Evolution of Sirenian Pachyosteosclerosis, a Model-case for the Study of Bone Structure in Aquatic Tetrapods (original) (raw)
Asagiri M, Takayanagi H (2007) The molecular understanding of osteoclast differentiation. Bone 40: 251–264 ArticleCASPubMed Google Scholar
Bénichou OD, Laredo JD, de Vernejoul MC (2000) Type II autosomal dominant osteopetrosis (Albers-Schönberg disease): clinical and radiological manifestations in 42 patients. Bone 26(1): 87–93 Google Scholar
Brandt A (1852) Dissertationes de ossificationis processu. Inaugural dissertation, Dorpat.
Buffrénil V de, Rage J-C (1993) La “ pachyostose ” vertébrale de Simoliophis (Reptilia, Squamata) : données comparatives et considérations fonctionnelles. Ann Paléontol 79: 315–335 Google Scholar
Buffrénil V de**,** Ricqlès A de, Ray CE, Domning DP (1990a) Bone histology of the ribs of the archaeocetes (Mammalia: Cetacea). J Vertebr Palentol 10(4): 455–466 Google Scholar
Buffrénil V de, Ricqlès A de, Sigogneau-Russell D, Buffetaut E (1990b) L’histologie osseuse des Champsosauridés : données descriptives et interprétations fonctionnelles. Ann Paléontol 76(4): 255–275 Google Scholar
Buffrénil V de, Schoevaert D (1988) On how the delphinid humerus becomes cancellous: ontogeny of a histological specialization. J Morphol 198: 146–164 Google Scholar
Buffrénil V de, Schoevaert D (1989) Données quantitatives et observations histologiques sur la pachyostose du squelette du dugong, Dugong dugon (Müller) (Sirenia, Dugongidae). Can J Zool 67: 2107–2119 Google Scholar
Castanet J (2006) Time recording in bone microstructures of endothermic animals. CR Palevol 5: 629–636 Article Google Scholar
Cave AJE, Aumonier FJ (1967) Observations on dugong histology. Quart J Roy Microsc Soc 87: 113–121 CAS Google Scholar
Cubo J (2000) Process heterochronies in endochondral ossification. J Theor Biol 205: 343–353 ArticleCASPubMed Google Scholar
D’Anastasio R (2004) Idiopathic hyperostosis: epidemiology and phylogeny. J Paleopathol 16(3): 133–145 Google Scholar
Domning DP (1978) Sirenian evolution in the North Pacific Ocean. Univ Calif Publ Geol Sci 118: 1–176 Google Scholar
——— (1994) A phylogenetic analysis of the Sirenia. In: Berta A, Demere TA (eds) Contributions in Marine Mammal Paleontology Honoring Frank C. Whitmore, Jr. Proc San Diego Soc Nat Hist, San Diego, pp 177–189
——— (2000) The readaptation of Eocene sirenians to life in water. Hist Biol 14(1–2): 115–119 Article Google Scholar
——— (2001b) Evolution of the Sirenia and Desmostylia. In: Mazin J-M, Buffrénil V de (eds) Secondary Adaptation of Tetrapods to Life in Water. Verlag Dr. F. Pfeil, München, pp 151–168
——— (2001c) Sirenians, seagrasses, and Cenozoic ecological change in the Caribbean. In: Miller W III, Walker SE (eds) Cenozoic Palaeobiology: The Last 65 Million Years of Biotic Stasis and Change. Palaeogeogr, Palaeoclimatol, Palaeoecol 166(1–2): 27–50
——— (2002) Sirenian evolution. In: Perrin WF, Wursig B, Thewissen JGM (eds) Encyclopedia of Marine Mammals. Academic Press, London, New York, pp 1083–1086 Google Scholar
Domning DP, Aguilera OA (2008) Fossil Sirenia of the west Atlantic and Caribbean region. VIII. Nanosiren garciae gen. et sp. nov. and Nanosiren sanchezi, sp. nov. J Vertebr Paleontol 28(2): 479–500 Article Google Scholar
Domning DP, Buffrénil V. de (1991) Hydrostasis in the Sirenia : quantitative data and functional interpretations. Mar Mamm Sci 7(4): 331–368 Google Scholar
