Abstract
The great majority of researchers concur that the presence of dinosaurs near the poles of their time are part of a large body of evidence that all Cretaceous dinosaurs had elevated metabolic rates more like their avian subbranch and mammals than low-energy reptiles. Yet a few still propose that nonavian dinosaurs were bradyenergetic ectothermic reptiles, and migrated away from the polar winters. The latter is not biologically possible because land animals cannot and never undertake very long seasonal migrations because the cost of ground locomotion is too high even for long limbed, tachyenergetic mammals to do so, much less low-energy reptiles. Nor was it geographically possible because marine barriers barred some polar dinosaurs from moving towards the winter sun. The presence of external insulation on some dinosaurs both strongly supports their being tachyenergetic endotherms and helps explain their ability to survive polar winters that included extended dark, chilling rains, sharp frosts, and blizzards so antagonistic to reptiles that the latter are absent from some locations that preserve dinosaurs including birds and mammals. The hypothesis that nonavian dinosaurs failed to survive the K/Pg crisis because they had reptilian energetics is illogical not only because they did not have such metabolisms, but because many low-energy reptiles did survive the crisis. The global super chill that apparently plagued K/Pg dinosaurs should have seriously impacted dinosaurs at all latitudes, but does not entirely readily explain their loss because some avian dinosaurs and other land tetrapods did survive. High- as well as low-latitude dinosaurs add to the growing evidence that high-energy endothermy has been a common adaptation in a wide variety of vertebrates and flying insects since the late Paleozoic.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amiot R, Lecuyer C, Buffetaut E, Escarguel G, Fluteau F, Martineau F (2006) Oxygen isotopes from biogenic apatites suggest widespread endothermy in Cretaceous dinosaurs. Earth Planet Sci Lett 246:41–54
Amiot R, Xu W, Zhinge Zm Xiaolin W, Buffataut Em Lecuyer C, Zhongli D, Fluteau F, Tsuyoshi H, Nao K, Jinyao M, Suteethorn V, Yauanging W, Xing X, Fusong Z (2011) Oxygen isotopes of east Asian dinosaurs reveal exceptionally cold Early Cretaceous climates. Proc Natl Acad Sci USA 108:5179–5183
Bakker R (1968) The superiority of dinosaurs. Discovery 3:11–22
Bakker R (1971) Dinosaur physiology and the origin of mammals. Evolution 25:636–658
Bakker R (1972) Anatomical and ecological evidence of endothermy in dinosaurs. Nature 238:81–85
Bakker R (1975) Dinosaur renaissance. Sci Amer 232(4):58–78
Bakker R, Zoehfeld K, Temple D, Flis C (2016) Endothermy acquired: tracks and productivity efficiency show elevated energy consumption during origin of dinosaurs and advanced therapsids. In: Soc Vert Paleont 76th Ann Meet Abstracts, p. 91
Barrick R, Stoskopf M, Showers W (1997) Oxygen isotopes in dinosaur bone. In: Farlow J, Brett-Surman M (eds) The complete dinosaur. Indiana University Press, Bloomington, pp 474–490
Bell P, Snively E (2008) Polar dinosaurs on parade: a review of dinosaur migration. Alcheringa 32:271–284
Bernal D, Donley M, Shadwick R, Syme D (2005) Mammal-like muscles power swimming in a cold-water shark. Nature 437:1349–1352
Bernard A, Lécuye C, Vincent P, Amiot R, Bardet N, Buffetaut E, Cuny G, Fourel F, Martineau F, Mazin Q, Prieur A (2010) Regulation of body temperature by some Mesozoic marine reptiles. Science 328:1379–1382
Brill R, Bushnell P (2001) The cardiovascular system of tunas. Fish Physiol 19:79–120
