Three-dimensional visualization of predatory gastropod feeding teeth with synchrotron scanning

Several families of neogastropod mollusks independently evolved the ability to drill through mineralized prey skeletons using their own mineralized feeding teeth, sometimes with shell-softening chemical agents produced by an organ in the foot. Teeth with more durable tooth shapes should extend their use and improve predator performance, but past studies have described only the cusped-side of teeth, mostly overlooking morphologies related to functional interactions between teeth. Here, we describe the three-dimensional morphology of the central drilling tooth (rachidian) from four species of the neogastropod family Muricidae using synchrotron tomographic microscopy and assemble a three-dimensional model of a multitooth series in drilling position for two of them to investigate their dynamic form. We find two new types of articulating surfaces, including a saddle joint at either end of the rachidian and a large tongue-and-groove joint in the center. The latter has a shape that maximizes contact surface area between teeth as they rotate away from each other during drilling. Articulating joints have not been described in Neogastropod radula previously, but they are consistent with an earlier hypothesis that impact forces on individual teeth during predatory drilling are dispersed by tooth-tooth interactions.

Automated summary

Several families of neogastropod mollusks have evolved the ability to drill through prey skeletons using their own feeding teeth. Researchers have discovered new articulating surfaces in the teeth of neogastropod mollusks, including saddle joints and tongue-and-groove joints, which optimize contact surface area and disperse impact forces during drilling. This finding provides new insight into the functional interactions between teeth and improves our understanding of predatory feeding in neogastropods.