Domning DP, Myrick AC Jr (1980) Tetracycline marking and the possible layering rate of bone in the Amazonian manatee (Trichechus inunguis). In: Perrin WF, Myrick AC Jr (eds) Age Determination of Toothed Whales and Sirenians. Rep Int Whal Commn (Special Issue 3): 203–207
Fawcett DW (1942) The amedullary bones of the Florida manatee (Trichechus latirostris). Am J Anat 71: 27–309 Article Google Scholar
Francillon-Vieillot H, Buffrénil V de, Castanet J, Geraudie J, Meunier FJ, Sire JY, Zylberberg L, Ricqlès A de (1990) Microstructures and mineralization of vertebrate skeletal tissues. In: Carter J (ed) Skeletal Biomineralizations: Patterns, Processes and Evolutionary Trends 1. Van Nostrand Reinhold, New York, pp 471–530
Gallivan GJ, Best RC, Kanwisher JW (1983) Temperature regulation in the Amazonian manatee, Trichechus inunguis. Physiol Zool 56: 255–262 Google Scholar
Gingerich PD, Domning DP, Blane CE, Uhen MD (1994) Cranial morphology of Protosiren fraasi (Mammalia, Sirenia) from the middle Eocene of Egypt: a new study using computed tomography. Mus Paleontol Univ Mich 29(2): 41–67 Google Scholar
Girondot M, Laurin M (2003) Bone profiler: a tool to quantify, model, and statistically compare bone-section compactness profiles. J Vertebr Paleontol 23(2): 458–461 Article Google Scholar
Gray NM, Kimberly K, Madar S, Tomko L, Wolfe S (2007) Sink or swim? Bone buoyancy control in early cetaceans. Anat Rec 290(6): 638–653 Article Google Scholar
Houssaye A, Buffrénil V de, Rage J-C, Bardet N (2008) An analysis of vertebral “pachyostosis” in Carentonosaurus mineaui (Mosasauroidea, Squamata) from the Cenomanian (early Late Cretaceous) of France, with comments on its phylogenetic and functional significance. J Vertebr Paleontol 28(3): 685–691 Google Scholar
Husar SL (1975) A review of the literature on the dugong (Dugong dugon). US Department of Interior Fish and Wildlife Service, Wildlife Research Report 4
Irvine AB (1983) Manatee metabolism and its influence on distribution in Florida. Biol Conserv 25: 315–334 Article Google Scholar
Kaiser HE (1960) Untersuchungen zur vergleichenden Osteologie der fossilen und rezenten Pachyostosen. Palaeontograph A 114(5–6): 113–196 Google Scholar
——— (1970) Das Abnorm in der Evolution. Acta Biotheor, suppl 9. E.J. Brill, Leyden.
Karsenty G (2007) The genetic transformation of bone biology. Genes Develop 13: 3037–3051 Article Google Scholar
Key LL Jr, Ries WL (2002) Osteopetrosis. In: Bilezikian JP, Raisz LG, Rodan GA (eds) Principles of Bone Biology, vol. 2. Academic Press, San Diego, pp 1217–1227 Google Scholar
Kiprijanoff AV (1881–1883) Studien über die fossilen Reptilien Russlands. Mém Acad Imp Sci Saint Petersbourg 7: 1–144 Google Scholar
Klevezal GA (1996) Recording Structures of Mammals: Determination of Age and Reconstruction of Life History. Balkema, Rotterdam. Google Scholar
Laurin M, Girondot M, Loth M-M (2004) The evolution of long bone microstructure and lifestyle in lissamphibians. Paleobiology 30(4): 589–613 Article Google Scholar
Madar SI (2007) The postcranial skeleton of early Eocene pakicetid cetaceans. J Paleontol 81(1): 176–200 Article Google Scholar
Marmontel M, O’Shea TJ, Kochman HI, Humphrey SR (1996) Age determination in manatees using growth-layer-counts in bone. Mar Mamm Sci 12(1): 54–88 Article Google Scholar
Marsh H (1980) Age determination of the dugong (Dugong dugon [Müller]) in Northern Australia and its biological implications. In: Perrin WF, Myrick AC (eds) Age Determination in Toothed Whales and Sirenians. Rep Int Whal Commn (Spec Issue 3): 181–201
