Ozone affects shikimate pathway genes and secondary metabolites in saplings of European beech (Fagus sylvatica L.) grown under greenhouse conditions

Betz, Gunter; Gerstner, Elke; Stich, Susanne; Winkler, Barbro; Welzl, Gerhard; Kremmer, Elisabeth; Langebartels, Christian; Heller, Werner; Sandermann, Heinrich; Ernst, D.

doi:10.1007/s00468-008-0300-1

Cited by 32 publications

(22 citation statements)

References 69 publications

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“…Thus, 4-year-old beech saplings can be classified as ozone-sensitive. This idea is further supported by the absence of free SA in sensitive birch clones (Vahala et al 2003), as well as in beech saplings (Betz et al 2009b). ACO1 and ACO2 were strongly induced at the onset of ozone treatment (150-190 nL L -1 ), but decreased upon continuous exposure (Fig.…”

Section: Discussionsupporting

confidence: 58%

“…The saplings were cultivated until full leaf development and were kept at a relative humidity of 70-80% and temperatures of 22-25 °C during day hours (6:00 to 20:00) and 17-20 °C during the night (20:00 to 6:00). At the beginning of June, saplings were exposed to ozone for 8 h/d (150 nl L -1 ) or pollutant-free air, and after 13 d the ozone concentration was increased to 190 nl L -1 for a further 70 d (Betz et al 2009b). For pollutant treatments ozone was added to conditioned air by mass flow controllers and injected into the cabinet by a fan (1180 m 3 h -1…”

Section: Plant Materials and Growth Conditionsmentioning

confidence: 99%

“…Three-year-old European beech saplings (Fagus sylvatica L., provenance 81024; Schlegel Baumschulen, Riedlingen, Germany) were planted in 14-L pots filled with natural forest soil (site Höglwald, Bavaria, Germany - Betz et al 2009b). Saplings were maintained during winter under a wooden pergola.…”

Section: Plant Materials and Growth Conditionsmentioning

confidence: 99%

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Effects of abiotic stress on gene transcription in European beech: ozone affects ethylene biosynthesis in saplings of Fagus sylvatica L.

Betz¹,

Gerstner²,

Olbrich³

et al. 2009

iForest

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© iForest -Biogeosciences and Forestry IntroductionEuropean beech is the most abundant broadleaf tree in Germany (Schütt et al. 1992). It is also of major importance for the European forest industry and was therefore chosen as an experimental species for our studies, to obtain deeper molecular insights into the potentially detrimental effects of ozone on European broadleaf forest ecosystems. Plants have long been known to exhibit responses to ozone exposure resembling the hypersensitive response following pathogen attack. Ozone has been qualified as an abiotic elicitor of plant defence reactions (Sandermann et al. 1998). These responses include phytoalexin production and synthesis of pathogenesis-related (PR) proteins, accompanied by the formation of various aromatic metabolites like lignins and flavonoids .Another well-known plant response to ozone exposure is the stimulation of ethylene biosynthesis (Tuomainen et al. 1997, Rao et al. 2002, Langebartels & Kangasjärvi 2004. Activation of ethylene biosynthesis is one of the fastest ozone-dependent biochemical responses so far observed in herbaceous plants, occurring within 5 hours, or even more rapidly (Schlagnhaufer et al. 1997, Nakajima et al. 2001, Moeder et al. 2002. This response was similarly rapid in birch (Vahala et al. 2003) and in an ozone-sensitive poplar clone (Diara et al. 2005). ACC synthase (ACS) and ACC oxidase (ACO), the two enzymes of ethylene biosynthesis, are encoded by gene families in herbaceous plants; several ACS and ACO isoforms have been reported to be induced by ozone (Nakajima et al. 2001, Moeder et al. 2002. In ozone-sensitive as well as ozone-tolerant birch clones, ozoneinduced accumulation of ACS and ACO transcripts was found (Vahala et al. 2003). Similarly, ozone fumigation of beech saplings (180-200 nl L -1 ) showed enhanced transcript levels of ACS2 and ACO1 (Nunn et al. 2005a). We therefore extended our study by reporting the cloning of ACS2 and ACO2, and analysing over a period of 3 month an ozone-induced expression of the ethylene biosynthesis genes (ACS1, ACS2, ACO1, ACO2), the accumulation of the ethylene precursor free ACC and conjugated ACC, and the emission of the end product of this pathway, ethylene, using beech saplings. Materials and methods Plant material and growth conditionsThree-year-old European beech saplings (Fagus sylvatica L., provenance 81024; Schlegel Baumschulen, Riedlingen, Germany) were planted in 14-L pots filled with natural forest soil (site Höglwald, Bavaria, Germany -Betz et al. 2009b). Saplings were maintained during winter under a wooden pergola. Before bud burst, the plants were treated with Promanal ® (Neudorff, Emmerthal, Germany), to prevent insect infestation. In spring the 4-year-old saplings were transferred to climate-controlled cabinets (39 m 2 ) of a greenhouse covered with UV-permeable glass sheets (http://www.helmholtz-muen chen.de/eus/index.php -Olbrich et al. , Betz et al. 2009a. Each cabinet contained 8 tables (2 m 2 per table) and 12 saplings were placed on a single table. The sap...

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Section: Discussionsupporting

confidence: 58%

Section: Plant Materials and Growth Conditionsmentioning

confidence: 99%

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Effects of abiotic stress on gene transcription in European beech: ozone affects ethylene biosynthesis in saplings of Fagus sylvatica L.