Brouwers E, Clemens W, Spicer R, Ager T, Carter L, Sliter W (1987) Dinosaurs on the North Slope, Alaska: high latitude, latest Cretaceous environments. Science 237:1608–1610
Brugger J, Feulner G, Petri S (2017) Baby, it’s cold outside: climate model simulations of the effects of the asteroid impact at the end of the Cretaceous. Geophys Res Lett 44:419–427
Carrier D, Farmer C (2000) The evolution of pelvic aspiration in archosaurs. Paleobiology 26:271–293
Chinsamy A, Thomas D, Tumarkan-Deratzian A, Fiorillo A (2012) Hadrosaurs were perennial polar residents. Anat Rec 295:610–614
Clarke A (2013) Dinosaur energetics: setting the bounds on feasible physiologies and ecologies. Am Nat 182:283–297
Clemens WA, Nelms LG (1993) Paleoecological implications of Alaskan terrestrial vertebrate fauna in latest Cretaceous time at high paleolatitudes. Geology 21(6):503–506
Constantine A, Chinsamy A, Vickers-Rich P, Rich T (1998) Periglacial environments and polar dinosaurs. S Afr J Sci 94:137–141
Crichton M (1990) Jurassic park. Knopf, New York
Desmond A (1976) The hot-blooded dinosaurs. The Dial Press, New York
Eagle R, Tutken T, Martin T, Tripati A, Fricke H, Connely M, Cifelli R, Eiler J (2011) Dinosaur body temperatures determined from isotopic ordering in fossil biominerals. Science 333:443–445
Erickson G, Brochu C (1999) How the ‘terror crocodile’ grew so big. Nature 398:205–206
Erickson G, Druckenmiller P (2011) Longevity and growth rate estimates for a polar dinosaur: a Pachyrhinosaurus specimen from the North Slope of Alaska showing a complete developmental record. Hist Biol 23:327–334
Erickson G, Curry Rogers K, Yerby S (2001) Dinosaurian growth patterns and rapid avian growth rates. Nature 412:429–433
Erickson G, Makovicky P, Inouye B, Chang-Fu Z, Ke-Qin G (2009a) A life table for Psittacosaurus lujiatuensis: initial insights into ornithischian population biology. Anat Rec 292:1514–1521
Erickson G, Rauhut O, Zhou Z, Turner A, Inouye B, Ho D, Norell M (2009b) Was dinosaurian physiology inherited by birds? Reconciling slow growth in Archaeopteryx. PLoS ONE 4:e7390
Erickson G, Zelenitsky D, Kay D, Norell M (2017) Dinosaur incubation periods directly determined from growth-line counts in embryonic teeth show reptilian-grade development. Proc Natl Acad Sci USA 114:540–545
Fancy S, Pank L, Whitten K, Regelin W (1989) Seasonal movements of caribou in Arctic Alaska as determined by satellite. Canad J Zool 67:644–650
Farmer C, Sander K (2010) Unidirectional airflow in the lungs of alligators. Science 327:338–340
Fiorillo A (2004) The dinosaurs of arctic Alaska. Sci Amer 291:84–91
Fiorillo A, Gangloff R (2001) The caribou migration model for Arctic hadrosaurs: a reassessment. Hist Biol 15:323–334
Fiorillo A, Tykoski R (2012) A new Maastrichtian species of the centrosaurine ceratopsid Pachyrhinosaurus form the North Slope of Alaska. Acta Palaeontol Pol 57:561–573
Fiorillo A, Tykoski R (2014) A diminutive new tyrannosaur from the top of the world. PLoS ONE 9:e91287
Fricke H, Rogers R (2000) Multiple taxon-multiple locality approach to providing oxygen isotope evidence for warm-blooded theropod dinosaurs. Geology 28:799–802
Gangloff R (2012) Dinosaurs under the aurora. Indiana University Press, Bloomington
Godefroit P, Golovneva L, Shchepetov S, Garcia G, Alekseev P (2008) The last polar dinosaurs in Russia. Naturwissen 96:459–501
Grady J, Enquist B, Dettweller-Robinson E, Wright N, Smith F (2014) Evidence for mesothermy in dinosaurs. Science 344:1268–1272
Graham J, Dickson K (2004) Tuna comparative physiology. J Exp Biol 207:4015–4024
Grellet-Tinner G, Fiorelli L (2010) A new Argentinean nesting site showing neosauropod dinosaur reproduction in a Cretaceous hydrothermal environment. Nat Comm 1:32. doi:10.1038/ncomms1031
