• Nicolas Courbin

    NCourbinChercheur postdoctoral / Postdoctoral researcher

    J'étudie les mécanismes de la répartition spatiale des grands herbivores, des grands carnivores et des oiseaux marins dans le but d'approfondir nos connaissances sur les interactions prédateur-proies (jeu spatial prédateur-proie, stratégie d'alimentation, stratégie de recherche des prédateurs, stratégie anti-prédatrice des proies) et d'améliorer les mesures de gestion et de conservation de la faune.

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  • Olivier COTTO

    Post-doctorant

    Olivier Cotto

    CEFE/CNRS
    Campus du CNRS
    1919, route de Mende
    34293 Montpellier 5

    Fax : +33/0 4 67 61 33 36

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  • Pierre-Edouard GUERIN

    pierre edouard guerin photo webIngénieur d'étude, bioinformaticien (2017 - 2021)

    Diplômé du master professionnel double compétence informatique et biologie de l’Université Paris Diderot, j'apporte mes compétences en programmation pour de nombreux projets scientifiques en collaboration avec des équipes de recherche.

    CEFE/CNRS
    Campus du CNRS
    1919, route de Mende
    34293 Montpellier 5

    • mail:This email address is being protected from spambots. You need JavaScript enabled to view it.
    • website:https://guerinpe.com/

     

  • Quentin STRUELENS

    STRUELENS Quentin photo profil

    Email: quentin.struelens < at > ird.fr

    Supervisor: Dr Olivier DANGLES

    Institutions: National Museum of Natural History (MNHN) / French National Research Institue for Sustainable Development (IRD)

    Keywords: Ecology, Agroecology, Socio-ecosystem dynamics, Tropical Andes.


    Title:Pest Management Across Scales: Insight From Mountainous Tropical Agroscapes.

    Context: the tropical Andes is a world full of gradients that occur at several spatial scales. At the crop scale, a mosaic of spatial and temporal microclimates exists due to the high diversity of crop plants and the diel temperature changes. At the landscape scale, the diversities of land-management and land-use produce a gradient of landscape complexity. Finally, at the human-community scale, there is a wide diversity and combinations of human cultures related to historical contingency. This combination of abiotic-, biotic- and human-related gradients makes the tropical Andes an attractive playground for ecologists who are interested in understanding the effects and interactions of these drivers on agroecosystems.

    Goal: I aim at identifying the drivers of pest control across these three spatial scales in order to propose practical solutions for the local farmer communities. Each chapter focuses on a specific scale, with its particular set of drivers of pest control.

    Chapter 1: At the crop scale, temperatures vary tremendously both spatially and temporally, which impacts the development and emergence of pests. To cope with this highly fluctuating environment, we expect species to have developed a variety of developmental and phenological adaptations. We integrated, for the first time, slow-fast thermal strategies into a mechanistic predictive framework. The model calibrated with the observed individual thermal strategies showed a high accuracy in phenological predictions. This model can therefore be used to accurately predict the emergence of pests in the Andean context. Read more...

    Chapter 2: At the landscape scale, we aim at identifying potential trade-offs and synergies between landscape characteristics and agrochemical use on insect diversity and functions. We are especially interested in the potentially opposite effect of these two drivers on arthropod pests and pollinators, which both ultimately influence crop yield.

    Chapter 3: At the human-community scale, we aim at assessing whether agrochemical resellers are responsible for pesticide overuse in the Andes. Reseller knowledge on common pests and the quality of their recommendations will be evaluated.

    Chapter 4: At the human-community and landscape scale, we aim at understanding how the perception of ecosystem services and the landscape can be influenced by the traditional knowledge of indigenous and non-indigenous farmers.

    Altogether, these different chapters will provide new insights in several areas of natural and human sciences, along with practical solutions to be included into an integrated pest management program.


    Publications:

    Struelens, Q., Rebaudo, F., Quispe, R., & Dangles, O. (2018). Thermal pace-of-life strategies improve phenological predictions in ectotherms. Scientific Reports, 8(1). https://doi.org/10.1038/s41598-018-34274-1

    Rebaudo, F., Struelens, Q., & Dangles, O. (2018). Modelling temperature-dependent development rate and phenology in arthropods: The devRate package for r. Methods in Ecology and Evolution, 9(4), 1144‑1150.  https://doi.org/10.1111/2041-210X.12935

    Mina, D., Struelens, Q., Carpio, C., Rivera, M., Rebai, N., Rebaudo, F., & Dangles, O. (2017). Lupin Pest Management in the Ecuadorian Andes: Current Knowledge and Perspectives. Outlooks on Pest Management, 28(6), 250‑256. https://doi.org/10.1564/v28_dec_05

