Journal of Heredity 2003:94(3)
© 2003 The American Genetic Association 94:236-242
The Mode of Evolution of Molecular Markers in Populations of House Mice Under Artificial Selection for Locomotor Behavior
From the School of Biological Sciences, Washington State University, Pullman, WA 99164-4236 (Morgan, Irwin, and Carter); Department of Biology, University of California, Riverside, CA 92521 (Garland); and Department of Biology, University of South Dakota, Vermillion, SD 57069 (Swallow). T. J. Morgan is currently at the Department of Genetics, College of Agriculture and Life Sciences, North Carolina State University, Raleigh, NC 27695.
Address correspondence to Theodore J. Morgan at the address above, or e-mail: tjmorgan{at}unity.ncsu.edu.
A complete understanding of the mode of evolution of molecular markers is important for making inferences about different population genetic parameters, especially because a number of studies have reported patterns of allelic variation at molecular markers that are not in agreement with neutral evolutionary expectations. In the present study, house mice (Mus domesticus) from the fourteenth generation of a selection experiment for increased voluntary wheel-running activity were used to test how selection on a complex behavior affects the distribution of allelic variation by examining patterns of variation at six microsatellite and four allozyme loci. This population had a hierarchical structure that allowed for simultaneous testing of the effects of selection and genetic drift on the distribution of allelic variation by comparing observed patterns of allele frequencies and estimates of genetic divergence at multiple hierarchical levels to expectations under models of neutral evolution. The levels of genetic divergence among replicate lines and between selection groups, estimated from microsatellite data or pooled microsatellite and allozyme data, were not significantly different from expectations under neutral evolution. Furthermore, the pattern of change of allele frequencies between the base population and generation 14 was largely in agreement with expectations under neutral evolution (although the PGM locus exhibited a pattern of change within populations that was difficult to explain under neutral evolution). Overall the results generally provide support for the neutral evolution of molecular markers.