AUTHOR=Pflug Ellen E. , Buchmann Nina , Siegwolf Rolf T. W. , Schaub Marcus , Rigling Andreas , Arend Matthias 

TITLE=Resilient Leaf Physiological Response of European Beech (Fagus sylvatica L.) to Summer Drought and Drought Release

JOURNAL=Frontiers in Plant Science

VOLUME=9

YEAR=2018

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2018.00187

DOI=10.3389/fpls.2018.00187

ISSN=1664-462X

ABSTRACT=<p>Drought is a major environmental constraint to trees, causing severe stress and thus adversely affecting their functional integrity. European beech (<italic>Fagus sylvatica</italic> L.) is a key species in mesic forests that is commonly expected to suffer in a future climate with more intense and frequent droughts. Here, we assessed the seasonal response of leaf physiological characteristics of beech saplings to drought and drought release to investigate their potential to recover from the imposed stress and overcome previous limitations. Saplings were transplanted to model ecosystems and exposed to a simulated summer drought. Pre-dawn water potentials (ψ<sub>pd</sub>), stomatal conductance (<italic>g</italic><sub>S</sub>), intercellular CO<sub>2</sub> concentration (<italic>c</italic><sub>i</sub>), net-photosynthesis (<italic>A</italic><sub>N</sub>), PSII chlorophyll fluorescence (<italic>PI</italic><sub>tot</sub>), non-structural carbohydrate concentrations (<italic>NSC</italic>; soluble sugars, starch) and carbon isotope signatures were measured in leaves throughout the growing season. Pre-dawn water potentials (ψ<sub>pd</sub>), <italic>g</italic><sub>S</sub>, <italic>c</italic><sub>i</sub>, <italic>A</italic><sub>N</sub>, and <italic>PI</italic><sub>tot</sub> decreased as drought progressed, and the concentration of soluble sugars increased at the expense of starch. Carbon isotopes in soluble sugars (δ<sup>13</sup><italic>C</italic><sub>S</sub>) showed a distinct increase under drought, suggesting, together with decreased <italic>c</italic><sub>i</sub>, stomatal limitation of <italic>A</italic><sub>N</sub>. Drought effects on ψ<sub>pd</sub>, <italic>c</italic><sub>i</sub>, and <italic>NSC</italic> disappeared shortly after re-watering, while full recovery of <italic>g</italic><sub>S</sub>, <italic>A</italic><sub>N</sub>, and <italic>PI</italic><sub>tot</sub> was delayed by 1 week. The fast recovery of <italic>NSC</italic> was reflected by a rapid decay of the drought signal in δ<sup>13</sup><italic>C</italic> values, indicating a rapid turnover of assimilates and a reactivation of carbon metabolism. After recovery, the previously drought-exposed saplings showed a stimulation of <italic>A</italic><sub>N</sub> and a trend toward elevated starch concentrations, which counteracted the previous drought limitations. Overall, our results suggest that the internal water relations of beech saplings and the physiological activity of leaves are restored rapidly after drought release. In the case of <italic>A</italic><sub>N</sub>, stimulation after drought may partially compensate for limitations on photosynthetic activity during drought. Our observations suggest high resilience of beech to drought, contradicting the general belief that beech is particularly sensitive to environmental stressors.</p>