    Struelens, Q., Gonzales Pomar, K., Loza Herrera, S., Nina Huanca, G., Dangles, O., & Rebaudo, F. (2017). Market access and community size influence pastoral management of native and exotic livestock species: A case study in communities of the Cordillera Real in Bolivia’s high Andean wetlands. PLOS ONE, 12(12), e0189409. https://doi.org/10.1371/journal.pone.0189409

    Rebaudo, F., Struelens, Q., Callizaya Condori, F., & Quispe, R. (2017). Relationship between temperature and development rate of Copitarsia incommoda (Lepidoptera: Noctuidae) in the Bolivian Andes. Applied Entomology and Zoology, 52(2), 313‑320. https://doi.org/10.1007/s13355-017-0480-5


     

  • Roger PRADEL

    alt

    Directeur de Recherche au CNRS / Senior Scientist at CNRS

    J'étudie la dynamique des populations sauvages et développe à cette fin des méthodes statistiques.

    I study the dynamics of wild populations and develop appropriate statistical methods.

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  • Sébastien LION

    Directeur de recherche CNRS (DR2)

    Tel : +33 (0)4 67 61 32 15

    E-mail : firstname.name [at] cefe.cnrs.fr

    Plus d'information sur mon site web personnel.

    More information on my personal web site.

  • Sophie CAILLON

    Sophie Caillon

    Chargée de recherche au CNRS
    Ethnobiologiste / géographe

    Responsable de l'équipe Interactions bioculturelles
    Chercheure associée à l'UMR CREDO
    Porteur du projet PICS Bien-Etre
    Membre de l'ANR ASSET, du projet Crop-Diversity LICCI et du projet UE FALAH

     

    Mon domaine de recherche peut être défini par deux thèmes : les relations Hommes-milieux, et l’agrobiodiversité. J’analyse comment les deux composantes du concept de biodiversité, les diversités culturelle et biologique, interagissent, et comment elles peuvent constituer un potentiel d’adaptation pour des sociétés confrontées à des changements de plus en plus rapides et globaux.

     

     

  • Stéphanie MANEL

    Stephanie MANEL

    Directrice d’Etudes EPHE

    My main field of research is landscape genetics.

    CEFE/CNRS
    Campus du CNRS
    1919, route de Mende
    34293 Montpellier cedex 5

    Tel. : +33(0)4 67 61 32 35

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    Keywords : Landscape genetics - Landscape connectivity - Adaptive genetic diversity - Local adaptation - Gene flow 

    Website: https://sites.google.com/site/stephaniemanel/home

  • Taïna LEMOINE

    Doctorante - Université Montpellier

    CEFE UMR 5175
    1919 Route de Mende
    34293 Montpellier FRANCE

    Deuxième étage, aile A, bureau n°206

    &

    AGAP UMR 1334
    2 Place Pierre Viala
    34060 Montpellier FRANCE

    This email address is being protected from spambots. You need JavaScript enabled to view it./This email address is being protected from spambots. You need JavaScript enabled to view it.

    Période :

    Novembre 2020 – Novembre 2023

    Financement :

    Projet ANR SCOOP : Sélectionner des plantes coopératives pour développer une agriculture plus durable (Coordination par Hélène Fréville, INRAE, AGAP).

    Encadrement :

    Cyrille Violle (UMR CEFE), Florian Fort (UMR CEFE) et Hélène Fréville (UMR AGAP).

    Mots-clés:complémentarité de niche, compétition, traits fonctionnels, stratégie d’utilisation de la ressource, agriculture, culture en mélange.

    Sujet de thèse :

    Qui coexiste avec qui ? Qui est en compétition avec qui ? Qui coopère avec qui ? Les interactions écologiques sont des processus majeurs qui influencent la coexistence des espèces et le fonctionnement des écosystèmes. Pour autant, les caractères phénotypiques qui confèrent aux espèces (ou aux génotypes) une aptitude à la compétition (ou à la coopération) élevée restent mal connus. C’est en particulier le cas pour les végétaux, tant sur les espèces sauvages que cultivées.

    De plus, la simplification des agrosystèmes couplée à l’utilisation massive d’intrants lors de la révolution verte a engendré une hausse sans précédent des rendements qui a permis de répondre aux besoins alimentaires des populations des pays industrialisés.

    Une des solutions envisagées pour limiter l’usage d’intrants, tout en maintenant des niveaux de production acceptables, est de réintroduire de la diversité dans les systèmes cultivés. Cette diversification des agrosystèmes peut se faire à l’échelle interspécifique comme dans les systèmes de culture associées (Bedoussac et al., 2015) mais aussi à l’échelle intraspécifique en cultivant des génotypes d’une même espèce en association au sein d’une parcelle.Cependant, augmenter la diversité dans une culture n’est pas toujours synonyme d’un meilleur fonctionnement de cette dernière. Les recherches doivent donc être poursuivies afin de concevoir des mélanges variétaux permettant d’assurer une productivité suffisante dans des agrosystèmes durables (Litrico & Violle 2015).

