Journal
FRONTIERS IN FORESTS AND GLOBAL CHANGE
Volume 4, Issue -, Pages -Publisher
FRONTIERS MEDIA SA
DOI: 10.3389/ffgc.2021.675299
Keywords
woody stem interaction with the atmosphere; woody stem photosynthesis; phylogenetic signal; water flux; carbon flux; bark water uptake
Funding
- USDA-NIFA Award [202067014-30916, 2020-67014-30915]
- Smithsonian Tropical Research Institute Earl S. Tupper Postdoctoral Fellowship
- DOE TES Award [DESC0019037]
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While woody stems have an impact on carbon and water dynamics, their direct exchange with the atmosphere is rarely quantified. Woody stem chlorophyll is present in diverse climates and species, suggesting an evolutionary advantage, but formal evaluation of this hypothesis is lacking. Studies have shown that some woody stems can conduct photosynthesis and uptake water through the bark, which can offset respiration costs and improve water balance, with potential implications for plant function in a changing climate.
While woody stems are known to influence carbon and water dynamics, direct exchange with the atmosphere is seldom quantified, limiting our understanding of how these processes influence the exchange of mass and energy. The presence of woody stem chlorophyll in a diversity of climates and across a range of species suggests an evolutionary advantage to sustaining carbon assimilation and water relations through permeable stem tissue. However, no formal evaluation of this hypothesis has been performed. In this mini-review, we explore the interactions between woody stems and the atmosphere by examining woody stem photosynthesis and bark-atmosphere water exchange. Specifically, we address the following questions: (1) How do water and carbon move between the atmosphere and woody stems? (2) In what climate space is woody stem photosynthesis and bark water uptake advantageous? (3) How ubiquitous across plant families is woody stem photosynthesis and bark-atmosphere water exchange? In the literature, only seven species have been identified as exhibiting bark water uptake while over 300 species are thought to conduct woody stem photosynthesis. The carbon dioxide and water gained from these processes can offset respiration costs and improve plant water balance. These species span diverse biomes suggesting a broad prevalence of bark-atmosphere permeability. Finally, our results demonstrate that there may be an evolutionary component as demonstrated by a high Pagel's lambda for the presence of stem photosynthesis. We end with recommendations for future research that explores how bark water and carbon interactions may impact plant function and mass flow in a changing climate.
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