Keywords
soil; terrestrial Oligochaeta; agricultural practices; climate change; porosity; earthworms; enchytraeids; pesticides; tillage; organic matter.
Contact
celine.pelosi@inra.fr
Tel.: +33 (0)4 32 72 22 28
Centre de recherche Provence-Alpes-Côte d'Azur
UMR 1114 EMMAH INRA-Avignon Université
Bâtiment Sol, Domaine Saint Paul, Site Agroparc
228 route de l'Aérodrome
CS 40 509
84 914 AVIGNON Cedex 9
France
Education and main positions
2019-now Researcher in Soil ecology, INRA / Avignon UNiversity, Avignon, France
2018 "Habilitation à diriger des recherches", Paris-Saclay University, Orsay, France
2011-2018 Researcher in Ecotoxicology, INRA / AgroParisTech, Versailles, France
2008–2010 Postdoctoral Fellowship in Landscape ecology, INRA Toulouse, France
2005-2008 PhD in Agroecology, INRA / AgroParisTech, Grignon, France
Research topic
Resilience of terrestrial Oligochaeta communities and associated functions (regulation of hydrodynamic properties of soils) in cultivated soils subject to climate change.
Based on my scientific background in ecology and ecotoxicology, I work on the effects of anthropic activities on soil organisms and the functions they provide. In particular, I am interested in the sensitivity of earthworm and enchytraeid populations and communities to environmental factors (soil moisture, temperature, agricultural practices including plowing, pesticide use, organic matter inputs, etc.) and their functional complementarity (soil structure, regulation of water flows, degradation of organic matter) in more or less disturbed systems.
My work addresses issues related to the ecological intensification of agrosystems, climate change and the preservation of natural resources (soils, biodiversity, water). Soil organisms are used as indicators of the vulnerability and adaptability of farming systems but also as agroecological levers for more sustainable systems.
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Thématique de recherche
Résilience des communautés d’annélides oligochètes terrestres en sols cultivés soumis aux changements climatiques et des fonctions associées, impliquées dans la régulation des propriétés hydrodynamiques des sols.
Écologue et écotoxicologue, je travaille sur les effets des activités anthropiques sur les organismes du sol et les fonctions qu’ils remplissent. Plus particulièrement, je m’intéresse à la sensibilité des populations et des communautés de vers de terre et d’enchytréides aux facteurs du milieu (humidité, température, pratiques agricoles dont le labour, l’utilisation de pesticides, les apports de matière organique, etc.) et à leur complémentarité fonctionnelle (structure du sol, régulation des flux d’eau, dégradation de la matière organique) dans des systèmes plus ou moins perturbés.
Mes travaux s’adressent à des enjeux relatifs à l’intensification écologique des agrosystèmes, aux changements climatiques et à la préservation des ressources naturelles (sols, biodiversité, eau). Les organismes du sol sont utilisés comme des indicateurs de la vulnérabilité et de la capacité d’adaptation des systèmes agricoles mais également comme des leviers agroécologiques pour des systèmes plus durables.
Publications
2020
P1. Pelosi C., Boros G., Schmidt O., van Oort F., 2020. Soil Oligochaeta communities after 9 decades of continuous fertilization in a bare fallow experiment. Soil Organisms, 92(2) 129–142.
P2. Nélieu S., Delarue G., Amossé J., Bart S., Péry A.R.R., Pelosi C., 2020. Soil dissipation and bioavailability to earthworms of two fungicides under laboratory and field conditions. Environmental Science and Pollution Research. DOI: 10.1007/s11356-020-10222-3.
P3. Pelosi C., Bertrand C., Daniele G., Coeurdassier M., Benoit P., Nélieu S., Lafay F., Bretagnolle V., Gaba S., Vulliet E. Fritsch C., 2020. Residues of currently used pesticides in soils and earthworms: a silent threat? Agriculture, Ecosystems & Environment. Sous presse.
P4. Amossé J., Bart S., Brulle F., Tebby C., Beaudouin R., Nélieu S., Lamy I., Péry A.R.R., Pelosi C., 2020. A two years field experiment to assess the impact of two fungicides on earthworm communities and their recovery. Ecotoxicology and Environmental Safety, in press.
