Frequency-dependent Seed Production and Hybridization Rates: Implications for Gene Flow between Locally Adapted Plant Populations.

Gene flow between genetically distinct plant populations can have significant evolutionary consequences. It can increase genetic diversity, create novel gene combinations, and transfer adaptations from one population to another. This study addresses the roles of frequency-dependent selection and mating system in gene exchange between two subspecies of Gilia capitata (Polemoniaceae). Long-distance migrants are likely to be rare in new habitats, and the importance of immigrant frequency to fitness, gene exchange, and ultimately introgression, has not been explored. To test for the importance of frequency in migration, a field experiment was conducted in which artificial populations (arrays) composed of different mixtures of the two subspecies were placed in the home habitats of both. Female function (seed production) and a portion of male function (hybridization rate) were compared for the two subspecies to assess the potential for gene exchange and introgression between them. Individual fitness (through both hybridization and seed production) for the inland subspecies varied with its frequency as an immigrant at the coastal site. Rare immigrants produced fewer seeds and fathered fewer hybrid offspring. In contrast, both forms of reproductive function were frequency independent for the coastal subspecies when it was an immigrant at the inland site. Seed production was high and insensitive to frequency, and immigrants from the coast never successfully fertilized the inland subspecies' seeds. To control for the effects of frequency-dependent pollinator behavior in the field, hand crosses were performed in the greenhouse using a range of pollen mixtures. The greenhouse experiment demonstrated that cross-fertilization is possible in only one direction, that cross-pollination in the other direction is only partially successful, and that pollen from the coastal subspecies has a strong negative effect on seed production by the inland subspecies. Experimental pollen supplementation in the field verified both the unilateral incompatibility and the negative effect of coastal pollen on inland plant seed production observed in the greenhouse. Contrasts between field array and greenhouse results suggest that pollinator behavior and other ecological factors act to exaggerate reproductive barriers between the two subspecies. In this system, immigrant frequency interacts with reproductive biology and pollinator ecology to enhance gene flow between the populations in one direction, while restricting gene establishment and introgression in the other direction.