International Scientific Team Discovers, Names Oldest Pterodactyloid Species


A diagram shows the fragmentary remains of Kryptodrakon progenitor. The skeletal outline is Pterodactylus antiques reprinted with permission from Peter Wellnhofer. Illustration | Brian Andres



Study rewrites chapter in understanding of prehistoric world, evolution of the great flying beasts.


By Vickie Chachere

USF News


TAMPA, Fla. (April 24, 2014) - An international research team has discovered and named the earliest and most primitive pterodactyloid, a group of flying reptiles that would go on to become the largest known flying creatures to have ever existed, and established they flew above the earth some 163 million years ago, longer than previously known.


Working from a fossil discovered in northwest China, the project–led by USF paleontologist Brian Andres, James Clark of the George Washington University Columbian College of Arts and Sciences, and Xu Xing of the Chinese Academy of Sciences–named the new pterosaur species Kryptodrakon progenitor.


Through scientific analysis the team established it as the first pterosaur to bear the characteristics of the Pterodactyloidea, which would become the dominant winged creatures of the prehistoric world. Their research was published online Thursday in the journal Current Biology.

The preserved bones ofKryptodrakon progenitorhasyielded new discoveries on the origin of thepterodactyloids, a group of flying reptiles that would go on to become the largest known flying creatures to haveever existed. Illustration | Brian Andres.


“This finding represents the earliest and most primitive pterodactyloid pterosaur, a flying reptile in a highly specialized group that includes the largest flying organisms,” says Chris Liu, program director in the National Science Foundation’s Division of Earth Sciences. “The research has extended the fossil record of pterodactyloids by at least five million years to the Middle-Upper Jurassic boundary about 163 million years ago.”


Kryptodrakon progenitorlived around the time of the Middle-Upper Jurassic boundary. Through studying the fossil fragments, researchers also determined that the pterodactyloids originated, lived, and evolved in terrestrial environments – rather than marine environments where other specimens have been found.


The fossil is of a small pterodactyloid with a wingspan estimate of about 4½-feet. Pterodactyloids – who went on to evolve into giant creatures, some as big as small planes – went extinct with the dinosaurs, about 66 million years ago. Pterosaurs are considered close relatives to the dinosaurs, but are not dinosaurs themselves.


The discovery provides new information on the evolution of pterodactyloids, Andres said. This area was likely a flood plain at the time the pterosaur lived, Andres said. As the pterosaurs evolved, their wings changed from being narrow, which are more useful for marine environments, to being more broad near the origin of the pterodactyloids – helpful in navigating land environments.


“He (Kryptodrakon progenitor)fills in a very important gap in the history of pterosaurs,” said Andres, a visiting associate professor in USF's School of Geosciences. “With him, they could walk and fly in whole new ways.”


The fossil that became the centerpiece of the research was discovered in 2001 by Chris Sloan, formerly of National Geographic and now president of Science Visualization. It was found in a mudstone of the Shishugou Formation of northwest China on an expedition led by Xu and Clark when Andres was a graduate student with Clark at GW. The desolate and harsh environment has become known to scientists worldwide as having “dinosaur death pits” for the quicksand in the area that trapped an extraordinary range of prehistoric creatures, stacking them on top of each other,including one of the oldest tyrannosaurs,Guanlong.Kryptodrakon progenitorwas found 35 meters below an ash bed that has been dated back to more than 161 million years.


The specimen is housed at the Institute of Vertebrate Paleontology and Paleoanthropology, Beijing, China. The nameKryptodrakon progenitorcomes fromKrypto(hidden) anddrakon(serpent), referring to“Crouching Tiger, Hidden Dragon” filmed near where the species was discovered, andprogenitor(ancestral or first-born), referring to its status as the earliest pterodactyloid, Andres said.


"Kryptodrakonis the second pterosaur species we've discovered in the Shishugou Formation and deepens our understanding of this unusually diverse Jurassic ecosystem,” Clark said. “It is rare for small, delicate fossils to be preserved in Jurassic terrestrial deposits, and the Shishugou fauna is giving us a glimpse of what was living alongside the behemoths likeMamenchisaurus."


The remote Shishugou Formation in northwest China is a famous area for the discovery of dinosaurs, pterosaurs, and other prehistoric creatures. The fossil that became the centerpiece of the new research on pterodactyloid pterosaurs was found in 2001 in the red mudstone layer shown here. The area was featured in the film Crouching Tiger, Hidden Dragon, which inspired the name for the newest discovery - Krypto (hidden) and drakon(serpent). Photo | James Clark.

The scientists write that the pterosaurs were a diverse group of Mesozoic flying reptiles that underwent a body plan reorganization, adaptive radiation, and replacement of earlier forms midway through their long history, resulting in the origin of the Pterodactyloidea, a highly-specialized group of pterosaurs of whichKryptodrakonis the earliest and most primitive species.


This new take on the ecological history of pterosaurs is supported by a significant correlation found between wing shape and environment in pterosaurs and modern flying vertebrates, like bats and birds, the researchers said. Pterosaurs, however, are not the ancestors of birds – those are the dinosaurs – and scientists still believe that pterosaurs did not evolve into birds or other modern animals humans would know.


The fieldwork was supported by the National Natural Science Foundation of China, the National Science Foundation Division of Earth Sciences of the USA, the Chinese Academy of Sciences, the National Geographic Society, the Jurassic Foundation, the Hilmar Sallee bequest, and the George Washington University. Study of the specimen was supported by the Chinese Academy of Sciences, the National Science Foundation Division of Earth Sciences and the National Natural Science Foundation of China.


Vickie Chachere is the Director for Special Projects at University Communications & Marketing and can be reached at vchachere@usf.edu.