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COMMENTARY
Mesozoic aviary takes form

Alan Feduccia ^*

Department of Biology, University of North Carolina, Chapel Hill, NC 27599-3280

When I attempted a modern synthesis of avian evolution in 1980 (1), I told the then science editor at Harvard University Press that I thought the information on avian evolution was coming in so sluggishly that there would be little need for a quick revision. Was I ever wrong! By the early 1980s, the revelation of the presence of volant paleognaths in the Northern hemisphere Paleogene (2) provided compelling evidence that ratites were not ancient passengers on drifting continents, but the product of a post-Cretaceous–Tertiary radiation from ancestors that for the most part flew to their respective continents. In the same year, an initially muted epiphany appeared with the dramatic discovery by Cyril Walker (3) of the existence of a completely unknown subclass of Mesozoic birds, which he called the enantiornithines, or opposite birds, so-called because the fusion of their tarsal elements was the opposite of that of ornithurine (modern-type) birds; they also possess a distinctive arrangement of the bones of the shoulder girdle and a unique sternum. The story of Mesozoic birds became complicated by the discovery in 1985, by Russian colleague Evgeny Kurochkin (4), of Ambiortus, a Lower Cretaceous archaic but modern-type ornithurine (carinate) bird with an advanced flight apparatus. However, Walker's discovery was followed by the discovery of additional enantiornithine or opposite birds from the Lower Cretaceous of Spain (5). In addition, at the 1992 meeting of the Society of Avian Paleontology and Evolution in Frankfurt, Germany, a young Chinese paleontology graduate student appeared for the first time and dazzled the conference participants with discoveries of a major radiation of opposite birds from the Early Cretaceous of China, represented by some 20 individual specimens belonging to at least three distinctive taxa. Zhonghe Zhou's discovery (6) was to lead the way to one of the most dramatic breakthroughs in avian evolution that followed during the ensuing years.

This window on the Early Cretaceous via the Chinese Jehol Biota ranks with only a handful of such deposits, including the Late Jurassic Solnhofen Limestone, that has given us relatively complete pictures of the biota of a particular time in the past and has revealed a relatively complete fauna of the world of the Early Cretaceous (7). In a recent issue of PNAS, Zhou continued his remarkable discoveries with colleague Fucheng Zhang (8), describing one of the most dramatic discoveries from the Chinese Early Cretaceous, a complete skeleton of Hongshanornis, the earliest known beaked ornithurine bird (archaic but modern-type bird), coeval with opposite birds (enantiornithines) from the same deposit. Hongshanornis was a small bird with strong flying capability and shows again the antiquity of modern avian flight architecture, only some 20 or so million years after the earliest known bird, the urvogel Archaeopteryx, as well as size reduction characteristic of more modern lineages.

View larger version (21K): [in this window] [in a new window]   Fig. 1. Simplified diagram of putative phylogenetic relationships of the major groups of the Mesozoic aviary discussed here (and excluding the more problematic avian microraptors and flightless bird Caudipteryx). The time of branching of the ornithurines remains a major question. (Modified from ref. 15.)

These two major clades of the Age of Reptiles were also distinctive in many other ways, and notably studies of long-bone histology show that enantiornithines and more basal birds still retained growth rings, grew slowly, and were likely ectothermic to a large degree. In contrast, the bone histology of Cretaceous ornithurines is similar to that of modern birds, devoid of growth rings (13). Such bone growth is suggestive of an endothermic physiology, a corollary of strong flight and migratory ability, perhaps associated with a shore-line habitat in Cretaceous ornithurines. Interestingly, Hongshanornis shows skeletal features that indicate a shore-dwelling habitat, conforming to what we know of many of the other Mesozoic ornithurines, especially the late Cretaceous ichthyornithiforms and hesperornithiforms. All but one of the enantiornithines is known from lacustrine or terrestrial habitats. Although speculative, it may be that the advanced physiology of ornithurines (advanced flight capability and endothermy) adapted this clade for the physiologically demanding shore-line ecosystem. Physiological differences may also explain why the enantiornithines became extinct along with the dinosaurs at the end of the Cretaceous, whereas the ornithurines by the end of the Cretaceous had produced the font of the modern, post-Cretaceous–Tertiary, avian radiation.

It is also clear that teeth were reduced and replaced by a beak several times in the Cretaceous ornithurines, as well as in some primitive lineages (Confuciusornis). In addition, another revelation is that Early Cretaceous ornithurines possessed a predentary bone in front of the dentaries, previously known only in late Cretaceous ornithurines (ichthyornithiforms and hesperornithiforms), and this character is very likely a synapomorphy of the clade, although it is also an independent character uniting the dinosaurian clade Ornithischia.

To date, there is simply no evidence, either structural or biological, for the existence of any form of protofeather (14). Nevertheless, thanks to the careful work of Zhou and Zhang (8) and others, the field of Mesozoic birds has made great strides, and the current discovery will go a long way toward clarifying what has been a murky picture of the avian past. We can now minimally say that the aviary of the Age of Reptiles comprised a number of basal groups, but was characterized by two major clades, the archaic land birds or enantiornithines (opposite birds), and the primitive ornithurines (birds of modern aspect), the totality of which produced an ancient adaptive radiation with a surprising morphological diversity, analogous in many respects to the diversity of modern birds.

Footnotes

A.F. wrote the paper.

Conflict of interest statement: No conflicts declared.

See companion article on page 18998 in issue 52 of volume 102.

^* E-mail: feduccia{at}bio.unc.edu.

© 2006 by The National Academy of Sciences of the USA

References

1. Feduccia, A. (1980) The Age of Birds (Harvard Univ. Press, Cambridge, MA).
2. Houde, P. & Olson, S. L. (1981) Science 214, 1236–1237.[Abstract/Free Full Text]
3. Walker, C. A. (1981) Nature 292, 51–53.[CrossRef]
4. Kurochkin, E. N. (1985) Cretaceous Res. 6, 271–278.
5. Sanz, J. L. & Bonaparte, J. F. (1992) in A New Order of Birds (Class Aves) from the Lower Cretaceous of Spain, Los Angeles County Museum of Science Series, ed. Campbell, K. E. (Los Angeles County Museum of Science, Los Angeles), Vol. 36, pp. 39–49.
6. Zhou, Z. (1995) Cour. Forschungsinst. Senckenberg 181, 9–22.
7. Chang, M.-M. (2003) The Jehol Biota: The Emergence of Feathered Dinosaurs, Beaked Birds, and Flowering Plants (Shanghai Scientific and Technical Publishers, Shanghai).
8. Zhou, Z. & Zhang, F. (2005) Proc. Natl. Acad. Sci. USA 102, 18998–19002.[Abstract/Free Full Text]
9. Martin, L. D. (1983) in Perspectives in Ornithology, eds. Brush, A. H. & Clark, G. A., Jr. (Cambridge Univ. Press, Cambridge, U.K.), pp. 291–338.
10. Martin, L. D. (1995) Cour. Forschungsinst. Senckenberg 181, 23–36.
11. Martin, L. D. & Zhou, Z. (1997) Nature 389, 556.
12. Clarke, J. A. & Norell, M. A. (2002) Am. Mus. Novitates 3387, 1–46.
13. Chinsamy-Turan, A. (2005) The Microstructure of Dinosaur Bone (John Hopkins Univ. Press, Baltimore).
14. Feduccia, A., Lingham-Soliar, T. & Hinchliffe, J. R. (2005) J. Morphol. 266, 125–166.[Medline]
15. Zhou, Z. (2004) Naturwissenschaften 91, 455–471.[CrossRef][ISI][Medline]

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