    Mon projet de thèse vise à comprendre par des approches comparatives en écologie fonctionnelle, qui s’appuie sur l’étude les variations de caractères, l’adaptation des plantes à leur environnement ainsi que les interactions qu’elles mettent en place. L’utilisation des traits fonctionnels est une manière d’appréhender la question de façon générique sous l’hypothèse que des traits candidats sont valides quelle que soit l’espèce (ou le génotype) considéré. J’étudie les interaction mises en place entre différents génotypes de blé dur afin de comprendre quels sont les mécanismes écologiques qui sous-tendent la relation diversité – productivité au sein de couverts monospécifiques. Je m’intéresse particulièrement aux traits racinaires qui restent encore peu étudiés à l’échelle des plantes cultivées.

    Publication :

    - Chabert, S., Lemoine, T., Cagnato, M. R., Morison, N., & Vaissière, B. E. (2018). Flower age expressed in thermal time: is nectar secretion synchronous with pistil receptivity in oilseed rape (Brassica napus L.)? Environmental and Experimental Botany, 155, 628-640.

    - Lemoine, T., Chabert, S., Fronteau, L., Conjeaud, J.-C., Vaissière, B. (2018). Mesurer et optimiser la sécrétion nectarifère. Bulletin Semences(259), 38-41.

    - Chabert, S., Lemoine, T., Fronteau, L., & Vaissière, B. E. (2017). Mesurer la sécrétion nectarifère: exemple d'une lignée hybride F1 et de son parent mâle stérile chez le colza d'hiver (Brassica napus L.). OCL, 24(6), D602.

     

  • Thierry CHAMBERT

    photo Thierry page web

    Postdoctoral Researcher

    My research interests lie at the interface between population dynamics, quantitative ecology, conservation and life history evolution. I mostly focus on empirical work, on wild animal populations, but I also do some methodological development and a bit of theoretical work.

  • Thomas LENORMAND

    altDirecteur de Recherche CNRS

    CEFE
    Campus du CNRS
    1919, route de Mende
    34293 Montpellier 5
    Tél : +33/0 4 67 61 32 91
    This email address is being protected from spambots. You need JavaScript enabled to view it.
    @Th_Lenormand

    My principal area of research is Evolutionary genetics and evolutionary ecology. I have a broad expertise in evolutionary biology, genetics and ecology.

    I have been working on adaptation and mutation, local adaptation, evolution of genetic systems (sex, recombination, sex chromosomes), evolution of gene duplicates, speciation, genetic conflicts, dispersal, biotic interactions (parasites, microbiota), statistics and fitness measures. I have been working with many empirical systems (vertebrates, insects, crustaceans, fungi, plants, helminths, bacteria), in the lab and in the field.

    Currently, my scientific activity rests on three axes: first I do theoretical work (theoretical population genetics, statistics, and bioinformatics development). I am particularly interested currently on the evolution of gene expression (on sex chromosomes or in asexuals). Second, I work on small crustaceans Artemia and Daphnia. I’m particularly interested currently on sex-asex transitions, biotic interactions and adaptation to temperature. Third, I do experimental evolution on E. coli. I'm particularly interested on testing fitness landscape models, adaptation to different doses of antibiotics, and coevolution of species coexisting by frequency dependence.

    Research interests by keywords
    adaptation, local adaptation, migration, speciation, (sex) chromosomes, clines, sex, parthenogenesis, meiosis, recombination, epistasis, dominance, mutations, resistance, duplications, modifiers, mating systems, sexual conflicts, parasites, microbiota.

    XYmus alt popgen  alt
    coli daphnia  alt silene

    Brief CV

    Research director CNRS (DR1)
    HDR (2007)
    Ph.D Evolutionary Biology (1998)

    Radcliffe Fellow, Harvard Univ. (2017-2018)
    ERC "starting grant" (2007)
    Theodosius Dobzhansky Prize (Society for the Study of Evolution), 2000
    Young Investigator Prize (American Society of Naturalists), 2000

    ResearchGate, GoogleScholarAcademicTree


     

    alt Editor2012 - 2015
    alt Associate editor2005 - 2008
    alt Associate editor2004 - 2011
    alt Associate editor2003 - 2007

     


    Interested to join the lab?

    If you're interested by the research topics mentionned above, or related ones, do not hesitate to contact me to discuss possible internships, PhDs or postdocs.


