analysis. Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Soils conducive and neutral to take-all disease of wheat were characterised by high concentrations of manganese, as well as elevated concentrations of monounsaturated fatty acids, terminally branched saturated fatty acids, and polyunsaturated fatty acids which were indicative of Gram-negative bacteria, Gram-positive bacteria and micro eukaryotes (primarily fungi), respectively. These soils were also characterised by low concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as low soil pH. Soil suppressive to take-all disease of wheat was characterised by the elevated levels of estimated of biomass and elevated concentrations of normal saturated fatty acids, which is ubiquitous to micro-organisms. The concentration of normal saturated fatty acids in suppressive soils is indicative of a low structural diversity. This soil was also characterised by high concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as elevated soil pH. The relationship between PLFAs and agricultural soils was investigated using principal component analysis (PCA), redundancy analysis (RDA) and discriminant analysis (DA). Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Hierarchical cluster analysis of the major phospholipid fatty acid groups indicated that the structural diversity differed significantly between soils conducive, suppressive, and neutral to take-all disease of wheat caused by Gaeumannomyces graminis var. tritici. The results indicate that the microbial community functionality as well as the microbial community structure was significantly influenced by the presence of take-all disease of wheat caused by Gaeumannomyces graminis var. tritici, and that the characterisation of microbial functional and structural diversity by analysis of community level physiological profiles and phospholipid fatty acid analysis, respectively, could be successfully used as an assessment criteria for the evaluation of agricultural soils conducive, suppressive, and neutral to take-all disease of wheat, as well as in crop rotation systems. This methodology might be of significant value in assisting in the management and evaluation of agricultural soils subject to the prevalence of other soilborne diseases. / Thesis (M.Sc. (Microbiology))--North-West University, Potchefstroom Campus, 2004.

Soil microbial communities

Gaeumannomyces graminis var. tritici

Take-all disease

Crop rotation

Diversity indices

Soil microbial community structure

Phospholipid fatty acids (PFLAs)

Soilborne disease suppressiveness / conduciveness : analysis of microbial community dynamics / by Johannes Hendrikus Habig

