Anurognathus was first named and described by Ludwig Döderlein in 1923.[1] The type species is Anurognathus ammoni. The specific nameammoni honours the Bavarian geologist Ludwig von Ammon, from whose collection Döderlein had acquired the fossil in 1922.
Anurognathus had a short head with pin-like teeth for catching insects and although it traditionally is ascribed to the long-tailed pterosaur group "Rhamphorhynchoidea", its tail was comparatively short, allowing it more maneuverability for hunting.[2] According to Döderlein the reduced tail of Anurognathus was similar to the pygostyle of modern birds.[3] Its more typical "rhamphorhynchoid" characters include its elongated fifth toe and short metacarpals and neck.[3] With an estimated wingspan of fifty centimetres (20 inches) and a nine centimetre long body (skull included), its weight was limited: in 2008 Mark Paul Witton estimated a mass of 40 g (1.4 oz) for a specimen with a 35 cm (14 in) wingspan.[4] The holotype was redescribed by Peter Wellnhofer in 1975.
Later a second, smaller specimen was found, probably of a subadult individual. Its slab and counterslab are separated and both were sold to private collections; neither has an official registration. It was described by S. Christopher Bennet in 2007. This second exemplar is much more complete and better articulated. It shows impressions of a large part of the flight membrane and under UV-light remains of the muscles of the thigh and arm become visible. It provided new information on many points of the anatomy. The skull was shown to have been very short and broad, wider than long. It transpired that Wellnhofer had incorrectly reconstructed the skull in 1975, mistaking the large eye sockets for the fenestrae antorbitales, skull openings that in most pterosaurs are larger than the orbits but in Anurognathus are small and together with the nostrils placed at the front of the flat snout. The eyes pointed forwards to a degree, providing some binocular vision. Most of the skull consisted of bone struts. The presumed pygostyle was absent; investigating the real nine tail vertebrae instead of impressions showed that they were unfused, though very reduced. The wing finger lacked the fourth phalanx. According to Bennett a membrane, visible near the shin, showed that the wing contacted the ankle and was thus rather short and broad. Bennett also restudied the holotype, interpreting bumps on the jaws as an indication that hairs forming a protruding bristle were present on the snout.[5]
According to Döderlein Anurognathus was, with its long wings, a swift flyer, surprising its prey, similar to the modern nightjar. Bennett, however, infers from the discovery of the true shorter size of the wings, combined with the short tail, that it was a slower flying predator, specialised in hunting by manoeuvrability, its large eyes adapted to a crepuscular way of life. This would also be supported by a very large flexibility of the wing finger joints.
Researcher Chris Bennett published a paper in 1995[7] that looked into the growth rates of pterosaurs. With the fossils found of Rhamphorhynchus, he was able to see that all bones that were preserved on few-day-old species were very hard from ossifications just as would be seen with adults. This developmental stage was rapidly progressing compared to that of modern-day birds. This would lead to the young pterosaurs being less dependent on their parents or for shorter durations and be able to fly away sooner at an earlier stage compared to how we see in modern-day birds.
Habib and Witton[8] also went in to describe how insectivory evolved with pterosaurs, just like what is seen with Anurognathus ammoni and Dendrorhynchoides curvidentatus, and how that relates to their functional morphology. They explained that with the great locomotion and flexibility that their wings showed, Anurognathus ammoni, Dendrorhynchoides curvidentatus, and some other small species, were able to catch insects and maneuver between low areas and potentially around/under trees. When predicting the gape measurements for these small pterosaurs, they used measurements of the premaxillary tip all the way to the jaw tips and then the width between the sections as references. They predicted 1734mm^2 for the estimated gaps provided from the holotype of Anurognathus, Dendrorhynchoides, and Jeholopterus. The research team ended up concluding that consumed prey would have to be very small in length, around 11 mm total.
^Döderlein, L. (1923). "Anurognathus Ammoni, ein neuer Flugsaurier". Sitzungsberichte der Mathematisch-Naturwissenschaftlichen Abteilung der Bayerischen Akademie der Wissenschaften zu München, 1923, 306-307.
^Unwin, David M. (2006). The Pterosaurs: From Deep Time. New York: Pi Press. p. 246. ISBN0-13-146308-X.
^ abIngrid Cranfield (ed.). "Anurognathus". The Illustrated Directory of Dinosaurs and Other Prehistoric Creatures. London: Salamander Books. pp. 292–295.
^Witton, M.P. (2008) "A new approach to determining pterosaur body mass and its implications for pterosaur flight". ZittelianiaB28: 143-159
^Bennett, S. C. (2007). "A second specimen of the pterosaur Anurognathus ammoni", Paläontologische Zeitschrift, 81: 376-398
^Bennett S. C. (1995). "A statistical study of Rhamphorhynchus from the Solnhofen Limestone of Germany: Year-classes of a single large species". Journal of Paleontology. 69: 569–580
^Habib, M., & Witton, M. (n.d.). Early Pterosaurs and Dimorphodontidae PTEROSAURIA > PREONDACTYLUS DIMORPHODONTIDAE. Pterosaurs, 74-76.