Disentangling the Effects of Water Stress on Carbon Acquisition, Vegetative Growth, and Fruit Quality of Peach Trees by Means of the QualiTree Model

Rahmati, Mitra; Mirás-Avalos, José Manuel; Valsesia, Pierre; Lescourret, Françoise; Génard, Michel; Davarynejad, Gholam Hossein; Bannayan, Mohammad; Azizi, Majid; Vercambre, Gilles

doi:10.3389/fpls.2018.00003

Cited by 43 publications

(29 citation statements)

References 75 publications

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“…Bordonaba and Terry () reported that the content of total sugars decreased from 70.8 to 67.1 mg/g FW in strawberry cutivar Florence, but increased from 58.6 and 68.8 to 82.3 and 81.6 mg/g FW, respectively, in cultivars Elsanta and Sonata, and did not change significantly in cultivars Christine and Symphony under low level of irrigation. In the case of fructose and glucose, irrigation exhibited negative impacts on the contents of these two sugars in fruits of satsuma mandarins (Yakushiji, Morinaga, & Nonami, ) and peach (Rahmati et al, ), but had no impact on their contents in kiwifruits (Miller, Smith, Boldingh, & Johansson, ). The impact of deficient irrigation on sucrose content in fruits of nectarine, peach, plum, satsuma mandarins, mango fruit, and strawberry were also investigated.…”

Section: Sugarsmentioning

confidence: 99%

“…Elevations in sucrose content in fruits of nectarine (Thakur & Singh, ), plum (Maatallah et al, ), and satsuma mandarins (Yakushiji et al, ) were detected under deficient irrigation, while no impact of such condition on the sucrose content in mango fruit and strawberry (Bordonaba & Terry, ; Terry et al, ) were found. In peach, the content of sucrose decreased in response to increased water deficit (Rahmati et al, ). The plants growing wildly will never be irrigated, but precipitation contributes in the same way as irrigation to the plant growth.…”

Section: Sugarsmentioning

confidence: 99%

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Regulation of phytochemicals in fruits and berries by environmental variation—Sugars and organic acids

et al. 2018

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Sugars and organic acids are important phytochemicals contributing to the nutrition and sensory properties of fruits and berries. Their contents are closely correlated to the genetic background of plants as well as to the environmental conditions during growth. This review focuses on the recent researches on the metabolism of these compounds in fruits and berries in response to the variation of environmental conditions, including temperature, radiation, and water supply. A great deal of investigations indicates that the influence of environmental factors on the composition of fruits/berries depended largely on the genetic background. Moreover, the metabolic regulation in response to environmental changes also varies between different plant developmental stages. Nevertheless, some general trends, like the positive correlation between light intensity and sugar content, were observed in most investigations. In grapes (Vitis vinifera L.), the content of malic acid always decreases as light intensity increases, and as the water supply decreases. Practical applications The contents of sugars and organic acids, and especially their relative ratio, are important indicators determining the taste and quality of fruits and fruit products. In this review, we summarized the investigations carried out on the regulation of these sensory contributing primary metabolites in fruits and berries in relation to the variation of environmental conditions. It was indicated that various factors, such as plant genotype, growing period, and interaction between environmental factors, might contribute to the impact of environmental changes on the composition of fruits/berries. The article not only provides comprehensive knowledges in food chemistry and plant physiology but also provide important background knowledge for berry cultivation and breeding, as well as useful guidelines for utilization of fruits and berries in food industry.

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Section: Sugarsmentioning

confidence: 99%

Section: Sugarsmentioning

confidence: 99%

Regulation of phytochemicals in fruits and berries by environmental variation—Sugars and organic acids

et al. 2018

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“…During the early stage of water stress, plants maintain the leaf water potential and CO 2 assimilation rate by decreasing stomatal conductance [11]. However, under severe and prolonged water stress, excessive decrease in stomatal conductance may result in decrease in CO 2 assimilation rate [7,12]. In addition, plants strive to maintain the water balance under drought stress by excessive production of proline and soluble sugars that helps maintaining the osmotic pressure in the cytoplasm [11].…”