Habig, Johannes Hendrikus

January 2003

Take-all is the name given to the disease caused by a soilborne fungus Gaeumannomyces graminis (Sacc.) von Arx and Olivier var. tritici Walker (Ggt), an ascomycete of the family Magnaportheaceae (Cook, 2003). This fungus is an aggressive soil-borne pathogen causing root rot of wheat (primary host), barley and rye crops (secondary host). The flowering, seedling, and vegetative growth stages can be affected by the infection of the whole plant, leaves, roots, and stems. Infections of roots result in losses in crop yield and quality primarily due to a lowering in nutrient uptake. Take-all is most common in regions where wheat is cultivated without adequate crop rotation. Crop rotation allows time between the planting dates of susceptible crops, which causes a decrease in the inoculum potential of soilborne plant pathogens to levels below an economic threshold by resident antagonistic soil microbial communities. Soilborne disease suppressiveness is an inherent characteristic of the physical, chemical, and/or biological structure of a particular soil which might be induced by agricultural practices and activities such as the cultivation of crops, or the addition of organisms or nutritional amendments, causing a change in the microfloral environment. Disturbances of soil ecosystems that impact on the normal functioning of microbial communities are potentially detrimental to soil formation, energy transfers, nutrient cycling, and long-term stability. In this regard, an overview of soil properties and processes indicated that the use of microbiological and biochemical soil properties, such as microbial biomass, the analysis of microbial functional diversity and microbial structural diversity by the quantification of community level physiological profiles and signature lipid biomarkers are useful as indicators of soil ecological stress or restoration properties because they are more responsive to small changes than physical and chemical characteristics. In this study, the relationship between physico-chemical characteristics, and different biological indicators of soil quality of agricultural soils conducive, suppressive, and neutral with respect to take-all disease of wheat as caused by the soilborne fungus Gaeumannomyces graminis var. tritici (Ggt), were investigated using various techniques. The effect of crop rotation on the functional and structural diversity of soils conducive to take-all disease was also investigated. Through the integration of quantitative and qualitative biological data as well as the physico-chemical characteristics of the various soils, the functional and structural diversity of microbial IV communities in the soils during different stadia of take-all disease of wheat were characterised. All results were evaluated statistically and the predominant physical and chemical characteristics that influenced the microbiological and biochemical properties of the agricultural soils during different stadia of take-all disease of wheat were identified using multivariate analyses. Although no significant difference @ > 0.05) could be observed between the various soils using conventional microbiological enumeration techniques, the incidence of Gliocladium spp. in suppressive soils was increased. Significant differences @ < 0.05) were observed between agricultural soils during different stadia of take-all disease of wheat. Although no clear distinction could be made between soils suppressive and neutral to take-all disease of wheat, soils suppressive and conducive to take-all disease of wheat differed substantially in their community level physiological profiles (CLPPs). Soils suppressive / neutral to take-all disease were characterised by enhanced utilisation of carboxylic acids, amino acids, and carbohydrates, while conducive soils were characterised by enhanced utilisation of carbohydrates. Shifts in the functional diversity of the associated microbial communities were possibly caused by the presence of Ggt and associated antagonistic fungal and bacterial populations in the various soils. It was evident that the relationships amongst the functionality of the microbial communities within the various soils had undergone changes through the different stages of development of take-all disease of wheat, thus implying different substrate utilisation capabilities of present soil microbial communities. Diversity indices were calculated as Shannon's diversity index (H') and substrate equitability (J) and were overall within the higher diversity range of 3.6 and 0.8, respectively, indicating the achievement of very high substrate diversity values in the various soils. A substantial percentage of the carbon sources were utilised, which contributed to the very high Shannon-Weaver substrate utilisation indices. Obtained substrate evenness (equitability) (J) indices indicated an existing high functional diversity. The functional diversity as observed during crop rotation, differed significantly (p < 0.05) from each other, implying different substrate utilisation capabilities of present soil microbial communities, which could possibly be ascribed to the excretion of root exudates by sunflowers and soybeans. Using the Sorenson's index, a clear distinction could be made between the degrees of substrate utilisation between microbial populations in soils conducive, suppressive, and neutral to take-all disease of wheat, as well as during crop rotation. Furthermore, the various soils could also be differentiated on the basis of the microbial community structure as determined by phospholipid fatty acid (PLFA) analysis. Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Soils conducive and neutral to take-all disease of wheat were characterised by high concentrations of manganese, as well as elevated concentrations of monounsaturated fatty acids, terminally branched saturated fatty acids, and polyunsaturated fatty acids which were indicative of Gram-negative bacteria, Gram-positive bacteria and micro eukaryotes (primarily fungi), respectively. These soils were also characterised by low concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as low soil pH. Soil suppressive to take-all disease of wheat was characterised by the elevated levels of estimated of biomass and elevated concentrations of normal saturated fatty acids, which is ubiquitous to micro-organisms. The concentration of normal saturated fatty acids in suppressive soils is indicative of a low structural diversity. This soil was also characterised by high concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as elevated soil pH. The relationship between PLFAs and agricultural soils was investigated using principal component analysis (PCA), redundancy analysis (RDA) and discriminant analysis (DA). Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Hierarchical cluster analysis of the major phospholipid fatty acid groups indicated that the structural diversity differed significantly between soils conducive, suppressive, and neutral to take-all disease of wheat caused by Gaeumannomyces graminis var. tritici. The results indicate that the microbial community functionality as well as the microbial community structure was significantly influenced by the presence of take-all disease of wheat caused by Gaeumannomyces graminis var. tritici, and that the characterisation of microbial functional and structural diversity by analysis of community level physiological profiles and phospholipid fatty acid analysis, respectively, could be successfully used as an assessment criteria for the evaluation of agricultural soils conducive, suppressive, and neutral to take-all disease of wheat, as well as in crop rotation systems. This methodology might be of significant value in assisting in the management and evaluation of agricultural soils subject to the prevalence of other soilborne diseases. / Thesis (M.Sc. (Microbiology))--North-West University, Potchefstroom Campus, 2004.

Soil microbial communities

Gaeumannomyces graminis var. tritici

Take-all disease

Crop rotation

Diversity indices

Soil microbial community structure

Phospholipid fatty acids (PFLAs)

