Chronic ozone exposure alters the secondary metabolite profile, antioxidant potential, anti-inflammatory property, and quality of red pepper fruit from Capsicum baccatum

Tropospheric ozone (O3) background concentrations have increased since pre-industrial times, reaching phytotoxic concentrations in many regions globally. However, the effect of high O3 concentrations on quality of fruit and vegetables remains unknown. Here, we evaluated whether O3 pollution alters t...

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Published in:Ecotoxicology and environmental safety 2016-07, Vol.129, p.16-24
Main Authors: Bortolin, Rafael Calixto, Caregnato, Fernanda Freitas, Divan Junior, Armando Molina, Zanotto-Filho, Alfeu, Moresco, Karla Suzana, de Oliveira Rios, Alessandro, de Oliveira Salvi, Aguisson, Ortmann, Caroline Flach, de Carvalho, Pâmela, Reginatto, Flávio Henrique, Gelain, Daniel Pens, Fonseca Moreira, José Cláudio
Format: Article
Language:English
Subjects:
Air Pollutants - toxicity
Anti-Inflammatory Agents - metabolism
Antioxidant potential
Antioxidants - metabolism
Bioactive compounds
Capsaicin - metabolism
Capsicum
Capsicum - drug effects
Capsicum - metabolism
Capsicum baccatum
Carotenoids - metabolism
Fruit - drug effects
Fruit - metabolism
Fruit quality
Oxidants - toxicity
Ozone
Ozone - toxicity
Pepper
Phenols - metabolism
Seeds - drug effects
Seeds - metabolism
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Summary:Tropospheric ozone (O3) background concentrations have increased since pre-industrial times, reaching phytotoxic concentrations in many regions globally. However, the effect of high O3 concentrations on quality of fruit and vegetables remains unknown. Here, we evaluated whether O3 pollution alters the quality of Capsicum baccatum peppers by changing the secondary compound profiles and biological activity of the fruit. C. baccatum pepper plants were exposed to ozone for 62 days in an open-top chamber at a mean O3 concentration of 171.6µg/m3. Capsaicin levels decreased by 50% in the pericarp, but remained unchanged in the seeds. In contrast, the total carotenoid content increased by 52.8% in the pericarp. The content of total phenolic compounds increased by 17% in the pericarp. The total antioxidant potential decreased by 87% in seeds of O3-treated plants. The seeds contributed more than the pericarp to the total radical-trapping antioxidant potential and total antioxidant reactivity. O3 treatment impaired the ferric-reducing antioxidant power of the seeds and reduced NO•-scavenging activity in the pericarp. However, O3 treatment increased ferrous ion-chelating activity and hydroxyl radical-scavenging activity in the pericarp. Our results confirm that O3 alters the secondary metabolite profile of C. baccatum pepper fruits and, consequently, their biological activity profile. [Display omitted] •Fruit quality alteration from ozone-exposed pepper plants was assessed.•O3 exposure decreases capsaicin (main pungent compound) content in pepper pericarp.•O3 exposure decreases total antioxidant potential in pepper seeds.•Anti-inflammatory property is decreased in pericarp of ozone-exposed pepper plants.
ISSN:0147-6513
1090-2414
DOI:10.1016/j.ecoenv.2016.03.004