Phylogéographie comparée d’un système multitrophique : les parasitoïdes du genre Horismenus spp. ont-ils échappé au processus de domestication du haricot au Mexique?

Laurin-Lemay, Simon

08 1900

Cette étude vise à comparer l’histoire évolutive des parasitoïdes du genre Horismenus (Hymenoptera: Eulophidae) à celle de leurs hôtes bruches (Coleoptera: Bruchidae) et plante hôte (Phaseolus vulgaris L.) cultivée dans le contexte d’agriculture traditionnelle, au sein de son centre de domestication Mésoaméricain. Nous avons analysé la structure génétique de 23 populations de quatre espèces de parasitoïdes au Mexique, en utilisant un fragment du gène mitochondrial COI afin de les comparer aux structures précédemment publiées des hôtes bruches et du haricot commun. Nous avons prédit que les structures génétiques des populations d’hôtes (bruches et plante) et de parasitoïdes seraient similaires puisque également influencées par la migration entremise par l’humain (HMM) étant donnée que les parasitoïdes se développent telles que les bruches à l’intérieur des haricots. Compte tenu des stratégies de manipulation reproductive utilisées par l’alpha-protéobactérie endosymbionte Wolbachia spp. pour assurer sa transmission, la structure génétique des populations de parasitoïdes inférée à partir du génome mitochondrial devrait être altérée conséquemment à la transmission conjointe des mitochondries et des bactéries lors de la propagation de l’infection dans les populations de parasitoïdes. Les populations du parasitoïde H. missouriensis sont infectées par Wolbachia spp. Tel que prédit, ces populations ne sont pas différenciées (FST = 0,06), ce qui nous empêche d’inférer sur une histoire évolutive parallèle. Contrairement aux bruches, Acanthoscelides obtectus et A. ovelatus, la HMM n'est pas un processus contemporain qui influence la structure génétique des populations du parasitoïde H. depressus, étant donné la forte différenciation (FST = 0,34) qui existe entre ses populations. La structure génétique observée chez H. depressus est similaire à celle de sa plante hôte (i.e. dispersion aléatoire historique à partir d'un pool génique ancestral très diversifié) et est probablement le résultat d’un flux génique important en provenance des populations de parasitoïdes associées aux haricots spontanées à proximité des champs cultivés. L’étude de l’histoire évolutive intégrant plusieurs niveaux trophiques s’est avérée fructueuse dans la détection des différentes réponses évolutives entre les membres du module trophique face aux interactions humaines et parasitaires, et montre la pertinence d’analyser les systèmes écologiques dans leur ensemble. / This study aims to compare the evolutionary history of Horismenus parasitoids (Hymenoptera: Eulophidae) to that of their bruchid beetle hosts (Coleoptera: Bruchidae) and their domesticated host plant (Phaseolus vulgaris L.) in the context of traditional agriculture within their Mesoamerican center of domestication. We analyzed the genetic structure of 23 populations of four Horismenus species in Mexico using COI mitochondrial gene fragments and compared the structures to previously published data on bean plant and beetle hosts. We predicted that because parasitoids complete their development within their beetle hosts, within the bean, the genetic structure of both the host and the parasitoid would be similar and equally influenced by human-mediated migration (HMM). Furthermore, because of reproductive manipulation strategies often used by the alpha-proteobacteria endosymbionte Wolbachia spp. to ensure its transmission, the genetic structure of parasitoid populations inferred from mitochondrial genome would be bias consequently to the conjoint transmission of mitochondria and the bacteria according to propagation of the infection within parasitoids populations. The populations of H. missouriensis parasitoids are infected by Wolbachia spp. As predicted, these populations are not differentiated (FST = 0.06) which prevents us to infer on a parallel evolutionary history. Unlike their bruchids hosts, Acanthoscelides obtectus and A. ovelatus, the HMM is not a contemporary process influencing H. depressus population genetic structure according to the strong populations differentiation (FST = 0.34). The genetic structure observed within H. depressus populations is similar to that of its host plant (i.e. historical random dispersal from a highly diversified ancestral gene pool) and is probably the result of extensive gene flow from parasitoids associated with wild beans populations adjacent to crop fields. The study of evolutionary history integrating multitrophic levels has proved to be fruitful in detecting different evolutionary responses among members of the trophic module face to human and parasite interactions, but also points out the pertinence of analyzing ecological systems as a whole.

