Chargé de recherche au CNRS   Mon activité de recherche porte sur les aspects écologiques et évolutifs des interactions entre espèces. Les deux thèmes principaux que j'étudie sont les interactions symbiotiques entre plantes, fourmis et champignons, et les interactions entre ingénieurs d'écosystèmes dans la structuration du paysage.   My research activity is focused on the ecological and evolutionary aspects of inter-specific interactions. My two main study topics are the symbiotic interactions among plants, ants and fungi, and the interaction among ecosystem engineers in landscape patterns.   Courriel : Cette adresse e-mail est protégée contre les robots spammeurs. Vous devez activer le JavaScript pour la visualiser.

 Publications

Activités de recherche

Axe 1 : Ecologie et évolution des symbioses plantes-fourmis-champignons

Dans les forêts tropicales, certaines plantes présentent des structures naturellement creuses (feuilles, tiges, pétioles ...) dans lesquelles vivent des fourmis. La plante fournit le gîte et le couvert (sous forme de nectar extrafloral par exemple). En contrepartie, les fourmis protègent la plante des herbivores et contribuent à l'approvisionnement de la plante en azote. Dans les cavités de la plante, les fourmis cultivent des champignons (de l'ordre des Chaetothyriales) qu'elles consomment. A partir de ce modèle d'étude j'aborde plusieurs sujets relatifs à l'écologie et à l'évolution des symbioses:

- Histoire évolutive des associations symbiotiques.

- Génétique des populations des partenaires symbiotiques.

- Spécificité d'association.

- Flux de nutriments entre les partenaires symbiotiques et stratégies d'approvisionnement.

- Médiation et communication chimique entre les partenaires symbiotiques.

Axe 2 : Organisation spatiale des paysages à motifs répétés

Certaines savanes tropicales sont constellées de buttes en terre (1-20 m de diamètre) régulièrement espacées. Dans la majorité des cas, ces buttes sont soit construites par des invertébrés du sol ("savanes à termites" par exemple), soit construites par l'homme pour permettre l'agriculture sur sols pauvres et régulièrement inondés (champs surélevés). Dans ces mêmes savanes saisonnièrement inondées se trouvent des barrages à poissons en terre. Les champs surélevés et les barrages à poissons en terre sont utilisés actuellement en Afrique, et présents sous forme de vestiges archéologiques pré-colombiens en Amérique du Sud. A partir de ces modèles d'étude j'aborde plusieurs sujets relatifs à l'organisation spatiale des paysages:

- Origine de la régularité spatiale des motifs répétés du paysage.

- Interactions entre les activités de l'Homme, les activités des invertébrés du sol, et leur milieu.

- Rôle des invertébrés du sol dans la conservation des vestiges archéologiques en terre.

Activités annexes

- Taxonomie, biodiversité et écologie des fourmis du paléarctique occidental.

- Interactions tropiques entre acariens dans les élevages de poules pondeuses.

- Syndrome de pollinisation par les mouches (en particulier, kleptomyiophilie).

English version:

Axis 1: Ecology and evolution of ant-plant-fungus symbioses

In tropical forests, some plant species have hollow structures (leaves, twigs, petioles ...) in which ants live. The plant provides nesting sites and food (e. g. extra-floral nectar). In return, the ants protect the plant against herbivores and provide it with nitrogen. In plant cavities, the ants grow fungi (of the order Chaetothyriales) for food. I use this study model to address various topics related to the ecology and evolution of symbioses:

- Evolutionary history of symbiotic associations.

- Population genetics of symbiotic partners.

- Partner specificity.

- Nutrient flux among symbiotic partners and nutrient acquisition strategies.

- Chemical mediation and communication between symbiotic partners.

Axis 2: Spatial organization of landscapes with repeated patterns.

Some tropical savannahs are dotted with regularly spaced earth mounds (1-20 m in diameter). In most cases, these mounds are either built by soil invertebrates (e.g. termite savannahs), or built by humans to grow crops on poor and regularly flooded soils (raised fields). Earthen fish weirs also occur in these seasonally flooded savannahs. Earthen fish weirs and raised fields are in use today in Africa, and occur in South America as pre-Columbian archaeological vestiges. I use these study models to address various topics related to landscape spatial organization:

- Origin of spatial regularity in repeated patterns of the landscape.

- Interactions between human activities, soil invertebrates activities, and their environment.

- Role of soil invertebrates in the conservation of earthen archaeological vestiges.

Side projects

- Taxonomy, biodiversity and ecology of the ants of the Western Palaearctic.

- Trophic interactions among mites in farms of laying hens.