    Preprints

    Molinier C, Lenormand T, Haag CR. 202X. No support for a meiosis suppressor in Daphnia pulex: Comparison of linkage maps reveals normal recombination in males of obligate parthenogenetic lineages. bioRxiv.

    Rode NO, Jabbour-Zahab R, Boyer L, Flaven É, Hontoria F, Van Stappen G, Haag C, Lenormand T. 202X. The origin of asexual brine shrimps. bioRxiv. Am. Nat. in revision.

    Pais-Costa AJ, Lievens EJ, Redón S, Sánchez MI, Jabbour-Zahab R, Joncour P, Van Hoa N, Van Stappen G, Lenormand T. 202X. Strong transgenerational effects but no genetic adaptation in zooplankton 24 years after an abrupt+ 10° C climate change. bioRxiv. Evolution Letters in revision.

    Recent papers

    Lenormand T, Roze D. 2022. Y recombination arrest and degeneration in the absence of sexual dimorphism. Science, in press.

    Boyer L, R Zahab, M Mosna, C Haag, T Lenormand. 2021. Not so clonal asexuals: unraveling the secret sex life of Artemia parthenogenetica. Evolution Letters 5:164-174.

    Bestová H, Segrestin J, von Schwartzenberg K, Škaloud P, Lenormand T, Violle C. 2021. Biological scaling in green algae: the role of cell size and geometry. Scientific Reports 11: 1-9.

    Simion P, Narayan J, Houtain A, Derzelle A, Baudry L, Nicolas E,... and Van Doninck K. 2021. Chromosome-level genome assembly reveals homologous chromosomes and recombination in asexual rotifer Adineta vaga. Science advances, 7: eabg4216.Lenormand T, F Fyon, E Sun, D Roze. 2020. Sex Chromosome Degeneration by Regulatory Evolution. Current Biology 30: 3001-3006.

    Lenormand, T., Fyon, F., Sun, E., & Roze, D. 2020. Sex chromosome degeneration by regulatory evolution. Current Biology 30: 3001-3006.

    Lievens EJP, Y Michalakis, T Lenormand. 2020. Trait-specific trade-offs prevent niche expansion in two parasites. Recommended by PCI Evol Biol. JEB 33:1704-1714.

    Harmand N, V Federico, T Hindre, T Lenormand. 2019. Non-linear frequency-dependent selection promotes long-term coexistence between bacteria species. Ecology Letters 22, 1192-1202

    Lievens EJP, Rode NO, Landes J, Segard A, Jabbour-Zahab R, Michalakis Y, Lenormand T. 2019. Long-term prevalence data reveals spillover dynamics in a multi-host (Artemia), multi-parasite (Microsporidia) community. International Journal for Parasitology, 49, 471-480.

     

    Selected publications by topics

    Adaptation and mutation effects


    Bourguet, D., T. Lenormand, T. Guillemaud, V. Marcel, D. Fournier, and M. Raymond. 1997. Variation of dominance of newly arisen adaptive genes. Genetics 147:1225-1234.

    Chevin L.-M., G. Martin, T. Lenormand. 2010. Fisher’s model and the genomics of adaptation: restricted pleiotropy, heterogeneous mutation and parallel evolution. Evolution 64: 3213-3231PDF

    Gallet R., Latour Y., Bradley H., and T. Lenormand. 2014. The dynamics of niche evolution upon abrupt environmental change. Evolution 68:1257-1269

    Gallet R, Violle C, Fromin N, Jabbour-Zahab R, Enquist B, Lenormand T. 2017. The evolution of bacterial cell size: the internal diffusion-constraint hypothesis. ISME J. 11:1559-156

    Harmand N, Gallet R, Jabbour-Zahab R, Martin G, Lenormand T. 2016. Fisher’s geometrical model and the mutational patterns of antibiotic resistance across dose gradients. Evolution 71:23-37.

    Harmand N, Gallet R, Martin G, Lenormand T. 2018. Evolution of bacteria specialization along an antibiotic dose gradient.Evol.Let. in press.

    Jasmin J.-N., Lenormand T. 2016.Accelerating mutational load is not due to synergistic epistasis or mutator alleles in mutation accumulation lines of yeast. Genetics DOI115.182774

    Labbé, P., Sidos, N., Raymond, M., and Lenormand, T., 2009. Resistance Gene Replacement in the Mosquito Culex Pipiens: Fitness Estimation from Long Term Cline Series. Genetics 182:303-312PDF

    Lenormand, T., D. Roze, F. Rousset. 2009. Stochasticity in evolution. Trends in Ecology & Evolution. 24: 157-165.PDF

    Lenormand T, Chevin LMC, Bataillon T. 2016. Parallel evolution : what does it (not) tell us and why is it (still) interesting? [Book chapter, in Chance in EvolutionRamsey G & C Pence Eds, Univ. Chicago Press]. 

