Abstract
During the Mesozoic, one of the most significant evolutionary processes was the secondary adaptation of tetrapods to life in water. Several non-related lineages invaded from the terrestrial realms and from the oceans of the entire world. Among these lineages, ichthyosaurs were particularly successful. Advance parvipelvian ichthyosaurs were the first tetrapods to evolve a fish-shaped body profile. The deep skeletal modifications of their bodies, as well as their biology, depict advance ichthyosaurs as the paradigm of secondary adaptation of reptiles to marine life. Functional inferences point to them as off-shore cruising forms, similar to a living tuna, and some of them were capable of deep diving. Bone histology of some genera such as Temnodontosaurus, Stenopterygius, Ichthyosaurus, and Caypullisaurus, characterized by overall cancellous bone, is consistent with the idea of a fish-shaped ichthyosaurs as fast and far cruisers. Here, we provide histological examination of the ribs of the Middle Jurassic parvipelvian Mollesaurus. Contrasting with the bone histology of other parvipelvian, Mollesaurus ribs are characterized by a compact and thick cortex. Our data indicate that the rib cage was heavy and suggest that not all advanced ichthyosaurs were fast cruisers. The compact and dense ribs in these parvipelvian show that advance ichthyosaurs were ecologically more diverse than previously thought and that the lightening of the skeleton reversed, as also occurred in the evolution of cetacean, at least once along the evolutionary history of ichthyosaurs.
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References
Abramoff MD, Magelhaes PJ, Ram SJ (2004) Image processing with ImageJ. Biophoton Int 11:36–42
de Buffrénil V, Mazin JM (1990) Bone histology of the ichthyosaurs: comparative data and functional interpretation. Paleobiology 16:435–447
de Buffrénil V, de Ricqlès A, Ray C, Domning D (1990) Bone histology of the ribs of the archaeocetes (Mammalia: Cetacea). J Vertebr Paleontol 10:455–466
de Buffrénil V, Canoville A, D'Anastasio R, Domning P (2010) Evolution of sirenian pachyosteosclerosis, a model-case for the study of bone structure in aquatic tetrapods. J Mamm Evol 17:101–120
de Ricqlès A, de Buffrénil V (2001) Bone histology, heterochronies and the return of tetrapods to life in water: where are we? In: Mazin J-M, de Buffrénil V (eds) Secondary adaptation to life in water. Verlag Dr. F. Pfeil, München, pp 289–306
Fernández M (1997) A new ichthyosaur from the Tithonian (Late Jurassic) of the Neuquén Basin, northwestern Patagonia, Argentina. J Paleontol 71:479–484
Fernández M (1999) A new ichthyosaur from the Los Molles Formation (Early Bajocian), Neuquén Basin, Argentina. J Paleontol 73:677–681
Fischer V, Clément A, Guiomar M, Godefroit P (2011) The first definite record of a Valanginian ichthyosaur and its implications on the evolution of post-Liassic Ichthyosauria. Cretac Res 32:155–163
Gray M, Kainec K, Mandar S, Tomko L, Wolfe S (2007) Sink or swim? Bone density as a mechanism for buoyancy control in early cetaceans. Anat Rec 290:638–653
Houssaye A (2009) “Pachyostosis” in aquatic amniotes: a review. Integr Zool 4:325–340
Houssaye A, Bardet N (2011) Rib and vertebral microanatomical characteristics of hydropelvic mosasauroids. Lethaia. doi:10.1111/j.1502-3931.2011.00273.x
Kiprijanoff W (1881) Studien über die fossilen Reptilien Russlands. Theil 1. Gattung Ichthyosaurus König aus dem Sewerischen Sandstein oder Osteolith der Kreide-Gruppe. Mém Acad Imp des Sci Saint-Pétersbourg 28:1–103
Kolb C, Sánchez-Villagra M, Scheyer T (2011) The palaeohistology of the basal ichthyosaur Mixosaurus Baur, 1887 (Ichthyopterygia, Mixosauridae) from the Middle Triassic: palaeobiological implications. C R Palevol 10:403–411
Lopuchowycz VB, Massare JA (2002) Bone microstructure of a cretaceous ichthyosaur. Paludicola 3:139–147
Massare J (1988) Swimming capabilities of Mesozoic marine reptiles: implications for method of predation. Paleobiology 14:187–205
Motani R (2002) Scaling effects in caudal fin kinematics: implication for ichthyosaurian speed. Nature 415:309–312
Motani R (2005) Evolution of fish-shaped reptiles (Reptilia: Ichthyopterygia) in their physical environments and constraints. Annu Rev Earth Planet Sci 33:395–420
Motani R (2009) The evolution of marine reptiles. Evo Edu Outreach 2:224–235
Motani R (2010) Warm-blooded “sea dragons?”. Science 328:1361–1362
Nakajima Y (2008) Growth strategies in early ichtchyosaurs: an osteohistological study. J Vertebr Paleontol 28(3 suppl):44A
Street H, O'Keefe F (2010) Evidence of pachyostosis in the cryptocleidoid plesiosaur Tatenectes laramiensis from the Sundance Formation of Wyoming. J Vertebr Paleontol 30:1279–1282
Talevi M, Fernández M, Salgado L (2011) Variación ontogenética en la histología ósea de Caypullisaurus bonapartei Fernández, 1997 (Ichthyosauria: Ophthalmosauridae). Ameghiniana, 48: in press
Taylor M (2000) Functional significance of bone ballast in the evolution of buoyancy control strategies by aquatic tetrapods. Hist Biol 14:15–31
Acknowledgments
We thank A. Garrido (Museo Olsacher, Argentina) and M. Reguero (Museo de La Plata, Argentina) for the provision of the material. This study was partially supported by PIP 0426, UNLP N 607, and PICT 0261.
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Communicated by: Robert Reisz
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Talevi, M., Fernández, M.S. Unexpected skeletal histology of an ichthyosaur from the Middle Jurassic of Patagonia: implications for evolution of bone microstructure among secondary aquatic tetrapods. Naturwissenschaften 99, 241–244 (2012). https://doi.org/10.1007/s00114-012-0886-4
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DOI: https://doi.org/10.1007/s00114-012-0886-4