Horismenus spp.

endosymbiontes Wolbachia spp.

processus de domestication

interactions multitrophiques

phylogéographie

Wolbachia spp. endosymbionts

domestication process

multitrophic interactions

phylogeography

parasitoid population genetics

Traitement des eaux usées dans des bioréacteurs multitrophiques grâce à des flocs de microalguesbactéries valorisables en biogaz / Wastewater treatment in multitrophic bioreactors by using flocs of microalgae-bacteria recoverable on biogas

Beji, Olfa

14 December 2018

Le traitement biologique des eaux usées urbaines et industrielles reste une activité ayant un impact négatif sur l’environnement et sur le changement climatique par l’émission des gaz à effet de serre (GES), notamment le CO2. Les changements innovants au niveau des procédés de traitement des eaux usées par l’intégration des flocs de microalgues-bactéries ont abouti à des procédés multitrophiques sans apport d’O2 et sans dégagement du CO2. Il s'agit d'une étude de faisabilité de ces flocs-MaB pour la photobioremédiation des polluants (organiques et minéraux) et pour la production de biomasse valorisable en bioénergie dans le cadre de l'économie circulaire. En présence de la lumière, les flocs-MaB ont été intégrés dans des photobioréacteurs à biomasse fixe afin d'assurer un traitement durable des eaux usées grâce aux échanges symbiotiques entre les micro-oragnismes en terme de nutriments et de gaz. L'encapsulation des flocs-MaB dans des billes de PVA-alginate a montré l'effet des conditions physico-chimiques et hydrodynamiques sur l'élimination des polluants et l'évolution multicellulaire des flocs au sein des réacteurs à multi-échelles. Par ailleurs, la biomasse multitrophique immobilisée sur des supports biodégradables d'olive (OPP) et sur des disques en PVC a assuré une meilleure performance des bioréacteurs à lit fluidisé et à disques rotatifs, respectivement, pour la bioremédiation des eaux usées. Les propriétés des supports (porosité, rugosité et structure) et les comportements hydrodynamiques ont été contrôlés pour favoriser l'attachement des biofilms multitrophiques. Le développement de biofilm montre l'effet des interactions multitrophiques entre les microalgues et les bactéries sur l'élimination des composés organiques (DCO) et nutriments (ammonium et phosphore). La biomasse des flocs-MaB a été récupérée et réutilisée pour le traitement du digestat liquide à l'issu du digesteur et pour améliorer la production de biométhane par une co-digestion anaérobie. Ce procédé multitrophique et intégré permet d'obtenir Zéro déchet à la sortie du processus / The biological treatment of urban and industrial wastewaters represents a process with a negative impact on the environment and on climate change through the emission of greenhouse gases (GHG), particularly CO2. In the presence of light, microalgae-bacteria flocs (MaB-flocs) have been integrated into photobioreactors with fixed biomass to ensure a sustainable wastewater treatment without O2 supply and CO2 release. The entrapment of flocs in PVA-alginate beads has shown the effect of physicochemical and hydrodynamic conditions on the elimination of pollutants and the multicellularity evolution within multi-scale bioreactors. In addition, the immobilization of biomass on biodegradable olive carriers and on PVC disks provided a better performance of fluidized bed and rotating discs bioreactors, respectively, for the bioremediation of wastewater. The properties of the supports (porosity, roughness, and structure) and the hydrodynamic behaviors have favored the attachment of multitrophic biofilms. Biofilm development shows the effect of multitrophic interactions between microalgae and bacteria on the organic compounds (COD) and nutrients (ammonium and phosphorus) removals. The MaB-flocs biomass was recovered and reused for the treatment of the digestate and to improve the production of biomethane by anaerobic co-digestion. This integrated multitrophic technology makes it possible to obtain zero wastes at the end of the process

