Quantifying the effects of ozone on plant reproductive growth and development

Leisner, Courtney P.; Ainsworth, Elizabeth A.

doi:10.1111/j.1365-2486.2011.02535.x

Cited by 125 publications

(97 citation statements)

References 80 publications

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“…O 3 caused the reduction and the abortion of bud and flowers (Black et al 2007) and the decrease in fruit weight and fruit number in a significant manner (Leisner and Ainsworth 2012), and in these processes ET could be actively involved (Wilkinson et al 2011). …”

Section: Ethylene (Et)mentioning

confidence: 96%

“…Two types of exposure are defined: (1) acute, high concentrations, above 120 ppb for a few hours, as may occur at most polluted sites and (2) chronic, an elevated background concentration with daily peak concentrations in the range of 40-120 ppb over several days in the growing season (Long and Naidu 2002). Chronic exposures to low levels of O 3 result in a (1) decline in photosynthesis, (2) growth inhibition, and (3) premature senescence, normally even without visible damage (Krupa 2003;Leisner and Ainsworth 2012;Vainonen and Kangasjärvi 2015). Conversely, acute exposures, which can occur several times throughout the growing season, lead to the induction of cell death and visible leaf injuries in sensitive plants (Rao et al 2000).…”

Section: Introductionmentioning

confidence: 97%

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Involvement of Phytohormones in Plant Responses to Ozone

Pellegrini

Trivellini

Cotrozzi

et al. 2016

Plant Hormones Under Challenging Environmental Factors

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Among various contaminants, ozone (O 3 ) is considered the most ubiquitous and phytotoxic atmospheric pollutant in industrialized and developing countries. It causes extensive risks for plant life, in terms of survival and productivity of wild and cultivated species. Plant response to O 3 resembles the biotic defense reactions and includes two steps: the first is a biphasic oxidative burst with a massive, rapid, and transient increase in apoplastic reactive oxygen species (ROS) production; the second is the induction of the hypersensitive response (HR) and systemic acquired resistance (SAR). In particular, the acute O 3 exposure (high concentrations for a few hours) results in the activation of programmed cell death (PCD) response that interacts with the synthesis of several hormones and other signaling molecules. The cross talk among all these molecules and their complex and interconnected signaling pathways are more important to determine (1) the initiation, propagation, and containment of O 3 -induced cell death, (2) the degree of the sensitivity of plants to this contaminant, and (3) the regulatory potential that plants have to promptly respond to oxidative stress. The present chapter reviews the role of phytohormones (such as ethylene, abscisic acid, gibberellins, auxins, and cytokinins) and other signaling molecules (such as salicylic and jasmonic acids, proline, and brassinosteroids), as well as their synergistic and antagonistic effects, in the complex signaling pathway involved in plant responses to O 3 stress.

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Section: Ethylene (Et)mentioning

confidence: 96%

Section: Introductionmentioning

confidence: 97%

Involvement of Phytohormones in Plant Responses to Ozone

Pellegrini

Trivellini

Cotrozzi

et al. 2016

Plant Hormones Under Challenging Environmental Factors

View full text Add to dashboard Cite

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“…Ozone has been frequently reported to cause severe risks to a variety of targets, including forest vegetation (Leisner and Ainsworth 2012) and human health (WHO 2000). In Europe, the Directive 2008/50/ EC ( /50/EC 2008 sets acceptable limits for ozone concentration and exposure to protect human health and vegetation, for which thresholds are also defined by UNECE (CLRTAP 2004).…”

Section: Introductionmentioning

confidence: 99%

Estimating ozone risks using forest monitoring networks—results for science, policy, and society

