The 75 species of Australian honeyeaters (Meliphagidae) are morphologically and ecologically diverse, with species feeding on nectar, insects, fruit, and other resources. We investigated ecomorphology and community structure of honeyeaters across Australia. First, we asked to what degree morphology and ecology (foraging behavior) are concordant. Second, we estimated rates of trait evolution. Third, we compared phylogenetic and trait community structure across the broad environmental gradients of continental Australia. We found that morphology explained 37% of the variance in ecology (and 62% vice versa), and that recovered multivariate ecomorphological relationships incorporated well-known bivariate relationships. Clades of large-bodied species exhibited elevated rates of morphological trait evolution, while members of Melithreptus showed slightly faster rates of ecological trait evolution. Finally, ecological trait diversity did not decline in parallel with phylogenetic diversity along a gradient of decreasing precipitation. We employ a new method (trait fields) and extend another (phylogenetic fields) to show that while species from phylogenetically clustered assemblages co-occur with morphologically similar species, these species are as varied in foraging behavior as those from more diverse assemblages. Thus, although closely related, these arid-adapted species have diverged in ecological space to a similar degree as their mesic counterparts, perhaps mediated by competition. [more]

The external appearance of an organism reflects selection from multiple drivers, including abiotic factors such as climate and substrate, and potentially biotic factors such as sexual selection and mimicry. Woodpeckers are an excellent group to examine how external phenotypes evolve because they occupy a broad range of climates across many habitats, and display patterns of rapid divergence and striking convergence. Here we show that both habitat and climate profoundly shape plumage evolution. However, we also find a strong signal that many species exhibit remarkable convergence not explained by these factors or shared ancestry. Instead, this convergence is associated with geographic overlap between species, suggesting occasional, strong selection for interspecific mimicry. Consequently, both abiotic and biotic factors, including interspecific interactions, are potent drivers of phenotypic evolution. [more]