    Lenormand, Nougué O, Jabbour-Zahab R, Arnaud F, Dezileau L, Chevin L.-M and Sánchez M. 2017 Resurrection Ecology in Artemia. Evol Appl. 11:76-87

    Lenormand T, Harmand N, Gallet R. Cost of resistance: an unreasonably expensive concept. bioRxiv.

    Manna F., Martin G., and T. Lenormand. 2011. Fitness landscape: an alternative theory for the dominance of mutations. Genetics 189:923-937.PDF.

    Manna F., Gallet R., Martin G., and T. Lenormand. 2012. The high throughput yeast deletion fitness data and the theories of dominance. JEB, 25:892-903.PDF.

    Martin, G., and T. Lenormand. 2006. A general multivariate extension of Fisher's geometrical model and the distribution of mutation fitness effects across species. Evolution 60:893-907. AwardedFisher Prize 2007, Best PhD paper published in Evolution in 2006.PDF

    Martin, G., and T. Lenormand. 2006. The fitness effect of mutations in stressful environments: a survey in the light of fitness landscape models. Evolution 60:2413-2427.PDF

    Martin, G., S.F. Elena and T. Lenormand. 2007. Distributions of epistasis in microbes fit predictions from a fitness landscape model. Nature Genetics 39:555-560.PDF

    Martin, G., and T. Lenormand. 2008. The distribution of beneficial and fixed mutation fitness effects close to an optimum. Genetics. 179: 907-916.PDF

    Martin, G., and T. Lenormand. 2015. The fitness effect of mutations across environments: Fisher's geometric model with multiple optima.Evolution 69:1433-1447

    Nougué O, Svendsen N, Zahab R, Lenormand T, Chevin LM. 2016.The ontogeny of tolerance curves : habitat quality versus acclimation in a stressful environment.J. Anim. Ecol. Doi 10.1111/1365-2656.12572.

    Local adaptation


    Alberto F., S. N. Aitken, R. Alía, S. C. González-Martínez, H. Hänninen, A. Kremer, F. Lefèvre, T. Lenormand, S. Yeaman, R. Whetten, O. Savolainen. 2013. Potential for evolutionary responses to climate change - evidence from tree populations. Global Change Biology doi: 10.1111/gcb.12181.

    Debarre F., Lenormand, T. and Gandon S. Evolutionary epidemiology of drug-resistance in space. 2009. PLoS Comp. Biol. 5:e1000337.PDF

    Debarre F.,and T. Lenormand. 2011.Distance-limited dispersal promotes coexistence at habitat boundaries: reconsidering the competitive exclusion principle. Ecology Letters, 14: 260-266PDF

    Epinat, G., and T. Lenormand. 2009. The evolution of assortative mating and selfing with in- and outbreeding depression. Evolution. 63: 2047-2060.PDF

    Gallet R, Latour Y, Hughes B S, Lenormand T. 2014. The dynamics of niche evolution upon abrupt environmental change. Evolution 68: 1257-1269

    Guillemaud, T., T. Lenormand, D. Bourguet, C. Chevillon, N. Pasteur, and M. Raymond. 1998. Evolution of resistance in Culex pipiens: Allele replacement and changing environment. Evolution 52:443-453.

    Labbe, P., T. Lenormand, and M. Raymond. 2005. On the worldwide spread of an insecticide resistance gene: a role for local selection. Journal of Evolutionary Biology 18:1471-1484.PDF

    Lenormand, T. 2002. Gene flow and the limits to natural selection. Trends in Ecology & Evolution 17:183-189.PDF

    Lenormand, T., D. Bourguet, T. Guillemaud, and M. Raymond. 1999. Tracking the evolution of insecticide resistance in the mosquito Culex pipiens. Nature 400:861-864.PDF

    Lenormand, T., and M. Raymond. 1998. Resistance management: the stable zone strategy. Proceedings of the Royal Society of London Series B-Biological Sciences 265:1985-1990.PDF

    Lenormand, T., and M. Raymond. 2000. Analysis of clines with variable selection and variable migration. American Naturalist 155:70-82.PDF

    Milesi P, Lenormand T., Lagneau C, Weill M, Labbé P. 2016. Relating Fitness to Long-term Environmental Variations in natura.Molecular Ecoloy 25:5483-5499.