Association of chickpea with soil fungi: a comparison of cultivars

2014 November 1900

Certain crop plants are susceptible to pathogens or unable to develop efficient microbial symbioses. These crops adversely impact soil biological quality with consequences on plant health and productivity of cropping systems. Chickpea is a rotational pulse crop with two types: kabuli and desi, and several cultivars. Cultivation of chickpea has inconsistent effects on soil microbial communities and subsequent wheat crops. I conducted field studies and used high throughput molecular analyses to explore the variations among chickpeas to identify cultivars developing fungal communities that are conducive to plant health and productivity. I also carried out greenhouse studies and used biochemical analyses to investigate the response of chickpea cultivars to arbuscular mycorrhizal (AM) fungi and non-AM fungal endophytes and identify the influence of root and root metabolites on the endophytic and pathogenic fungi. Cultivars and types of chickpeas and environmental conditions promoted different fungal communities in the root endosphere. Funneliformis and Claroideoglomus were the dominant AM fungal genera and Fusarium and Alternaria were the dominant non-AM fungal genera in the roots of chickpea. The roots of cultivars CDC Corrine, CDC Cory and CDC Anna hosted the most diverse fungal communities in contrast to CDC Alma and CDC Xena roots which hosted the least diverse communities. Plant response to AM and non-AM fungal endophytes varied with genotype and type of chickpea. The root symbiosis effectively promoted plant growth in CDC Cory, CDC Anna and CDC Frontier and stimulated nitrogen fixation in CDC Corrine. Cultivars of chickpea responded differently to dual inoculation of the AM and non-AM fungal endophytes. Co-inoculation with AM and non-AM fungal endophytes had additive effects on CDC Corrine, CDC Anna and CDC Cory but non-AM fungal endophytes reduced the positive effect of AM fungi in Amit and CDC Vanguard. Desi chickpea appeared to form more efficient symbioses with soil fungal resources than kabuli chickpea. Protein(s) up-regulated in the mycorrhizal roots of the desi chickpea CDC Anna suppressed the growth of the fungal endophytes Trichoderma harzianum and Geomyces vinaceus and of the pathogens Fusarium oxysporum and Rhizoctonia sp. The formation of AM symbiosis decreased the production of root bioactive metabolites soluble in 25% methanol. Some of the root metabolites stimulated the growth of Trichoderma harzianum and Geomyces vinaceus, and a few inhibited Rhizoctonia sp. and Fusarium oxysporum. A few metabolites with contrasting effects on the different fungal species were detected. The non-protein phytochemicals had selective effects on the endophytes and pathogens whereas the antifungal proteins of mycorrhizal roots were non-selective. Overall the study reveals a "genotype effect" of chickpea on the soil microbiota suggesting the possibility to improve the performance of this crop through the selection of genotypes improving the communities of root associated fungi, by associating and responding to beneficial fungi and repressing the pathogens.

Root-associated microbial communities

Arbuscular mycorrhizal fungi

Fungal endophytes

Fungal pathogens

Host preference

Disease resistance

Chickpea Cultivars

Root bioactive phytochemicals

Plant genotype

Plant symbioses

Plant breeding

Influence des pratiques de recharge des aquifères par des eaux pluviales sur les communautés microbiennes des nappes phréatiques / Influence of managed aquifer recharge practices by stromwater runoff on groundwater bacterial communities

