Age‐dependent increase in α‐tocopherol and phytosterols in maize leaves exposed to elevated ozone pollution

Wedow, Jessica M.; Burroughs, Charles; Acosta, Lorena Rios; Leakey, Andrew D. B.; Ainsworth, Elizabeth A.

doi:10.1002/pld3.307

Cited by 10 publications

(6 citation statements)

References 96 publications

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“…In addition, antioxidants in the apoplast, including ascorbate, glutathione, and phenolic compounds, directly scavenge ROS (Ainsworth, 2017;Grace & Logan, 2000;Wedow et al, 2021a). However, previous studies have failed to demonstrate a clear pattern of correlation between O 3 sensitivity and antioxidant compound levels among diverse species (Betzelberger et al, 2010;Choquette et al, 2020;Li et al, 2016;Wedow et al, 2021b). Furthermore, variation in plant responses to O 3 may also be partly explained by genetic background (Choquette et al, 2019;Sorgini et al, 2019).…”

Section: What Factors Influence O 3 Sensitivity Among Species?mentioning

confidence: 99%

“…This further suggests that C 4 crops may have lower stomatal O 3 uptake than C 3 crops. Nevertheless, previous studies have shown significant impacts of O 3 on maize ( Zea mays ) (Choquette et al, 2019 , 2020 ; Sorgini et al, 2019 ; Wedow et al, 2021b ; Yendrek et al, 2017a , 2017b ), switchgrass ( Panicum virgatum ) (Li et al, 2019 ) and sugarcane (Saccharum spp.) (Moura et al, 2018 ), but not on sorghum ( Sorghum bicolor L.) (Li et al, 2021 ) under field conditions, implying the adverse effects of O 3 on plant photosynthesis and productivity vary among C 4 species and genotypes.…”

Section: Introductionmentioning

confidence: 99%

“…This further suggests that C 4 crops may have lower stomatal O 3 uptake than C 3 crops. Nevertheless, previous studies have shown significant | 3381 impacts of O 3 on maize (Zea mays) (Choquette et al, 2019(Choquette et al, , 2020Sorgini et al, 2019;Wedow et al, 2021b;Yendrek et al, 2017aYendrek et al, , 2017b, switchgrass (Panicum virgatum) (Li et al, 2019) and sugarcane (Saccharum spp.) (Moura et al, 2018), but not on sorghum (Sorghum bicolor L.) (Li et al, 2021) We assessed the impacts of elevated O 3 on leaf morphology and physiology in 22 genotypes of four C 4 bioenergy species that cover a broad range of stomatal conductance and LMA (Choquette et al, 2020;Ferguson et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

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Testing unified theories for ozone response in C₄ species

Moller

Mitchell

et al. 2022

Global Change Biology

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There is tremendous interspecific variability in O 3 sensitivity among C 3 species, but variation among C 4 species has been less clearly documented. It is also unclear whether stomatal conductance and leaf structure such as leaf mass per area (LMA) determine the variation in sensitivity to O 3 across species. In this study, we investigated leaf morphological, chemical, and photosynthetic responses of 22 genotypes of four C 4 bioenergy species (switchgrass, sorghum, maize, and miscanthus) to elevated O 3 in side-by-side field experiments using free-air O 3 concentration enrichment (FACE).The C 4 species varied largely in leaf morphology, physiology, and nutrient composition. Elevated O 3 did not alter leaf morphology, nutrient content, stomatal conductance, chlorophyll fluorescence, and respiration in most genotypes but reduced net CO 2 assimilation in maize and photosynthetic capacity in sorghum and maize. Species with lower LMA and higher stomatal conductance tended to show greater losses in photosynthetic rate and capacity in elevated O 3 compared with species with higher LMA and lower stomatal conductance. Stomatal conductance was the strongest determinant of leaf photosynthetic rate and capacity. The response of both area-and mass-based leaf photosynthetic rate and capacity to elevated O 3 were not affected by LMA directly but negatively influenced by LMA indirectly through stomatal conductance. These results demonstrate that there is significant variation in O 3 sensitivity among C 4 species with maize and sorghum showing greater sensitivity of photosynthesis to O 3 than switchgrass and miscanthus. Interspecific variation in O 3 sensitivity was determined by direct effects of stomatal conductance and indirect effects of LMA. This is the first study to provide a test of unifying theories explaining variation in O 3 sensitivity in C 4 bioenergy grasses. These findings advance understanding of O 3 tolerance in C 4 grasses and could aid in optimal placement of diverse C 4 bioenergy feedstock across a polluted landscape.

