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Three keys to the radiation of angiosperms into freezing environments

Nature volume 506pages 89–92 (2014)Cite this article

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A Corrigendum to this article was published on 20 May 2015

A Corrigendum to this article was published on 15 October 2014

This article has been updated

Abstract

Early flowering plants are thought to have been woody species restricted to warm habitats1,2,3. This lineage has since radiated into almost every climate, with manifold growth forms4. As angiosperms spread and climate changed, they evolved mechanisms to cope with episodic freezing. To explore the evolution of traits underpinning the ability to persist in freezing conditions, we assembled a large species-level database of growth habit (woody or herbaceous; 49,064 species), as well as leaf phenology (evergreen or deciduous), diameter of hydraulic conduits (that is, xylem vessels and tracheids) and climate occupancies (exposure to freezing). To model the evolution of species’ traits and climate occupancies, we combined these data with an unparalleled dated molecular phylogeny (32,223 species) for land plants. Here we show that woody clades successfully moved into freezing-prone environments by either possessing transport networks of small safe conduits5 and/or shutting down hydraulic function by dropping leaves during freezing. Herbaceous species largely avoided freezing periods by senescing cheaply constructed aboveground tissue. Growth habit has long been considered labile6, but we find that growth habit was less labile than climate occupancy. Additionally, freezing environments were largely filled by lineages that had already become herbs or, when remaining woody, already had small conduits (that is, the trait evolved before the climate occupancy). By contrast, most deciduous woody lineages had an evolutionary shift to seasonally shedding their leaves only after exposure to freezing (that is, the climate occupancy evolved before the trait). For angiosperms to inhabit novel cold environments they had to gain new structural and functional trait solutions; our results suggest that many of these solutions were probably acquired before their foray into the cold.

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Figure 1: Time-calibrated maximum-likelihood estimate of the molecular phylogeny for 31,749 species of seed plants.
Figure 2: Coordinated evolutionary transition rates between leaf phenology or conduit diameter and climate occupancy.
Figure 3: Coordinated evolutionary transition rates between growth form and climate occupancy.

Change history

  • 03 January 2014

    The Dryad Digital Repository doi number has been updated.

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Acknowledgements

We thank T. Robertson and A. Hahn at the Global Biodiversity Information Facility for providing species’ georeference points, A. Ordonez for providing growth form data, and A. Miller and D. Ackerly for helpful comments on a draft of this manuscript. Support for this work was given to the working group “Tempo and Mode of Plant Trait Evolution: Synthesizing Data from Extant and Extinct Taxa” by the National Evolutionary Synthesis Center (NESCent), National Science Foundation grant #EF- 0905606 and Macquarie University Genes to Geoscience Research Centre.

Author information

Authors and Affiliations

  1. Department of Biological Sciences, George Washington University, Washington DC 20052, USA,

    Amy E. Zanne

  2. Center for Conservation and Sustainable Development, Missouri Botanical Garden, St Louis, 63121, Missouri, USA

    Amy E. Zanne

  3. Department of Biological Sciences, University of Idaho, Moscow, 83844, Idaho, USA

    David C. Tank & Jonathan M. Eastman

  4. Institute for Bioinformatics and Evolutionary Studies, University of Idaho, Moscow, 83844, Idaho, USA

    David C. Tank & Jonathan M. Eastman

  5. Department of Ecological Sciences, Systems Ecology, de Boelelaan 1085, 1081 HV Amsterdam, the Netherlands,

    William K. Cornwell

  6. Evolution & Ecology Research Centre, School of Biological, Earth and Environmental Sciences, University of New South Wales, Sydney, 2052, New South Wales, Australia

    William K. Cornwell, Angela T. Moles, Frank Hemmings & Laura Warman

  7. Department of Ecology and Evolutionary Biology, University of Michigan, Ann Arbor, 48109, Michigan, USA

    Stephen A. Smith

  8. Department of Zoology and Biodiversity Research Centre, University of British Columbia, Vancouver, British Columbia V6T1Z4, Canada,

