Elevated CO2 compensates for drought effects in lemon saplings via stomatal downregulation, increased soil moisture, and increased wood carbon storage

•Under drought, lemon tree growth is maintained at elevated, but not ambient, CO2.•Stomatal downregulation at elevated [CO2] reduced water-use but not photosynthesis.•CO2-induced increases in root and shoot starch are transient but significant.•Together, the three CO2-related mechanisms reduce droug...

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Bibliographic Details
Published in:Environmental and experimental botany 2018-04, Vol.148, p.117-127
Main Authors: Paudel, Indira, Halpern, Moshe, Wagner, Yael, Raveh, Eran, Yermiyahu, Uri, Hoch, Guenter, Klein, Tamir
Format: Article
Language:English
Subjects:
CO2
Drought resistance
Stomatal adjustment
Storage carbohydrates
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Summary:•Under drought, lemon tree growth is maintained at elevated, but not ambient, CO2.•Stomatal downregulation at elevated [CO2] reduced water-use but not photosynthesis.•CO2-induced increases in root and shoot starch are transient but significant.•Together, the three CO2-related mechanisms reduce drought effects on young lemon trees. Tree growth enhancement under elevated [CO2] is much smaller than originally anticipated; yet carbon overabundance can lead to increased wood carbon storage and to stomatal downregulation and hence reduced water-use. Notably, all three outcomes increase tree drought resistance. Here we studied growth, water relations, and nonstructural carbohydrates of 60 lemon saplings growing in CO2-controlled rooms at the same greenhouse, under 400, 650, and 850 ppm [CO2]. At each [CO2] level, 10 saplings were exposed to 1-month dry-down after 2 months of standard irrigation, followed by re-watering for another month. The other 10 saplings served as controls. Under drought, tree growth was maintained at elevated, but not ambient, CO2, linked with mild vs. severe tree water stress (leaf water potential of −3.5 at elevated and −5.5 MPa at ambient [CO2]). Stomatal downregulation with increasing [CO2] meant that leaf transpiration and diurnal plant water-use were 13–46% lower at elevated vs. ambient [CO2] but photosynthesis was still 15–25% higher. CO2-induced increases in root and shoot starch were transient but significant. Our results suggest that when predicting tree growth in a warmer and drier future, concomitant atmospheric CO2 concentration must be considered. In young lemon trees, elevated CO2 partially compensated for drought effects on tree growth and water status, and might delay some of the effects of the anthropogenic climate change.
ISSN:0098-8472
1873-7307
DOI:10.1016/j.envexpbot.2018.01.004