Details

<p>Preface to the 2nd Edition    ix</p> <p>Chapter 1.  The Scope and Basic Premises of Population Genetics  1-1</p> <p>Basic Premises of Population Genetics  1-1</p> <p>Population Genomics1-12</p> <p>Section 1:  Population Structure and History</p> <p>Chapter 2.  Modeling Evolution and the Hardy-Weinberg Law  2-1</p> <p>How to Model Microevolution  2-1</p> <p>The Hardy-Weinberg Model  2-4</p> <p>Hardy-Weinberg for Two Loci2-19</p> <p>Chapter 3.  Systems of Mating  3-1</p> <p>Inbreeding  3-1</p> <p>Assortative Mating3-25</p> <p>Disassortative Mating3-45</p> <p>Chapter 4.  Genetic Drift  4-1</p> <p>Basic Evolutionary Properties of Genetic Drift  4-2</p> <p>Founder and Bottleneck Effects  4-7</p> <p>Genetic Drift and Disequilibrium4-11</p> <p>Genetic Drfit, Disequilibrium, and System of Mating4-13</p> <p>Effective Population Size4-18</p> <p>Chapter 5.  Genetic Drift in Large Populations and Coalescence  5-1</p> <p>Newly Arisen Mutations  5-1</p> <p>Neutral Alleles  5-3</p> <p>The Coalescent5-22</p> <p>Chapter 6.  Gene Flow and Population Subdivision  6-1</p> <p>Gene Flow Between Two Local Populations  6-1</p> <p>The Balance of Gene Flow and Drift  6-6</p> <p>An Example of the Balance of Drift and Gene Flow6-27</p> <p>Factors Influencing The Amount and Patter of Gene Flow6-42</p> <p>Total Effective Population Size in Subdivided Populations6-62</p> <p>Multiple Modes of Inheritance and Population Structure6-71</p> <p>Admixture6-76</p> <p>Identifying Subpopulations and Population Structure6-81</p> <p>A Final Warning6-96</p> <p>Chapter 7.  Population History  7-1</p> <p>Inferring Historical Effective Population Sizes  7-6</p> <p>Inferring Historical Gene Flow Patterns and Admixture 7-11</p> <p>Using Haplotype Trees to Study Population History 7-19</p> <p>Model Based Approaches to Phylogeographic Analysis 7-56</p> <p>Direct Studies Over Space and Past Times 7-70</p> <p>Historical Population Genetics and Macroevolution 7-75</p> <p>Section 2:  Genotype and Phenotype</p> <p>Chapter 8.  Basic Quantitative Genetic Definitions and Theory  8-1</p> <p>“Simple” Mendelian Phenotypes  8-2</p> <p>Nature Versus Nurture?  8-7</p> <p>The Fisherian Model of Quantitative Genetics8-13</p> <p>Chapter 9.  Quantitative Genetics:  Unmeasured Genotypes  9-1</p> <p>Correlation Between Relatives  9-2</p> <p>The Distinction Between Heritability and Inheritance9-17</p> <p>Response to Selection9-19</p> <p>The Problem of Between-Population Differences in Mean</p> <p>Phenotype 9-21</p> <p>Controlled Crosses for the Analysis of Between Population</p> <p>Differences 9-30</p> <p>The Balance Between Mutation, Drift, and Gene Flow Upon</p> <p>Phenotypic Variance 9-36</p> <p>Chapter 10.  Quantitative Genetics:  Measured Genotypes  10-1</p> <p>Marker Association Studies  10-5</p> <p>Candidate Loci10-35</p> <p>Candidate Loci and Genetic Architecture10-51</p> <p>Section 3:  Natural Selection and Adaptation</p> <p>Chapter 11.  Natural Selection  11-1</p> <p>The Fundamental Equation of Natural Selection:  Measured</p> <p>Genotypes  11-4</p> <p>Sickle-Cell Anemia as an Example of Natural Selection 11-10</p> <p>Adaptation as a Polygenic Process 11-24</p> <p>The Fundamental Theorem of Natural Selection:  Unmeasured</p> <p>Genotypes  11-29</p> <p>Some Implications of the Fundamental Equations of Natural</p> <p>Selection 11-33</p> <p>The Course of Adaptation and Natural Selection 11-47</p> <p>Chapter 12.  Interactions of Natural Selection with Other Evolutionary Forces</p> <p>         and the Detection of Natural Selection      12-1</p> <p>The Interaction of Natural Selection with Mutation   12-3</p> <p>The Interaction of Natural Selection with Mutation and System of</p> <p>Mating   12-8</p> <p>The Interaction of Natural Selection with Gene Flow 12-12</p> <p>The Interaction of Natural Selection with Genetic Drift 12-21</p> <p>The Interactions of Natural Selection, Genetic Drift, and</p> <p>Gene Flow 12-28</p> <p>The Interactions of Natural Selection, Genetic Drift, and Mutation 12-45</p> <p>The Interactions of Natural Selection, Genetic Drift, Mutation, and</p> <p>Recombination 12-65</p> <p>Candidate Loci 12-71</p> <p>Quantitative Genetic Approaches to Detecting Selection 12-75</p> <p>The Neutralist/Selectionist Debate 12-80</p> <p>Chapter 13.  Units and Targets of Selection   13-1</p> <p>The Unit of Selection   13-4</p> <p>Targets of Selection Below the Level of the Individual 13-18</p> <p>Targets of Selection Above the Level of the Individual 13-51</p> <p>Chapter 14.  Selection in Heterogeneous Environments   14-1</p> <p>Coarse-Grained Spatial Heterogeneity   14-4</p> <p>Coarse-Grained Temporal Heterogeneity 14-34</p> <p>Fine-Grained Heterogeneity 14-56</p> <p>Coevolution 14-74</p> <p>Chapter 15.  Selection in Age-Structured Populations   15-1</p> <p>Life History and Fitness   15-3</p> <p>The Evolution of Senescence  15-13</p> <p>Abnormal Abdomen:  An Example of Selection in an</p> <p>Age-Structured Population  15-24</p> <p>Overview  15-63</p> <p>Appendices</p> <p>Appendix 1.  Genetic Survey Techniques   A1-1</p> <p>Appendix 2.  Probability and Statistics   A2-1</p> <p>References     R-1</p> Index