    Gene duplication evolution


    Labbe, P., A. Berthomieu, C. Berticat, H. Alout, M. Raymond, T. Lenormand, and M. Weill. 2007. Independent duplications of the acetylcholinesterase gene conferring insecticide resistance in the mosquito Culex pipiens. Molecular Biology and Evolution 24:1056-1067. PDF

    Lenormand, T., T. Guillemaud, D. Bourguet, and M. Raymond. 1998. Appearance and sweep of a gene duplication: Adaptive response and potential for new functions in the mosquito Culex pipiens. Evolution 52:1705-1712. PDF

    Labbé P., Milesi P., Yébakima A., Weill M., and T. Lenormand. 2014. Gene dosage effects on fitness in recent adaptive duplications : ace-1 in the mosquito Culex pipiens. Evolution 68: 2092-2101

    Labbe, P., C. Berticat, A. Berthomieu, S. Unal, C. Bernard, M. Weill and T. Lenormand. 2007. Forty years of erratic insecticide resistance evolution in the mosquito Culex pipiens. PLoS Genetics, 3:e205. PDF

    Milesi P, Weill M, Lenormand T., Labbé P. 2017. Heterogeneous gene duplications can be adaptive because they permanently associate overdominant alleles.Evolution Letters, in press

    Sex, recombination, life cycles


    Fyon F, Lenormand T. 2018. Cis-regulator runaway and divergence in asexuals. Evolution 10.1111/evo.13424

    Haag C, Theodosiou L, Zahab R, Lenormand T. 2017. Low recombination rates in sexual species and sex-asex transitions Phil. Trans. Roy. Soc. B. DOI: 10.1098/rstb. 2016-0461

    Lenormand T, Engelstädter J, Johnston SE, Wijnker E, Haag CR. 2016. Evolutionary mysteries in meiosis. Phil. Trans. Roy. Soc. B, Doi 10.1098/rstb.2016.0001. alsohereon BiorXiv

    Lenormand, T. 2003. The evolution of sex dimorphism in recombination. Genetics 163:811-822.PDF

    Lenormand, T., and S. P. Otto. 2000. The evolution of recombination in a heterogeneous environment. Genetics 156:423-438.PDF

    Lenormand, T., and J. Dutheil. 2005. Recombination difference between sexes: A role for haploid selection.PLoS Biology 3:396-403. PDF

    Lenormand T, Roze D, Cheptou P-O, Maurice S. 2010. L'évolution du sexe: un carrefour pour la biologie évolutive. in Biologie évolutive.M. Raymond, F. Thomas, T. Lefèvre, Eds. DeBoeck.
    Everything you ever wanted to know about sex, but in French

    Lievens EJP, Henriques GJB, Michalakis Y, Lenormand T. 2016.Maladaptive sex ratio adjustment in the invasive brine shrimp Artemia franciscana. Curr Biol. 26:1463–1467

    Martin, G., S. P. Otto, and T. Lenormand. 2006. Selection for recombination in structured populations. Genetics 172:593-609.PDF

    Mollion M, Ehlers BK, Figuet E, Santoni S, Lenormand T, Maurice S, Galtier N, Bataillon T. 2017.Patterns of genome-wide nucleotide diversity in the gynodioecious plant Thymus vulgaris are compatible with recent sweeps of cytoplasmic genes. Genome biology and evolution 10:239-248

    Nougué O, Flaven E, Jabbour-Zahab R, Rode N O, Dubois M-P, Lenormand T. 2015. Characterization of nine new polymorphic microsatellite markers in Artemia parthenogenetica. Biochemical Systematics and Ecology 58, 59-63

    Nougué O, Rode NO, Jabbour Zahab R, Ségard A, Chevin LMC, Haag C, Lenormand T. 2015. Automixis in Artemia: solving a century old controversy. J. Evol. Biol. 28:2337-2348

    Otto, S. P., and T. Lenormand. 2002. Resolving the paradox of sex and recombination. Nature Reviews Genetics 3:252-261.PDF

    Rescan M, Lenormand T, Roze D. 2016. Interaction between genetic and ecological effects on the evolution of life cycles. American Naturalist 187: 19-34

    Roze, D., and T. Lenormand. 2005. Self-fertilization and the evolution of recombination. Genetics 170:841-857.PDF

    Henry, P. Y., L. Vimond, T. Lenormand, and P. Jarne. 2006. Is delayed selfing adjusted to chemical cues of density in the freshwater snail Physa acuta? Oikos 112:448-455.PDF

    Svendsen N, Reisser CMO, Dukić M, Thuillier V, Ségard A, Liautard-Haag C, Fasel D, Hürlimann E, Lenormand T, Galimov Y and Haag CR. 2015. Uncovering Cryptic Asexuality in Daphnia magna by RAD-Sequencing. Genetics 201:1143-1155

    Speciation


    Bierne, N., T. Lenormand, F. Bonhomme, and P. David. 2002. Deleterious mutations in a hybrid zone: can mutational load decrease the barrier to gene flow? Genetical Research 80:197-204.PDF

    Chevin, L.-M., Decorzent G., T. Lenormand. 2014. Niche dimensionality and the genetics of ecological speciation. Evolution 68:1244-1256

    Fel-Clair, F., J. Catalan, T. Lenormand, and J. Britton-Davidian. 1998. Centromeric incompatibilities in the hybrid zone between house mouse subspecies from Denmark: Evidence from patterns of NOR activity. Evolution 52:592-603.

