Abstract
Elevated concentrations of CO2 (CO2) in plants with C3 photosynthesis metabolism, such as wheat, stimulate photosynthetic rates. However, photosynthesis tends to decrease as a function of exposure to high (CO2) due to down-regulation of the photosynthetic machinery, and this phenomenon is defined as photosynthetic acclimation. Considerable efforts are currently done to determine the effect of photosynthetic tissues, such us spike, in grain filling. There is good evidence that the contribution of ears to grain filling may be important not only under good agronomic conditions but also under high (CO2). The main objective of this study was to compare photoassimilate production and energy metabolism between flag leaves and glumes as part of ears of wheat (Triticum turgidum L. subsp. durum cv. Amilcar) plants exposed to ambient [a(CO2)] and elevated [e(CO2)] (CO2) (400 and 700 μmol mol–1, respectively). Elevated CO2 had a differential effect on the responses of flag leaves and ears. The ears showed higher gross photosynthesis and respiration rates compared to the flag leaves. The higher ear carbohydrate content and respiration rates contribute to increase the grain dry mass. Our results support the concept that acclimation of photosynthesis to e(CO2) is driven by sugar accumulation, reduction in N concentrations and repression of genes related to photosynthesis, glycolysis and the tricarboxylic acid cycle, and that these were more marked in glumes than leaves. Further, important differences are described on responsiveness of flag leaves and ears to e(CO2) on genes linked with carbon and nitrogen metabolism. These findings provide information about the impact of e(CO2) on ear development during the grain filling stage and are significant for understanding the effects of increasing (CO2) on crop yield.
Highlights
Atmospheric CO2 concentrations (CO2) have increased considerably since the pre-industrial era (≈280 ppm), reaching 414.5 ppm by 2020 (Noaa/Esrl, 2020)
High (CO2) in plants with C3 photosynthetic metabolism, such as wheat, stimulate photosynthetic rates and an increase in plant biomass is observed despite decreases in stomatal conductance (Aranjuelo et al, 2011)
The experiment was conducted with durum wheat plants (Triticum turgidum subsp. durum), using the genotype Amilcar, which is a commercial wheat cultivar widely used in the Navarra region
Summary
Atmospheric CO2 concentrations (CO2) have increased considerably since the pre-industrial era (≈280 ppm), reaching 414.5 ppm by 2020 (Noaa/Esrl, 2020). High (CO2) in plants with C3 photosynthetic metabolism, such as wheat, stimulate photosynthetic rates and an increase in plant biomass is observed despite decreases in stomatal conductance (Aranjuelo et al, 2011). This response is not linear, and after the first stimulation, the photosynthetic rate tends to decrease as a function of the duration of high (CO2) exposure, which is due mainly to accumulation of sugars and down-regulation of photosynthetic machinery, including a decrease in Rubisco protein content and activity. Further work in understanding leaf and ear photosynthesis and C allocation is required to evaluate the ability of crops to exploit projected increases in atmospheric (CO2)
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