Voisin, Jérémy

12 July 2017

En ville, les systèmes de récupération et d'infiltration des eaux pluviales dans le sous-sol ont pour conséquence d'augmenter la connectivité hydrologique entre la surface et la nappe phréatique. Ces pratiques d'infiltration produisent de nombreuses perturbations physico-chimiques au niveau de la nappe (ex. augmentation des variations thermiques, baisse des concentrations en oxygène dissous, enrichissement de la nappe en matière organique dissoute) mais les conséquences sur le compartiment microbien restent peu connues. L'objectif principal de la thèse est de déterminer les effets de l'infiltration des eaux pluviales sur les communautés microbiennes des nappes phréatiques, aussi bien en termes d'abondance, d'activités que de diversité génétique bactérienne. En se basant sur les changements environnementaux associés à l'infiltration des eaux pluviales et l'analyse des communautés bactériennes, un objectif fondamental est d'évaluer l'importance des phénomènes de dispersion (ex. transferts) et de sélection par des facteurs abiotiques (ex. disponibilité des ressources nutritives) sur les assemblages bactériens au sein des nappes phréatiques. Ces travaux ont été axés sur des expérimentations de terrain utilisant deux approches d'échantillonnage : une méthode active (prélèvements d'eau) et une méthode passive (incubation de substrats artificiels). La description des communautés a été effectuée par une méthode de séquençage de nouvelle génération (i.e. Illumina MiSeq) en se basant sur le gène rrs. Les résultats de ce travail mettent en avant une influence significative des pratiques d'infiltration sur les bactériomes d'un aquifère. En effet, le développement, les activités et la diversité des micro-organismes retrouvés dans la nappe ont été stimulés significativement par l'enrichissement en carbone organique dissous biodégradable engendré par ces pratiques. Néanmoins, cet impact est fortement réduit dans les systèmes étudiés où la zone non saturée est épaisse (> 10 m) et agit comme un filtre physique, chimique et biologique efficace entre le bassin d'infiltration et l'aquifère. Les faibles similarités entre les structures génétiques des bactériomes des eaux d'infiltration et dans la nappe indiquent que la zone non saturée joue un rôle efficace sur la rétention des bactéries dans les systèmes étudiés. En conclusion, cette thèse constitue la première étude d'envergure visant à quantifier la réponse du compartiment microbien des aquifères à des perturbations engendrées par l'infiltration des eaux pluviales en milieu urbain. Elle ouvre aussi de nouvelles perspectives sur les méthodes et outils d'évaluation de la qualité des nappes phréatiques / In urban area, managed aquifer recharge (MAR) systems raises hydrological connectivity between surface and groundwater. These infiltration practices are the cause of many disturbances in groundwaters (e.g. increase of thermal variations, decrease of dissolved oxygen or enrichment in organic matter) but associated consequences on microbial compartment remains unclear. The main aim of the thesis is to determine the effects of stormwater runoff infiltration on microbial communities of groundwater, in terms of abundance, activities and bacterial diversity. Based on environmental changes associated to MAR practices and bacterial community analyses, a fundamental question is to assess the importance of dispersal (e.g. transfers) and selection by abiotic factors (e.g. nutrients availability) on groundwater communities assemblage. This study is based on field experiments with two complementary strategies of sampling: an active one (i.e. groundwater sampling) and a passive one (incubation of artificial substrate). Communities’ description was made by next-generation sequencing (i.e. Illumina MiSeq) of rrs gene. The results showed a significant influence of MAR practices on microbial communities. Growth, activities and diversity of groundwater micro-organisms were mainly stimulated by biodegradable dissolved organic carbon enrichment associated to MAR practices. Nonetheless, this impact was reduced in systems where the vadose zone is thick (> 10 m) and acts as a physical, chemical and biological filter between the infiltration basin and the aquifer. Low similarities between bacterial communities of infiltration waters and bacterial communities of groundwaters reveal that vadose zone is effective on the retention of bacteria in studied systems. To conclude, this thesis constitutes the first major study that aimed to quantify microbial compartment response to disturbances caused by MAR practices in urban area. It also opens new perspectives on assessment tool for groundwater quality

Aquifère

Recharge Artificielle

Communauté microbienne

Diversité

Transfert

Sélection

Substrats Artificiels

Séquençage de nouvelle génération

Aquifer

Artificial recharge

Microbial communities

Diversity

Transfer

Selection

Artificial substrates

Next-generation sequencing

577

Využití mikrobiálních komunit jako markeru podmínek v podzemních biotopech / Use of microbial community structure as a marker of conditions in underground biotops

Burkartová, Kateřina

January 2017

The amount of data obtained by barcoding of prokaryotic 16S rDNA from natural habitats is increasing exponentially. Thus, methods enabling us to extract useful information from these data are of increasing importance. In this thesis microbial communities from water, sludge and drilling dust were analyzed by 16S rDNA sequencing in three geologically well described sedimentary aquifers in Bohemian Massif. The main goal of this research was to establish how different analytical approaches can be useful in interpretation of groundwater biogeochemical processes. Three approaches were used: First, taxonomy and metabolic traits of the most abundant microorganisms were assessed. Second, ordination methods showing metabolic and taxonomic variability between communities were used. Last the analysis of phylogenetic dissimilarity using UniFrac metrics was performed. When analyzing individual localities separately, the shift in microbial community composition corresponds with the change of environmental conditions. The unconstrained ordination method based on the variability in metabolic traits indicated, that sludge samples are more informative than water samples when asking which electron donor is used in microbial communities. On the other hand, unconstrained ordination methods were useless when the...

Etude des communautés microbiennes d'un système hydrothermal serpentinisé, la baie de Prony en Nouvelle-Calédonie : approches culturales et moléculaires. / Study of microbial communities of a serpentinizing hydrothermal system, the Bay of Prony, New Caledonia : cultivation and molecular approaches