Betz¹,

Gerstner²,

Olbrich³

et al. 2009

iForest

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“…Elevated O 3 can alter the enzymatic activity of the shikimic acid pathway, enhancing the production of a number of phenolic compounds involved in stress responses (Close and McArthur 2002;Cabané et al 2004). High molecular mass polyphenolics, such as condensed tannins, have been reported to be effective antioxidants (Hagerman et al 1997), and increases in phenolic compounds under elevated O 3 may be a stress-defensive antioxidant response (Heath 2008;Betz et al 2009). Also, increased lignin accumulation in poplar under elevated O 3 is suggested to provide a structural barrier and/or antioxidant activity to reactive oxygen species, thereby increasing tolerance to O 3 (Cabané et al 2004).…”

Section: Discussionmentioning

confidence: 97%

Atmospheric change alters foliar quality of host trees and performance of two outbreak insect species

2011

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This study examined the independent and interactive effects of elevated carbon dioxide (CO(2)) and ozone (O(3)) on the foliar quality of two deciduous trees species and the performance of two outbreak herbivore species. Trembling aspen (Populus tremuloides) and paper birch (Betula papyrifera) were grown at the Aspen FACE research site in northern Wisconsin, USA, under four combinations of ambient and elevated CO(2) and O(3). We measured the effects of elevated CO(2) and O(3) on aspen and birch phytochemistry and on gypsy moth (Lymantria dispar) and forest tent caterpillar (Malacosoma disstria) performance. Elevated CO(2) nominally affected foliar quality for both tree species. Elevated O(3) negatively affected aspen foliar quality, but only marginally influenced birch foliar quality. Elevated CO(2) slightly improved herbivore performance, while elevated O(3) decreased herbivore performance, and both responses were stronger on aspen than birch. Interestingly, elevated CO(2) largely offset decreased herbivore performance under elevated O(3). Nitrogen, lignin, and C:N were identified as having strong influences on herbivore performance when larvae were fed aspen, but no significant relationships were observed for insects fed birch. Our results support the notion that herbivore performance can be affected by atmospheric change through altered foliar quality, but how herbivores will respond will depend on interactions among CO(2), O(3), and tree species. An emergent finding from this study is that tree age and longevity of exposure to pollutants may influence the effects of elevated CO(2) and O(3) on plant-herbivore interactions, highlighting the need to continue long-term atmospheric change research.

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“…3). Ozone also functions as a general abiotic elicitor of defense signaling pathways, particularly of phenolic compounds (Kangasjärvi et al 1994;Heath 2008;Betz et al 2009a). The two mechanisms may, of course, interact, as reductions in carbohydrate precursors for the shikimic acid pathway may constrain induced defensive responses.…”

Section: Ozonementioning

confidence: 99%

Impacts of Elevated Atmospheric CO2 and O3 on Forests: Phytochemistry, Trophic Interactions, and Ecosystem Dynamics

2010

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Prominent among the many factors now affecting the sustainability of forest ecosystems are anthropogenically-generated carbon dioxide (CO2) and ozone (O3). CO2 is the substrate for photosynthesis and thus can accelerate tree growth, whereas O3 is a highly reactive oxygen species and interferes with basic physiological functions. This review summarizes the impacts of CO2 and O3 on tree chemical composition and highlights the consequences thereof for trophic interactions and ecosystem dynamics. CO2 and O3 influence phytochemical composition by altering substrate availability and biochemical/physiological processes such as photosynthesis and defense signaling pathways. Growth of trees under enriched CO2 generally leads to an increase in the C/N ratio, due to a decline in foliar nitrogen and concomitant increases in carbohydrates and phenolics. Terpenoid levels generally are not affected by atmospheric CO2 concentration. O3 triggers up-regulation of antioxidant defense pathways, leading to the production of simple phenolics and flavonoids (more so in angiosperms than gymnosperms). Tannins levels generally are unaffected, while terpenoids exhibit variable responses. In combination, CO2 and O3 exert both additive and interactive effects on tree chemical composition. CO2-and O3-mediated changes in plant chemistry influence host selection, individual performance (development, growth, reproduction), and population densities of herbivores (primarily phytophagous insects) and soil invertebrates. These changes can effect shifts in the amount and temporal pattern of forest canopy damage and organic substrate deposition. Decomposition rates of leaf litter produced under elevated CO2 and O3 may or may not be altered, and can respond to both the independent and interactive effects of the pollutants. Overall, however, CO2 and O3 effects on decomposition will be influenced more by their impacts on the quantity, rather than quality, of litter produced. A prominent theme to emerge from this and related reviews is that the effects of elevated CO2 and O3 on plant chemistry and ecological interactions are highly context- and species-specific, thus frustrating attempts to identify general, global patterns. Many of the interactions that govern above- and below-ground community and ecosystem processes are chemically mediated, ultimately influencing terrestrial carbon sequestration and feeding back to influence atmospheric composition. Thus, the discipline of chemical ecology is fundamentally important for elucidating the impacts of humans on the health and sustainability of forest ecosystems. Future research should seek to increase the diversity of natural products, species, and biomes studied; incorporate long-term, multi-factor experiments; and employ a comprehensive “genes to ecosystems” perspective that couples genetic/genomic tools with the approaches of evolutionary and ecosystem ecology.

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Ozone affects shikimate pathway genes and secondary metabolites in saplings of European beech (Fagus sylvatica L.) grown under greenhouse conditions

Cited by 32 publications

References 69 publications

Effects of abiotic stress on gene transcription in European beech: ozone affects ethylene biosynthesis in saplings of Fagus sylvatica L.

Effects of abiotic stress on gene transcription in European beech: ozone affects ethylene biosynthesis in saplings of Fagus sylvatica L.

Atmospheric change alters foliar quality of host trees and performance of two outbreak insect species

Impacts of Elevated Atmospheric CO2 and O3 on Forests: Phytochemistry, Trophic Interactions, and Ecosystem Dynamics

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