| My
lab focuses on the theoretical and empirical investigation
of functional constraints on
phenotypic evolution at both microevolutionary (rate
and direction of phenotypic change) and macroevolutionary
(patterns of covariation among populations and species,
convergence) levels. “Functional constraints” has
been variously, and often vaguely, defined. Consequently,
we are working on a simple, but comprehensive, quantitative
genetic model of phenotypic evolution that unambiguously
defines old terms such as functional constraints,
functional integration, and functional trade-offs
and suggests
new terms such as functional facilitations and functional
evolvability. The model makes predictions about patterns
of trait variation and intertrait covariation within
and among populations. Tests of the model require
measures of the ability of organisms to perform fitness-related
tasks such as acquire prey, avoid predators, and
attract
mates. The empirical work in the lab, then, tends
to resemble an animal Olympiad. The model also requires
functionally relevant measures of morphology, which
we satisfy with a combination of geometric morphometric
variables and biomechanical shape indices. We use
Trinidadian guppies, threespine sticklebacks, minute
flying wasps (Mymaridae and Trichogrammatidae) and,
of course, the fruit fly, Drosophila melanogaster,
to test various aspects of the functional constraints
model.
|
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