Bes, Méline

02 February 2016

La serpentinisation est un processus d’altération des roches ultramafiques entrainant la formation de fluides alcalins chauds, riches en dihydrogène et méthane. Elle fournit l'énergie et la matière pour soutenir des communautés microbiennes chimiosynthétiques mais crée des conditions extrêmes en termes de pH et de disponibilité limitée en accepteurs d’électrons. Ce travail porte sur l’étude des communautés procaryotiques du système hydrothermal serpentinisé côtier de la baie de Prony en Nouvelle-Calédonie. Il a permis de déterminer leur composition taxonomique, leur structure et leur diversité. Le « noyau stable » des communautés indigènes déterminé par des techniques moléculaires (DGGE, SSCP, séquençage de banques de clones) se compose de Methanosarcinales, Thaumarchaeota, Chloroflexi, Alpha-, Gamma-, Delta, Beta-proteobacteria et Firmicutes. Ces communautés sont alimentées par des réactions d’oxydoréduction impliquant l’hydrogène, le méthane et les composés soufrés. Elles sont caractérisées par une faible diversité archéenne composée principalement de Methanosarcinales utilisant ou produisant le méthane. Le séquençage haut-débit de l’ADNr 16S bactérien et archéen a permis de mettre en évidence la présence de très nombreux taxons rares, certains jouant potentiellement un rôle dans les cycles biogéochimiques de Prony. Une nouvelle espèce de bactérie fermentaire, Acetoanaerobium pronyense ST07-YE, appartenant aux Firmicutes a été isolée et caractérisée par une approche culturale. Cette bactérie pourrait jouer un rôle important dans le maintien de certaines populations microbiennes, comme les méthanogènes, dans l’écosystème par la production de composés comme l’acétate. / Serpentinization is an alteration process of ultramafic rocks resulting in hydrogen- and methane-rich alkaline hot fluids formation. Serpentinization can provide energy and matter to support chemosynthetic microbial communities but also creates extreme living conditions in terms of pH and limited availability of electron acceptors. This work consisted in the study of the microbial communities of the coastal serpentinized hydrothermal system of the Bay of Prony in New Caledonia. It allowed to determine the taxonomic composition, diversity and structure of prokaryotic communities. The "stable core" of indigenous communities identified by molecular methods (DGGE, SSCP, Sanger sequencing of clone libraries) consisted of Methanosarcinales, Thaumarchaeota, Chloroflexi, Alpha-, Gamma-, Delta, Beta-proteobacteria and Firmicutes. These communities are fueled by redox reactions involving hydrogen, methane and sulfur compounds. The low archaeal diversity is mainly composed of Methanosarcinales who are potential primary producers using or producing methane. High throughput sequencing of the bacterial and archaeal 16S rDNA highlighted numerous rare taxa. Some potentially play a role in the biogeochemical cycles of Prony. The fermentative Acetoanaerobium pronyense ST07-YE sp. nov., belonging to Firmicutes, was isolated and characterized by cultivation approach. This bacterium capable of acetate and other substrates production may play an important role in this ecosystem, especially in the maintenance methanogens.

Communautés microbiennes

Baie de Prony

Serpentinisation

Approche culturale

Biologie moléculaire

Pyroséquençage

Microbial communities

Bay of Prony

Serpentinization

Cultivation approach

Molecular biology

Pyrosequencing

550

Diversité et fonctions des microorganismes associés à la litière de garrigue : influence de facteurs biotiques et abiotiques dans un contexte de changement climatique / Diversity and functions of microorganisms associated to shrubland litter : influence of biotics and abiotics factors under climate change.

Rancon, Anais

15 December 2014

Mon travail de thèse s'est attaché à étudier les effets de la diversité des litières et de la macrofaune du sol sur les communautés microbienne, sous contrainte hydrique. Dans une première partie, le suivi des communautés microbiennes associées aux feuilles de la litière (feuilles mortes) et de la phyllosphère (feuilles vivantes), pendant un an en conditions naturelles, a montré des différences marquées selon l'état physiologique de la feuille, l'importance de l'espèce végétale hôte sur les communautés microbiennes ainsi que l'évolution des communautés au cours de l'année. Une deuxième partie présente les résultats d'une expérience de décomposition en microcosmes selon deux modalités d'humidité, un gradient de dissimilarité fonctionnelle des espèces de litière, et la présence/absence d'une macrofaune détritivore. Nos résultats confortent l'importance de l'espèce végétale sur les communautés microbiennes et montrent que la présence de détritivores favorise la diversité microbienne. Enfin, une dernière partie évalue l'impact d'une diminution des précipitations et de la diversité des litières sur les communautés microbiennes lors d'une expérience de décomposition d'un an in situ, à l'aide de dispositifs d'exclusion de pluie. La composition des mélanges de litières a une influence plus marquée sur les communautés microbiennes que la baisse des précipitations. En conclusion, les résultats de mes travaux ont tendance à minorer l'effet d'une diminution des précipitations sur les communautés microbiennes, mais soulignent la sensibilité des interactions entre communauté végétale, macrofaune et microorganismes face au changement climatique. / My PhD work focused on studying the effects of litter diversity and soil macrofauna on microbial communities under water stress. In the first part, the monitoring of microbial communities associated with leaf litter (dead leaves) and phyllosphere (living leaves) for one year under natural conditions, showed marked differences depending on the physiological state of leaves, the importance of the host plant species on microbial communities and the changes of communities during the year. A second part presents the results of a microcosms decomposition experience under two humidity conditions, a functional dissimilarity gradient of litter species and the presence / absence of a detritivorous macrofauna. Our results reinforce the importance of the plant species on microbial communities and show that the presence of scavengers encourages microbial diversity. A final section assesses the impact of a decrease in precipitation and litter diversity on microbial communities in an in situ decomposition experiment during one year, using rain excluder devices . The composition of litter mixtures has a stronger influence on the microbial communities than lower rainfall. In conclusion, the results of my work tend to underestimate the effect of a decrease in precipitation on microbial communities, but emphasize the sensitivity of the interactions between plant community, macro- and micro-organisms to climate change.

