Check out my profile on Research Gate and on Google Scholar or explore my full publication list below. Most papers are available online through the public repository at HAL CNRS
2023
3.
George A. Brusch; Jean‐François Le Galliard; Robin Viton; Rodrigo S. B. Gavira; Jean Clobert; Olivier Lourdais
In: Oikos, vol. 2023, no. 3, 2023, ISSN: 0030-1299, 1600-0706.
Links | BibTeX | Tags: climate change, pregnancy, temperature
@article{brusch_reproducing_2023,
title = {Reproducing in a changing world: combined effects of thermal conditions by day and night and of water constraints during pregnancy in a cold‐adapted ectotherm},
author = {George A. Brusch and Jean‐François Le Galliard and Robin Viton and Rodrigo S. B. Gavira and Jean Clobert and Olivier Lourdais},
url = {https://onlinelibrary.wiley.com/doi/10.1111/oik.09536},
doi = {10.1111/oik.09536},
issn = {0030-1299, 1600-0706},
year = {2023},
date = {2023-03-01},
urldate = {2023-07-18},
journal = {Oikos},
volume = {2023},
number = {3},
keywords = {climate change, pregnancy, temperature},
pubstate = {published},
tppubtype = {article}
}
2021
2.
Andréaz Dupoué; Audrey Trochet; Murielle Richard; Mahaut Sorlin; Michaël Guillon; Jules Teulieres-Quillet; Clément Vallé; Cyrielle Rault; Maud Berroneau; Matthieu Berroneau; Olivier Lourdais; Pauline Blaimont; Romain Bertrand; Gilles Pottier; Olivier Calvez; Olivier Guillaume; Hugo Le Chevalier; Jérémie Souchet; Jean-François Le Galliard; Jean Clobert; Fabien Aubret
Genetic and demographic trends from rear to leading edge are explained by climate and forest cover in a cold-adapted ectotherm Journal Article
In: Diversity and Distributions, vol. 27, no. 2, pp. 267-281, 2021.
Abstract | Links | BibTeX | Tags: climate change, ectotherms, gene flow, inbreeding
@article{https://doi.org/10.1111/ddi.13202b,
title = {Genetic and demographic trends from rear to leading edge are explained by climate and forest cover in a cold-adapted ectotherm},
author = {Andréaz Dupoué and Audrey Trochet and Murielle Richard and Mahaut Sorlin and Michaël Guillon and Jules Teulieres-Quillet and Clément Vallé and Cyrielle Rault and Maud Berroneau and Matthieu Berroneau and Olivier Lourdais and Pauline Blaimont and Romain Bertrand and Gilles Pottier and Olivier Calvez and Olivier Guillaume and Hugo Le Chevalier and Jérémie Souchet and Jean-François Le Galliard and Jean Clobert and Fabien Aubret},
url = {https://onlinelibrary.wiley.com/doi/abs/10.1111/ddi.13202},
doi = {https://doi.org/10.1111/ddi.13202},
year = {2021},
date = {2021-01-01},
journal = {Diversity and Distributions},
volume = {27},
number = {2},
pages = {267-281},
abstract = {Abstract Aim Determining whether altitudinal shifts in species distributions leave molecular footprints on wild populations along their range margins from rear to leading edge. Location South-west France. Methods We compared the demographic and genetic variation in 42 wild populations of the Western oviparous subclade B2 of a cold-adapted lizard (Zootoca vivipara louislantzi). These populations can be divided into four ecological units across altitudinal clines in South-west France (rear edge: <100 m, admixture zone: 100–500 m, continuous range: 500–1,300 m and leading edge: >1,300 m above sea level). Results Within the rear edge were found the highest levels of inbreeding, genetic differentiation and evidence of interrupted gene flow compared to central or colonizing areas. Within the leading edge, altitudinal range expansion occurred over the last centuries and populations showed relatively low genetic diversity. These demographic and genetic trends were better explained by inhospitable (warm and dry) climate conditions and forest cover. Main conclusions This empirical evidence illustrates that molecular footprints of climate conditions and habitat quality on wild population trends can be perceived after recent events, which should be of particular importance to accurately understand and anticipate human-induced global change on wild species and ecosystems.},
keywords = {climate change, ectotherms, gene flow, inbreeding},
pubstate = {published},
tppubtype = {article}
}
Abstract Aim Determining whether altitudinal shifts in species distributions leave molecular footprints on wild populations along their range margins from rear to leading edge. Location South-west France. Methods We compared the demographic and genetic variation in 42 wild populations of the Western oviparous subclade B2 of a cold-adapted lizard (Zootoca vivipara louislantzi). These populations can be divided into four ecological units across altitudinal clines in South-west France (rear edge: <100 m, admixture zone: 100–500 m, continuous range: 500–1,300 m and leading edge: >1,300 m above sea level). Results Within the rear edge were found the highest levels of inbreeding, genetic differentiation and evidence of interrupted gene flow compared to central or colonizing areas. Within the leading edge, altitudinal range expansion occurred over the last centuries and populations showed relatively low genetic diversity. These demographic and genetic trends were better explained by inhospitable (warm and dry) climate conditions and forest cover. Main conclusions This empirical evidence illustrates that molecular footprints of climate conditions and habitat quality on wild population trends can be perceived after recent events, which should be of particular importance to accurately understand and anticipate human-induced global change on wild species and ecosystems.