Harrell T, Perez-Huerta A, Suarez C (2016) Endothermic mosasaurs? Possible thermoregulation of Late Cretaceous mosasaurs indicated by stable oxygen isotopes in fossil bioapatite marine fish and pelagic seabirds. Palaeont 59:351–363
Heinrich B (1993) The hot-blooded insects. Harvard University Press, Cambridge
Horner J, Padian K (2004) Age and growth dynamics of Tyrannosaurus rex. Proc R Soc Lond B 271:1875–1880
Huttenlocker A, Farmer C (2017) Bone microvasculature tracks red blood cell size diminution in Triassic mammal and dinosaur forerunners. Curr Biol 27:1–7
Kohler M, Marin-Moratalla N, Jordana X, Aanes R (2012) Seasonal bone growth and physiology in endotherms shed light on dinosaur physiology. Nature 487:358–361
Lewy Z (2015) How the Deccan vulcanism and the Chicxulub asteroid impact resulted in the biological crisis ending the Mesozoic era. J Geogr Environ Earth Sci Int 3:1–11
Lewy Z (2016) Dinosaur demise in light of their alleged perennial polar residency. Int J Earth Sci. doi:10.1007/s00531-016-1426-9
Martin A (2009) Dinosaur burrows in the Otway Group of Victoria, Australia, and their relation to Cretaceous polar environments. Cret Res 30:1223–1237
McNab B (2009) Resources and energetics determined dinosaur body size. Proc Natl Acad Sci USA 106:12188–12189
Molnar R, Wiffen J (1994) A Late Cretaceous polar dinosaur fauna from New Zealand. Cret Res 15:689–706
Organ C, Shedlock A, Meade A, Pagel M, Edwards S (2007) Origin of avian genome size and structure in non-avian dinosaurs. Nature 446:180–184
Ostrom J (1970) Terrestrial vertebrates as indicators of Mesozoic climates. N Am Paleontol Conv Proc D: 347-376
Padian K, Ricqles A, Horner J (2001) Dinosaurian growth rates and bird origins. Nature 412:405–408
Paul G (1988) Physiological, migratorial, climatological, geophysical, survival and evolutionary implications of Cretaceous polar dinosaurs. J Palaeont 62:640–652
Paul G (1994) Physiology and migration of North Slope dinosaurs. In: Thurston D, Fujita K (eds) 1992 Proceedings International Conference on Arctic Margins. Anchorage: U.S. Department of the Interior, pp 405–408
Paul G (2002) Dinosaurs of the air. The Johns Hopkins University Press, Baltimore
Paul G (2012) Evidence for avian-mammalian aerobic capacity and thermoregulation in Mesozoic dinosaurs. In: Farlow J (ed) The complete dinosaur, 2nd edn. Indiana University Press, Bloomington, pp 819–872
Paul G (2013) How far did dinosaurs really migrate? J Exp Biol 216:3762
Perry S, Christian A, Breuer T, Pajor N, Codd J (2009) Implications of an avian-style respiratory system for gigantism in sauropod dinosaurs. J Exp Zool 311A:600–610
Pontzer H, Allen V, Hutchinson J (2009) Biomenchanics of running indicates endothermy in bipedal dinosaurs. PLoS ONE 4:e7783
Priede I (1985) Metabolic scope in fishes. In: Tyler P, Calow P (eds) Fish energetics: new perspectives. The Johns Hopkins University Press, Baltimore, pp 33–64
Reid E (2012) “Intermediate” dinosaurs: the case updated. In: Farlow J (ed) The complete Dinosaur, 2nd edn. Indiana University Press, Bloomington, pp 873–921
Rich T, Vickers-Rich P (2001) Dinosaurs of darkness. Indiana University Press, Bloomington
Rich P, Rich T, Wagstaff B, Mason J, Douthitt C, Gregory R, Felton E (1988) Evidence for low temperatures and biologic diversity in Cretaceous high latitudes of Australia. Science 242:1403–1406
Ricqles A (1976) On bone histology of fossil and living reptiles, with comments on its functional and evolutionary significance. In: Cox B, Bellairs A (eds) Morphology and biology of reptiles. Academic Press, London, pp 123–149
