Abstract
Although stable carbon isotopic composition (δ13C) of plants has been widely used to indicate different water regimes in terrestrial ecosystems over the past four decades, the changes in the plant δ13C value under waterlogging have not been sufficiently clarified. With the enhanced global warming in recent years, the increasing frequency and severity of river floods in Arctic regions lead to more waterlogging on willows that are widely distributed in river lowland. To investigate the δ13C changes in plants under different water conditions (including waterlogging), we measured the δ13C values in the leaves of willows with three species, Salix boganidensis, S. glauca, and S. pulchra, and also monitored changes in plant physiology, under several major flooding conditions in Northeastern Siberia. The foliar δ13C values of willows varied, ranging from −31.6 to −25.7‰ under the different hydrological status, which can be explained by: (i) under normal conditions, the foliar δ13C values decrease from dry (far from a river) to wet (along a river bank) areas; (ii) the δ13C values increase in frequently waterlogged areas owing to stomatal closure; and (iii) after prolonged flooding periods, the δ13C values again decrease, probably owing to the effects of not only the closure of stomata but also the reduction of foliar photosynthetic ability under long period of waterlogging. Based on these results, we predict that plant δ13C values are strongly influenced by plant physiological responses to diverse hydrological conditions, particularly the long periods of flooding, as occurs in Arctic regions.
Highlights
Over the past four decades, stable carbon isotopic composition (d13C, ‰ relative to Vienna Pee Dee Belemnite, VPDB) of plants has been widely employed as a conventional tool to estimate changes in carbon flux as plant physiology responds to environmentalHow to cite this article Fan et al (2018), Effect of floods on the d13C values in plant leaves: a study of willows in Northeastern Siberia
For the inter-annual changes from 2015 to 2016 on transect SKA, an increase in foliar d13C value was observed for PA (+0.8 ± 0.6‰); whereas, a decrease was recorded for both, PB (-1.2 ± 0.5‰) and PC (-1.0 ± 0.8‰)
The foliar d13C values were lower under wet conditions than under dry conditions, because the former conditions allowed for stomatal opening
Summary
Over the past four decades, stable carbon isotopic composition (d13C, ‰ relative to Vienna Pee Dee Belemnite, VPDB) of plants has been widely employed as a conventional tool to estimate changes in carbon flux as plant physiology responds to environmentalHow to cite this article Fan et al (2018), Effect of floods on the d13C values in plant leaves: a study of willows in Northeastern Siberia. The magnitude of isotopic fractionation is highly dependent on physiological conditions (Farquhar, Ehleringer & Hubick, 1989; Robinson, 2001). It is well known that carbon isotopic fractionation (D13C) in plants is a function of the ratio of leaf intercellular-(ci) to atmospheric (ca) CO2 concentrations (ci/ca) (Farquhar & Sharkey, 1982; Farquhar, Ehleringer & Hubick, 1989), as given in Eq (1): D13C 1⁄4 d13Ca. À d13Cp a þ ðb aÞ Â Ci Ca ; (1). Where, d13Ca and d13Cp are the d13C values of atmospheric CO2 and photosynthate, respectively; while a and b are the carbon isotopic fractionations associated with CO2 diffusion and enzymatic carboxylation (carbon fixation) in plant leaves, respectively.
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