Flocs de microalgues-bactéries

Photobioréacteur multitrophique

Co-digestion anaérobie

Économie circulaire

Encapsulation

Comportement hydrodynamique

Interactions symbiotiques

Microalgae-bacteria flocs

Multitrophic photobioreactor

Anaerobic co-digestion

Circular economy

Encapsulation

Hydrodynamic behavior

Symbiotic interactions

660.6

628.5

Multitrophic plant insect interactions in dependence of belowground processes / Multitrophische Pflanze-Insekt Interaktionen in Abhängigkeit von unterirdischen Prozessen

Poveda Morciniec, Katja Andrea

19 May 2005

No description available.

570 Biowissenschaften

Biologie

Agricultural Sciences

Blattläuse

Bodenorganismen

Weizen

Zersetzer

Landbau

Herbivorie

Sinapis arvensis

Septoria spp

multitrophische Interaktionen

aphids

cereals

decomposers

farming systems

herbivory

Sinapis arvensis

Septoria spp.

soil organisms

multitrophic interactions

42.44

42.90

48.16

WN 000: Ökologie {Biologie}

YA

Phylogéographie comparée d’un système multitrophique : les parasitoïdes du genre Horismenus spp. ont-ils échappé au processus de domestication du haricot au Mexique?

Laurin-Lemay, Simon

08 1900

Cette étude vise à comparer l’histoire évolutive des parasitoïdes du genre Horismenus (Hymenoptera: Eulophidae) à celle de leurs hôtes bruches (Coleoptera: Bruchidae) et plante hôte (Phaseolus vulgaris L.) cultivée dans le contexte d’agriculture traditionnelle, au sein de son centre de domestication Mésoaméricain. Nous avons analysé la structure génétique de 23 populations de quatre espèces de parasitoïdes au Mexique, en utilisant un fragment du gène mitochondrial COI afin de les comparer aux structures précédemment publiées des hôtes bruches et du haricot commun. Nous avons prédit que les structures génétiques des populations d’hôtes (bruches et plante) et de parasitoïdes seraient similaires puisque également influencées par la migration entremise par l’humain (HMM) étant donnée que les parasitoïdes se développent telles que les bruches à l’intérieur des haricots. Compte tenu des stratégies de manipulation reproductive utilisées par l’alpha-protéobactérie endosymbionte Wolbachia spp. pour assurer sa transmission, la structure génétique des populations de parasitoïdes inférée à partir du génome mitochondrial devrait être altérée conséquemment à la transmission conjointe des mitochondries et des bactéries lors de la propagation de l’infection dans les populations de parasitoïdes. Les populations du parasitoïde H. missouriensis sont infectées par Wolbachia spp. Tel que prédit, ces populations ne sont pas différenciées (FST = 0,06), ce qui nous empêche d’inférer sur une histoire évolutive parallèle. Contrairement aux bruches, Acanthoscelides obtectus et A. ovelatus, la HMM n'est pas un processus contemporain qui influence la structure génétique des populations du parasitoïde H. depressus, étant donné la forte différenciation (FST = 0,34) qui existe entre ses populations. La structure génétique observée chez H. depressus est similaire à celle de sa plante hôte (i.e. dispersion aléatoire historique à partir d'un pool génique ancestral très diversifié) et est probablement le résultat d’un flux génique important en provenance des populations de parasitoïdes associées aux haricots spontanées à proximité des champs cultivés. L’étude de l’histoire évolutive intégrant plusieurs niveaux trophiques s’est avérée fructueuse dans la détection des différentes réponses évolutives entre les membres du module trophique face aux interactions humaines et parasitaires, et montre la pertinence d’analyser les systèmes écologiques dans leur ensemble. / This study aims to compare the evolutionary history of Horismenus parasitoids (Hymenoptera: Eulophidae) to that of their bruchid beetle hosts (Coleoptera: Bruchidae) and their domesticated host plant (Phaseolus vulgaris L.) in the context of traditional agriculture within their Mesoamerican center of domestication. We analyzed the genetic structure of 23 populations of four Horismenus species in Mexico using COI mitochondrial gene fragments and compared the structures to previously published data on bean plant and beetle hosts. We predicted that because parasitoids complete their development within their beetle hosts, within the bean, the genetic structure of both the host and the parasitoid would be similar and equally influenced by human-mediated migration (HMM). Furthermore, because of reproductive manipulation strategies often used by the alpha-proteobacteria endosymbionte Wolbachia spp. to ensure its transmission, the genetic structure of parasitoid populations inferred from mitochondrial genome would be bias consequently to the conjoint transmission of mitochondria and the bacteria according to propagation of the infection within parasitoids populations. The populations of H. missouriensis parasitoids are infected by Wolbachia spp. As predicted, these populations are not differentiated (FST = 0.06) which prevents us to infer on a parallel evolutionary history. Unlike their bruchids hosts, Acanthoscelides obtectus and A. ovelatus, the HMM is not a contemporary process influencing H. depressus population genetic structure according to the strong populations differentiation (FST = 0.34). The genetic structure observed within H. depressus populations is similar to that of its host plant (i.e. historical random dispersal from a highly diversified ancestral gene pool) and is probably the result of extensive gene flow from parasitoids associated with wild beans populations adjacent to crop fields. The study of evolutionary history integrating multitrophic levels has proved to be fruitful in detecting different evolutionary responses among members of the trophic module face to human and parasite interactions, but also points out the pertinence of analyzing ecological systems as a whole.