P5. Pelosi C., Baudry E., Schmidt O.,2020. Earthworm communities in rural and urban environments: Comparison of the mustard oil and electrical sampling methods. Urban Ecosystems, DOI: 10.1007/s11252-020-01023-0.
P6. Laurent C., Bravin M.N., Crouzet O., Pelosi C., Tillard E., Lecomte P., Lamy I., 2020. Increased soil pH and dissolved organic matter after a decade of organic fertilizer application mitigates copper and zinc availability despite contamination. Science of the Total Environment. 709, 135927.
P7. Aubert M., Banas D., Bernier N., Blouin M., Bolzonella C., Bonneval K., Brun J.J., Fritz I., Giannini R., Hager H., Katzensteiner K., Lowenfels J., Menta C., Micheloni C., Paoletti M.G., Pelosi C., Piccolo A., Ponge J.F., Singh S.K., Tassinato E., Teo G., Tomasi M., Zanella A. 2020. Organic Food “Yes”, Organic Food “No” A Discussion between Specialists with the Italian Parliament in the Fray. Austin Anthropology 4(1): 1012.
P8. Bart S., Pelosi C., S. Nélieu, I. Lamy, Péry A.R.R., 2020. An energy-based model to analyse growth data of earthworms exposed to two fungicides. Environmental Science and Pollution Research 27, 741–750.
2019
P9. Bart S., Pelosi C., Péry A.R.R., 2019. Towards a better understanding of the life cycle of the earthworm Aporrectodea caliginosa: New data and energy-based modelling. Pedobiologia 77, 150592.
P10. Bart S., Pelosi C., Barraud A., Péry A. R. R., Cheviron N., Grondin V., Mougin C., Crouzet O. 2019. Earthworms mitigate pesticide effects on soil microbial activities. Frontiers in Microbiology, 10, article 1535.
P11. Bart S., Barraud A., Amossé J., Péry A.R.R., Mougin C., Pelosi C. 2019. Effects of two common fungicides on the reproduction of Aporrectodea caliginosa in natural soil. Ecotoxicology and Environmental Safety, 181 518–524.
P12. Chassé P., Pelosi C., Lata J.-C., Barot S. 2019. Impact of crop genetic diversity on a litter consumer. Basic and Applied Ecology, 36, 1-11.
2018
P13. Bart S., Amossé J., Lowe C., Mougin C., Péry A.R.R., Pelosi C., 2018. Aporrectodea caliginosa s.s, a relevant earthworm species for a posteriori pesticide risk assessment: Current knowledge and recommendations for culture and experimental design. Environmental Science and Pollution Research 25, 33867–33881. DOI: 10.1007/s11356-018-2579-9.
P14. Daniele G., Lafay F., Pelosi C., Fritsch C., Vulliet E., 2018. Development of a method for the simultaneous determination of multi-class pesticides in earthworms by liquid chromatography coupled to tandem electrospray-mass spectrometry. Analytical and Bioanalytical Chemistry, 410 (20), 5009-5018. DOI: 10.1007/s00216-018-1151-2
P15. Bart S., Roudine S., Amossé J., Mougin C., Péry A.R.R., Pelosi C., 2018. How to assess the feeding activity in ecotoxicological laboratory tests using enchytraeids? Environmental Science and Pollution Research, https://doi.org/10.1007/s11356-018-1701-3.
P16. Amossé J., Boros G., Bart S., Péry A.R.R., Pelosi C., 2017-2018. First record of terrestrial Enchytraeidae (Annelida: Clitellata) in Versailles palace’s park, France. Opuscula Zoologica, 48(2), 53-58.
P17. Amossé J., Bart S., Péry A.R.R., Pelosi C., 2018. Short-term effects of two fungicides on enchytraeid and 1earthworm communities under field conditions. Ecotoxicology, 27 (3), 300–312. DOI: 10.1007/s10646-018-1895-7.
