Three keys to the radiation of angiosperms into freezing environments
Zanne, Amy E
Tank, David C
Cornwell, William K
Eastman, Jonathan M
Smith, Stephen A
FitzJohn, Richard G
McGlinn, Daniel J
O’Meara, Brian C
Moles, Angela T
Reich, Peter B
Royer, Dana L
Soltis, Douglas E
Stevens, Peter F
Westoby, Mark
Wright, Ian J
Aarssen, Lonnie
Bertin, Robert I
Calaminus, Andre
Govaerts, Rafaël
Hemmings, Frank
Leishman, Michelle R
Oleksyn, Jacek
Soltis, Pamela S
Swenson, Nathan G
Warman, Laura
Beaulieu, Jeremy M
Tank, David C
Cornwell, William K
Eastman, Jonathan M
Smith, Stephen A
FitzJohn, Richard G
McGlinn, Daniel J
O’Meara, Brian C
Moles, Angela T
Reich, Peter B
Royer, Dana L
Soltis, Douglas E
Stevens, Peter F
Westoby, Mark
Wright, Ian J
Aarssen, Lonnie
Bertin, Robert I
Calaminus, Andre
Govaerts, Rafaël
Hemmings, Frank
Leishman, Michelle R
Oleksyn, Jacek
Soltis, Pamela S
Swenson, Nathan G
Warman, Laura
Beaulieu, Jeremy M
2014
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Three keys to the radiation of angiosperms into freezing environments
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2014
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Nature Publishing Group
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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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http://www.nature.com/nature/journal/v506/n7486/full/nature12872.html
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10.1038/nature12872
Previously Published Citation
Amy E. Zanne, David C. Tank, William K. Cornwell, Jonathan M. Eastman, Stephen A. Smith, Richard G. Fitzjohn, . . . Jeremy M. Beaulieu. (2013). Three keys to the radiation of angiosperms into freezing environments. Nature, 506(7486), 89.
Suggested citation
Zanne, Amy E; Tank, David C; Cornwell, William K; Eastman, Jonathan M; Smith, Stephen A; FitzJohn, Richard G; McGlinn, Daniel J; O’Meara, Brian C; Moles, Angela T; Reich, Peter B; Royer, Dana L; Soltis, Douglas E; Stevens, Peter F; Westoby, Mark; Wright, Ian J; Aarssen, Lonnie; Bertin, Robert I; Calaminus, Andre; Govaerts, Rafaël; Hemmings, Frank; Leishman, Michelle R; Oleksyn, Jacek; Soltis, Pamela S; Swenson, Nathan G; Warman, Laura; Beaulieu, Jeremy M. (2014). Three keys to the radiation of angiosperms into freezing environments. Retrieved from the University Digital Conservancy, 10.1038/nature12872.
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