    Fel-Clair, F., T. Lenormand, J. Catalan, J. Grobert, A. Orth, P. Boursot, M. C. Viroux, and J. BrittonDavidian. 1996. Genomic incompatibilities in the hybrid zone between house mice in Denmark: Evidence from steep and non-coincident chromosomal clines for Robertsonian fusions. Genetical Research 67:123-134.

    Ganem, G, C. Litel, and T. Lenormand. 2008. Variation in mate preference across a house mouse hybrid zone. Heredity. 6:594-601PDF

    Gay, L., P. Crochet, D. Bell, and T. Lenormand. 2008. Comparing genetic and phenotypic clines in hybrid zones: a window on tension zone models. Evolution 62: 2789-2806PDF

    Lenormand T. 2012. From local adaptation to speciation: specialization and reinforcement. International Journal of Ecology. Ecological speciation (special issue) article ID 508458.PDF

    Lenormand, T., F. FelClair, K. Manolakou, P. Alibert, and J. BrittonDavidian. 1997. Chromosomal transmission bias in laboratory hybrids between wild strains of the two European subspecies of house mice.Genetics 147:1279-1287. PDF

    Dispersal


    Billiard, S., and T. Lenormand. 2005. Evolution of migration under kin selection and local adaptation. Evolution 59:13-23. PDF

    Lenormand, T., T. Guillemaud, D. Bourguet, and M. Raymond. 1998. Evaluating gene flow using selected markers: A case study. Genetics 149:1383-1392. PDF

    Rieux A, Lenormand T., Carlier J., de Lapeyre de Bellaire L., Ravigne V. 2013 Using neutral cline decay to estimate contemporary dispersal: a generic tool and its application to a major crop pathogen.Ecology Letters 16 :721-730

    Genetic conflicts


    Autran D, Baroux C, Raissig MT, Lenormand T, Wittig M, Grob S, Steimer A, Barann M, Klostermeir UC, Leblanc O, Vielle-Calzada JP, Rosenstiel P, Grimanelli D, Grossniklaus U. 2011.Maternal epigenetic pathways control parental contributions to Arabidopsisearly embryogenesis. Cell 145: 707-719.PDF

    Cailleau A., P.-O. Cheptou, T. Lenormand. 2010. Ploidy and the evolution of endosperm of flowering plants. Genetics 184:439-453.PDF

    Cailleau A, Grimanelli D, Cheptou P-O, Lenormand T. 2018. Dividing a maternal pie among half-sibs: genetic conflicts and the control of resource allocation to seeds in maize. Am. Nat. in press.

    Fyon F., Cailleau A., Lenormand T. 2015. Enhancer runaway and the Evolution of diploid gene expression.PLoS Genet. DOI 10.1371/journal.pgen.1005665.

    Rode N., Charmantier A., Lenormand T. 2011.Male-female coevolution in the wild : evidence from a time series inArtemia franciscana. Evolution 65:2881-2892.PDF
    On the web See a great summary by Carl Zimmer
    here or in Wiredhere.

    Biotic interactions


    Ehlers B., David P., Damgaard C.F., Lenormand T. 2016. Competitor relatedness, indirect soil effects, and plant co-existence. Journal of Ecology 104: 1134-1135

    Gallet, R., T. Lenormand and I.-N. Wang, 2012 Phenotypic stochasticity prevents lytic bacteriophage population from extinction during bacterial stationary phase. Evolution 66: 3485-3494.PDF

    Lievens EJP, Rode NO, Landes J, Segard A, Jabbour-Zahab R, Michalakis Y, Lenormand T. 2018. Long-term prevalence data reveals spillover dynamics in a multi-host (Artemia), multi-parasite (Microsporidia) community. bioRxiv 248542.

    Lievens EJP, Perreau JMA, Agnew P, Michalakis Y, Lenormand T. 2018. Decomposing parasite fitness in a two-host, two-parasite system reveals the underpinnings of parasite specialization. bioRxiv 256974.