P18. Taheri S., Pelosi C., Dupont L., 2018. Harmful or useful? A case study of the exotic peregrine earthworm morphospecies Pontoscolex corethrurus. Soil Biology & Biochemistry, 116, 277-289. DOI: 10.1016/j.soilbio.2017.10.030.
P19. Pelosi C., Römbke J., 2018. Enchytraeids as bioindicators of land use and management. In Humusica, a manual of humus forms. Special issue in Applied Soil Ecology, 123, 775-779. doi: 10.1016/j.apsoil.2017.05.014.
2017
P20. Marchand L., Brunel-Muguet S., Lamy I., Zhang Q., Mench M., Pelosi C., 2017. Modulation of trace element bioavailability for two earthworm species (Aporrectodea icterica Savigny, 1826 and Aporrectodea longa Ude, 1885) after biochar amendment into a contaminated technosol. Ecotoxicology, 26, 1378-1391. DOI 10.1007/s10646-017-1862-8.
P21. Römbke J., Schmelz R.M., Pelosi C., 2017. Effects of organic pesticides on Enchytraeids (Oligochaeta) in agroecosystems: Laboratory and higher-tier tests. Frontiers in Environmental Science, 5, article no 20 http://dx.doi.org/doi:10.3389/fenvs.2017.00020. Fait marquant du département Environnement-Agronomie INRA en 2016.
P22. Bart S., Laurent C., Péry A.R.R., Pelosi C., 2017. Differences in sensitivity between earthworm and enchytraeid exposed to two commercial fungicides. Ecotoxicology and Environmental Safety 140, 177-184.
P23. Pelosi C., Barriuso E., Bedos C., Benoit P., Mamy L., Mougin C., 2017. Fate and impact of pesticides: new directions to explore. Environmental Science and Pollution Research, 24(8), 6841–6843. DOI 10.1007/s11356-017-8383-0.
P24. Pelosi C., Grandeau G., Capowiez Y., 2017. Temporal dynamics of earthworm-related macroporosity in tilled and non-tilled cropping systems. Geoderma 289,169-177.
P25. Hossard L., Guichard L., Pelosi C., Makowski D., 2017. Lack of evidence for a decrease in synthetic pesticide use on the main arable crops in France. Science of the Total Environment 575, 152-161.
2016
P26. Pelosi C., Römbke J., 2016. Are Enchytraeidae (Oligochaeta, Annelida) good indicators of agricultural management practices? Soil Biology and Biochemistry, 100, 255-263.
P27. Marchand L., Pelosi C., Zhang Q., Maillard A., Gonzales-Centeno R., Mench M., Brunel-Muguet S., 2016. Trace element bioavailability, yield and seed quality of rapeseed (Brassica napus L.) modulated by biochar incorporation into a contaminated technosol. Chemosphere, 156, 150-162. DOI 10.1016/j.chemosphere.2016.04.129.
P28. Pelosi C., Pey B., Caro G., Cluzeau D., Peigné J., Hedde M., 2016. Dynamics of earthworm taxonomic and functional diversity in ploughed and no tilled cropping systems. Soil & Tillage Research, 156, 25–32.
P29. Nélieu S., Delarue G., Awad P., Fraillon F., Pelosi C., 2016. Evaluation of epoxiconazole bioavailability in soil to the earthworm Aporrectodea icterica. Environmental Science and Pollution Research, 23, 2977–2986.
P30. Pelosi C., Lebrun M., Beaumelle L., Cheviron N., Delarue G., Nélieu S., 2016. Sublethal effects of epoxiconazole on the earthworm Aporrectodea icterica. Environmental Science and Pollution Research, 23, 3053–3061. DOI 10.1007/s11356-015-4845-4.
2015
P31. Ricci, F., Bentze L., Montagne D., Houot S., Bertrand, M., Pelosi C., 2015. Positive effects of alternative cropping systems on terrestrial Oligochaeta (Clitellata Annelida). Soil organisms, 87, 71–83.
P32. Henneron L., Bernard L., Hedde M., Pelosi C., Villenave C., Chenu C., Bertrand M., Girardin C., Blanchart E., 2015. Fourteen years of evidence for positive effects of conservation agriculture and organic farming on soil life. Agronomy for Sustainable Development, 35, 169-181. DOI 10.1007/s13593-014-0215-8.
