Your search keyword '"Séverine Vuilleumier"' showing total 2 results

1. Positive feedback in the transition from sexual reproduction to parthenogenesis

Author

Janie Dubman, Tanja Schwander, Séverine Vuilleumier, and Bernard J. Crespi

Subjects

Male, Insecta, Offspring, Oviposition, Parthenogenesis, Population, Biology, General Biochemistry, Genetics and Molecular Biology, Sexual Behavior, Animal, reproductive insurance, Research articles, Animals, positive feedback loop, Timema, education, Selection (genetic algorithm), Ovum, General Environmental Science, mate limitation, Population Density, education.field_of_study, General Immunology and Microbiology, Ecology, Reproduction, General Medicine, sex ratio, biology.organism_classification, Biological Evolution, Sexual reproduction, Evolutionary biology, Sexual selection, Female, General Agricultural and Biological Sciences, Sex ratio

Abstract

Understanding how new phenotypes evolve is challenging because intermediate stages in transitions from ancestral to derived phenotypes often remain elusive. Here we describe and evaluate a new mechanism facilitating the transition from sexual reproduction to parthenogenesis. In many sexually reproducing species, a small proportion of unfertilized eggs can hatch spontaneously (‘tychoparthenogenesis’) and develop into females. Using an analytical model, we show that if females are mate-limited, tychoparthenogenesis can result in the loss of males through a positive feedback mechanism whereby tychoparthenogenesis generates female-biased sex ratios and increasing mate limitation. As a result, the strength of selection for tychoparthenogenesis increases in concert with the proportion of tychoparthenogenetic offspring in the sexual population. We then tested the hypothesis that mate limitation selects for tychoparthenogenesis and generates female-biased sex ratios, using data from natural populations of sexually reproducingTimemastick insects. Across 41 populations, both the tychoparthenogenesis rates and the proportions of females increased exponentially as the density of individuals decreased, consistent with the idea that low densities of individuals result in mate limitation and selection for reproductive insurance through tychoparthenogenesis. Our model and data fromTimemapopulations provide evidence for a simple mechanism through which parthenogenesis can evolve rapidly in a sexual population.

Published

2010

2. Does colonization asymmetry matter in metapopulations?

Author

Séverine Vuilleumier and Hugh P. Possingham

Subjects

media_common.quotation_subject, Population Dynamics, Population, Metapopulation, Biology, Models, Biological, Asymmetry, Animals, Computer Simulation, Ecosystem, General Biochemistry, Genetics and Molecular Biology, Quantitative Biology::Populations and Evolution, Colonization, education, General Environmental Science, media_common, education.field_of_study, General Immunology and Microbiology, Ecology, General Medicine, Symmetric systems, Habitat, Local extinction, Biological dispersal, General Agricultural and Biological Sciences, Research Article

Abstract

Despite the considerable evidence showing that dispersal between habitat patches is often asymmetric, most of the metapopulation models assume symmetric dispersal. In this paper, we develop a Monte Carlo simulation model to quantify the effect of asymmetric dispersal on metapopulation persistence. Our results suggest that metapopulation extinctions are more likely when dispersal is asymmetric. Metapopulation viability in systems with symmetric dispersal mirrors results from a mean field approximation, where the system persists if the expected per patch colonization probability exceeds the expected per patch local extinction rate. For asymmetric cases, the mean field approximation underestimates the number of patches necessary for maintaining population persistence. If we use a model assuming symmetric dispersal when dispersal is actually asymmetric, the estimation of metapopulation persistence is wrong in more than 50% of the cases. Metapopulation viability depends on patch connectivity in symmetric systems, whereas in the asymmetric case the number of patches is more important. These results have important implications for managing spatially structured populations, when asymmetric dispersal may occur. Future metapopulation models should account for asymmetric dispersal, while empirical work is needed to quantify the patterns and the consequences of asymmetric dispersal in natural metapopulations.

Published

2006