Garrigue méditerranéenne

Sècheresse

Décomposition de la litière

Communautés microbiennes

Approches expérimentales

Mésocosmes

Dispositifs d'exclusion de pluie

Mediterranean shrubland

Litter decomposition

Microbial communities

Experimental approach

Mesocosms

Rain exclusion devices

Traitement de composés soufrés organiques récalcitrants par biofiltration : optimisation des conditions opératoires pour une application industrielle / Treatment of recalcitrant organic sulphur compounds by biofiltration : optimization of operating conditions for an industrial application.

Legrand, Paul

30 September 2011

Les émissions odorantes constituent un enjeu environnemental dont l'importance n'a cessé de croître dans les zones urbaines et industrielles. Les émissions anthropogéniques de composés soufrés contribuent à une concentration locale excédant fortement le seuil de perception. Afin de satisfaire des contraintes règlementaires de plus en plus strictes, les procédés biologiques dont la biofiltration sont une alternative intéressante car respectueuse de l'environnement et de moindre coût. Les seuils de perception des composés soufrés, très bas (µg. m-3), obligent à atteindre des efficacités d'abattement particulièrement élevées, le résiduel de concentration pouvant être à l'origine d'un impact notable sur les populations riveraines. L'étude a donc consisté à améliorer les performances des biofiltres concernant l'élimination des composés soufrés i) en ajustant certains paramètres opératoires clefs tels que le sens de circulation de l'effluent gazeux, le pH et l'ensemencement du matériau support, ii) en considérant le dimensionnement des biofiltres mis en œuvre (unités pilotes de laboratoire et semi-industrielles) et iii) la complexité du gaz à traiter (mono-polluant et mélange de composés à traiter). / Odorous emissions are a serious concern whose importance became higher in urban and industrial areas. Anthropogenic emissions of sulphur compounds lead to local concentration that exceeds strongly the odour threshold of human nose. In order to fulfil legal requirements that have become stricter in recent years, biological processes and biofiltration more accurately are an interesting alternative as biofilters provide an expanding variety of opportunities for economical and environmentally friendly solutions for many waste gas emissions. The odour thresholds of sulphur compounds are very low (µg.m3 air) and then require that biofilters provide high removal efficiency as the residual concentration can induce an odorous impact on neighbourhood populations.Hence, the study consisted in improving biofilters performances concerning sulphur compounds treatment i) by upgrading important operating parameters such as air flow distribution, pH and inoculation of packing material, ii) by considering biofilters design (laboratory and semi-industrial pilot units) and iii) the gaseous effluent complexity (only one pollutant and mixture of different compounds).

Nuisances odorantes

Biofiltration

Composés soufrés organiques

Équarrissage

Communautés microbiennes

Olfactométrie

Odour annoyance

Biofiltration

Organic sulphur compounds

Animal rendering

Microbial communities

Olfactometry

Impact des métabolites secondaires de plantes sur des bactéries pathogènes de la rhizosphère : existe-t-il un lien entre la résistance sur métaux et la modulation de résistance aux antibiotiques ? / Metabolic adaptation of plants to metal stress : consequences on rhizospheric bacterial communities and the selection of antibiotic resistant populations