P33. Pelosi C., Bertrand M., Thénard J., Mougin C., 2015. Earthworms in a 15 years agricultural trial. Applied Soil Ecology 88, 1-8.
2014
P34. Pey B., Laporte M.-A., Nahmani J., Auclerc A., Capowiez Y., Caro G., Cluzeau D., Cortet J., Decaëns T., Dubs F., Joimel S., Guernion M., Briard C., Grumiaux F., Laporte B., Pasquet A., Pelosi C., Pernin C., Ponge J.-F., Salmon S., Santorufo L., Hedde M., 2014. A thesaurus for soil invertebrate trait-based approaches. PLoS ONE 9(10): e108985. doi:10.1371/journal.pone.0108985.
P35. Pey B., Nahmani J., Auclerc A., Capowiez Y., Cluzeau D., Cortet J., Decaëns T., Deharveng L., Dubs F., Joimel S., Briard S., Grumiaux F., Laporte M.-A., Pasquet A., Pelosi C., Pernin C., Ponge J.-F., Salmon S., Santorufo L., Hedde M., 2014. Current use of and future needs for soil invertebrate functional traits in community ecology. Basic and Applied Ecology 15, 194-206.
P36. Pelosi C., Chiron F., Dubs F., Hedde M., Ponge J.-F., Salmon S., Cluzeau D., Nélieu S., 2014. A new method to measure allyl isothiocyanate (AITC) concentrations in mustard—Comparison of AITC and commercial mustard solutions as earthworm extractants. Applied Soil Ecology, 80, 1-5.
P37. Pelosi C., Bonthoux S., Castellarini F., Goulard M., Ladet S., Balent G., 2014. Is there an optimum scale for predicting bird species’ distribution in agricultural landscapes? Journal of Environmental Management, 136, 54-61.
P38. Pelosi C., Capowiez Y., Caro G., Guernion M., Hedde M., Peigné J., Pey B., Piron D., Cluzeau D., 2014. Reducing tillage in cultivated fields increases earthworm functional diversity. Applied Soil Ecology, 83, 79-97.
P39. Pelosi C., Barot S., Capowiez Y., Hedde M., Vandenbulcke F., 2014. Pesticides and earthworms. A review. Agronomy for Sustainable Development, 34(1), 199-228. DOI: 10.1007/s13593-013-0151-z.
2013
P40. Pelosi C., Toutous L., Chiron F., Dubs F., Hedde M., Muratet A., Ponge J.-F., Salmon S., Makowski D., 2013. Reduction of pesticide use can increase earthworm populations in wheat crops in a European temperate region. Agriculture, Ecosystems & Environment, 181, 223-230. DOI: http://dx.doi.org/10.1016/j.agee.2013.10.003. Fait marquant du centre INRA Versailles Grignon en 2013.
P41. Pelosi C., Joimel S., Makowski D., 2013. Searching for a more sensitive earthworm species to be used in pesticide homologation tests - a meta-analysis. Chemosphere, 90, 895-900. DOI: 10.1016/j.chemosphere.2012.09.034. Fait marquant du département Environnement-Agronomie et Fait Marquant Scientifique de l’INRA (rubrique agroécologie) en 2012.
2012
P42. Pulleman M., Creamer R., Hamer U., Helder J., Pelosi C., Peres G., Rutgers M., 2012. Soil biodiversity, biological indicators and soil ecosystem services - an overview of European approaches. Current Opinion in Environmental Sustainability, 4, 529-538. DOI: 10.1016/j.cosust.2012.10.009.
2011
P43. Valantin-Morison M., Sarthou J.-P., de Tourdonnet S., Gosme M., Bertrand M., Roger-Estrade J., Aubertot J.-N., Rusch A., Motisi N., Pelosi C., Doré T., 2011. Agroecosystem management and biotic interactions: a review. Agronomy for Sustainable Development, 31, 491-514. DOI 10.1007/s13593-011-0009-1.