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Section: What Factors Influence O 3 Sensitivity Among Species?mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Testing unified theories for ozone response in C₄ species

Moller

Mitchell

et al. 2022

Global Change Biology

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“…So far, only four C 4 crops have been studied for O 3 response using O 3 ‐FACE facilities (Table 1 ). Research from SoyFACE showed elevated O 3 concentrations (approximately 100 ppb) significantly reduced leaf photosynthetic capacity in maize (Choquette et al., 2019 , 2020 ; Sorgini et al., 2019 ; Wedow et al., 2021b ; Yendrek et al., 2017a , b ), but had little or no effect on photosynthesis and biomass yield in switchgrass (Li et al., 2019a ) and sorghum (Li et al., 2021 ). These studies also reported considerable genotypic variation in O 3 sensitivity among maize and sorghum lines (Choquette et al., 2019 ; Li et al., 2021 ; Yendrek et al., 2017a , b ).…”

Section: Lessons Learned From Face Experimentsmentioning

confidence: 99%

“…Wedow et al. ( 2021b ) investigated differential sensitivity between two inbred maize lines (B73 and Mo17) and the hybrid cross (B73 x Mo17) in relation to the accumulation of defense metabolites in leaf tissue. Senescence was accelerated in the hybrid compared to the inbred lines under elevated [O 3 ] and O 3 ‐induced reductions in photosynthetic carbon assimilation during grain filling were greater in the hybrid line, leading to significantly greater yield loss.…”

Section: Lessons Learned From Face Experimentsmentioning

confidence: 99%

Approaches to investigate crop responses to ozone pollution: from O₃‐FACE to satellite‐enabled modeling

Montes

Demler

et al. 2021

The Plant Journal

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Ozone (O 3 ) is a damaging air pollutant to crops. As one of the most reactive oxidants known, O 3 rapidly forms other reactive oxygen species (ROS) once it enters leaves through stomata. Those ROS in turn can cause oxidative stress, reduce photosynthesis, accelerate senescence, and decrease crop yield. To improve and adapt our feed, fuel, and food supply to rising O 3 pollution, a number of Free Air Concentration Enrichment (O 3 -FACE) facilities have been developed around the world and have studied key staple crops. In this review, we provide an overview of the FACE facilities and highlight some of the lessons learned from the last two decades of research. We discuss the differences between C 3 and C 4 crop responses to elevated O 3 , the possible trade-off between productivity and protection, genetic variation in O 3 response within and across species, and how we might leverage this observed variation for crop improvement. We also highlight the need to improve understanding of the interaction between rising O 3 pollution and other aspects of climate change, notably drought. Finally, we propose the use of globally modeled O 3 data that are available at increasing spatial and temporal resolutions to expand upon the research conducted at the limited number of global O 3 -FACE facilities.

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Ozone stress response of leaf BVOC emission and photosynthesis in mountain birch (Betula pubescens spp. czerepanovii) depends on leaf age

Jaakkola,

Hellén,

Olin

et al. 2024

Plant Enviro Interactions

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Oxidative stress from ozone (O3) causes plants to alter their emission of biogenic volatile organic compounds (BVOC) and their photosynthetic rate. Stress reactions from O3 on birch trees can result in prohibited plant growth and lead to increased BVOC emission rates as well as changes in their compound blend to emit more monoterpenes (MT) and sesquiterpenes (SQT). BVOCs take part in atmospheric reactions such as enhancing the production of secondary organic aerosols (SOA). As the compound blend and emission rate change with O3 stress, this can influence the atmospheric conditions by affecting the production of SOA. Studying the stress responses of plants provides important information on how these reactions might change, which is vital to making better predictions of the future climate. In this study, measurements were taken to find out how the leaves of mature mountain birch trees (Betula pubescens ssp. czerepanovii) respond to different levels of elevated O3 exposure in situ depending on leaf age. We found that leaves from both early and late summers responded with induced SQT emission after exposure to 120 ppb O3. Early leaves were, however, more sensitive to increased O3 concentrations, with enhanced emission of green leaf volatiles (GLV) and tendencies of both induced leaf senescence as well as poor recovery in the photosynthetic rate between exposures. Late leaves had more stable photosynthetic rates throughout the experiment and responded less to exposure at different O3 levels.

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Age‐dependent increase in α‐tocopherol and phytosterols in maize leaves exposed to elevated ozone pollution

Cited by 10 publications

References 96 publications

Testing unified theories for ozone response in C₄ species

Testing unified theories for ozone response in C₄ species

Approaches to investigate crop responses to ozone pollution: from O₃‐FACE to satellite‐enabled modeling

Ozone stress response of leaf BVOC emission and photosynthesis in mountain birch (Betula pubescens spp. czerepanovii) depends on leaf age

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Age‐dependent increase in α‐tocopherol and phytosterols in maize leaves exposed to elevated ozone pollution

Cited by 10 publications

References 96 publications

Testing unified theories for ozone response in C4 species

Testing unified theories for ozone response in C4 species

Approaches to investigate crop responses to ozone pollution: from O3‐FACE to satellite‐enabled modeling

Ozone stress response of leaf BVOC emission and photosynthesis in mountain birch (Betula pubescens spp. czerepanovii) depends on leaf age

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Product

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Testing unified theories for ozone response in C₄ species

Testing unified theories for ozone response in C₄ species

Approaches to investigate crop responses to ozone pollution: from O₃‐FACE to satellite‐enabled modeling