THE EVOLUTION OF TETRAPOD FEEDING BEHAVIOR: KINEMATIC HOMOLOGIES IN PREY TRANSPORT.

Abstract

One of the major features of the aquatic-to-terrestrial transition in vertebrate evolution was the change in the mechanism used to transport prey from the jaws to the throat. Primarily, vertebrates use hydraulic transport, but the transition to terrestrial life was accompanied by modifications of the hyobranchial apparatus that permit tongue-based transport. Despite an extensive data base on amniote feeding systems and mechanisms of intraoral prey transport, few data are available on the mechanism of prey transport in anamniote tetrapods. Transport cycles of four Ambystoma tigrinum (Amphibia) feeding on worms and crickets were filmed at 150 flames per second to produce quantitative profiles of the intraoral transport cycles for the two prey types. During the transport cycle the head and body remain stationary relative to the background: transport in Ambystoma tigrinum thus does not involve inertial movements of the head or body. Prey type had little effect on the kinematics of prey transport. The process of prey transport may be divided into four phases: preparatory, fast opening, closing, and recovery. The preparatory phase itself is divided into two parts: an extended segment that may include slight slow opening and a static phase prior to mouth opening where no change in gape occurs. The kinematic profile of transport in terrestrial salamanders is extremely similar to that used by fishes during hydraulic (aquatic) prey transport. We hypothesize that the distinct recovery and preparatory phases in the transport cycle of anamniote tetrapods are together homologous to the slow opening phases of the amniote cycle, and that during the evolution of terrestrial prey processing systems the primitive extended preparatory phase has become greatly compressed and incorporated into the amniote gape cycle.