- Fly pollination syndrome (kleptomyiophily in particular).

Publications

Schifani E., Alicata A., Menchetti M., Borowiec L., Fisher B.L., Karaman C., Kiran K., Oueslati W., Salata S., Blatrix R., 2022. Revisiting the morphological species groups of West-Palearctic Aphaenogaster ants (Hymenoptera: Formicidae) under a phylogenetic perspective: toward an evolutionary classification. Arthropod Systematics & Phylogeny, 80, 627–648. https://doi.org/10.3897/asp.80.e84428

Dupray S., Blatrix R., Roy L., Soulié A.-S., Dadu L., Degueldre D., Sleeckx N., Bicout D. J., Roy L., 2022. Population dynamics of a poultry hematophagous mite: characterization of the population growth and identification of factors of its slowdown using closed mesocosms. Pest Management Science, 78, 4151-4165. https://doi.org/10.1002/ps.7033

Kidyoo A., Kidyoo M., McKey D., Proffit M., Deconninck G., Wattana P., Uamjan N., Ekkaphan P., Blatrix, R., 2022. Pollinator and floral odor specificity among four synchronopatric species of Ceropegia (Apocynaceae) suggests ethological isolation that prevents reproductive interference. Scientific Reports, 12, 13788. https://doi.org/10.1038/s41598-022-18031-z

Kass J. M., Guénard B., Dudley K.L., Jenkins C.N., Azuma F., Fisher B.L., Parr C.L., Gibb H., Longino J.T., Ward P.S., Chao A., Lubertazzi D., Weiser M., Jetz W., Guralnick R., Blatrix R., Des Lauriers J., Donoso D.A., Georgiadis C., Gomez K., Hawkes P.G., Johnson R.A., Lattke J.E., MacGown J.A., Mackay W., Robson S., Sanders N.J., Dunn R.R., Economo E.P., 2022. The global distribution of known and undiscovered ant biodiversity. Science Advances, 8, eabp9908. https://doi.org/10.1126/sciadv.abp9908

McKey D., Rodrigues L., Ruiz-Pérez J., Blatrix R., Rostain S., 2022. Thinking outside the continent and outside the box: Cross-continental comparative studies can enrich studies of pre-columbian raised-field agriculture. Journal of Ethnobiology, 42, 152-179. https://doi.org/10.2993/0278-0771-42.2.152

Blatrix R., Aramayo J.L., Zangerlé A., Roux B., Jouanne M., Anselme B., de Boisvilliers M., Krasnopolski C., Assenbaum M., McKey D., 2022. Interpreting landscapes of pre-Columbian raised-field agriculture using high-resolution LiDAR topography. Journal of Archaeological Science: Reports, 42, 103408. https://doi.org/10.1016/j.jasrep.2022.103408

Centanni J., Kaufmann B., Blatrix R., Blight O., Dumet A., Jay-Robert P., Vergnes A., 2022. High resolution mapping in Southern France reveals that distributions of supercolonial and monodomous species in the Tapinoma nigerrimum complex (Hymenoptera: Formicidae) are related to sensitivity to urbanization. Myrmecological News, 32, 41-50. https://doi.org/10.25849/myrmecol.news_032:041

Aubert C., Le Moguédec G., Assio C., Blatrix R., N’dédé Ahizi M., Codjo Hedegbetan G., Gnanki Kpera N., Lapeyre V., Martin D., Labbé P., Shirley M.H., 2022. Evaluation of the use of drones to monitor a diverse crocodylian assemblage in West Africa. Wildlife Research, 49, 11-23. https://doi.org/10.1071/WR20170

Zriki G., Blatrix R., Bicout D. J., Gimenez O., Soulié A.-S., Dadu L., Degueldre D., Chiron G., Sleeckx N., Roy L., 2021. Population-level impact of native arthropod predators on the Poultry Red Mite Dermanyssus gallinae. Journal of Experimental Zoology Part A: Ecological and Integrative Physiology, 335, 552-563. https://doi.org/10.1002/jez.2496

Blatrix R., Kidyoo A., Kidyoo M., Piapukiew J., Satjarak A., Paliyavuth C., Boonchai W., McKey D., 2021. The symbiosis between Philidris ants and the ant-plant Dischidia major includes fungal and algal associates. Symbiosis, 83, 305-315. DOI: https://doi.org/10.1007/s13199-021-00751-x

Zriki G., Blatrix R., Dadu L., Soulié A.-S., Dijoux J., Degueldre D., Sleeckx N., Roy L., 2021. No deleterious effect of inundative releases of biological agents on native arthropod assemblages in poultry farms: a mesocosm experiment. Biological Control, 156, 104560. DOI: https://doi.org/10.1016/j.biocontrol.2021.104560

