Courtier Lab VA

Evolution and genetics

Virginie COURTIER-ORGOGOZO

Our research focuses on the mutations responsible for evolutionary change.

We use a combination of different approaches to identify the mutations responsible for evolutionary change and to reconstruct past evolutionary events. We hope that our work will provide new and rigorous data to better understand our evolution, past and future.

Keywords: evolution, species, Drosophila, genome, genetics, ecology, bioadhesive, development, QTL mapping

+33 (0)157278043 virginie.courtier(at)ijm.fr @Biol4Ever https://courtier.ijm.fr/

Research

Our research investigates the mutations responsible for evolutionary changes.

Since Darwin, research in evolutionary biology tries to understand biodiversity – the great number of species in nature, each with features so well adapted to its environment. In our current understanding of evolution, the genes and the mutations responsible for phenotypic differences have no distinctive features: mutations occur randomly and a few of them happen to spread in populations through selection and chance. However, phenotypic evolution may not be totally random in terms of genetics. There might be rules to be discovered about the mutations underlying natural evolution.

We are using a combination of various approaches to identify the mutations responsible for evolutionary changes and to reconstruct past evolutionary events. We hope that our work will provide new and rigorous data to better understand our evolution, past and future.

EVOLUTION OF FLY GLUE (PI: V. COURTIER-ORGOGOZO)

At the end of the larval stage, Drosophila larvae produce a proteinaceous glue that allows the animal to adhere to a substrate for several days during metamorphosis. We aim to use the powerful genetic tools of the model organism Drosophila melanogaster to explore the molecular basis for fly glue adhesion. We want to identify the genes involved in glue adhesion and understand how they have changed during evolution so that the glue can stick to various substrates in diverse environments. We developed a new assay to quantify Drosophila glue adhesiveness and we plan to measure adhesion of glue mutants and to compare adhesion between different Drosophila melanogaster populations and Drosophila species.

EVOLUTION OF LEFT-RIGHT SIZE ASYMMETRY (PI: MICHAEL LANG)

How left-right asymmetries in organ size develop remains a mystery. Drosophila pachea has evolved a unique left-right asymmetry in genitalia lobes. No left-right size asymmetry has been described in D. melanogaster. We are trying to uncover the mechanisms that triger asymmetric lobe development and the role of these asymmetric lobes during copulation. We use a stock of Drosophila pachea containing spontaneous symmetric mutant males and we perform micro-scale laser removal of lobe bristles and micro-scale surgery of lobes. We are also examining left-right asymmetries in behavior and morphology in species closely related to D. pachea, in order to understand how left-right asymmetry in lobe size evolved in D. pachea.

EVOLUTION OF GENITALIA (PI: V. COURTIER-ORGOGOZO)

We wish to understand how the morphology of genital organs change rapidly during evolution. We combine developmental studies, genomics, genetics, quantitative genetics, population genetics, microCT scans, laser microsurgery and behavioral experiments to understand how genes and cellular mechanisms modulate organ shape in a subtle and precise way, and how this can affect reproduction and long-term evolution. We examine the following genital organs: hypandrial bristles, ventral branches and posterior lobes.

THE ORIGIN OF COVID-19

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DATABASES

Gephebase contains a list of all the genes and mutations that have been found to be responsible for phenotypic differences (morphological, physiological and behavioral traits) between populations or strains for pluricellular organisms. A preliminary list was deposited in Dryad in 2013 and the full open access website is available here

FlyPhenomics provides a compilation of the phenotypes that have been reported to differ between at least two species of the D. melanogaster subgroup. More than 150 morphological, physiological and behavioral differences have been described between 1919 and 2006.
associated paper: Orgogozo V, Stern DL, How different are recently diverged species? More than 150 phenotypic differences have been reported for the D. melanogaster species subgroup. Fly 2009 Mar-Apr;3(2):117.

FlyPNS :

description of the embryonic and larval peripheral nervous system of D. melanogaster.
made with Wesley Grueber.
associated paper: Orgogozo V, Grueber WB, FlyPNS, a database of the Drosophila embryonic and larval peripheral nervous system. BMC Dev Biol. 2005 Feb 17; 5(1):4.

Members

Group Leader:

Virginie COURTIER-ORGOGOZO

Directrice de Recherche 2e classe

Téléphone : +33 (0)157278043, +33 (0)157278087

virginie.courtier(at)ijm.fr

Members:

Savandara	BESSE	Postdoc
Alexis	LALOUETTE	Assistant professor
Jean-Noël	LORENZI	Engineer
Manon	MONIER	Postdoc
Sunitha	NARASIMHA	Engineer
Isabelle	NUEZ	Engineer
Michaël	RERE	Researcher
Roshan Kumar	VIJENDRAVARMA	Researcher

Selected Publications

van Helden, J., Butler, C. D., Achaz, G., Canard, B., Casane, D., Claverie, J. M., … & Halloy, J. (2021). An appeal for an objective, open, and transparent scientific debate about the origin of SARS-CoV-2. The Lancet. Featured in several newspapers including il Fatto Quotidiano Daily Mail ThePrint

Peluffo AE, Hamdani M, Vargas-Valderrama A, David JR, Mallard F, Graner F, Courtier-Orgogozo V. A morphological trait involved in reproductive isolation between Drosophila sister species is sensitive to temperature. Ecology and Evolution 11(12), 7492-7506. doi: 10.1002/ece3.7580 DRYAD Supp Data BioRxiv

Borne, F., Prigent, S.R., Molet, M., Courtier-Orgogozo, V. (2021) Drosophila glue protects from predation. Proc. R. Soc. B. 288: 20210088. doi: 10.1098/rspb.2021.0088 DRYAD Supp Data BioRxiv
Actualité CNRS

Lefèvre, B.M., Catté, D., Courtier-Orgogozo, V., Lang, M. (2021) Male genital lobe morphology affects the chance to copulate in Drosophila pachea. BMC Ecol Evo 21, 23. doi: 10.1186/s12862-021-01759-z PDF

Rode N, Courtier-Orgogozo V, Débarre F. (2020) Can a population targeted by a CRISPR-based homing gene drive be rescued? G3. 10 (9), 3403-3415. doi: 10.1534/g3.120.401484 BioRxiv

Courtier-Orgogozo V, Danchin A, Gouyon PH, Boëte C (2020) Evaluating the Probability of CRISPR-based Gene Drive Contaminating Another Species. Evolutionary Applications 00:1–18. doi: 10.1111/eva.12939 BioRxiv PDF

All the publications since 2017

Publications

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Preprint

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Review

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Book chapter

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Theses

Alexandre Peluffo, Flora Borne

ongoing : Manon Monier

Collaborations

International

Andolfatto, Columbia University, USA
Martin, Georges Washington University, USA
Matute, Chicago University, USA
Santos, University of Cambridge, Cambridge, UK
Schilthuizen, Leiden, Netherlands
D.L. Stern, Janelia farm, Ashburn, USA

National

Danchin, Paris
Graner, Université Paris 7, Paris
Montagné and T. Chertemps, Université Paris 6, Paris
Morizot, Marseille
Rode, Montpellier
Wiltgen, Montpellier