Heterozygote excess in a self-incompatible and partially clonal forest tree species -Prunus avium L

Heterozygote excess in a self-incompatible and partially clonal forest tree species -Prunus avium L

Wild cherry (Prunus avium L.), a partially asexual self‐incompatible forest tree, shows heterozygote excess, which is a poorly studied phenomenon. In three natural populations, we found significant heterozygote excess at almost all investigated loci (eight microsatellites and markers for the self‐in...

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Bibliographic Details
Published in:Molecular ecology Vol. 15; no. 8; pp. 2109 - 2118
Main Authors: STOECKEL, SOLENN, GRANGE, JÉRÔME, FERNÁNDEZ-MANJARRES, JUAN F., BILGER, ISABELLE, FRASCARIA-LACOSTE, NATHALIE, MARIETTE, STÉPHANIE
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Publishing Ltd 01-07-2006
Wiley
Subjects:
asexual reproduction
Environmental Sciences
France
gametophytic self-incompatibility
Genetics
Genetics, Population
heterosis
Heterozygote
Life cycles
Linkage Disequilibrium
Microsatellite Repeats - genetics
Models, Genetic
negative FIS
Plant populations
Polymorphism, Genetic
Population Density
Prunus - genetics
Prunus avium
Reproduction, Asexual
Selection, Genetic
small breeding population
Trees
wild cherry tree
France
REPRODUCTION ASEXUEE
VIGUEUR HYBRIDE
MERISIER
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Summary:Wild cherry (Prunus avium L.), a partially asexual self‐incompatible forest tree, shows heterozygote excess, which is a poorly studied phenomenon. In three natural populations, we found significant heterozygote excess at almost all investigated loci (eight microsatellites and markers for the self‐incompatibility locus). We examined four hypotheses to account for this observed heterozygote excess. First, negative FIS can result from a lack of selfed progeny in small populations of outcrossing species. A second explanation for negative FIS is selection during the life cycle of the most heterozygous individuals. A third explanation is negative assortative mating when reproduction occurs between individuals bearing phenotypes more dissimilar than by chance. The last explanation for negative FIS relies on asexual reproduction. Expectations for each hypothesis were tested using empirical data. Patterns of FIS differed among loci. Nevertheless, our experimental results did not confirm the small sample size hypothesis. Although one locus is probably under a hitch‐hiking effect from the SI locus, we rejected the effect of the self‐incompatibility locus for the genome as a whole. Similarly, although one locus showed a clear pattern consistent with the selection of heterozygous individuals, the heterosis effect over the whole genome was rejected. Finally, our results revealed that clonality probably explains significant negative FIS in wild cherry populations when considering all individuals. More theoretical effort is needed to develop expectations and hypotheses, and test them in the case of species combining self‐incompatibility and partially asexual reproduction.
Bibliography:ark:/67375/WNG-SPKX6WK0-V
istex:7BC62FE9C566DC78D79145BA28375D331A4D1AEA
ArticleID:MEC2926
Present address: Unité de Recherche sur les Espèces Fruitières et la Vigne, INRA, Domaine de la Grande Ferrade, 71 Avenue Edouard Bourlaux, 33883 Villenave d’Ornon cedex France.
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0962-1083
1365-294X
DOI:10.1111/j.1365-294X.2006.02926.x