2010
P44. Pelosi C., Goulard M., Balent G., 2010. The spatial scale mismatch between ecological processes and agricultural management: Do difficulties come from underlying theoretical frameworks? Agriculture, Ecosystems & Environment, 139, 455-462. DOI: 10.1016/j.agee.2010.09.004.
2009
P45. Pelosi C., Bertrand M., Capowiez Y., Boizard H., Roger-Estrade J., 2009. Earthworm collection from agricultural fields: comparisons of selected expellants in presence/absence of hand sorting. European Journal of Soil Biology, 45, 176-183. DOI: 10.1016/j.ejsobi.2008.09.013.
P46. Pelosi C., Bertrand M., Roger-Estrade J., 2009. Earthworm community in conventional, organic and direct seeding with living mulch cropping systems. Agronomy for Sustainable Development, 29, 287-295. DOI: 10.1051/agro/2008069.
2008
P47. Pelosi C., Bertrand M., Makowski D., Roger-Estrade J., 2008. WORMDYN: A model of Lumbricus terrestris population dynamics in agricultural fields. Ecological Modelling, 218, 3-4, 219-234. DOI: 10.1016/j.ecolmodel.2008.07.002.
2007
P48. Velasquez E., Pelosi C., Brunet D., Grimaldi M., Martins M., Rendeiro A. C., Barrios E., Lavelle P., 2007. This ped is my ped: Visual separation and nearinfrared spectra allow determination of the origins of soil macroaggregates. Pedobiologia, 51, 75-87. DOI: 10.1016/j.pedobi.2007.01.002.
Data paper
P49. Lüscher, G., Ammari, Y., Andriets, A., Angelova, S., Arndorfer, M., Bailey, D., Balázs, K., Bogers, M., Bunce, R., Choisis, J. P., Dennis, P., Díaz, M., Dyman, T., Eiter, S., Fjellstad, W., Fraser, M., Friedel, J. K., Garchi, S., Geijzendorffer, I. R., Gomiero, T., González-Bornay, G., Guteva, Y., Herzog, F., Jeanneret, P., Jongman, R. H. G., Kainz, M., Kwikiriza, N., López, Díaz, M., Moreno, G., Nicholas-Davies, P., Nkwiine, C., Opio, J., Paoletti, M. G., Podmaniczky, L., Pointereau, P., Pulido, F., Sarthou, J.-P., Schneider, M. K., Sghaier, T., Siebrecht, N., Stoyanova, S., Wolfrum, S., Yashchenko, S., Albrecht, H., Báldi, A., Belényesi, M., Benhadi-Marin, J., Blick, T., Buholzer, S., Centeri, C., Choisis, N., Cuendet, G., De Lange, H., Déjean, S., Deltshev, C., Díaz Cosín, D., Dramstad, W., Elek, Z., Engan, G., Evtushenko, K., Falusi, E., Finch, O.-D., Frank, T., Gavinelli, F., Genoud, D., Gillingham, P., Grónás, V., Gutiérrez, M., Häusler, W., Heer, X., Hübner, T., Isaia, M., Jerkovich, G., Jesus, J., Kakudidi, E., Kelemen, E., Koncz, N., Kovacs, E., Kovács-Hostyánszki, A., Last, L., Ljubomirov, T., Mandery, K., Martínez-Rodríguez, J., Mayr, J., Mjelde, A., Muster, C., Nascimbene, J., Neumayer, J., Odegaard, F., Ortiz-Sánchez, F. J., Oschatz, M.-L., Papaja-Hülsbergen, S., Paschetta, M., Pavett, M., Pelosi, C., Penksza, K., Pommeresche, R., Popov, V., Radchenko, V., Richner, N., Riedel, S., Scullion, J., Sommaggio, D., Szalkovszki, O., Szerencsits, E., Trigo, D., Vale, J., van Kats, R., Vasilev, A., Whittington, A, Wilkes-Allemann, J., Zanetti, T., 2016. Farmland biodiversity and agricultural management on 237 farms in 13 European and 2 African regions. Ecology, 97(6), p. 1625.
