Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

Population genetics, molecular markers and the study of dispersal in plants

Population genetics, molecular markers and the study of dispersal in plants Summary 1 Long‐distance dispersal events are biologically very important for plants because they affect colonization probabilities, the probabilities of population persistence in a fragmented habitat, and metapopulation structure. They are, however, very difficult to investigate because of their low frequency. We reviewed the use of molecular markers in the population genetics approach to studying dispersal. With these methods the consequences of long‐distance dispersal are studied, rather than the frequency of the dispersal events themselves. 2 Molecular markers vary, displaying different amounts of variation and different modes of inheritance: they may be either dominant or codominant, and may or may not be subjected to genetic recombination. Use of markers has inspired the development of maximum likelihood techniques that take the evolutionary history of alleles into account while estimating gene flow. 3 Inferring seed dispersal rates from indirect measurements of gene flow involves three steps: (i) quantifying genetic differentiation among populations and using this to estimate the rate of gene flow; (ii) producing a genetic dispersal curve by regressing geographical distance among populations against the amount of gene flow; and (iii) separating seed‐mediated from pollen‐mediated gene flow, by comparing differentiation in nuclear vs. cytoplasmic molecular markers. In this way, potentially very low levels of gene flow can be detected. 4 The indirect approach is based on a number of assumptions. The validity of each assumption should be assessed by independent methods or the estimates of gene flow and dispersal should be mainly used in a comparative context. In metapopulations, with frequent extinction and colonization, the relationship between genetic differentiation and gene flow is not straightforward, and other methods should be used. 5 Highly variable molecular markers, especially microsatellites, have facilitated a direct genetic approach to measuring gene flow, based on parental analyses. 6 The population genetic approach provides different information about dispersal than ecological methods. Thus population genetic and ecological methods may supplement each other, and together lead to a better insight into the dispersal process than either of the methods on its own. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of Ecology Wiley

Population genetics, molecular markers and the study of dispersal in plants

Loading next page...
 
/lp/wiley/population-genetics-molecular-markers-and-the-study-of-dispersal-in-Q84mpTphos

References (128)

Publisher
Wiley
Copyright
Copyright © 1999 Wiley Subscription Services, Inc., A Wiley Company
ISSN
0022-0477
eISSN
1365-2745
DOI
10.1046/j.1365-2745.1999.00389.x
Publisher site
See Article on Publisher Site

Abstract

Summary 1 Long‐distance dispersal events are biologically very important for plants because they affect colonization probabilities, the probabilities of population persistence in a fragmented habitat, and metapopulation structure. They are, however, very difficult to investigate because of their low frequency. We reviewed the use of molecular markers in the population genetics approach to studying dispersal. With these methods the consequences of long‐distance dispersal are studied, rather than the frequency of the dispersal events themselves. 2 Molecular markers vary, displaying different amounts of variation and different modes of inheritance: they may be either dominant or codominant, and may or may not be subjected to genetic recombination. Use of markers has inspired the development of maximum likelihood techniques that take the evolutionary history of alleles into account while estimating gene flow. 3 Inferring seed dispersal rates from indirect measurements of gene flow involves three steps: (i) quantifying genetic differentiation among populations and using this to estimate the rate of gene flow; (ii) producing a genetic dispersal curve by regressing geographical distance among populations against the amount of gene flow; and (iii) separating seed‐mediated from pollen‐mediated gene flow, by comparing differentiation in nuclear vs. cytoplasmic molecular markers. In this way, potentially very low levels of gene flow can be detected. 4 The indirect approach is based on a number of assumptions. The validity of each assumption should be assessed by independent methods or the estimates of gene flow and dispersal should be mainly used in a comparative context. In metapopulations, with frequent extinction and colonization, the relationship between genetic differentiation and gene flow is not straightforward, and other methods should be used. 5 Highly variable molecular markers, especially microsatellites, have facilitated a direct genetic approach to measuring gene flow, based on parental analyses. 6 The population genetic approach provides different information about dispersal than ecological methods. Thus population genetic and ecological methods may supplement each other, and together lead to a better insight into the dispersal process than either of the methods on its own.

Journal

Journal of EcologyWiley

Published: Aug 1, 1999

There are no references for this article.