<p><b>Alan R. Templeton, PhD</b>, is Charles Rebstock Professor Emeritus of Biology and Statistical Genomics at Washington University in St. Louis. His research focus is on the application of molecular genetic techniques and statistical population genetics to a variety of basic and applied evolutionary problems. He is on the editorial boards of <i>Molecular Phylogenetics and Evolution and Evolutionary Bioinformatics Online</i>.</p>

<p><b>Explore the fundamentals of the biological implications of population genetic theory</b></p><p>In the newly revised Second Edition of <i>Population Genetics and Microevolutionary Theory</i>, accomplished researcher and author Alan R. Templeton delivers a fulsome discussion of population genetics with coverage of exciting new developments in the field, including new discoveries in epigenetics and genome-wide studies. The book prepares students to successfully apply population genetics analytical tools by providing a solid foundation in microevolutionary theory.</p><p>The book emphasizes that population structure forms the underlying template upon which quantitative genetics and natural selection operate and is a must-read for future population and evolutionary geneticists and those who wish to work in genetic epidemiology or conservation biology.</p><p>You’ll learn about a wide array of topics, including quantitative genetics, the interactions of natural selection with other evolutionary forces, and selection in heterogeneous environments and age-structured populations. Appendices that cover genetic survey techniques and probability and statistics conclude the book.</p><p>Readers will also benefit from the inclusion of:</p><ul><li>A thorough introduction to population genetics, including the scope of the subject, its premises, and the Hardy-Weinberg Model of Microevolution</li><li>An exploration of systems of mating, including a treatment of the use of runs of homozygosity to show pedigree inbreeding in distant ancestors</li><li>A practical discussion of genetic drift, including the use of effective sizes in conservation biology (with a discussion of African rhinos as an example)</li><li>A concise examination of coalescence, including a treatment of the infinite sites model</li></ul><p>Perfect for graduate students in genetics and evolutionary biology programs and advanced undergraduate biology majors, <i>Population Genetics and Microevolutionary Theory</i> will also earn a place in the libraries of students taking courses in conservation biology, human genetics, bioinformatics, and genomics.</p>

US