Beak elongation as key innovation in shorebird adaptive radiation

Adaptive radiations often hinge on the emergence of key innovations - traits that unlock new ecological opportunities and drive lineage diversification. In shorebirds (Charadriiformes), variation in beak length has long been associated with resource partitioning, yet its role as a functional innovation has remained untested. Here, we integrate behavioral, morphological, and phylogenetic data from 29 Western Palearctic shorebird species to test whether beak elongation acted as key innovation. We show that species with longer than expected beaks (relative to body size) consistently exhibit distinct foraging and food transport mechanisms. These morphological-behavioral syndromes occur across independent lineages, suggesting convergent evolution driven by ecological constraints. Phylogenetic analyses reveal independent origins of beak elongation, reinforcing its role as a repeated evolutionary solution. Our findings support a functionally integrated view of adaptation, where morphological change enables novel behaviors and ecological exploitation, catalyzing adaptive radiation. This study provides a testable framework for identifying key innovations and underscores the importance of coordinated trait evolution in shaping biodiversity.