Gene flow in Plantago I. Gene flow and neighbourhood size in P. lanceolata

This study investigated the genetic structure of a population of the highly outcrossed perennial shrub, Banksia spinutosa. Three variable loci were detected; Pgm1, Adh1 and Pgi2. Some genetic differentiation was detected in the population, and as a whole it deviated from a panmictic unit.This primarily resulted from the behaviour of Pgi2. This locus exhibited a large deficit of heterozygotes, possibly in association with a Wahiund effect. However, deviations from panmixia were small compared with species which are predominantly self-fertilizing, and estimates of gene flow indicated that the movement of genes occurs over a fairly wide area. This study provides the first description of spatial genetic variability within a population of Banksia spinutosa.

Section: Discussionmentioning

confidence: 99%

Population genetic structure of Banksia spinulosa

Carthew

1993

“…Neigh-bourhood sizes of the different runs are given in Table 2. These sizes were chosen because of the gene flow distances measured in Plantago lanceolata (Bos et at., 1986) and the densities of flowering Plantago media in sympatric cytotype populations in the Pyrenees (Van Dijk etal., 1994).…”

Section: The Modelmentioning

confidence: 99%

Simulations of flowering time displacement between two cytotypes that form inviable hybrids

Dijk

Bijlsma

1994

The evolution of reproductive isolation by flowering time displacement between two cytotypes that produce inviable hybrids was studied by computer simulations in an isolation-by-distance model. Flowering time distribution was stabilized by mass-action, both by the mating procedure and by pollen-limited seed-production in early or late flowering plants. Coexistence had to last long enough for flowering time divergence to evolve. This could only be achieved in a mosaic of local patches or parapatry. The model showed that flowering time displacement occurred despite the stabilizing effect of mass-action and the restricted width of the interaction zone. Initially an inverse dine for flowering time was formed but after 200 generations this dine had become monotonic. In contrast to the possible swamping effect by gene flow from outside the zone, there was a spread of genes into the allopatric ranges.

“…, 1985). Experiments in a wind tunnel with release and recapture of pollen on the same or at a lower level showed comparable pollen flow patterns (Bos et a!., 1986). These patterns are presented in fig.…”

Section: Gene Flow Characteristics Of the Modelmentioning

confidence: 50%

“…In an earlier paper (Bos et aL, 1986) we measured gene flow in a P. lanceolata population and argued that in certain conditions restricted gene flow leads to substructuring of the population. In this paper the species P. lanceolata serves as an example to describe-among other things-the influence of the reproductive character "protogyny-growth syndrome" on the amount of inbreeding and genetic structure in a simulated population.…”

Section: Discussionmentioning

confidence: 99%

Gene flow in Plantago. II. Gene flow pattern and population structure. A simulation study

Bos

Vanderharing

1988

The relative effects of the pattern of pollen flow, pattern of seed dispersal, presence or absence of a selfincompatibility system and annual versus perennial life cycle on hoiuozygosity and the evolution of population structure in a plant species were studied using computer simulation. Starting with a random distribution of genotypes at a diallelic marker locus in populations of 2500 individuals, simulations were run for the equivalent of 100 or 400 years. Sixteen different situations were investigated, one of which corresponded to a species like Plantago lanceolata: a perennial herb with restricted seed dispersal, a gametophytic self-incompatibility system and a protogyny-growth syndrome. Regression analysis of fixation index values (F) showed that the presence of the protogyny-growth syndrome or self-incompatibility lowered the increase of homozygosity, while restricted seed dispersal and perenniality promoted inbreeding. Analysis of population structure demonstrated that the "patchiness" of a population after 100 generations was higher in a perennial species than in an annual, while the pollen flow pattern caused by the presence of the protogyny syndrome reduced the development of population structure.It appears that genetic structure within populations of a species like P. lanceolata can still be explained by restricted gene flow, in spite of the presence of outcrossing mechanisms like self-incompatibility and protogyny.