Changes in redox status in raspberry (Rubus idaeus L.) fruit during ripening

The knowledge of the mechanisms affecting the process of berry fruit ripening is important, not only to correctly determine the appropriate date of harvest, at which the fruit is most palatable and characterized by adequate shelf-life stability, but also, to develop new strategies of regulating the...

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Published in:Biocatalysis and agricultural biotechnology 2024-10, Vol.61, p.103380, Article 103380
Main Authors: Piechowiak, Tomasz, Sowa-Borowiec, Patrycja
Format: Article
Language:English
Subjects:
adenosinetriphosphatase
agricultural biotechnology
Antioxidants
autophagy
Berries
biocatalysis
biosynthesis
cell respiration
DNA
energy
ethylene production
fruit quality
fruits
glutathione
homeostasis
Immunoblotting
molecular weight
oxidative stress
polyphenols
Quality
raspberries
Ripening
ROS
Rubus idaeus
shelf life
ubiquitination
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description The knowledge of the mechanisms affecting the process of berry fruit ripening is important, not only to correctly determine the appropriate date of harvest, at which the fruit is most palatable and characterized by adequate shelf-life stability, but also, to develop new strategies of regulating the ripening process before harvesting. It is recognized that berry fruit quality and its post-harvest shelf-life depend on the cellular redox homeostasis. We, therefore, decided to conduct a comprehensive analysis of the level of oxidative stress status in the raspberry fruit proper at different stages of fruit ripening, from green to overripe fruit. We assessed both the level of typical oxidative stress markers, i.e. ROS production, expression of antioxidant enzymes, degree of cell damage, as well as the expression of selected proteins involved in the energy, glutathione, and polyphenols metabolism. We found two stage-related peaks of ROS production. The first - in green fruit, which corresponded to the maximum expression of antioxidant enzymes (MnSOD, CAT), PARP-1, as well as proteins related to glutathione biosynthesis (GS, γ-GC), autophagy (ATG-8) and ubiquitination (UBQ-11). The second one, in the overripe fruit, was responsible for the intensification of oxidative modifications of cell components, i.e. lipids, proteins, and DNA, as well as the loss of low molecular-weight antioxidants. The fruit ripening process, in turn, was manifested by a strong increase in the expression of proteins involved in the biosynthesis of polyphenols (PAL, CHS), cellular respiration (ACO-1, Cyt-C-ox, ATPase), ethylene biosynthesis and signaling (SAMs, EIN-2) and increasing amounts of ABA. [Display omitted] •Raspberry ripening is regulated by ROS, ABA and ethylene.•Autophagy and ubiquitination occur most intensively in green fruit.•Fruit ripening is associated with an increase in PAL and CHS expression.•The greatest degree of damage of cell components is in overripe fruit.
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It is recognized that berry fruit quality and its post-harvest shelf-life depend on the cellular redox homeostasis. We, therefore, decided to conduct a comprehensive analysis of the level of oxidative stress status in the raspberry fruit proper at different stages of fruit ripening, from green to overripe fruit. We assessed both the level of typical oxidative stress markers, i.e. ROS production, expression of antioxidant enzymes, degree of cell damage, as well as the expression of selected proteins involved in the energy, glutathione, and polyphenols metabolism. We found two stage-related peaks of ROS production. The first - in green fruit, which corresponded to the maximum expression of antioxidant enzymes (MnSOD, CAT), PARP-1, as well as proteins related to glutathione biosynthesis (GS, γ-GC), autophagy (ATG-8) and ubiquitination (UBQ-11). The second one, in the overripe fruit, was responsible for the intensification of oxidative modifications of cell components, i.e. lipids, proteins, and DNA, as well as the loss of low molecular-weight antioxidants. The fruit ripening process, in turn, was manifested by a strong increase in the expression of proteins involved in the biosynthesis of polyphenols (PAL, CHS), cellular respiration (ACO-1, Cyt-C-ox, ATPase), ethylene biosynthesis and signaling (SAMs, EIN-2) and increasing amounts of ABA. 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The second one, in the overripe fruit, was responsible for the intensification of oxidative modifications of cell components, i.e. lipids, proteins, and DNA, as well as the loss of low molecular-weight antioxidants. The fruit ripening process, in turn, was manifested by a strong increase in the expression of proteins involved in the biosynthesis of polyphenols (PAL, CHS), cellular respiration (ACO-1, Cyt-C-ox, ATPase), ethylene biosynthesis and signaling (SAMs, EIN-2) and increasing amounts of ABA. 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subjects adenosinetriphosphatase
agricultural biotechnology
Antioxidants
autophagy
Berries
biocatalysis
biosynthesis
cell respiration
DNA
energy
ethylene production
fruit quality
fruits
glutathione
homeostasis
Immunoblotting
molecular weight
oxidative stress
polyphenols
Quality
raspberries
Ripening
ROS
Rubus idaeus
shelf life
ubiquitination
title Changes in redox status in raspberry (Rubus idaeus L.) fruit during ripening
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