Patterns of Inbreeding Depression and Architecture of the Load in Subdivided Populations

Patterns of Inbreeding Depression and Architecture of the Load in Subdivided Populations

Sylvain Glémin^a,b, Joëlle Ronfort^a, and Thomas Bataillon^a
^a Institut National de la Recherche Agronomique-SGAP Montpellier, F-34130 Mauguio, France
^b Génétique et Environnement CC065, Institut des Sciences de l'Evolution, Université Montpellier II, F-34095 Montpellier, France

Corresponding author: Sylvain Glémin, GPIA. CC63, Université Montpellier II, 34095 Montpellier Cedex 5, France., glemin{at}univ-montp2.fr (E-mail)

Communicating editor: M. UYENOYAMA

Inbreeding depression is a general phenomenon that is due mainlyto recessive deleterious mutations, the so-called mutation load.It has been much studied theoretically. However, until veryrecently, population structure has not been taken into account,even though it can be an important factor in the evolution ofpopulations. Population subdivision modifies the dynamics ofdeleterious mutations because the outcome of selection dependson processes both within populations (selection and drift) andbetween populations (migration). Here, we present a generalmodel that permits us to gain insight into patterns of inbreedingdepression, heterosis, and the load in subdivided populations.We show that they can be interpreted with reference to single-populationtheory, using an appropriate local effective population sizethat integrates the effects of drift, selection, and migration.We term this the "effective population size of selection" (N^S_e).For the infinite island model, for example, it is equal to where N is the local population size, m the migration rate,and h and s the dominance and selection coefficients of deleteriousmutation. Our results have implications for the estimation andinterpretation of inbreeding depression in subdivided populations,especially regarding conservation issues. We also discuss thepossible effects of migration and subdivision on the evolutionof mating systems.

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