Pham, Hoang-Nam

22 May 2017

L'objectif de cette thèse est d'évaluer les modifications du métabolisme secondaire des plantes contaminées aux éléments trace métalliques (ETM) et leurs conséquences sur les communautés bactériennes rhizosphériques associées incluant des bactéries présentant des phénotypes de MultiDrug Résistance (MDR). Nous nous sommes focalisés sur deux contextes de sols exposés aux métaux : la phytoremédiation de sites miniers au Vietnam et la reconversion de sols agricoles contaminés par la re-déposition atmosphérique d'activités métallurgiques en France. Nos résultats ont mis en évidence que la contamination par différents types de métaux (dont Cu et Pb principalement) a conduit à une altération de la production des métabolites secondaires des racines, tiges et feuilles de la plante hyperaccumulatrice Pteris vittata et que concernant les racines des tendances similaires dans les changements métaboliques ont pu être observés dans un autre type de contexte de pollution (Zn et Pb plus particulièrement). De même, les profils métaboliques des parties souterraines (racines et rhizomes) de Miscanthus x giganteus ont été modifiés par les concentrations en Pb, Cd et Zn des sols agricoles. Pour les deux plantes examinées des dérivés de l'acide chlorogénique ont été retrouvés en proportions augmentées dans les racines malgré des contextes de nature des sols et de pollutions métalliques très contrastés. Cependant, les dérivés de tanin catéchiques sont spécifiquement trouvés en proportions plus élevées dans les racines de P. vittata sous pression métallique. Ces polyphénols sont connus pour leur capacité à piéger les radicaux libres et leur pouvoir antioxydant et pourraient donc être impliqués dans l'adaptation de ces plantes au stress métallique en contribuant à limiter le stress oxydatif généré par les ETM. Au niveau des parties aériennes, nous n'avons étudié que le changement pour P. vittata et avons mis en évidence une proportion plus élevée de dérivés flavonoïdiques pour les plantes contaminées. Nos résultats de métagénomique nous permettent de conclure également sur un effet des ETM sur la diversité et la richesse spécifique des communautés bactériennes des sols étudiés : une forte contamination en Cu (10 fois la limite autorisée) a diminué la diversité et la richesse bactérienne, alors que pour des niveaux en ETM plus modérés incluant Cu, Pb et Zn, la diversité des communautés bactériennes rhizosphériques semble plus influencée par la plante ou la saison plutôt que par l'effet des ETM. Cet effet sur la composition bactérienne de la rhizosphère de P. vittata se traduit par un enrichissement de certains genres connus comme pathogènes opportunistes de l'homme, notamment Ralstonia, Acinetobacter, Burkholderia et Mycobacterium. En outre, le genre Cupriavidus, connu comme très résistant aux ETM est le seul genre spécifiquement associé à P. vittata qui ait été augmenté au sein de la communauté rhizosphérique pour les deux sites miniers étudiés par rapport aux sols rhizosphériques non pollués. Ce genre pourrait donc être impliqué dans le processus d'adaptation de cette plante au stress métallique. Quant aux communautés rhizosphériques de Miscanthus x giganteus, la sélection de Stenotrophomonas et Pseudomonas dans les sols agricoles contaminés a été observée. Dans le cadre de cette thèse nous avons également mis au point une méthode rapide pour tester l'impact de métabolites végétaux sur des souches pathogènes d'origine clinique et environnementale et également évaluer leur activité inhibitrice de pompes à efflux (IPE) de la famille des RND. Nos données ont ainsi permis de mettre en évidence des activités intéressantes et comparables à celle de l'inhibiteur de pompe à efflux PAßN pour des composés testés qui étaient extraits des racines de Fallopia x bohemica ou des dérivés de ces derniers. / The objective of this thesis is to evaluate the modification of plant secondary metabolism production contaminated with metallic trace elements (MTE) and its consequences on the associated rhizospheric bacterial communities including bacteria presenting MultiDrug Resistant (MDR) phenotypes. We have focused on two contexts of metals exposure: the phytoremediation of mining sites in Vietnam and the reconversion of agricultural soils contaminated by the atmospheric re-deposition of metallurgical activities in France. Our results highlighted that contamination by different types of metals (mainly Cu and Pb) has led to an alteration in the production of secondary metabolites in the roots, stems and leaves of the hyper-accumulating Pteris vittata and for roots, a similar trend in the metabolic changes could be observed in another type of pollution context (Zn and Pb more particularly). Similarly, the metabolic profiles of the underground parts (roots and rhizomes) of Miscanthus x giganteus were modified by the concentrations of Pb, Cd and Zn in agricultural soils. For the two plants examined chlorogenic acid derivatives have been found in increased proportions in the roots despite soil type and pollution context were highly contrasted. However, catechic tannin derivatives are specifically found in higher proportions in the roots of P. vittata under metal pressure. These polyphenols are known for their ability to scavenge free radicals and their antioxidant properties and thus could be involved in the adaptation of these plants to metallic stress by helping to limit the oxidative stress generated by MTE. At the level of the aerial parts, we studied only the change for P. vittata and evidenced higher proportions of flavonoid derivatives for contaminated plants. Our metagenomic results allow us to conclude also on the effect of MTE on the diversity and the specific richness of the bacterial communities of the studied soils: a high contamination of Cu (10 times the allowed limit) decreased dramatically bacterial richness and diversity, while for more moderate MTE levels including Cu Pb and Zn, the diversity of rhizosphere bacterial communities was more explained by plant or season effect rather than an effect of MTE. This effect on P.vittata rhizosphere bacterial composition is reflected by an enrichment in genera known as opportunistic human pathogens, including Ralstonia, Acinetobacter, Burkholderia and Mycobacterium. In addition, Cupriavidus, known as a highly resistant genus, is the only P. vittata specifically associated genus found in increased proportions at both mining sites compared to non-contaminated rhizosphere soils. This genus could then be involved in the adaptation process of this plant with metal stress. As for the rhizospheric communities of Miscanthus x giganteus, the selection of Stenotrophomonas and Pseudomonas in agricultural soils contaminated with MTE was observed. As a part of this thesis, we have also developed a rapid method for testing the impact of plant metabolites on pathogenic strains of clinical and environmental origin and their efflux pump inhibition (EPI) activity of RND family. Our data thus showed interesting and notable EPI activities comparable to that of the efflux pump inhibitor PAßN for tested compounds issued from Fallopia x bohemica roots or for their derivatives.

