Mating Within the Meiotic Tetrad and the Maintenance of Genomic Heterozygosity

doi:10.1534/genetics.166.4.1751

Mating Within the Meiotic Tetrad and the Maintenance of Genomic Heterozygosity

Michael E. Hood^a and Janis Antonovics^a
^a Department of Biology, University of Virginia, Charlottesville, Virginia 22903

Corresponding author: Michael E. Hood, Gilmer Hall, University of Virginia, Charlottesville, VA 22903., michael.hood{at}virginia.edu (E-mail)

Communicating editor: M. E. ZOLAN

Mating among the products of a single meiosis (automixis ormeiotic parthenogenesis) is found in diverse groups of plant,animal, and fungal taxa. Restoration of the diploid stage isoften strictly controlled and brings together products separatedat the first meiotic division. Despite apparent similaritiesto diploid selfing, the theoretical prediction is that heterozygosityshould be maintained on all chromosomes when it is linked tothe centromeres and thus also segregates at the first meioticdivision. Using the fungus Microbotryum, we directly test thisprediction by linear tetrad analysis. The patterns of meioticsegregation for chromosome size variation (electrophoretic karyotypes)and PCR products (AFLP procedures) were determined for Microbotryumlineages native to North America and Europe. Our data reveala surprisingly dynamic genome that is rich in heterozygosityand where size-dimorphic autosomes are common. The genetic variationagrees with the prediction of centromere-linked heterozygosity.This was observed to the greatest extent in the lineage of Microbotryumnative to North America where there was consistent first-divisionsegregation and independent assortment of multiple linkage groups.The data also show properties that distinguish the fungal sexchromosomes from the autosomes in both lineages of Microbotryum.We describe a scenario where the mating system of automixiswith first-division restitution is the result of feedback mechanismsto control exposure of genetic load.

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