| Literature DB >> 28565164 |
Abstract
Gene frequencies in large populations are determined by a balance between selection and gene flow between neighborhoods of different selection regimes. This balance is affected by the area of the patches of a given selection regime relative to the gene-flow distance. If patches are small relative to gene-flow distance, similarity in the total area occupied by different patch types is a crucial condition for the stability of polymorphisms. However, if patches are larger than the gene-flow distance, then the relative area of different patch types is less important because of reduced gene flow resulting from isolation by distance. Two morphs (striped and unstriped) of the walking-stick Timema cristinae were each strongly associated with patches of distinct species of food plants on which they are most cryptic. The frequency of a morph was high on the plant on which it is most cryptic when either: (1) the area occupied by the food plant (patch) was very large; (2) the patch was completely isolated from other patches; or (3) the patch was larger than adjacent patches. Results (1) and (2) are consistent with isolation-by-distance models, and result (3) is consistent with Levene's multiple-niche polymorphism model. © 1994 The Society for the Study of Evolution.Entities:
Keywords: Crypsis; Timema cristinae.; gene flow; genetic variation; habitat heterogeneity; host specialization; isolation by distance; multiple-niche polymorphism; natural selection; spatial scale
Year: 1994 PMID: 28565164 DOI: 10.1111/j.1558-5646.1994.tb02220.x
Source DB: PubMed Journal: Evolution ISSN: 0014-3820 Impact factor: 3.694