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Statistical Challenges for Studying the Evolution of Function Valued Traits. Patrick A. Carter School of Biological Sciences Washington State University. Interesting Problems in Evolutionary Biology. How do organisms evolve?
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Statistical Challenges for Studying the Evolution of Function Valued Traits Patrick A. Carter School of Biological Sciences Washington State University
Interesting Problems in Evolutionary Biology • How do organisms evolve? • What processes are involved (selection, genetic drift); how do they interact? • What is the role of genetic variation in evolution? • How does genetic variation shape evolution? • How does evolution alter genetic variation? • What influences the tempo of evolution? • Constraints • My lab investigates these questions at the both the genetic and physiological levels.
Basic Quantitative Genetics • Most traits show continuous variation and are influenced by many genes. • If family relationships are known, the phenotypic variance can be partitioned: • VP = VG+VE • VG also can be partitioned: • VG = VA + VD + VI • VA is additive genetic variance (variance in breeding values) • One trait: simple variance • Multiple traits: G matrix • FV Trait: G function
Interesting Questions about the Evolution of FV Traits • Have we estimated the phenotypic function in the most meaningful way biologically? • Has the phenotypic function evolved in response to selection, and in the way we predicted? • Has the underlying genetic variance-covariance function evolved in response to selection?
Statistical Challenges • Register the curves in a biologically meaningfully way. • Compare mean trajectories from different populations with different evolutionary histories. • Compare G functions from different populations with different evolutionary histories.
Registration • How do we align curves that contain variation in multiple points of biological interest? • Growth curves of larval insects: • Hatch • High Growth • Peak = hormonal shift • Wandering phase = loss of body mass • Pupation = end of larval phase
Population Comparisons • Evolutionary biologists frequently want to compare characteristics of populations with different evolutionary histories, especially: • Mean population phenotypes (has selection changed the trait?) • Genetic variances and covariances (has selection eroded the variances and covariances as alleles become fixed?)
Statistical Challenges • Formally compare mean phenotypic curves • Most experimental designs are nested, with replicate lines nested within experimental selection group. Replicates lines can provide information about genetic drift. • Formally compare G functions (and their eigenfunctions) from different populations.
Acknowledgements • Students: Ted Morgan, Steph Kane, Greg Ragland, Drew Reinbold, Kristy Bellinger, Kristen Irwin, Anna Heink • Collaborators: Fun Value Group • Funding: NSF (DEB 0083638, DEB 0105079, EF 0328594), National Institute of Mathematical and Biological Synthesis
Statistical Challenges • Formally compare growth curves in selected vs. non-selected populations. • Compare selection responses: along axis of major variation vs. axis in “nearly null space”. • Formally compare G functions from different populations.