Horismenus spp.

endosymbiontes Wolbachia spp.

processus de domestication

interactions multitrophiques

phylogéographie

Wolbachia spp. endosymbionts

domestication process

multitrophic interactions

phylogeography

parasitoid population genetics

Insect frugivore interactions : the potential for beneficial and neutral effects on host plants

Wilson, Alexsis Jane

January 2008

Frugivorous insects, specialised herbivores that consume fruit and seeds, are considered detrimental to host plant fitness. Their direct link to genetic fitness via consumption of plant reproductive tissue, and their negative socioeconomic association with agriculture exacerbates their harmful status. However, empirical testing of insect frugivore effects on host plants, and ecological research on the contribution of insect frugivores to multitrophic frugivory systems, is lacking. In the current study, direct effects of a non-mutualistic, insect frugivore/host plant system were tested and results showed variable effects. Beneficial, detrimental, but predominantly neutral effects on germination and seed production were observed between the Queensland fruit fly (Bactrocera tryoni) and tomato and capsicum plants. Significant effects on seed production were unexpected because infestation occurs after seed set. It was also found that eggplant, although a recorded host of B. tryoni, is inconsistent in its ability to sustain B. tryoni larvae through to its final instar. These results confirmed a simplification and presumption associated with insect frugivore (specifically fruit fly)/host plant interactions. Larval movement, infestation-induced fruit decay, pulp removal and germination were then investigated. For all hosts (tomato, apple and paw paw), treatments infested by B. tryoni decayed significantly quicker and to a greater extent than uninfested treatments, with obvious but variable changes to the texture and appearance. The movement of B. tryoni larvae, pattern of infestation-induced decay and pulp removal was unique and host dependent for all hosts. Only seeds from infested tomato were shown to germinate during the experiment. This indicated that host fruit characteristics are responsible, in part, for variable direct effects on host plant fitness by insect frugivores. Variable direct effects between insect frugivores and host plants, combined with the more rapid decay of infested fruits is likely to have implications for seed dispersal and seed predation by a third trophic level. The characteristics of fruit that are changed by infestation by an insect frugivore were then tested for their effect on a vertebrate frugivore, to illustrate the importance of recognising multitrophic interactions and indirect effects in frugivory. Specifically, seed predating rodents were incorporated into the study and their response to infested and uninfested fruits were recorded, as well as their reaction to the changes in fruit caused by insect frugivores (i.e. texture, smell, larvae presence and sound). Apple and pear infested with B. tryoni larvae were found to attract rodents, while infested tomato and paw paw had a neutral effect on the native rats. This differed from the predominant finding in the literature, which was a deterrent effect on avian seed dispersers. Vertebrate response to fruit infested with insect frugivores therefore, is variable. Assessing the indirect effect of insect frugivores on host plant fitness by attracting or deterring another trophic level requires knowledge of the direct effect between the introduced trophic level and the host plant. For example, the attraction of a seed predator may be as detrimental to host plant fitness as the deterrence of a seed disperser. This illustrates the complexity associated with assessing insect frugivore effects on host plant fitness. Results also indicated that differences in pulp texture, caused by infestation, have a significant effect on rodent preference for infested or uninfested treatments. Pulp texture is likely to effect rodent foraging efficiency, whereas the presence of B. tryoni larvae was observed to be inconsequential to rodent response to fruits. For rodents, and indeed any trophic level motivated by foraging efficiency, this finding raises the issue that for long lived fruiting plants, outside factors such as food abundance and competition for food, may cause a variable response to fruits infested by insect frugivores. From these investigations it has become apparent that insect frugivores are not consistently harmful to host plant fitness, as suggested by their negative stigma, but are likely to contribute variable effects, directly and indirectly, on multiple components of plant fitness and multitrophic frugivory systems.

