%0 Journal Article %1 slatkin1990detecting %A Slatkin, M %A Maddison, W P %D 1990 %J Genetics %K dispersal_estimation isolation_by_distance parsimony phylogenetics %N 1 %P 249-260 %T Detecting isolation by distance using phylogenies of genes %U http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1204129/ %V 126 %X We introduce a method for analyzing phylogenies of genes sampled from a geographically structured population. A parsimony method can be used to compute s, the minimum number of migration events between pairs of populations sampled, and the value of s can be used to estimate the effective migration rate M, the value of Nm in an island model with local populations of size N and a migration rate m that would yield the same value of s. Extensive simulations show that there is a simple relationship between M and the geographic distance between pairs of samples in one- and two-dimensional models of isolation by distance. Both stepping-stone and lattice models were simulated. If two demes k steps apart are sampled, then, s, the average value of s, is a function only of k/(Nm) in a one-dimensional model and is a function only of k/(Nm)2 in a two-dimensional model. Furthermore, log(M) is approximately a linear function of log(k). In a one-dimensional model, the regression coefficient is approximately -1 and in a two-dimensional model the regression coefficient is approximately -0.5. Using data from several locations, the regression of log(M) on log(distance) may indicate whether there is isolation by distance in a population at equilibrium and may allow an estimate of the effective migration rate between adjacent sampling locations. Alternative methods for analyzing DNA sequence data from a geographically structured population are discussed. An application of our method to the data of R. L. Cann, M. Stoneking and A. C. Wilson on human mitochondrial DNA is presented.

@article{slatkin1990detecting, abstract = {We introduce a method for analyzing phylogenies of genes sampled from a geographically structured population. A parsimony method can be used to compute s, the minimum number of migration events between pairs of populations sampled, and the value of s can be used to estimate the effective migration rate M, the value of Nm in an island model with local populations of size N and a migration rate m that would yield the same value of s. Extensive simulations show that there is a simple relationship between M and the geographic distance between pairs of samples in one- and two-dimensional models of isolation by distance. Both stepping-stone and lattice models were simulated. If two demes k steps apart are sampled, then, s, the average value of s, is a function only of k/(Nm) in a one-dimensional model and is a function only of k/(Nm)2 in a two-dimensional model. Furthermore, log(M) is approximately a linear function of log(k). In a one-dimensional model, the regression coefficient is approximately -1 and in a two-dimensional model the regression coefficient is approximately -0.5. Using data from several locations, the regression of log(M) on log(distance) may indicate whether there is isolation by distance in a population at equilibrium and may allow an estimate of the effective migration rate between adjacent sampling locations. Alternative methods for analyzing DNA sequence data from a geographically structured population are discussed. An application of our method to the data of R. L. Cann, M. Stoneking and A. C. Wilson on human mitochondrial DNA is presented.}, added-at = {2015-08-24T20:10:31.000+0200}, author = {Slatkin, M and Maddison, W P}, biburl = {https://www.bibsonomy.org/bibtex/295f7377320a353074e798b4be2eeded7/peter.ralph}, interhash = {e96220c40d4214dbab1b514192cbb431}, intrahash = {95f7377320a353074e798b4be2eeded7}, journal = {Genetics}, keywords = {dispersal_estimation isolation_by_distance parsimony phylogenetics}, month = sep, number = 1, pages = {249-260}, pmid = {2227384}, timestamp = {2015-08-24T20:10:31.000+0200}, title = {Detecting isolation by distance using phylogenies of genes}, url = {http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1204129/}, volume = 126, year = 1990 }