Section: Introductionmentioning

confidence: 99%

Effects of Soil Water Deficit on Three Tree Species of the Arid Environment: Variations in Growth, Physiology, and Antioxidant Enzyme Activities

et al. 2021

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Low water availability predicted under climate change is a major abiotic factor limiting plants growth and productivity. In this study a greenhouse experiment was conducted on three important tree species of arid environment: Conocarpus erectus (CE), Acacia modesta (AM), and Salix tetrasperma (ST). Young saplings were subjected to control (C), medium (MWD) and severe soil water deficit (SWD) treatments and response was evaluated. Results showed that in all the three species leaf, stem and root dry weight production remained similar to C under MWD treatment but decreased significantly under SWD. The highest decrease in total dry weight was noticed in ST and the lowest was evidenced in AM under SWD. Root:shoot ratio increased significantly in both CE and AM under MWD and SWD. Furthermore, chlorophyll content decreased while proline content increased significantly in both MWD and SWD treatments. The production of oxidants (hydrogen peroxide and superoxide anions) and antioxidants (superoxide dismutase, catalase, peroxidase and ascorbate peroxidase) increased significantly under both MWD and SWD treatments and were the highest in AM in both MWD and SWD treatments. Therefore, we may conclude that all the three species can tolerate medium water stress due to increased root production and an effective antioxidant defense mechanism.

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“…Over the past few decades, the frequency and intensity of regional and global extremes in water deficits have increased. Its impact on growth, morphology, and physiological processes within the aboveground and belowground parts of a plant can be measured in several ways, e.g., gas exchange, stomatal conductance, water relations, root longevity, leaf water potential, activity of phytohormones and reactive oxygen species, cell division, nutrient assimilation and transport, and metabolic processes ( Ergo et al, 2018 ; Rahmati et al, 2018 ). Under drought conditions, plants generally close their stomata to minimize water losses, thereby reducing photosynthetic capacity.…”

Section: Introductionmentioning

confidence: 99%

Effects of Exogenous Dopamine on the Uptake, Transport, and Resorption of Apple Ionome Under Moderate Drought

et al. 2018

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The frequency and intensity of water deficits is expected to increase because of global warming. Drought stress is often one of the most limiting factors for plant growth. We conducted greenhouse pot experiments to address how dopamine affects the drought-resistance traits of apple trees at the physiological and molecular levels. Our factorial design consisted of dopamine and no-dopamine applications combined with well-watered and moderate-drought conditions. Seedling biomass, photosynthesis rates, chlorophyll concentrations, and stomatal apertures were markedly reduced under stress but dopamine treatment mitigated the inhibiting effects of drought on plant growth and helped maintain strong photosynthesis, chlorophyll levels, and stomatal functioning. Concentrations of most macro-, micro-, and trace elements decreased in response to drought. This stress also diminished the uptake and transport of elements in the leaves and stems, but increased the partitioning of elements in the roots. Nutrient resorption proficiency decreased while nutrient resorption efficiency increased for most analyzed elements. Exogenous dopamine significantly increased the concentrations, uptake, and transport of nutrients under drought stress, and also altered their distribution within the whole plant. However, this molecule had a negative effect on nutrient resorption. Although transcript levels of a key chlorophyll degradation gene, pheide a oxygenase, and senescence-associate gene 12 were elevated upon drought treatment, dopamine significantly suppressed the upregulation of those genes under such stress conditions. These observations indicate that dopamine has an important anti-senescence effect that might be helpful for regulating nutrient uptake, transport, and resorption, and ultimately influencing overall plant growth. Thus, understanding the role of dopamine in drought tolerance introduces new possibilities to use this compound for agricultural purposes.

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Disentangling the Effects of Water Stress on Carbon Acquisition, Vegetative Growth, and Fruit Quality of Peach Trees by Means of the QualiTree Model

Cited by 43 publications

References 75 publications

Regulation of phytochemicals in fruits and berries by environmental variation—Sugars and organic acids

Regulation of phytochemicals in fruits and berries by environmental variation—Sugars and organic acids

Effects of Soil Water Deficit on Three Tree Species of the Arid Environment: Variations in Growth, Physiology, and Antioxidant Enzyme Activities

Effects of Exogenous Dopamine on the Uptake, Transport, and Resorption of Apple Ionome Under Moderate Drought

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