seed predator, seed disperser

Plant diversity and landscape-scale effects on multitrophic interactions involving invertebrates

Tiede, Julia

15 November 2017

No description available.

570

biodiversity

ecosystem functioning

experimental grassland

landscape ecology

metabarcoding

next generation sequencing

gut microbiome

multitrophic interactions

arthropods

insects

lady beetles

ground beetles

vitual ecologist

individual-based model

pitfall trapping bias

field slugs

molecular trophic interactions

Biologie (PPN619462639)

The Role of Nursery Size and Plant Phenology on the Reproduction of and Relationships within a Fig-fig Wasp Nursery Pollination System

Krishnan, Anusha

January 2014

Obligate nursery pollination mutualisms such as the fig–fig wasp system, with their central plant–pollinator mutualism associated with non-pollinating satellite wasp species, can function as closed system microcosms representative of tritrophic communities. In this system, enclosed inflorescences (syconia) function as sites of seed production, as well as brood-sites for the progeny of herbivorous mutualistic pollinators, non-pollinating gallers and parasitoids of the two. Plant reproductive traits such as inflorescence size (syconium volume) and within-plant phenology (within-tree asynchrony) as can affect inter-species relationships among the three trophic levels in such plant–herbivore–parasitoid systems. Induced or natural variations in such plant traits could influence various direct and indirect effects among the organisms in the community and could even lead to the formation of feedback cycles. Furthermore, changes in the abiotic environment could have major impacts on the biotic associations in the system either by affecting the community members directly, or through their effects on plant reproductive traits. Ficus racemosa with its fig wasp community comprised of a single herbivorous pollinator mutualist, three non-pollinating parasitic gallers and three non-pollinating parasitoids was used as a model to investigate: (1) the role of mutualistic and parasitic fig wasps in affecting within-tree phenology; (2) direct and indirect biotic associations between various groups of fig wasps (pollinators, gallers and parasitoids) and the influence of inflorescence size and within-tree phenology on them; and (3) variations in the reproduction of and the biotic associations between the organisms of the community under variable abiotic climatic conditions. Patterns of plant reproductive phenology are usually considered evolved responses directed at optimizing resource use, pollen receipt/donation schedules and seed dispersal for plant individuals. Within-plant reproductive synchrony or asynchrony can arise due to variation in floral initiation patterns, as well as from localised proximate mechanistic responses to interactants such as pollinators, parasites and herbivores which could affect floral longevity or fruit development time. The investigation was begun by exploring the role of a mutualistic pollinator, and for the first time in a brood-site mutualism, that of parasitic herbivores (gallers) and parasitoids in influencing within-plant reproductive phenology. Since a syconium functions as an inflorescence which develops into a fruit after pollination, investigations were carried out on the impact on syconium synchrony of fig wasps that began their development within the brood site syconium at pre-pollination, pollination, and post-pollination stages via their effects on the development time of individual syconia in Ficus racemosa. We found that syconium initiation patterns were not the only proximate mechanism for within-tree reproductive asynchrony, and that individual syconia (even within a tree) had highly plastic development times dependent on their sizes, pollination time and the species of wasp progeny developing within them. Syconium volume, pollination early in the pollen-receptive phase and presence of early-ovipositing galler progeny reduced syconium development time, whereas the presence of late-ovipositing parasitoid progeny or