Fluctuating Selection,Egg Banks and Population Genetic Structure in Cyclically Parthenogenetic Species

Associations between neutral genetic markers and genes under selection have been suggested to explain the population genetic structure of neutral genes in cyclically parthenogenetic freshwater invertebrates. A simulation model was constructed in order to analyse the extrapolated consequences of observed fluctuations in genotype frequencies in Daphnia, in the presence of egg banks. When of sufficient depth and magnitude, egg banks in combination with fluctuating selection were shown to maintain genetic variation within populations indefinitely. The level of equilibrium diversity increased with the depth and magnitude of the banks, and with intensity of selection. The same threshold was responsible for genetic differentiation between populations, which was independent of migration rate, and which was attained very rapidly following initial Hardy–Weinberg equilibrium. In the absence of selection, egg banks increased the effective size of local populations, thereby decreasing genetic differentiation at migration-drift equilibrium. These results suggest that egg banks are crucial to the genetic structure in the presence of fluctuating selective pressures, but more data are needed if this knowledge is to be used in an improved general understanding of the genetic structure of cyclically parthenogenetic species.