Ectomycorrhizal colonization and growth of the hybrid larch F 1 under elevated CO 2 and O 3

Wang, Xiaona; Qu, Laiye; Mao, Qiaozhi; Watanabe, Makoto; Hoshika, Yasutomo; Koyama, Akihiro; Kawaguchi, Korin; Tamai, Yasukatsu; Koike, Takao

doi:10.1016/j.envpol.2014.11.031

Cited by 53 publications

(55 citation statements)

References 65 publications

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“…These trends have suggested that Qs may have higher ability for the recover from O 3 damages and may be more tolerant to eO 3 than Qm under eCO 2 based on the summary made by Kohno et al (2005) and Yamaguchi et al (2011). No significant effects were observed in foliar P concentration at eO 3 for both species at the present study, which was in agreement with the results of Wang et al (2015). Although we hypothesized that leaf P would be increased under eCO 2 since the acquisition of P is strongly affected by physiological condition of host plants through the morphological and the physiological properties of rhizosphere (Adalsteinsson et al, 1994;Ruiz et al, 1996;Kayama et al, 2005;Kayama and Yamanaka, 2014;Wang et al, 2015), there was no difference in leaf P at eCO 2 .…”

Section: Discussionsupporting

confidence: 83%

“…No significant effects were observed in foliar P concentration at eO 3 for both species at the present study, which was in agreement with the results of Wang et al (2015). Although we hypothesized that leaf P would be increased under eCO 2 since the acquisition of P is strongly affected by physiological condition of host plants through the morphological and the physiological properties of rhizosphere (Adalsteinsson et al, 1994;Ruiz et al, 1996;Kayama et al, 2005;Kayama and Yamanaka, 2014;Wang et al, 2015), there was no difference in leaf P at eCO 2 . This was also supported by Conroy (1992), indicating the view that eCO 2 increased the P demand of leaves.…”

Section: Discussionsupporting

confidence: 82%

“…Despite the fact that some previous researches indicated eO 3 and eCO 2 treatment decreased foliar K in potato and beech (e.g. Fangmeier et al, 2002;Thomas et al, 2006), what we found in this study ( Table 2) is in consistence with Wang et al (2015) where leaf K was not clearly different at eO 3 and eCO 2 from that grown under ambient. It was possibly because the decreased photosynthetic rate (Kitao et al, 2015) was somehow offset by the enhanced phytohormones induced by eO 3 or eCO 2 (Yong et al, 2000;Winwood et al, 2007;Matyssek et al, 2012), thereby regulating the foliar K independent with the specific gas treatments.…”

Section: Discussionsupporting

confidence: 29%

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Foliar chemical composition of two oak species grown in a free-air enrichment system with elevated O3 and CO2

Shi

Kitao

Agathokleous

et al. 2016

J. Agric. Meteorol.

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Ground level ozone (O 3 ) is rapidly increasing in Asia and penetrates plants via stomata. Atmospheric carbon dioxide (CO 2 ) has also been increasing in global and in short term may promote plant growth via photosynthetic enhancement. Oaks are representative deciduous broadleaved trees native to northeastern Asia. In this study, we focused on the effects of elevated O 3 and/or CO 2 on leaf nutrients status (phosphorous, nitrogen, potassium, magnesium, etc.) of two oak species: Konara oak (Quercus serrata) and Mizunara oak (Quercus mongolica var. crispula) to assess their function. We investigated foliar starch and sugar contents and nutrients composition of leaves of 2-year-old oak seedlings grown under elevated O 3 and/or CO 2 in a free air enrichment system. From elements concentration, nitrogen and magnesium may become the major indices in assessing the O 3 effects on these species, and investigation of both of them would be of use in field studies to discriminate O 3 and CO 2 effects, especially under the projected elevated CO 2 levels.