pollination late in the pollen-receptive phase increased syconium development time. These results suggest an ongoing tug-of-war between syconium inhabitants to modify syconium development times. Parasitic fig wasps pull in different directions to suit their own needs, such that final syconium development times are likely to be a compromise between conflicting demands from developing seeds and from different wasp species. Inter-species relationships among the three trophic levels in plant–herbivore–parasitoid systems can potentially include various direct and indirect effects possibly mediated by induced or natural variations in plant traits. Analysing the seed and fig wasp compositions of microcosm replicates, i.e. individual syconia, shows that besides direct competition for resources and predator–prey interactions, the F. racemosa community also displays exploitative or apparent competition and trait-mediated indirect interactions. Syconium volume and within-tree asynchrony were reproductive plant traits that not only affected plant–herbivore and plant–parasitoid associations, but also possibly modified herbivore–herbivore and herbivore–parasitoid interactions. Our results also indicated that the reciprocal effects of higher trophic level fauna on plant traits (and vice versa) within this system drive a positive feedback cycle between syconium inhabitants and within-tree reproductive asynchrony. In the F. racemosa system, abiotic environmental factors could affect the reproduction of mutualistic pollinators, non-mutualistic parasites and seed production via seasonal changes in plant reproductive traits such as syconium volume within-tree asynchrony. Temperature, relative humidity and rainfall defined four seasons: winter; hot days, cold nights; summer and wet seasons. Syconium volumes were highest in winter and lowest in summer, and affected syconium contents positively across all seasons. Greater transpiration from the nurseries was possibly responsible for smaller syconia in summer. The 3–5°C increase in mean temperatures between the cooler seasons and summer reduced fig wasp reproduction and increased seed production nearly two-fold. Yet, seed and pollinator progeny production were never negatively related in any season confirming the mutualistic fig–pollinator association across seasons. Parasites affected seed production negatively in some seasons, but had a surprisingly positive relationship with pollinators in most seasons. While within-tree reproductive phenology did not vary across seasons, its effect on syconium inhabitants varied with season. In all seasons, within-tree reproductive asynchrony affected parasite reproduction negatively, whereas it had a positive effect on pollinator reproduction in winter and a negative effect in summer. Seasonally variable syconium volumes probably caused the differential effect of within-tree reproductive phenology on pollinator reproduction. Within-tree reproductive asynchrony itself was positively affected by intra-tree variation in syconium contents and volume, creating a unique feedback loop which varied across seasons. Therefore, nursery size affected fig wasp reproduction, seed production and within-tree reproductive phenology via the feedback cycle in this system. Climatic factors affecting plant reproductive traits can cause biotic relationships between plants, mutualists and parasites to vary seasonally and must be accorded greater attention, especially in the context of climate change.

Plant Reproductive Phenology

Fig Wasp Reproduction

Fig-Fig Wasp Nursery Pollination System

Nursery Pollination Mutualisms

Multitrophic Communities

Mutualistic and Parasitic Fig Wasps

Ficus Racemosa

Fig–fig Wasp System

Pollination Mutualism

Fig Wasps

Fig Nematodes

Ecology

Amoebae in the rhizosphere and their interactions with arbuscular mycorrhizal fungi : effects on assimilate partitioning and nitrogen availability for plants / Amibes dans la rhizosphère et leurs interactions avec les mycorhizes à arbuscules : effets sur la répartition des assimilats et sur la disponibilité en azote pour les plantes

