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Extinction and re-evolution of similar adaptive types (ecomorphs) in Cenozoic North American ungulates and carnivores reflect van der Hammen's cycles

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Abstract

Numerous patterns in periodicity (e.g., climate, extinction, and sedimentary cycles) and evolutionary change (e.g., chronofaunas and coordinated stasis) have been described based on aspects of the geologic record. Recently, convergent occurrences of faunal types or "repeating faunas" have received attention, but a highly specific, iterative pattern was first reported over 40 years ago. In the late 1950s, van der Hammen described climatic/floral cycles on the order of six million years based on a succession of A, B, and C pollen community types in South America. These A–B–C cycles are also seen in the replacement pattern of particular carnivore and ungulate adaptive types in Cenozoic North America as reported by Martin in the 1980s. For example, in the last 36 million years, there were four iterations of a sabertooth cat ecomorph independently evolving, dominating the niche through an A–B–C cycle, and then going extinct. Here we show further support for the existence of these cycles in the dominance turnover in hippo and dog ecomorphs in the North American Cenozoic. Shared patterns of extinction and re-evolution of adaptive types among plants and mammals across two continents suggest a global mechanism, which appears to be climatic change. Iterative climatic cycles of various scales may form a predictive framework for understanding fundamental patterns in the geologic record, such as radiations, extinction, rates of change, convergence, and sedimentary cycles.

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Fig. 1.
Fig. 2A–C.

References

  • Benson RH, Chapman RE, Deck TL (1984) Paleoceanographic events and deep-sea ostracodes. Science 224:1334–1336

    Google Scholar 

  • Brett CE, Baird GC (1995) Coordinated stasis and evolutionary ecology of Silurian to Middle Devonian faunas in the Appalachian Basin. In: Erwin DH, Anstey RL (eds) New approaches to speciation in the fossil record. Columbia University Press, New York, pp 285–315

  • Burger D (1966) Palynology of uppermost Jurassic and lowermost Cretaceous strata in the eastern Netherlands. Leidse Geol Meded 35:206–276

    Google Scholar 

  • Damuth JD, Jablonski D, Harris JA, Potts R, Stucky RK, Sues H-D, Weishampel DB (1992) Taxon-free characterization of animal communities. In: Behrensmeyer AK, Damuth JD, DiMichele WA, Potts R, Sues H-D, Wing SL (eds) Terrestrial ecosystems through time. University of Chicago Press, Chicago, pp 183–203

  • d'Orbigny AD (1849) Cours elamentaire de paleontologie et de geologie stratigraphiques, vol 1. Masson, Paris

  • Eldredge N, Gould SJ (1972) Punctuated equilibria: an alternative to phyletic gradualism. In: Schopf TJM (ed) Models in paleobiology. Freeman and Cooper, San Francisco, pp 82–115

  • Fischer AG (1981) Climatic oscillations in the biosphere. In: Nitecki MH (ed) Biotic crises in ecological and evolutionary time. Academic Press, New York, pp 103–131

  • Hammen T van der (1957) Climatic periodicity and evolution of South American Maastrichtian and Tertiary floras. Bogotá Bol Geol 5(2):49–91

    Google Scholar 

  • Hammen T van der (1961) Upper Cretaceous and Tertiary climatic periodicities and their causes. N Y Acad Sci Ann 95:440–448

    Google Scholar 

  • Hammen T van der (1965) Paläoklima, Stratigraphie und Evolution. Geol Rundschau 54:428–441

    Google Scholar 

  • Krasilov V (1974) Causal biostratigraphy. Lethaia 7(3):173–179

    Google Scholar 

  • Krasilov V (1987) Periodicity in the development of life. Paleontol J 3:9–15

    Google Scholar 

  • Leidelmeyer P (1966) The Paleocene and lower Eocene pollen flora of Guyana. Leidse Geol Meded 38:49–70

    Google Scholar 

  • Martin LD (1985) Tertiary extinction cycles and the Pliocene-Pleistocene boundary. Inst Tertiary-Quaternary Studies Symp Series 1:33–40

    Google Scholar 

  • Martin LD (1993) Fossil history of the terrestrial Carnivora. In: Gittleman JL (ed) Carnivore behavior and evolution. Cornell University Press, Ithaca, pp 536–568

  • Martin LD (1994) Cenozoic climatic history from a biological perspective. Inst Tertiary-Quaternary Studies Symp Series 2:39–56

    Google Scholar 

  • Martin LD, Meehan TJ (2002) Recognizing a global stratigraphy. Institute Tertiary-Quaternary Studies Symp Series 3:175–185

    Google Scholar 

  • Matthew WD (1915) Climate and evolution. N Y Acad Sci Ann 24:171–318

    Google Scholar 

  • Olson EC (1952) The evolution of a Permian vertebrate chronofauna. Evol 6(2):181–196

    Google Scholar 

  • Palmer AR (1965) Biomere—a new kind of biostratigraphic unit. J Paleontol 39:149–153

    Google Scholar 

  • Schindewolf OH (1950) Grundfragen der Paläontologie. E Schweizerbart'sche Verlagsbuchhandlung, Erwin Nügele, Stuttgart

  • Schultz CB, Stout TM (1980) Ancient soils and climatic changes in the Central Great Plains. Trans Neb Acad Sci 8:187–205

    Google Scholar 

  • Sepkoski JJ (1993) Ten years in the library: new data confirm paleontological patterns. Paleobiology 19(1):43–51

    PubMed  Google Scholar 

  • Simpson GG (1944) Tempo and mode in evolution. Columbia University Press, New York

  • Stitt JH (1975) Adaptive radiation, trilobite paleoecology, and extinction, Ptychaspid biomere, Late Cambrian of Oklahoma. Fossils Strata 4:381–390

    Google Scholar 

  • Stout TM (1978) The comparative method in stratigraphy: the beginning and end of an ice age. Trans Neb Acad Sci 6:1–18

    Google Scholar 

  • White JA, Keller BL (1984) Evolutionary stability and ecological relationships of morphology in North American Lagomorpha. In: Mengal RM (ed) Papers in vertebrate paleontology honoring Robert Warren Wilson. Carnegie Mus Nat Hist Special Publ 9:58–66

    Google Scholar 

  • Wolfe JA (1985) Distribution of major vegetational types during the Tertiary. Geophys Monogr 32:357–375

    Google Scholar 

  • Woodburne MO (1987) Cenozoic mammals of North America: geochronology and biostratigraphy. University of California Press, Berkeley

    Google Scholar 

Download references

Acknowledgements

T.J.M. wishes to thank his PhD committee at Kansas University: L.D. Martin, D. Miao, R.W. Wilson, R.M. Timm, P. Wells, and D.W. Frayer.

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Correspondence to T. J. Meehan.

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Meehan, T.J., Martin, L.D. Extinction and re-evolution of similar adaptive types (ecomorphs) in Cenozoic North American ungulates and carnivores reflect van der Hammen's cycles. Naturwissenschaften 90, 131–135 (2003). https://doi.org/10.1007/s00114-002-0392-1

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