Evolution and Selection of Quantitative Traits

This is the second volume in a planned trilogy that summarises the modern field of quantitative genetics, informed by empirical observations from wide-ranging fields (agriculture, evolution, ecology, and human biology) as well as population genetics, statistical theory, mathematical modeling, genetics, and genomics.

Zusatztext A masterful synthesis of the growing points in selection analysis. Informationen zum Autor Bruce Walsh is Professor of Ecology and Evolutionary Biology at the University of Arizona. He has taught advanced classes on quantitative genetics in 25 different countries and his research interests are at the interface of biology, genetics, mathematical modelling, and statistics. He is also an avid lepidopterist, having described over two dozen species of new moths and has three species named after him.Michael Lynch is Professor in the Schoool of Life Sciences at Arizona State University and is Center Director of the Biodesign Center for Mechanims of Evolution. His research is focused on mechanisms of evolution at the gene, genomic, cellular, and phenotypic levels, with special attention being given to the roles of mutation, random genetic drift, and recombination. He is a member of the US National Academy of Sciences, and a fellow of the American Academy of Arts and Sciences. Klappentext This is the second volume in a planned trilogy that summarises the modern field of quantitative genetics, informed by empirical observations from wide-ranging fields (agriculture, evolution, ecology, and human biology) as well as population genetics, statistical theory, mathematical modeling, genetics, and genomics. Zusammenfassung This is the second volume in a planned trilogy that summarises the modern field of quantitative genetics, informed by empirical observations from wide-ranging fields (agriculture, evolution, ecology, and human biology) as well as population genetics, statistical theory, mathematical modeling, genetics, and genomics. Inhaltsverzeichnis Preface I Introduction 1: Changes in quantitative traits over time II Evolution at one and two loci 2: Neutral evolution in one- and two-locus systems 3: The genetic effective size of a population 4: The nonadaptive forces of evolution 5: The population genetics of selection 6: Theorems of natural selection: Results of Price, Fisher, and Robertson 7: Interaction of selection, mutation, and drift 8: Hitchhiking and selective sweeps 9: Using molecular data to detect selection: Signatures from recent single events 10: Using molecular data to detect selection: Signatures from multiple historical events III Drift and quantitative traits 11: Changes in genetic variance induced by drift 12: The neutral divergence of quantitative traits IV Short-term response on a single character 13: Short-term changes in the mean: 1. The breeder's equation 14: Short-term changes in the mean: 2. Truncation and threshold selection 15: Short-term changes in the mean: 3. Permanent versus transient response 16: Short-term changes in the variance: 1. Changes in the additive variance 17: Short-term changes in the variance: 2. Changes in environmental variance 18: Analysis of short-term selection experiments: 1. Least-squares approaches 19: Analysis of short-term selection experiments: 2. Mixed-model and bayesian approaches 20: Selection response in natural populations V Selection in structured populations 21: Family-based selection 22: Associative effects: Competition, social interactions, group and kin selection 23: Selection under inbreeding VI Population-genetic models of trait response 24: The infinitesimal model and its extensions 25: Long-term response: 1. Deterministic aspects 26: Long-term response: 2. Finite population size and mutation 27: Long-term response: 3. Adaptive walks 28: Maintenance of quantitative genetic variation VII Measuring selection on traits 29: Individual fitness and the measurement of univariate selecton 30: Measuring multivariate selection VIII Appendices A1: Diffusion theory A2: Introduction to Bayesian Analysis A3: Markov Chain Monte Car...

A masterful synthesis of the growing points in selection analysis.

Auteur
Bruce Walsh is Professor of Ecology and Evolutionary Biology at the University of Arizona. He has taught advanced classes on quantitative genetics in 25 different countries and his research interests are at the interface of biology, genetics, mathematical modelling, and statistics. He is also an avid lepidopterist, having described over two dozen species of new moths and has three species named after him. Michael Lynch is Professor in the Schoool of Life Sciences at Arizona State University and is Center Director of the Biodesign Center for Mechanims of Evolution. His research is focused on mechanisms of evolution at the gene, genomic, cellular, and phenotypic levels, with special attention being given to the roles of mutation, random genetic drift, and recombination. He is a member of the US National Academy of Sciences, and a fellow of the American Academy of Arts and Sciences.

Contenu

• Preface

• I

• Introduction

• 1: Changes in quantitative traits over time

• II

• Evolution at one and two loci

• 2: Neutral evolution in one- and two-locus systems

• 3: The genetic effective size of a population

• 4: The nonadaptive forces of evolution

• 5: The population genetics of selection

• 6: Theorems of natural selection: Results of Price, Fisher, and Robertson

• 7: Interaction of selection, mutation, and drift

• 8: Hitchhiking and selective sweeps

• 9: Using molecular data to detect selection: Signatures from recent single events

• 10: Using molecular data to detect selection: Signatures from multiple historical events

• III

• Drift and quantitative traits

• 11: Changes in genetic variance induced by drift

• 12: The neutral divergence of quantitative traits

• IV

• Short-term response on a single character

• 13: Short-term changes in the mean: 1. The breeder's equation

• 14: Short-term changes in the mean: 2. Truncation and threshold selection

• 15: Short-term changes in the mean: 3. Permanent versus transient response

• 16: Short-term changes in the variance: 1. Changes in the additive variance

• 17: Short-term changes in the variance: 2. Changes in environmental variance

• 18: Analysis of short-term selection experiments: 1. Least-squares approaches

• 19: Analysis of short-term selection experiments: 2. Mixed-model and bayesian approaches

• 20: Selection response in natural populations

• V

• Selection in structured populations

• 21: Family-based selection

• 22: Associative effects: Competition, social interactions, group and kin selection

• 23: Selection under inbreeding

• VI

• Population-genetic models of trait response

• 24: The infinitesimal model and its extensions

• 25: Long-term response: 1. Deterministic aspects

• 26: Long-term response: 2. Finite population size and mutation

• 27: Long-term response: 3. Adaptive walks

• 28: Maintenance of quantitative genetic variation

• VII

• Measuring selection on traits

• 29: Individual fitness and the measurement of univariate selecton

• 30: Measuring multivariate selection

• VIII

• Appendices

• A1: Diffusion theory

• A2: Introduction to Bayesian Analysis

• A3: Markov Chain Monte Carlo and Gibbs sampling

• A4: Multiple comparisons: Bonferroni corrections, false-discovery rates, and meta-analysis

• A5: The geometry of vectors and matrices: Eigenvalues and eigenvectors

• A6: Derivatives of vectors and vector-valued functions

• Literature Cited

• Author Index

• **Organism and Trait Index…