Kidyoo A., Kidyoo M., Blatrix R., Deconninck G., McKey D., Ekkaphan P., Proffit M., 2021. Molecular phylogenetic analysis and taxonomic reconsideration of Ceropegia hirsuta (Apocynaceae, Asclepiadoideae) reveals a novelty in Thailand, Ceropegia citrina sp. nov., with notes on its pollination ecology. Plant Systematics and Evolution, 307, 14. DOI: https://doi.org/10.1007/s00606-020-01723-2

Kokolo B., Attéké C., Ibrahim B., M'Batchi B., Blatrix R., 2020. Phenotypic plasticity in size of ant–domatia. Scientific Reports, 10, 20948.

Blatrix R., Aubert C., Decaëns T., Berquier C., Andrei-Ruiz M.-C., Galkowski C., 2020. Contribution of a DNA barcode for assessing the specificity of ant taxa (Hymenoptera: Formicidae) in Corsica. European Journal of Entomology, 117, 402-429.

Roy L., Taudière A., Papaïx J., Blatrix R., Chiron G., Zriki G., Bonato O., Barnagaud J.Y., 2020. Evaluating the link between predation and pest control services in the mite world. Ecology and Evolution, 10, 9968-9980.

Zriki G., Blatrix R., Roy L., 2020. Predation interactions among henhouse-dwelling arthropods, with a focus on the poultry red mite Dermanyssus gallinae. Pest Management Science, 76, 3711-3719.

Galkowski C., Aubert C., Blatrix R., 2019. Aphaenogaster ichnusa Santschi, 1925, bona species, and redescription of Aphaenogaster subterranea (Latreille, 1798) (Hymenoptera, Formicidae). Sociobiology, 66, 420-425.

Kokolo B., Atteke C., Eyi Mintsa B. A., Ibrahim B., McKey D., Blatrix R., 2019. Congeneric mutualist ant symbionts (Tetraponera, Pseudomyrmecinae) differ in level of protection of their myrmecophyte hosts (Barteria, Passifloraceae). Journal of Tropical Ecology, 35, 255-259.

Moreno L. F., Mayer V., Voglmayr H., Blatrix R., Stielow J. B., Teixeira M. M., Vicente V. A., de Hoog S., 2019. Genomic analysis of ant domatia-associated melanized fungi (Chaetothyriales, Ascomycota). Mycological progress, 18, 541-552.

Blatrix R., Colindre L., Wegnez P., Galkowski C., Colin T. (2018). Atlas des fourmis de Corse. Office de l'Environnement de la Corse. Corte. 148 pp.

Blatrix R., Colin T., Wegnez P., Galkowski C., Geniez P. (2018). Introduced ants (Hymenoptera, Formicidae) of mainland France and Belgium, with a focus on greenhouses. Annales de la Société Entomologique de France, 54, 293-308.

Blatrix R., Roux B., Béarez P., Prestes-Carneiro G., Amaya M., Aramayo J.L., Rodrigues L., Lombardo U., Iriarte J., de Souza J.G., Robinson M., Bernard C., Pouilly M., Durécu M., Huchzermeyer C., Kalebe M., Ovando A., McKey D. (2018). The unique functioning of a pre-Columbian Amazonian floodplain fishery. Scientific Reports, 8, 5998.

Blatrix R., Galkowski C. (2018). Une nouvelle station, alpine, pour Formica suecica Adlerz, 1902, (Hymenoptera, Formicidae). Bulletin de la Société linnéenne de Bordeaux, 153 NS46, 71-74.

Sakolrak B., Blatrix R., Sangwanit U., Kobmoo N. (2018). Experimental infection of the ant Polyrhachis furcata with Ophiocordyceps reveals specificity of behavioural manipulation. Fungal Ecology, 33, 122-124.

Mayer V., Nepel M., Blatrix R., Oberhauser F., Fiedler K., Schönenberger J., Voglmayr H. ( 2018). Transmission of fungal partners to incipient Cecropia-tree ant colonies. Plos One, 13, e0192207.

Sakolrak B., Blatrix R., Sangwanit U., Arnamnart N., Noisripoom W., Thanakitpipattana D., Buatois B., Hossaert-McKey M., Kobmoo N. (2018). Ant-produced chemicals are not responsible for the specificity of their Ophiocordyceps fungal pathogens. Fungal Ecology, 32, 80-86.