Ricqles A, Padian K, Knoll F, Horner J (2008) On the origin of high growth rates in archosaurs and their ancient relatives: complementary histological studies on Triassic archosauriforms and the problem of a “phylogenetic signal” in bone histology. Ann Paleont 94:57–76
Ruben J, Jones T, Geist N, Hillenius W, Harwell A, Quick D (2012) Metabolic physiology of dinosaurs and early birds. In: Farlow J (ed) The complete dinosaur, 2nd edn. Indiana University Press, Bloomington, pp 785–818
Russell D (1990) Mesozoic vertebrates of Arctic Canada. In: Harington C (ed) Canada’s missing dimension: science and history in the Canadian Arctic islands, vol 1. Canadian Museum of Nature, Ottawa, pp 81–90
Sander P, Christian A, Clauss W, Fechner R, Gee C, Griebler E, Gunga H, Hummel J, Mallison H, Perry S, Preuschoft H, Rauhut O, Remes K, Tutken T, Wings O, Witzel U (2011) Biology of the sauropod dinosaurs: the evolution of gigantism. Biol Rev 86:117–155
Schweitzer M, Marshall C (2001) A molecular model for the evolution of endothermy in the theropod-bird lineage. J Exp Zool 291:317–338
Seymour R (2013) Maximal aerobic and anaerobic power generation in large crocodiles versus mammals: implications for dinosaur gigantothermy. PLoS ONE 8:e69361
Seymour R (2016) Cardiovascular physiology of dinosaurs. Physiology 31:430–441
Seymour R, Lillywhite H (2000a) Hearts, necks posture and metabolic intensity of sauropod dinosaurs. Proc Royal Soc Lond B 267:1883–1887
Seymour R, Lillywhite H (2000b) Hearts, neck posture and metabolic intensity of sauropod dinosaurs. Nature 264:664–666
Seymour R, Bennett-Stamper C, Johnston S, Carrier D, Grigg G (2004) Evidence for endothermic ancestors of crocodiles at the stem of archosaur evolution. Physiol Biochem Zool 77:1051–1067
Seymour R, Smith S, White C, Henderson D, Schwarz-Wings D (2012) Blood flow to long bones indicates activity metabolism in mammals, reptiles and dinosaurs. Proc Biol Sci 279:451–456
Shelton C, Sander P (2017) Long bone histology of Ophiacodon reveals the geologically earliest occurrence of fibrolamellar bone in the mammalian stem lineage. Comptes Rend Palevol. doi:10.1016/j.crpv.2017.02.002
Spicer R, Herman A (2010) The Late Cretaceous environment of the Arctic: a quantitative reassessment based on plant fossils. Paleogeog Palaeoclim Palaeoecol 295:423–442
Spicer R, Herman A, Amiot R, Spicer T (2016) Environmental adaptations and constraints on latest Cretaceous Arctic dinosaurs. Global Geol 19:187–204
Teitelbaum C et al (2015) How far to go? Determinants of migration distance of distance in land mammals. Ecol Lett 18:545–552
Thompson G (1995) Foraging patterns and behaviours, body postures and movement speed for Varanus gouldii, in a semi-urban environment. J Royal Soc Wes Aust 78:107–114
Varricchio D, Jackson F (2016) Reproduction in Mesozoic birds and evolution of the modern avian reproductive mode. Auk 133:654–684
Vavrek M, Hills L, Currie P (2014) A hadrosaurid from the Late Cretaceous Kanguk Formation of Axel Heiberg Island, Nunavut, Canada, and its ecological and geographical implications. Arctic 67:1–9
Wegner NC, Snodgrass OE, Dewar H, Hyde JR (2015) Whole-body endothermy in a mesopelagic fish, the opah, Lampris guttatus. Science 348(6236):786–789
Xu X et al (2012) A gigantic feathered dinosaur from the Lower Cretaceous of China. Nature 484:92–95
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Paul, G. Polar and K/Pg nonavian dinosaurs were low-metabolic rate reptiles vulnerable to cold-induced extinction, rather than more survivable tachyenergetic bird relatives: comment on an obsolete hypothesis. Int J Earth Sci (Geol Rundsch) 106, 2991–2998 (2017). https://doi.org/10.1007/s00531-017-1509-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00531-017-1509-2