Sniffing out morphological convergence in the turbinal complex of myrmecophagous placentals.

Abstract

The length of the snout in mammals has important evolutionary consequences for the functional systems housed within the rostrum. However, whether increased snout lengths lead to expanded olfactory performance has rarely been examined. Here, we investigate inner rostral function among 10 species of myrmecophagous (ant- and/or termite-eating) placental mammals and 10 closely related species. We use nondestructive computed tomography scanning methods to characterize inner rostral function based on the underlying morphology of the turbinal bones in the nasal cavity. Three approaches were chosen to address this question, including the quantification of functional turbinal surface area, the quantification of functional turbinal three-dimensional complexity, and geometric morphometrics. By including non-model species from several different mammalian orders, we were able to extend the discussion surrounding turbinal homologies to comparisons across mammals. Our results show no increased olfactory function in all myrmecophagous species relative to their sister taxa, which suggests that there is no trade-off for increased olfactory capabilities in myrmecophagous species with elongated snouts. We found no evidence of convergence in turbinal morphology among all five myrmecophagous lineages. However, we found evidence of morphological convergence in the turbinals between the giant armadillo and the aardvark, suggesting a more complex interplay between the evolution of turbinal morphology and ecological correlates. While myrmecophagy alone may not be a strong enough ecological signal to overcome phylogenetic and developmental constraints, we suggest that this might be the case at the intersection of this dietary specialization with a primarily underground lifestyle where odorants may be difficult to detect.