Koller, Robert

14 November 2008

Les interactions entre les végétaux et les organismes telluriques sont déterminantes pour la décomposition des matières organiques et la nutrition minérale des plantes. L’objectif général de la thèse était de comprendre comment les interactions multi-trophiques dans la rhizosphere agissent sur la disponibilité en azote minéral et l’allocation en carbone dans la plante. Nous avons mis au point des dispositifs de culture de plante, permettant de contrôler l’environnement biotique des racines (inoculation par des espèces symbiotiques modèles : un protozoaire bactériophage et/ou une espèce mycorhizienne à arbuscules). Nous avons utilisé l’azote 15N et le carbone 13C pour tracer le cheminement de l’azote du sol vers la plante et le carbone assimilé par photosynthèse, de la plante vers le sol et les microorganismes du sol. L’allocation de C vers les racines et la rhizosphère est dépendante de la qualité de la litière foliaire enfouie. La structure de la communauté microbienne déterminée par l’analyse des profils d’acides gras (PLFA) est modifiée par la présence de protozoaires pour la litière à C/N élevé. Les mycorhizes à arbuscules et les protozoaires présentent une complémentarité pour l’acquisition du C et de N par la plante. Les protozoaires remobilisent l’azote de la biomasse microbienne par leur activité de prédation. Les hyphes fongiques transportent du C récent issu de la plante vers des sites riches en matière organique non accessibles aux racines. Ainsi, l’activité de la communauté microbienne est stimulée et la disponibilité en N augmentée lorsque des protozoaires sont présents. Les perspectives de ce travail sont de déterminer si (i) les interactions étudiées dans ce dispositif modèle peuvent être généralisées à d’autres interactions impliquant d’autres espèces de champignons mycorhiziens et de protozoaires (ii) la phénologie de la plante et la composition des communautés végétales influence la nature et l’intensité des réponses obtenues / Plants interact with multiple root symbionts for fostering uptake of growth-limiting nutrients. In turn, plants allocate a variety of organic resources in form of energy-rich rhizodeposits into the rhizosphere, stimulating activity, growth and modifying diversity of microorganisms. The aim of my study was to understand how multitrophic rhizosphere interactions feed back to plant N nutrition, assimilate partitioning and growth. Multitrophic interactions were assessed in a single-plant microcosm approach, with arbuscular mycorrhizal fungi (Glomus intraradices) and bacterial feeding protozoa (Acanthamoeba castellanii) as model root symbionts. Stable isotopes enabled tracing C (13C) and N (15N) allocation in the plant and into the rhizosphere. Plant species identity is a major factor affecting plant-protozoa interactions in terms of N uptake and roots and shoot morphology. Plants adjusted C allocation to roots and into the rhizosphere depending on litter quality and the presence of bacterial grazers for increasing plant growth. The effect of protozoa on the structure of microbial community supplied with both, plant C and litter N, varied with litter quality added to soil. AM-fungi and protozoa interact to complement each other for plant benefit in C and N acquisition. Protozoa re-mobilized N from fast growing rhizobacteria and by enhancing microbial activity. Hyphae of AM fungi acted as pipe system, translocating plant derived C and protozoan remobilized N from source to sink regions. Major perspectives of this work will be to investigate whether (i) multitrophic interactions in our model system can be generalized to other protozoa-mycorrhiza-plant interactions (ii) these interactions are depending on plant phenology and plant community composition

Rhizosphère

Azote

Carbone

Isotope stable

Plantago lanceolata

Holcus lanatus

Boucle microbienne

Interactions multitrophiques

Protozoaires

Acanthamoeba castellanii

Champignon mycorhizien à arbuscules

Glomus intraradices

Rhizosphere

Holcus lanatus

Zea mays

Carbon

Nitrogen

Stable isotope

13C

15N

Microbial loop

Multitrophic interactions

Protozoa

Acanthamoeba castellanii

Arbuscular mycorrhizal fungi

Glomus intraradices

Microbial community

Plantago lanceolata

Litter quality

PFLA

Effets des changements d'utilisation des terres sur la biodiversité fonctionnelle des prairies en paysage agricole / Effects of land use intensification on grassland functional biodiversity within agricultural landscapes

