Bird-like dinosaur tells story of finger evolution James Clark, the Ronald B. Weintraub Professor of Biology in The George Washington University's Columbian College of Arts and Sciences, and Xu Xing, of the Chinese Academy of Science's Institute of Vertebrate Palaeontology and Paleoanthropology in Beijing, have discovered a unique beaked, plant-eating dinosaur in China. This finding demonstrates that theropod, or bird-footed, dinosaurs were more ecologically diverse in the Jurassic period than previously thought and offers important new evidence about how the three-fingered hand of birds evolved from the hand of dinosaurs. The discovery is featured in this week's edition of the journal Nature.
Title: The Integration of Ventilation and Locomotion in Archosaurs Authors: David R. Carrier and Colleen G. Farmer
Movements of the pelvis have recently been found to contribute to ventilation in both crocodilians and birds. Alligators have a kinetic pelvis in which the ischiopubic and ischiotruncus muscles rotate the pubic bones ventrally to increase abdominal volume and thereby facilitate inspiration. In birds, the entire pelvis rocks on the axial skeleton to produce ventilation. Although the mechanisms of pelvic aspiration are very different in crocodilians and birds, it is unusual among vertebrates for the pelvic musculoskeletal system to play an active role in inspiration. This observation raises the possibility that the pelvic musculoskeletal system may have played an important role in the ventilation of basal archosaurs. Based on the mechanism of pelvic aspiration in crocodilians and the structure of gastralia in basal archosaurs, we suggest that an ischiotruncus muscle pulled the medial aspect of the gastralia caudally, and thereby helped to produce inspiration by increasing the volume of the cuirassal basket. The proposed mechanism of cuirassal breathing in non-avian theropods leads us to suggest that the phase relationship of the ventilatory and locomotor cycles in running theropods was the opposite of that observed in running birds. Furthermore, we suggest that the ventilatory cycle of flying pterosaurs was entrained to the locomotor cycle with a phase relationship that was the opposite of that observed during flight in modern birds.
Title: The evolution of pelvic aspiration in archosaurs Authors: David R. Carrier and Colleen G. Farmer
Movements of the pelvic girdle have recently been found to contribute to inspiratory airflow in both crocodilians and birds. Although the mechanisms are quite different in birds and crocodilians, participation of the pelvic girdle in the production of inspiration is rare among vertebrates. This raises the possibility that the pelvic musculoskeletal system may have played a role in the ventilation of basal archosaurs. Judging from the mechanism of pelvic aspiration in crocodilians and the structure of gastralia in basal archosaurs, we suggest that an ischiotruncus muscle pulled the medial aspect of the gastralia caudally, and thereby helped to produce inspiration by increasing the volume of the abdominal cavity. From this basal mechanism, several archosaur lineages appear to have evolved specialized gastralia, pelvic kinesis, and/or pelvic mobility. Kinetic pubes appear to have evolved independently in at least two clades of Crocodylomorpha. This convergence suggests that a diaphragmatic muscle may be basal for Crocodylomorpha. The pelvis of pterosaurs was long, open ventrally, and had prepubic elements that resembled the pubic bones of Recent crocodilians. These characters suggest convergence on the pelvic aspiratory systems of both birds and crocodilians. The derived configuration of the pubis, ischium and gastralia of non-avian theropods appears to have enhanced the basal gastral breathing mechanism. Changes in structure of the pelvic musculoskeletal system that were present in both dromaeosaurs and basal birds may have set the stage for a gradual reduction in the importance of gastral breathing and for the evolution of the pelvic aspiration system of Recent birds. Lastly, the structure of the pelvis of some ornithischians appears to have been permissive of pubic and ischial kinesis. Large platelike prepubic processes evolved three times in Ornithischia. These plates are suggested to have been instrumental in an active expansion of the lateral abdominal wall to produce inspiratory flow. Thus, many of the unique features found in the pelvic girdles of various archosaur groups may be related to the function of lung ventilation rather than to locomotion.
Hadrosaur, dead 80 million years, yields oldest protein yet sequenced. Scientists have isolated and detailed the sequences of eight fragments of a protein from the fossilised thigh bone of a duck-billed dinosaur. The protein - the bone connective tissue collagen - was isolated from an 80-million-year-old hadrosaur fossil, making it the oldest ever to be sequenced
A dinosaur bone from Malta and analysis by Montana State University scientists have helped confirm that protein can be preserved for millions of years and that birds and dinosaurs are close relatives. Announced in the May 1 issue of Science, the discovery in an 80-million-year-old hadrosaur showed that a previous, similar find in a 68-million-year-old Tyrannosaurus rex wasn't a fluke, said a research team led by North Carolina State University, Harvard University, Harvard Medical School and Beth Israel Deaconess Medical Centre.
Take a chicken, subtract the feathers, give it teeth, swap three long fingers for each wing and add a tail. What do you get? A dino-chicken. Birds descended from dinosaurs, said Jack Horner, Museum of the Rockies curator.
The discovery of a petite, plant-eating dinosaur with primitive plumage could mean that the dinosaur from which all others evolved had feather-like protrusions, according to the latest study. The find in northeastern China is a scientific bombshell, further shattering the once axiomatic view that feathered birds and scaly reptiles developed along different evolutionary paths.
A herd of young birdlike dinosaurs met their death on the muddy margins of a lake some 90 million years ago, according to a team of Chinese and American palaeontologists that excavated the site in the Gobi Desert in western Inner Mongolia. The Sudden death of the herd in a mud trap provides a rare snapshot of social behaviour. Composed entirely of juveniles of a single species of ornithomimid dinosaur (Sinornithomimus dongi), the herd suggests that immature individuals were left to fend for themselves when adults were preoccupied with nesting or brooding.
Birds survived the catastrophe that killed off the dinosaurs because their brains were better developed, a study of fossils has shown. Dinosaurs and early birds such as Archaeopterix, right, died out during a mass extinction thought to have been caused by a meteor 65 million years ago, but modern-style birds, which had bigger brains, survived.
The earliest known bird, the magpie-sized Archaeopteryx lithographica, was able to hear like a modern emu. In this respect at least, Archaeopteryx appears to have been more bird-like than reptile-like. A team of scientists found the length of a part of the inner ear of birds and reptiles could be used to predict their hearing ability. Details of the work appear in one of the journals of the UK Royal Society.