    Richard G. FitzJohn

  9. Department of Biological Sciences, Macquarie University, Sydney, 2109, New South Wales, Australia

    Richard G. FitzJohn, Mark Westoby, Ian J. Wright & Michelle R. Leishman

  10. Department of Biology and the Ecology Center, Utah State University, Logan, 84322, Utah, USA

    Daniel J. McGlinn

  11. Department of Ecology and Evolutionary Biology, University of Tennessee, Knoxville, 37996, Tennessee, USA

    Brian C. O’Meara

  12. Department of Forest Resources, University of Minnesota, St Paul, 55108, Minnesota, USA

    Peter B. Reich & Jacek Oleksyn

  13. Hawkesbury Institute for the Environment, University of Western Sydney, Penrith, 2751, New South Wales, Australia

    Peter B. Reich

  14. Department of Earth and Environmental Sciences, Wesleyan University, Middletown, 06459, Connecticut, USA

    Dana L. Royer

  15. Department of Biology, University of Florida, Gainesville, 32611, Florida, USA

    Douglas E. Soltis & Andre Calaminus

  16. Florida Museum of Natural History, University of Florida, Gainesville, 32611, Florida, USA

    Douglas E. Soltis & Pamela S. Soltis

  17. Genetics Institute, University of Florida, Gainesville, 32611, Florida, USA

    Douglas E. Soltis & Pamela S. Soltis

  18. Department of Biology, University of Missouri—St Louis, St Louis, 63121, Missouri, USA

    Peter F. Stevens

  19. Department of Biology, Queen’s University, Kingston, Ontario K7L 3N6, Canada,

    Lonnie Aarssen

  20. Department of Biology, College of the Holy Cross, Worcester, 01610, Massachusetts, USA

    Robert I. Bertin

  21. Royal Botanic Gardens, Kew, Richmond, Surrey TW9 3AB, United Kingdom ,

    Rafaël Govaerts

  22. Polish Academy of Sciences, Institute of Dendrology, 62-035 Kornik, Poland ,

    Jacek Oleksyn

  23. Department of Plant Biology and Ecology, Evolutionary Biology and Behavior, Program, Michigan State University, East Lansing, 48824, Michigan, USA

    Nathan G. Swenson

  24. Institute of Pacific Islands Forestry, USDA Forest Service, Hilo, 96720, Hawaii, USA

    Laura Warman

  25. National Institute for Mathematical & Biological Synthesis, University of Tennessee, Knoxville, 37996, Tennessee, USA

    Jeremy M. Beaulieu

Authors
  1. Amy E. Zanne
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Contributions

A.E.Z., W.K.C., D.C.T. and J.M.B. designed the initial project, wrote the original manuscript and carried out analyses. J.M.E., S.A.S. and D.C.T. constructed the timetree. J.M.E., R.G.F., D.J.M., B.C.O’M. and S.A.S. were major quantitative contributors, especially with the development of new methods, analyses, graphics and writing. A.T.M., P.B.R., D.L.R., D.E.S., P.F.S., I.J.W. and M.W. were large contributors through the development of initial ideas, methods, dataset curation, analyses and writing. L.A., R.I.B., A.C., R.G., F.H., M.R.L., J.O., P.S.S., N.G.S. and L.W. contributed data sets and discussions, and read drafts.

Corresponding author

Correspondence to Amy E. Zanne.

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Competing interests

The authors declare no competing financial interests.

Additional information

Data and code are deposited at the Dryad Digital Repository (http://dx.doi.org/10.5061/dryad.63q27) and TRY (http://www.try-db.org/).

Extended data figures and tables

Extended Data Figure 1 Examples of the definition of ‘woody’.

ad, We defined ‘woody’ as having a prominent aboveground stem that is persistent over time and with changing environmental conditions. a, Liriodendron tulipifera (Magnoliaceae), Joyce Kilmer Memorial Forest, Robbinsville, North Carolina, USA. b, Carnegiea giganteana (Cactaceae), Biosphere II, Tucson, Arizona, USA, c, Rhopalostylis sapida (Arecaceae) and Cyathea sp. (Cyatheaceae), Punakaiki, South Island, New Zealand. d, Pandanus sp. (Pandanaceae), Moreton Bay Research Station, North Stradbroke Island, Queensland, Australia (photographs by A.E.Z.).

Extended Data Figure 2 Reference timetree used for congruification analyses.

Results of the divergence time estimation of 639 taxa of seed plants from the reanalysis of a previously described10 phylogeny. Fossil calibrations are indicated at the nodes with green circles, and numbers correspond to fossils described in Supplementary Table 2. Concentric dashed circles represent 100-Myr intervals as indicated by the scale bar.

Extended Data Table 1 Number of species in different growth forms by clade
Full size table
Extended Data Table 2 Coordinated evolutionary model fits for leaf phenology, conduit diameter and climate occupancy
Full size table
Extended Data Table 3 Coordinated evolutionary model transition rates
Full size table
Extended Data Table 4 Coordinated evolutionary model fits for growth form and climate occupancy
Full size table

Supplementary information

Supplementary Information

This file contains Supplementary Methods, Supplementary References and Supplementary Tables 1-4. (PDF 2886 kb)

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Zanne, A., Tank, D., Cornwell, W. et al. Three keys to the radiation of angiosperms into freezing environments. Nature 506, 89–92 (2014). https://doi.org/10.1038/nature12872

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