Abstract
The current level of tropospheric ozone (O3) is expected to reduce the net primary production of forest trees. Here, we evaluated the negative effects of O3 on the photosynthetic CO2 uptake of Japanese forest trees species based on their cumulative stomatal O3 uptake, defined as the phytotoxic O3 dose (POD). Seedlings of four representative Japanese deciduous broad-leaved forest tree species (Fagus crenata, Quercus serrata, Quercus mongolica var. crispula and Betula platyphylla var. japonica) were exposed to different O3 concentrations in open-top chambers for two growing seasons. The photosynthesis–light response curves (A-light curves) and stomatal conductance were measured to estimate the leaf-level cumulative photosynthetic CO2 uptake (ΣPn_est) and POD, respectively. The whole-plant-level ΣPn_est were highly correlated with the whole-plant dry mass increments over the two growing seasons. Because whole-plant growth is largely determined by the amount of leaf area per plant and net photosynthetic rate per leaf area, this result suggests that leaf-level ΣPn_est, which was estimated from the monthly A-light curves and hourly PPFD, could reflect the cumulative photosynthetic CO2 uptake of the seedlings per unit leaf area. Although the O3-induced reductions in the leaf-level ΣPn_est were well explained by POD in all four tree species, species-specific responses of leaf-level ΣPn_est to POD were observed. In addition, the flux threshold appropriate for the linear regression of the responses of relative leaf-level ΣPn_est to POD was also species-specific. Therefore, species-specific responses of cumulative photosynthetic CO2 uptake to POD could be used to accurately evaluate O3 impact on the net primary production of deciduous broad-leaved trees.
Highlights
Tropospheric ozone (O3 ) has detrimental effects on vegetation [1,2,3]
Photosynthetic parameters other than the A-light curve could offer a better indication of the overall damage of O3 on photosynthesis and its mechanisms, we did not measure the parameters, because we focused on the effects of O3 on the cumulative photosynthetic CO2 uptake rather than the mechanisms underlying the
We evaluated the negative effects of O3 on leaf-level photosynthetic CO2 uptake, which could be incorporated into models of the carbon cycling, in the seedlings of four representative Japanese deciduous broad-leaved forest tree species based on phytotoxic O3 dose (POD)
Summary
Tropospheric ozone (O3 ) has detrimental effects on vegetation [1,2,3]. Current O3 levels adversely affect growth and physiological functions, such as the photosynthesis of forest tree species [4,5].Because of this phytotoxicity, net primary production (NPP) and biomass accumulation by temperateForests 2019, 10, 556; doi:10.3390/f10070556 www.mdpi.com/journal/forestsForests 2019, 10, 556 forests were estimated to be reduced by 1–16% [6]. Current O3 levels adversely affect growth and physiological functions, such as the photosynthesis of forest tree species [4,5]. Because of this phytotoxicity, net primary production (NPP) and biomass accumulation by temperate. Despite robust evidence for the negative impact of O3 on plant productivity, the indirect effect of O3 on radiative forcing was not mentioned in the Intergovernmental Panel on Climate Change Fifth Assessment report because of a lack of corroborating studies [8]. It is necessary to quantify the negative impact of O3 on the photosynthetic CO2 uptake of Japanese forest tree species to account for the indirect effect of O3 on radiative forcing
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