Abstract
Climate is a major evolutionary force in driving adaptive differentiation and plasticity in plant function. Xylem anatomy and hydraulic architecture are critical to water use, growth and responses of trees to drought and thus important in delimiting their ecological niches. How wood properties have been shaped through evolution by their climatic origins and the importance of plasticity for species persistence remain open questions critical to understanding plant responses to changing climate. We measured 11 wood anatomical traits for 18 Quercus (oak) species in arboreta that span contrasting climates (California-US, southwestern France and central England). We investigated coordinate evolution of xylem anatomical properties with climatic niche and intraspecific variation in relation to growth environment. Species originating from climates with drier summers had traits associated with higher resistance to drought—higher density of vasicentric tracheids (VT), lower vessel hydraulic diameter (Dmh) and lower hydraulic conductivity. Species that evolved in climates with drier, hotter summers or colder winters had higher numbers of VT than those from mesic climates, supporting hypotheses that VT are critical for water transport during drought. We found limited intraspecific variation in xylem traits associated with growth environment—only four traits (pit fraction, VT, vessel density and Dmh)—differed among gardens. Xylem traits showed high lability across the phylogeny, consistent with evidence for parallel sympatric adaptive radiation and global diversification of the oaks. Our results provide evidence for the physiological mechanisms that underlie adaptation to changing environments and responses to climate change.
Original language | English (US) |
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Pages (from-to) | 326-340 |
Number of pages | 15 |
Journal | Functional Ecology |
Volume | 36 |
Issue number | 2 |
DOIs | |
State | Published - Feb 2022 |
Bibliographical note
Funding Information:We thank Béatrice Chasse, Gérard Lionet, David Coomes, Cathleen Lapadat and Celine Bares for assistance with wood sample collection and preparation. We thank the Pouyouleix Arboretum in France, the Sir Harold Hillier in England and the Peter J. Shields Oak Grove at UC Davis arboretum in California for access to the materials and logistical support. We thank Gerard Sapes and Béatrice Chasse for valuable comments and edits on the manuscript. Permit PCIP-19-00256 from the US Department of Agriculture was used for importation of samples to the U.S.NSF DBI 2021898 and NSF DEB 1146380. The authors have no conflict of interest to declare.
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© 2021 British Ecological Society