    Nougué O, Gallet R, Chevin LMC, Lenormand T. 2015.Niche Limits of Symbiotic Gut Microbiota Constrain the Salinity Tolerance of Brine Shrimp. American Naturalist 186:390-403
    Microbiota impact the niche and an extended definition of realized niches

    Rode N.O., Lievens EJP, Flaven E., Segard A., Jabbour-Zahab R., Sanchez M, Lenormand T. 2013. Why join groups? Lessons from parasite-manipulated Artemia. Ecology Letters 16:493-501.PDF
    On the web:
    Parasites Make Their Hosts Sociable So They Get Eaten. Ed Yong's National Geographic Blog

    Rode N.O., Landes J., Lievens E.J.P., Flaven E., Segard A., Jabbour-Zahab R., Michalakis Y., Agnew P., Vivares C., Lenormand T. 2013. Cytological, molecular and life cycle characterization of Anostracospora rigaudi n. g., n. sp. and Enterocytospora artemiae n. g., n. sp., two new microsporidian parasites infecting gut tissues of the brine shrimp Artemia.Parasitology 140:1168-1185

    Sánchez M.I., N.O. Rode, E. Flaven, S. Redón, F. Amat, G.P. Vasileva, T. Lenormand.2012. Differential susceptibility to parasites of invasive and native species of Artemia living in sympatry: consequences for the invasion ofA. franciscana in the Mediterranean Region. Biological Invasion, 14:1819-1829.PDF

    Sanchez M., Pons I., Martinez-Haro M., Taggart M.A., Lenormand T., Green A. 2016. When parasites are good for health: cestode parasitism increases resistance to arsenic in brine shrimps. PLoS PathogensDOIe1005459

    Vasileva G.P., Redon S., Amat F., Nikolov P.N., Sanchez M., Lenormand T., Georgiev B.B. 2009 Records of cysticercoids of Fimbriarioides tadornae (Maksimova, 1976) and Branchiopodataenia gvozdevi (Maksimova, 1988) (Cyclophyllidea, Hymenolepididae) from brine shrimps at the Mediterraneancoasts of Spain and France, with a key to cestodes from Artemia spp. from the Western Mediterranean.Acta Parasitologica 54: 143-150. PDF

    Fitness


    Gallet R., Cooper T., Elena S.F., T. Lenormand. 2012. Measuring selection coefficients below 10-3 : method, questions and prospects. Genetics, 190:175-186.PDF
    Over 150 millions phenotypes scored, one of the most precise measure of selection ever made and the questions it raises

    Gimenez O., R. Covas, C. Brown, M. Anderson, M. Bomberger Brown, and T. Lenormand. 2006. Nonparametric estimation of natural selection on a quantitative trait using capture-mark-recapture data. Evolution 60:460-466.PDF

    Gimenez O., Gregoire A., Lenormand T. 2009. Estimating and visualizing fitness surfaces using mark-recapture data.Evolution. 63: 3097-3105.

    Lenormand T, Rode NO, Chevin LMC, Rousset F. 2016. Valeur sélective: définitions, enjeux et mesures. in Biologie évolutive 2nd edition.M. Raymond, F. Thomas, T. Lefèvre, Eds. DeBoeck.
    Everything you ever wanted to know about fitness, but in French

     


     

    alt




    Download CFit : a stand-alone package to fit clines

     

     

    Normal 0 21 false false false FR X-NONE X-NONE

  • Victor CAZALIS

    Doctorant

    VictorCAZALIS
    Université de Montpellier

    Thèse soutenue le 09/11/2020

    This email address is being protected from spambots. You need JavaScript enabled to view it.

    CEFE/CNRS UMR5175
    Etage 3, aile C, bureau 306

    Project: How much difference are Protected Areas making to the conservation of biodiversity?

    Supervisor: Ana RODRIGUES

    My PhD aims to understand the effectiveness of protected areas in conserving biodiversity, using bird monitoring datasets. Comparing spatially biodiversity inside and outside protected areas, I wish to understand which biodiversity metrics (abundance, richness, specialisation, rarity index, endemism...) are affected by the presence of protected areas across the globe and how.

     

    *** This page has not been updated since November 2020.

    Please visit my personal webpage instead: https://victorcazalis.github.io ***

     

  • Yohan SASSI

    DoctorantYohan Sassi
    Université de Montpellier

    CEFE/CNRS
    1919, route de Mende
    34293 Montpellier cedex 5

    Tél : +33/0 4 67 61 xx xx
    3ème étage, bureau 306

    This email address is being protected from spambots. You need JavaScript enabled to view it.

    Projet:
    Comportements sociaux et risques de collision des vautours fauves en vol /
    Social behaviours and collision risks of griffon vultures in flight

    Superviseurs: Olivier Duriez et Yann Tremblay (Marbec).