Your search keyword '"Gérard, Pierre R."' showing total 3 results

1. Polyploidy and interspecific hybridization : partners for adaptation, speciation and evolution in plants

Author

Alix, Karine, Gérard, Pierre R., Schwarzacher, Trude, and Heslop-Harrison, J. S. (Pat)

Published

2017

2. Assortative mating and differential male mating success in an ash hybrid zone population

Author

Frascaria-Lacoste Nathalie, Fernández-Manjarrés Juan F, Austerlitz Frédéric, Klein Etienne K, and Gérard Pierre R

Subjects

Evolution, QH359-425

Abstract

Abstract Background The structure and evolution of hybrid zones depend mainly on the relative importance of dispersal and local adaptation, and on the strength of assortative mating. Here, we study the influence of dispersal, temporal isolation, variability in phenotypic traits and parasite attacks on the male mating success of two parental species and hybrids by real-time pollen flow analysis. We focus on a hybrid zone population between the two closely related ash species Fraxinus excelsior L. (common ash) and F. angustifolia Vahl (narrow-leaved ash), which is composed of individuals of the two species and several hybrid types. This population is structured by flowering time: the F. excelsior individuals flower later than the F. angustifolia individuals, and the hybrid types flower in-between. Hybrids are scattered throughout the population, suggesting favorable conditions for their local adaptation. We estimate jointly the best-fitting dispersal kernel, the differences in male fecundity due to variation in phenotypic traits and level of parasite attack, and the strength of assortative mating due to differences in flowering phenology. In addition, we assess the effect of accounting for genotyping error on these estimations. Results We detected a very high pollen immigration rate and a fat-tailed dispersal kernel, counter-balanced by slight phenological assortative mating and short-distance pollen dispersal. Early intermediate flowering hybrids, which had the highest male mating success, showed optimal sex allocation and increased selfing rates. We detected asymmetry of gene flow, with early flowering trees participating more as pollen donors than late flowering trees. Conclusion This study provides striking evidence that long-distance gene flow alone is not sufficient to counter-act the effects of assortative mating and selfing. Phenological assortative mating and short-distance dispersal can create temporal and spatial structuring that appears to maintain this hybrid population. The asymmetry of gene flow, with higher fertility and increased selfing, can potentially confer a selective advantage to early flowering hybrids in the zone. In the event of climate change, hybridization may provide a means for F. angustifolia to further extend its range at the expense of F. excelsior.

Published

2006

3. Assortative mating and differential male mating success in an ash hybrid zone population

Author

Gérard, Pierre R., Klein, Etienne K., Austerlitz, Frédéric, Fernandez-Manjarres, Juan F., Frascaria-Lacoste, Nathalie, Université Paris-Sud - Paris 11 (UP11), Biostatistique et Processus Spatiaux (BioSP), Institut National de la Recherche Agronomique (INRA), Ecologie Systématique et Evolution (ESE), and Ecole Nationale du Génie Rural, des Eaux et des Forêts (ENGREF)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

dispersion du pollen, arbre forestier, Time Factors, Genotype, FRAXINUS ANGUSTIFOLIA, Evolution, Biodiversité et Ecologie, flux de gènes, MESH: Phenotype, fraxinus, MESH: Genotype, Evolution, Molecular, Biodiversity and Ecology, feuillu, modèle mathématique, modèle génétique, MESH: Inbreeding, QH359-425, FRAXINUS EXCELSIOR, Inbreeding, MESH: Models, Genetic, MESH: Models, Theoretical, FACTEUR TEMPS, MESH: Evolution, Molecular, MESH: Fraxinus, [SDV.GEN.GPO]Life Sciences [q-bio]/Genetics/Populations and Evolution [q-bio.PE], Models, Statistical, Models, Genetic, MESH: Time Factors, food and beverages, Models, Theoretical, frêne, phénologie, phénotype, Phenotype, pollen, MESH: Pollen, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, MESH: Models, Statistical, Research Article

Abstract

Background The structure and evolution of hybrid zones depend mainly on the relative importance of dispersal and local adaptation, and on the strength of assortative mating. Here, we study the influence of dispersal, temporal isolation, variability in phenotypic traits and parasite attacks on the male mating success of two parental species and hybrids by real-time pollen flow analysis. We focus on a hybrid zone population between the two closely related ash species Fraxinus excelsior L. (common ash) and F. angustifolia Vahl (narrow-leaved ash), which is composed of individuals of the two species and several hybrid types. This population is structured by flowering time: the F. excelsior individuals flower later than the F. angustifolia individuals, and the hybrid types flower in-between. Hybrids are scattered throughout the population, suggesting favorable conditions for their local adaptation. We estimate jointly the best-fitting dispersal kernel, the differences in male fecundity due to variation in phenotypic traits and level of parasite attack, and the strength of assortative mating due to differences in flowering phenology. In addition, we assess the effect of accounting for genotyping error on these estimations. Results We detected a very high pollen immigration rate and a fat-tailed dispersal kernel, counter-balanced by slight phenological assortative mating and short-distance pollen dispersal. Early intermediate flowering hybrids, which had the highest male mating success, showed optimal sex allocation and increased selfing rates. We detected asymmetry of gene flow, with early flowering trees participating more as pollen donors than late flowering trees. Conclusion This study provides striking evidence that long-distance gene flow alone is not sufficient to counter-act the effects of assortative mating and selfing. Phenological assortative mating and short-distance dispersal can create temporal and spatial structuring that appears to maintain this hybrid population. The asymmetry of gene flow, with higher fertility and increased selfing, can potentially confer a selective advantage to early flowering hybrids in the zone. In the event of climate change, hybridization may provide a means for F. angustifolia to further extend its range at the expense of F. excelsior.

Published

2006