About 150 million years ago, in what is now southern Germany, the earliest known bird, Archaeopteryx, possessed a surprisingly sophisticated mouth adapted for efficient feeding – a feature researchers believe may have been crucial for generating the energy needed for flight. A new analysis of a remarkably well-preserved fossil, published on , , reveals previously unseen details of the animal’s oral anatomy, suggesting a link between specialized feeding and the evolution of avian flight.
Archaeopteryx, often described as the earliest dinosaur classified as a bird, lived alongside other feathered dinosaurs that were related to birds but incapable of powered flight. Distinguishing between these groups can be challenging for paleontologists. The newly studied fossil, acquired by the Field Museum in Chicago in after decades in private collections, is particularly significant due to its completeness, including secondary feathers essential for flight.
“Archaeopteryx is the oldest dinosaur that we know of to fly using feathered airfoils,” explains Jingmai O’Connor, a paleontologist at the Field Museum. “Because flying takes more energy than walking, running, or swimming, then it should have features associated with more efficient feeding.” This hypothesis drove O’Connor and her colleagues to investigate the bird’s mouth structure using X-ray scans and ultraviolet imaging.
The research team identified three key features. First, they discovered a series of bumps on the roof of the mouth that fluoresced under UV light, indicating the presence of soft tissues. These structures appear similar to oral papillae found in modern birds – firm, fleshy cones that aid in manipulating and ingesting food. Second, the fossil contained a tongue bone comparable to those found in contemporary birds, enhancing tongue maneuverability. “In the evolution of birds, in response to their increased caloric demands, they evolve a mobile tongue… and they evolve these oral papillae,” O’Connor stated. “Like in living birds, these are structures that work together.”
The third significant finding was a network of small tunnels at the tip of Archaeopteryx’s beak, revealed through X-ray scanning. These channels likely housed nerves, forming a sensitive bill-tip organ similar to those found in modern birds, which are used to locate food.
The discovery adds to the understanding of how birds evolved from land-dwelling dinosaurs. The meticulous preparation of the fossil allowed researchers to identify traces of soft tissues and microscopic bones, providing a detailed look at the animal’s anatomy.
Michael Pittman, a paleontologist at the Chinese University of Hong Kong who was not involved in the study, acknowledged the importance of the research. “I think It’s an important study because prior to it, people hadn’t been looking for these sorts of structures,” he said. “They have three features proposed in the specimen that in modern birds are associated with efficient feeding.”
While the study strongly suggests a connection between these mouth features and efficient feeding, Pittman cautions that definitively linking them to the development of flight requires further investigation. “Whether it’s a relationship with flight I would say is very much a working hypothesis. I think we need to do more sampling to be able to support that,” he explained. “But as a hypothesis, it’s definitely very exciting.”
Archaeopteryx was first discovered in , and to date, scientists have analyzed 14 body fossils. This latest research, building on over 160 years of study, continues to refine our understanding of the evolutionary journey from dinosaurs to birds, highlighting the crucial role of anatomical adaptations in enabling flight.