Cristofori

Bacaro

Confalonieri

et al. 2015

Annals of Forest Science

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Abstract& Key message Few integration steps (adding low-cost ozone measurements, link to existing conventional monitors, joint data processing) transformed the traditional forest monitoring network into a multifunctional infrastructure producing information relevant for estimating risk to vegetation and human health & Context Traditionally, forest monitoring networks have been designed to assess status and trends of forest condition. We argue that they can help providing answers to a much broader range of questions for science, policy, and society. Here, we concentrate on the example of ground-level ozone pollution. & Aims The aim of this study is to demonstrate the value of present forest monitoring networks as infrastructures thatwith few integration steps-can provide important data and information to estimate the risk posed by ground-level ozone to vegetation and human health. & Methods We measured ozone concentration by passive samplers at the local (Trentino, northern Italy) plots of the ICP Forests Level I network over the period [2007][2008][2009][2010][2011]. By integrating these data with those from conventional ozone monitors (mostly located in urban areas), we (i) obtained an even distribution of air quality measurements over the investigated area, (ii) estimated international exposure indicators for vegetation and human population, and (iii) obtained data allowing geostatistical modeling and mapping of ozone concentrations, exposure, and associated potential risk. & Results Mean May-July ozone concentration ranged from 58 to 169 μg m −3, depending on forest site and year. ModelingHandling Editor: Pasi RAUTIO Contribution of the co-authors Antonella Cristofori contributed to design the experiment, running field work, and write the paper; Giovanni Bacaro contributed to model ozone concentrations and write the paper; Mauro Confalonieri contributed to organize field work and write the paper; Fabiana Cristofolini contributed to design the experiment, running field work, and write the paper; Luisa Frati contributed to model ozone concentrations, derive and map ozone risk for population, and write the paper; Francesco Geri contributed to map ozone concentrations and write the paper; Elena Gottardini contributed to design the experiment, running field work, coordinating the research project, and write the paper; Gabriele Tonidandel contributed to collect ozone concentration data and write the paper; Fabio Zottele contributed to spatialize temperature data and write the paper; Marco Ferretti contributed to design the experiment, supervise the work, and write the paper. ) provided evidence that the risk threshold for vegetation in terms of AOT40 was exceeded in large parts (90 %) of the study area, and frequently even by two times, depending on the year. With respect to population, up to 43 % of the dwellers were exposed to medium-high risk of exceedances of the information threshold. & Conclusion Ozone measurements carried out at the ICP Forests Level I forest monitoring network permitted mapping ozone levels...

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“…O 3 is one of the most damaging tropospheric air pollutants affecting plant growth and productivity (Leisner and Ainsworth, 2012). Concentrations of tropospheric O 3 have increased considerably since the Industrial Revolution, especially during the past 60 years, and are likely to continue to increase by 10-30 parts per billion (ppb) by 2100 if current high emission rates continue in the Northern Hemisphere (The Royal Society, 2008).…”

Section: Introductionmentioning

confidence: 99%

Impact of Elevated Ozone on Growth, Yield and Nutritional Quality of Two Wheat Species in Northern India

Tomer

Bhatia

Kumar

et al. 2015

Aerosol Air Qual. Res.

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Sensitivity to tropospheric ozone is highly variable in cultivars of different plant species. Wheat, an important cereal crop, has been found to be sensitive to elevated ozone levels leading to differences in grain yields. The objective of this study was to compare the effects of elevated tropospheric ozone on growth, yield and nutritional quality of two species of wheat, Triticum aestivum (PBW 343) and Triticum durum (HD 2936), which are tropical wheat cultivars commonly grown in northern India. Experiments were conducted growing winter wheat (rabi season) under elevated tropospheric ozone in northern India for two years in open-top chambers (OTCs) under charcoal-filtered air (CF), non-filtered air (NF), open air (OA) and elevated ozone (EO) concentration (NF + 25-35 ppb O 3 ). There were different species responses to EO, with the modern aestivum wheat cultivar being more sensitive than durum wheat. The declines in all growth and yield parameters were greater in T. aestivum than T. durum in both the years. On average there was a 7% greater reduction in the photosynthetic rate and stomatal conductance in T. aestivum as compared to T. durum under EO at the flowering stage, and a 6% more reduction in leaf chlorophyll was observed on T. aestivum as compared to T. durum. Exposure to elevated O 3 caused a decrease in the number of leaves and leaf area index, rubisco enzyme activity and chlorophyll in both the species. More reductions in grain yield were observed in T. aestivum (15 and 19%) as compared to T. durum (9 and 13%) under EO in the two years, respectively. Filtration of air significantly increased all growth and yield parameters in both species of wheat.

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Quantifying the effects of ozone on plant reproductive growth and development

Cited by 125 publications

References 80 publications

Involvement of Phytohormones in Plant Responses to Ozone

Involvement of Phytohormones in Plant Responses to Ozone

Estimating ozone risks using forest monitoring networks—results for science, policy, and society

Impact of Elevated Ozone on Growth, Yield and Nutritional Quality of Two Wheat Species in Northern India

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