Abstract
Between-branch nitrogen competition is expected to be important during spring in temperate deciduous trees as nitrogen allocation would be higher in branches from earlier budburst than in those from later budburst. Such phenology-induced branch interaction would influence plant photosynthesis, but this has not been evaluated. Warming experiments were conducted on whole crowns (warmed trees; trunks and all branches of the same tree were warmed) or parts of the crowns (warmed branches with unwarmed control branches in the same tree), with unwarmed control trees, in saplings of the deciduous species Fraxinus lanuginosa. Spring leaf phenology and leaf photosynthetic traits were investigated to determine how the difference in temperature affects leaf phenology and photosynthetic traits. The timing of budburst was influenced by temperature—budburst was earlier in warmed trees and warmed branches than in control trees and control branches, but budburst timing did not differ between control trees and control branches or between warmed trees and warmed branches. In contrast, leaf traits were affected by the variation in phenology within crowns—nitrogen content and photosynthetic capacity were greater in the leaves of the warmed branches than in the control branches, but they did not differ between the leaves of warmed trees and control trees. Thus, branch warming altered the distribution of nitrogen between warmed and unwarmed branches as warmed branches developed faster, resulting in intracrown variation in leaf photosynthetic traits.
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Acknowledgements
I thank Dr. Ülo Niinemets and an anonymous reviewer for their helpful comments on the manuscript, and Drs Tsutom Hiura, Tatsuro Nakaji, and the members of Tomakomai Experimental Forest, Hokkaido University for their advice on the study. This study was partly supported by grants from JSPS (15K07465 and 19K06130).
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NO conceived, designed, and executed this study and wrote the manuscript. No other person is entitled to authorship.
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Communicated by Ylo Niinemets.
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Osada, N. Differential springtime branch warming controls intra-crown nitrogen allocation and leaf photosynthetic traits in understory saplings of a temperate deciduous species. Oecologia 196, 331–340 (2021). https://doi.org/10.1007/s00442-021-04929-4
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DOI: https://doi.org/10.1007/s00442-021-04929-4