Blatrix R., Peccoud J., Born C., Piatscheck F., Benoit L., Sauve M., Djiéto-Lordon C., Atteke C., Wieringa J. J., Harris D. J., McKey D. (2017). Comparative analysis of spatial genetic structure in an ant-plant symbiosis reveals a tension zone and highlights speciation processes in tropical Africa. Journal of Biogeography, 44, 1856-1868.

Blatrix R., Wegnez P., Colin T., Galkowski C. (2017). Neuf nouvelles espèces de fourmis pour la Corse. Revue de l'Association Roussillonnaise d'Entomologie, 26, 60-64.

Diamé L., Taylor B., Blatrix R., Vayssières J.-F., Rey J.-Y., Grechi I., Diarra K. (2017). A preliminary checklist of the ant (Hymenoptera, Formicidae) fauna of Senegal. Journal of Insect Biodiversity, 5, 1-16.

Galkowski C., Lebas C., Wegnez P., Lenoir A., Blatrix R. (2017). Re-description of Proformica nasuta (Nylander, 1856) (Hymenoptera, Formicidae) using an integrative approach. European Journal of Taxonomy, 290, 1-40.

McKey D., Blatrix R. (2017). Ecological and evolutionary responses of protective ant-plant mutualisms to environmental changes. Pp. 223-246. In: Oliveira P. and Koptur S. eds. Ant-Plant Interactions: Impacts of humans on terrestrial ecosystems. Cambridge University Press, Cambridge.

Vasse M., Voglmayr H., Mayer V., Gueidan C., Nepel M., Moreno L., de Hoog S., Selosse M.-A., McKey D., Blatrix R. (2017). A phylogenetic perspective on the association between ants (Hymenoptera: Formicidae) and black yeasts (Ascomycota: Chaetothyriales). Proceedings of the Royal Society B: Biological Sciences, 284, 20162519.

Blatrix R ., Lebas L., Galkowski C., Wegnez P., Pimenta R., Morichon D. (2016). Vegetation cover and elevation drive diversity and composition of ant (Hymenoptera : Formicidae) communities in a montane Mediterranean ecosystem. Myrmecological News, 22, 119-127.

Kokolo B., Atteke C., Ibrahim B., Blatrix R. (2016). Pattern of specificity in the tripartite symbiosis between Barteria plants, ants and Chaetothyriales fungi. Symbiosis, 69, 169-174.

Lebas C., Galkowski C., Blatrix R., Wegnez P. (2016). Fourmis d'Europe occidentale. Delachaux et Niestlé, 415 pp.

Nepel M., Voglmayr H., Blatrix R., Longino J. T., Fiedler K., Schönenberger J., Mayer V. E. (2016). Ant-cultivated Chaetothyriales in hollow stems of myrmecophytic Cecropia sp. trees - diversity and patterns. Fungal Ecology, 23, 131-140.

Blatrix R., Geniez P. (2015). Les fourmis de nos serres. Sauvages et Cultivées, 7, 26-27- Outreach publications.

Diamé L., Blatrix R., Grechi I., Rey J. Y., Sane C. A. B., Vayssières J. F., De Bon H., Diarra K. (2015). Relations between the design and management of Senegalese orchards and ant diversity and community composition. Agriculture, Ecosystems & Environment, 212, 94-105.

Hanshew A. S., McDonald B. R., Diaz Diaz C., Djiéto-Lordon, C., Blatrix R., Currie C. R. (2015). Characterization of actinobacteria associated with three ant–plant mutualisms. Microbial Ecology, 69, 192-203.

Lebas C., Galkowski C., Wegnez P., Espadaler X., Blatrix R. (2015). The exceptional diversity of ants on mount Coronat (Pyrénées-Orientales), and Temnothorax gredosi (Hymenoptera, Formicidae) new to France. Revue de l'Association Roussillonnaise d'Entomologie, 24, 24-33.

Mayer V., Frederickson M., McKey D., Blatrix R. (2014). Current issues in the evolutionary ecology of ant-plant symbioses. New Phytologist, 202, 749-764.

• Champignons
• Plantes
• Animaux
• Biologie évolutive
• Ecologie des interactions
• Ecologie des paysages
• Biogéographie, macro écologie et phylogéographie
• Etudes de terrains
• Etudes expérimentales
• Terrestre sol
• Terrestre aérien
• Milieux herbacés
• Milieux boisés
• Tropical
• Arthropodes
• Evolutionary biology
• Interactions ecology
• Landscape ecology
• Field studies
• Experimental studies
• Soil
• Grasslands
• Woodlands
• Tropical (EN)
• Arthropods
• Fungi
• Plants
• Animals