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Section: Discussionsupporting

confidence: 83%

Section: Discussionsupporting

confidence: 82%

Section: Discussionsupporting

confidence: 29%

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Foliar chemical composition of two oak species grown in a free-air enrichment system with elevated O3 and CO2

Shi

Kitao

Agathokleous

et al. 2016

J. Agric. Meteorol.

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“…Reduced C allocation to roots impairs mycorrhizal symbiosis, for instance, in birch (Kasurinen et al., 2005), hybrid aspen (Edwards & Zak, 2011), beech (Pritsch et al., 2009), hybrid larch (Wang et al., 2015), and blue wild rye ( Elymus glaucus ; Yoshida, Gamon, & Andersen, 2001). Mycorrhizae are ubiquitous in all terrestrial ecosystems and play an essential role in soil–plant nutrient exchange and via the turnover of external mycelium for the transfer of root‐derived C to SOM (Godbold et al., 2006).…”

Section: Changes In Soil Microbiota and Nutrient Cyclingmentioning

confidence: 99%

Current and future ozone risks to global terrestrial biodiversity and ecosystem processes

Fuhrer

Martin

Mills

et al. 2016

Ecology and Evolution

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Risks associated with exposure of individual plant species to ozone (O3) are well documented, but implications for terrestrial biodiversity and ecosystem processes have received insufficient attention. This is an important gap because feedbacks to the atmosphere may change as future O3 levels increase or decrease, depending on air quality and climate policies. Global simulation of O3 using the Community Earth System Model (CESM) revealed that in 2000, about 40% of the Global 200 terrestrial ecoregions (ER) were exposed to O3 above thresholds for ecological risks, with highest exposures in North America and Southern Europe, where there is field evidence of adverse effects of O3, and in central Asia. Experimental studies show that O3 can adversely affect the growth and flowering of plants and alter species composition and richness, although some communities can be resilient. Additional effects include changes in water flux regulation, pollination efficiency, and plant pathogen development. Recent research is unraveling a range of effects belowground, including changes in soil invertebrates, plant litter quantity and quality, decomposition, and nutrient cycling and carbon pools. Changes are likely slow and may take decades to become detectable. CESM simulations for 2050 show that O3 exposure under emission scenario RCP8.5 increases in all major biomes and that policies represented in scenario RCP4.5 do not lead to a general reduction in O3 risks; rather, 50% of ERs still show an increase in exposure. Although a conceptual model is lacking to extrapolate documented effects to ERs with limited or no local information, and there is uncertainty about interactions with nitrogen input and climate change, the analysis suggests that in many ERs, O3 risks will persist for biodiversity at different trophic levels, and for a range of ecosystem processes and feedbacks, which deserves more attention when assessing ecological implications of future atmospheric pollution and climate change.

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“…Moreover, the carbon (C) gain and allocation below ground are also increased. As an indirect result of these changes, the relationship of tree roots and symbionts is altered (Wang et al 2015b).…”

Section: Introductionmentioning

confidence: 99%

Effects of CO2 and O3 on the interaction between root of woody plants and ectomycorrhizae

Wang

Agathokleous

et al. 2016

J. Agric. Meteorol.

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The increase of atmospheric carbon dioxide (CO 2 ) and tropospheric ozone (O 3 ) concentrations has affected forest ecosystems both above and below ground. A high dose of O 3 alters stomatal function and accelerates foliar senescence, which lead to changes in assimilation and water use efficiency. Consequently, biomass production and plant growth are suppressed by elevated levels of O 3 . In contrast, elevated CO 2 ameliorates these responses of plants to high O 3 via stomatal closure. The harmful effect of O 3 on above ground is indirectly linked with below-ground. Importantly, the fine root dynamics and the relationship with symbiotic fungi are significantly influenced. However, the effects of such a changing environment on forest rhizosphere are still poorly understood. The aim of this study is to analyze the combination effect of CO 2 and O 3 on tree roots and ectomycorrhizae. In particular, we summarize and discuss 1) the response of ectomycorrhizal symbionts (colonization rate, community composition, richness, and diversity) under these environmental stresses; and 2) the root dynamics under elevated CO 2 and O 3 concentrations, along with current methodologies used for root sampling.

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Ectomycorrhizal colonization and growth of the hybrid larch F 1 under elevated CO 2 and O 3

Cited by 53 publications

References 65 publications

Foliar chemical composition of two oak species grown in a free-air enrichment system with elevated O<sub>3</sub> and CO<sub>2</sub>

Foliar chemical composition of two oak species grown in a free-air enrichment system with elevated O<sub>3</sub> and CO<sub>2</sub>

Current and future ozone risks to global terrestrial biodiversity and ecosystem processes

Effects of CO<sub>2</sub> and O<sub>3</sub> on the interaction between root of woody plants and ectomycorrhizae

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