Le Provost, Gaëtane

16 January 2017

Comprendre comment la biodiversité des prairies répond aux changements d’utilisation des terres constitue un enjeu majeur pour la conservation de la biodiversité et le maintien des services écosystémiques dans les paysages agricoles. Dans ce travail de thèse, nous avons cherché (i) à analyser la réponse simultanée d’un ensemble de taxons appartenant à différents niveaux trophiques (plantes, herbivores, pollinisateurs, prédateurs) aux changements d’utilisation des terres agissant à différentes échelles spatiales et temporelles ; (ii) à approcher les mécanismes impliqués dans cette réponse et notamment le rôle des interactions trophiques. Notre approche est basée sur l’utilisation de multiples traits fonctionnels liés à l’acquisition des ressources, la taille et la mobilité des organismes. Nous avons testé la réponse de ces traits à l’histoire des paysages, leur configuration et leur composition. Nous montrons qu’il existe une réponse générale de la diversité fonctionnelle multitrophique aux changements d’utilisation des terres. Nous mettons en évidence l’importance des effets historiques du changement d’utilisation des terres à l’échelle des paysages agricoles menaçant le maintien de communautés fonctionnellement diversifiées dans ces paysages. En considérant un set de traits multiples, notre travail a permis d’approcher certains mécanismes par lesquels les changements d’utilisation des terres présents et passés impactent différentes facettes de la biodiversité. Enfin, l’utilisation des traits fonctionnels a permis d’appréhender l’importance des interactions trophiques et leur implication dans la structuration des communautés animales dans les milieux agricoles. / Understanding how grassland biodiversity responds to land use intensification is crucial for both biodiversity conservation and the management of key ecosystem services in agricultural landscapes. My PhD aims at (i) identifying and generalising the effects of land use intensification operating at different spatial and temporal scales across multiple taxonomic groups and trophic levels (plants, herbivores, pollinators, predators and top-predators) ; (ii) investigating the underlying mechanisms of biodiversity response, and particularly the role of trophic interactions. We used multiple functional traits related to resource acquisition, the size of the organisms and their mobility. We tested how multitrophic functional trait diversity responded to landscape history, composition and heterogeneity. Considering multiple taxonomic groups simultaneously, our study brings out a clear response of overall biodiversity to land use intensification. We found that legacy effects of land use intensification operating at the landscape scale are major drivers of present-day multitrophic functional trait diversity in agricultural landscapes. By considering a core set of organismal traits reflecting similar functions across trophic levels, our approach reveals multiple dimensions by which land use intensification filters out biodiversity over time and allows us to generalise its effect across multiple trophic levels and trait-spectrum. Finally, trait-based approach allowed us to assess the importance of trophic interactions and their contribution in shaping animal communities in agricultural landscapes.

Changements d'utilisation des terres

Paysage agricole

Histoire du paysage

Diversité fonctionnelle multitrophique

Prairie

Interactions plantes-insectes

Taille corporelle

Traits liés à la mobilité

Traits d'acquisition des ressources

Land use intensification

Agricultural landscape

Landscape history

Multitrophic functional trait diversity

Grassland

Plant-insect interactions

Body size

Mobility-related traits

Resource-acquisition traits

Effects of land-use intensity in grasslands on diversity, life-history traits and multitrophic interactions / Auswrikungen der Landnutzungsintensität in Grünländern auf Diversität,

Börschig, Carmen

07 March 2012

No description available.

500 Naturwissenschaften

RA 000

Blattläuse

Bottom-up

endophytische Pilze

gefährdete Arten

Grünland

Landnutzungsintensität

Life-History traits

Nachtfalter

multitrophische Interaktionen

Schmetterlinge

Top-down

aphids

bottom-up

butterflies

endangered species

endophytic fungi

grassland

land-use intensity

life-history traits

moths

multitrophic interactions

top-down

42.91

42.75