Marsh H, Spain AV, Heinsohn GE (1978) Minireview. Physiology of the dugong. Comp Biochem Physiol A61: 159–168 Article Google Scholar
Meister W (1962) Histological structure of the long bones of penguins. Anat Rec 143: 377–386 ArticleCASPubMed Google Scholar
Nopcsa F von (1923) Vorläufige Notiz über die Pachyostose und Osteosklerose einiger mariner Wirbeltiere. Anat Anz 56: 353–359 Google Scholar
Nopcsa F von, Heidsieck E (1934) Über eine pachyostotische Rippe aus der Kreide Rügens. Acta Zool (Stockholm) 15: 431–455 Google Scholar
Parfitt AM (1982) The coupling of bone formation to bone resorption: a critical analysis of the concept and its relevance to the pathogenesis of osteoporosis. Metabol Bone Disease Rel Res 4: 1–6 ArticleCAS Google Scholar
Pilleri G, Biosca J, Via L 1989. The Tertiary Sirenia of Catalonia. Brain Anatomy Institute, University of Berne, Ostermundigen (Berne)
Popoff SN, Marks SC (1995) The heterogeneity of the osteopetroses reflects the diversity of cellular influences during skeletal development. Bone 17(5): 437–445 ArticleCASPubMed Google Scholar
Ricqlès A de (1975) Recherches paléohistologiques sur les os longs des tetrapods. VII.—Sur la classification, la signification fonctionnelle et l’histoire des tissus osseux des tétrapodes (première partie). Ann Paléontol (Vertébrés) 61: 51–129
——— (1989) Les mécanismes hétérochroniques dans le retour des tétrapodes au milieu aquatique. Geobios, mém spéc 12: 337–348 Google Scholar
Ricqlès A de, Buffrénil V de (1995) Sur la présence de pachyostéosclérose chez la rhytine de Steller [_Rhytina (Hydrodamalis) gigas_], sirénien récent éteint. Ann Sci Nat, Zool (13ème série) 16: 47–53
——— (2001) Bone histology, heterochronies and the return of tetrapods to life in water: where are we? In: Mazin J-M, Buffrénil V de (eds) Secondary Adaptation of Tetrapods to Life in Water. Verlag Dr. F. Pfeil, München, pp 289–306
Sander M, Andrassy P (2006) Lines of arrested growth and long bone histology in Pleistocene large mammals from Germany: what do they tell us about dinosaur physiology? Palaeontograph A 277: 143–159 Google Scholar
Sickenberg O (1931) Morphologie und Stammesgeschichte der Sirenen. Palaeobiologica 4: 405–444 Google Scholar
Stein BR (1989) Bone density and adaptation in semi-aquatic mammals. J Mammal 70(3): 467–476 Article Google Scholar
Väänanen HK, Laitala-Leinonen T (2008) Osteoclast lineage and function. Arch Biochem Biophys 473: 132–138 ArticlePubMed Google Scholar
Vernejoul MC de, Bénichou O (2001) Human osteopetrosis and other sclerosing disorders: recent genetic developments. Calcif Tissue Int 69: 1–6 Google Scholar
Wall WP (1983) The correlation between high limb-bone density and aquatic habits in Recent mammals. J Paleontol 57(2): 197–207. Google Scholar
Wiffen J, Buffrénil V de, Ricqlès A de, Mazin J-M (1995) Ontogenetic evolution of bone structure in Late Cretaceous Plesiosauria from New Zealand. Geobios 28 (5): 625–640 Google Scholar
Zalmout IS, Ul-Haq M, Gingerich P (2003) New species of Protosiren (Mammalia, Sirenia) from the early middle Eocene of Balochistan (Pakistan). Contrib Mus Pal Univ Michigan 31(3): 79–87 Google Scholar
Zangerl R (1935) Pachypleurosaurus edwardsi Cornalia. Osteologie, Variationsbreite, Biologie. Die Triasfauna der Tessiner Kalkalpen. Mém Soc Pal Suisse 56: 1–8 Google Scholar