2018
1.
Jean Clobert; André Chanzy; Jean-François Le Galliard; Abad Chabbi; Lucile Greiveldinger; Thierry Caquet; Michel Loreau; Christian Mougin; Christian Pichot; Jacques Roy; Laurent Saint-André
How to Integrate Experimental Research Approaches in Ecological and Environmental Studies: AnaEE France as an Example Journal Article
In: Frontiers in Ecology and Evolution, vol. 6, 2018, ISSN: 2296-701X.
Abstract | Links | BibTeX | Tags: climate change, modelling, research infrastructure
@article{clobert_how_2018,
title = {How to Integrate Experimental Research Approaches in Ecological and Environmental Studies: AnaEE France as an Example},
author = {Jean Clobert and André Chanzy and Jean-François Le Galliard and Abad Chabbi and Lucile Greiveldinger and Thierry Caquet and Michel Loreau and Christian Mougin and Christian Pichot and Jacques Roy and Laurent Saint-André},
url = {https://www.frontiersin.org/articles/10.3389/fevo.2018.00043/full?&utm_source=Email_to_authors_&utm_medium=Email&utm_content=T1_11.5e1_author&utm_campaign=Email_publication&field=&journalName=Frontiers_in_Ecology_and_Evolution&id=255505},
doi = {10.3389/fevo.2018.00043},
issn = {2296-701X},
year = {2018},
date = {2018-01-01},
urldate = {2018-04-21},
journal = {Frontiers in Ecology and Evolution},
volume = {6},
abstract = {Human activities have altered continental ecosystems worldwide and generated a major environmental crisis, prompting urgent societal questions on how to best produce goods while at the same time securing sustainable ecological services and raising needs to better understand and predict biodiversity and ecosystems dynamics under global changes. To tackle these questions, experimentation on ecosystems is necessary to improve our knowledge of processes and to propose scientifically sound management strategies. Experimental platforms able to manipulate key factors of global change and including state of the art observation methodologies are available worldwide but how to best integrate them has been rarely addressed. Here, we present and discuss the case of the national research infrastructure AnaEE France dedicated to the study of continental ecosystems and designed to congregate complementary experimental approaches in order to facilitate their access and use through a range of distributed and shared services. The conceptual design of AnaEE France includes five modules. Three modules gather experimental facilities along a gradient of experimental control ranging from highly controlled Ecotron facilities, semi-natural field mesocosms to in natura experimental sites covering major continental ecosystems (forests, croplands, grasslands and lakes). In addition, AnaEE France also includes shared instruments that can be implemented in experiments and analytical platforms specifically dedicated to environmental biology. To promote reuse of data, generalize results and improve predictive models, AnaEE France further gathers modelling and information systems. The implementation of AnaEE France allowed for mutual synergies, improved the technical skills, stimulated new experiments and helped our scientific community to enter into the big data sharing era.},
keywords = {climate change, modelling, research infrastructure},
pubstate = {published},
tppubtype = {article}
}
Human activities have altered continental ecosystems worldwide and generated a major environmental crisis, prompting urgent societal questions on how to best produce goods while at the same time securing sustainable ecological services and raising needs to better understand and predict biodiversity and ecosystems dynamics under global changes. To tackle these questions, experimentation on ecosystems is necessary to improve our knowledge of processes and to propose scientifically sound management strategies. Experimental platforms able to manipulate key factors of global change and including state of the art observation methodologies are available worldwide but how to best integrate them has been rarely addressed. Here, we present and discuss the case of the national research infrastructure AnaEE France dedicated to the study of continental ecosystems and designed to congregate complementary experimental approaches in order to facilitate their access and use through a range of distributed and shared services. The conceptual design of AnaEE France includes five modules. Three modules gather experimental facilities along a gradient of experimental control ranging from highly controlled Ecotron facilities, semi-natural field mesocosms to in natura experimental sites covering major continental ecosystems (forests, croplands, grasslands and lakes). In addition, AnaEE France also includes shared instruments that can be implemented in experiments and analytical platforms specifically dedicated to environmental biology. To promote reuse of data, generalize results and improve predictive models, AnaEE France further gathers modelling and information systems. The implementation of AnaEE France allowed for mutual synergies, improved the technical skills, stimulated new experiments and helped our scientific community to enter into the big data sharing era.