Adaptation

Métabolisme secondaire

Eléments traces métalliques

Communautés bactériennes

Multirésistant

Plant secondary metabolites

Heavy metal

MDR modulation

Phytochemical analysis

Microbial communities

Metagenomic analysis

Desenvolvimento, validação e aplicação de método molecular baseado na análise do rRNA para a identificação das bactérias formadoras de biofilme metabolicamente ativas na superfície das membranas de osmose reversa. / Development, validation and application of molecular method based on extraction, amplification and sequencing of the rRNA for the identification of biofilm-forming bacteria on the surface of the reverse osmosis membranes.

Roberta Novaes Amorim Almeida

14 April 2009

Um método baseado na extração de rRNA, seguido de RT-PCR rRNA 16S, clonagem e ARDRA foi otimizado e validado para a identificação das bactérias ativas em biofilmes. O método foi analisado primeiro com consórcios artificiais de três organismos. As etapas de clonagem e RT não causaram variações importantes na composição destes consórcios, do contrário da etapa de PCR, onde foi necessária a redução de 30 para 10 ciclos para limitar a distorção da proporção de templates. A análise de biofilmes reais indicou que clones dominantes podem ser identificados com o critério de ocorrência de >2% na biblioteca, mas que a reprodutibilidade de análises ainda é insatisfatória, possivelmente devido a fatores como a micro heterogeneidade espacial do biofilme, viés na reação de PCR e formação de mais de um clone de ARDRA por organismo. O armazenamento do biofilme a -20 °C por 2 meses não levou à alterações expressivas em sua composição. O perfil de clones detectado com o kit (Mo Bio) de extração de RNA foi muito diferente do perfil detectado com o método otimizado neste trabalho. / A method based on extraction of rRNA, followed by RT-PCR of 16S rRNA, cloning and ARDRA was optimized and validated for identification of bacteria active in biofilms. The method was first tested with artificial three-membered consortia. Cloning and RT did not lead to significant changes in the composition of the artificial consortia, but a reduction in cycle number in the PCR reaction from 30 to 10 was necessary for limiting the distortion in the proportion of amplicons relative to that of the templates. Analysis of real biofilms revealed that clones from active organisms occurred in frequencies >2% in the clone library, but reproducibility of analysis was unsatisfactory, probably due to factors such as the spatial heterogeneity of colonization of biofilms by microbes, PCR bias and more than one ARDRA clone per organism. Storage of biofilm samples at -20 °C for 2 months did not lead to important changes in composition. Very different clone profiles were obtained in the analysis of the same biofilm sample with the optimized method and with a kit (Mo Bio) for extraction of RNA.

Biofilmes

Biofouling

Biotecnologia

Comunidades microbiana

Metabolismo (Atividade)

Osmose reversa

rRNA 16S

16S rRNA

Biofilms

Biotechnology

Metabolism (Activity)

Microbial communities

Reverse osmosis

\"Biofouling\"