Interaction between increased CO2 and temperature enhance plant growth but do not affect millet grain production

Lima, Gabriela Viana de Oliveira; Oki, Yumi; Bordignon, Leandra; Siqueira, Wallison K.; França, Marcel Giovanni Costa; Boanares, Daniela; Franco, Augusto C.; Fernandes, Geraldo Wilson

doi:10.4025/actasciagron.v44i1.53515

Cited by 4 publications

(2 citation statements)

References 35 publications

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“…Previous work has reported that the blueberry crop presents high yield instability associated with the capacity to assimilate CO 2 due to a year-to-year environmental variation [ 24 ]. Light and temperature are two of the most important environmental factors in crop production; the CO 2 is assimilated in photosynthesis and its concentration increase in the atmosphere may influence carbon uptake and assimilation rate and, therefore, plant growth [ 25 ]. Photosynthesis increases as CO 2 increases until it reaches saturating concentrations, as high CO 2 allows plants to use the light more efficiently.…”

Section: Discussionmentioning

confidence: 99%

Photosynthetic Response of Blueberries Grown in Containers

Salazar-Gutiérrez,

Lawrence,

Coneva

et al. 2023

Plants

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Recently, there has been increased interest in container blueberry production as a viable alternative to open-field blueberry planting. Container production of blueberries offers numerous advantages, among these, a lack of limitation by suboptimal soil conditions in the open field and the ability to control substrate pH, drainage, and organic matter. The photosynthetic response for three container-grown Southern highbush blueberry (interspecific Vaccinium hybrids) cultivars including ‘Jewel’, ‘Meadowlark’, and ‘Victoria’ and a rabbiteye blueberry (Vaccinium virgatum) ‘Baldwin’, were measured during the spring and summer of 2022. It was hypothesized that the three cultivars evaluated would have different photosynthetic responses. The objective of this study was to determine the photosynthetic activity of different blueberry cultivars during the first year of crop establishment. A series of measurements were conducted every 2 h throughout the day and for different dates using a gas exchange data analyzer on newly matured fully expanded leaves located in the top middle section of the canopy for each cultivar. The response curves showed that net photosynthesis (A) became saturated at moderate light, with saturation occurring at a photosynthetic photon flux density (PPFD) of 1932 µmol m−2 s−1. At this point, the rate of CO2 assimilation was approximately 16.84 µmol CO2 m−2 s−1. No differences in (A) were found among cultivars. Overall, the attained values of photosynthesis provide a strong conceptual basis for understanding the cultivar variation response when grown in containers; therefore, the containerized system may serve as a production system for early fruiting blueberries in Alabama, USA.

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Section: Discussionmentioning

confidence: 99%

Photosynthetic Response of Blueberries Grown in Containers

Salazar-Gutiérrez,

Lawrence,

Coneva

et al. 2023

Plants

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“…In addition, eCO 2 can also mitigate the effects of drought by increasing WUE and improving PSII function [ 4 , 45 ]. Moreover, in combination with temperature stress, eCO 2 can also accelerate plant growth [ 46 ]. However, both high and ultra-high concentrations of CO 2 are known to exert a negative effect on photosynthesis via drought and heat stress [ 20 , 47 ].…”

Section: Introductionmentioning

confidence: 99%

Drought Has a Greater Negative Effect on the Growth of the C3 Chenopodium quinoa Crop Halophyte than Elevated CO2 and/or High Temperature

Rakhmankulova,

Shuyskaya,

Prokofieva

et al. 2024

Plants

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Plant growth and productivity are predicted to be affected by rising CO2 concentrations, drought and temperature stress. The C3 crop model in a changing climate is Chenopodium quinoa Willd—a protein-rich pseudohalphyte (Amaranthaceae). Morphophysiological, biochemical and molecular genetic studies were performed on quinoa grown at ambient (400 ppm, aCO2) and elevated (800 ppm, eCO2) CO2 concentrations, drought (D) and/or high temperature (eT) treatments. Among the single factors, drought caused the greatest stress response, inducing disturbances in the light and dark photosynthesis reactions (PSII, apparent photosynthesis) and increasing oxidative stress (MDA). Futhermore, compensation mechanisms played an important protective role against eT or eCO2. The disruption of the PSII function was accompanied by the activation of the expression of PGR5, a gene of PSI cyclic electron transport (CET). Wherein under these conditions, the constant Rubisco content was maintained due to an increase in its biosynthesis, which was confirmed by the activation of rbcL gene expression. In addition, the combined stress treatments D+eT and eCO2+D+eT caused the greatest negative effect, as measured by increased oxidative stress, decreased water use efficiency, and the functioning of protective mechanisms, such as photorespiration and the activity of antioxidant enzymes. Furthermore, decreased PSII efficiency and increased non-photochemical quenching (NPQ) were not accompanied by the activation of protective mechanisms involving PSI CET. In summary, results show that the greatest stress experienced by C. quinoa plants was caused by drought and the combined stresses D+eT and eCO2+D+eT. Thus, drought consistently played a decisive role, leading to increased oxidative stress and a decrease in defense mechanism effectiveness.

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