Interactive effect of elevated CO2 concentration and drought on photosynthetic and physiological indexes of foxtail millet
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Abstract
There is a lack of knowledge on the interactive effects of elevated atmospheric carbon dioxide (CO2) concentrations (CO2) and drought on the photosynthesis and physiological processes underlying foxtail millet drought resistance. An experiment was conducted in an open-top chamber with two CO2 treatments, ambient CO2 (CK, 400 μmol·mol-1) and elevated CO2 (ECO2, 600 μmol·mol-1), and two water treatments, normal water (relative water content was 75%-85% soil capacity) and drought (relative water content was 35%-45% soil capacity). We quantified the interactive effects of elevated CO2 and drought on the gas exchange parameters, fluorescence parameters, and drought-resistant physiological indicators in millet. The results showed that elevated CO2 could reduce the content of photosynthetic pigment under drought conditions. Elevated CO2 aggravated millet stomatal closure at the booting stage, alleviated the negative effects of drought on the net photosynthetic rate at the filling stage, and increased the water utilization efficiency. During the booting stage, elevated CO2 resulted in a 66.7% reduction in stomatal conductance under normal water conditions and a 77.7% reduction under drought conditions. During the grouting period, under normal water conditions, elevated CO2 led to a 19.0% increase in the grain net photosynthetic rate and a 37.1% increase in water use efficiency; under drought conditions, it led to an 87.7% increase in the grain net photosynthetic rate and a 39.2% increase in water use efficiency, respectively compared with that of ambient CO2. Drought significantly reduced all of the millet fluorescence kinetic parameters, except non-photochemical quenching (NPQ), and elevated CO2 alleviated this effect in the grouting period. At the booting stage, ECO2 and drought showed significant interactive effects on the intrinsic efficiency of photosystem Ⅱ (PSⅡ) (Fv/Fm'), PSⅡ photochemistry (ΦPSⅡ), and the highest photosynthetic electron transport (ETR) and photochemical quenching coefficient (qP). Elevated CO2 significantly reduced the content of cellulose and activity of peroxidase (POD) under normal water conditions. POD activity (under ECO2), and contents of proline, soluble total sugar, starch content (under CK), and the cellulose content (under ECO2) were significantly increased under drought conditions. We conclude that elevated CO2 can enhance the drought resistance of C4 foxtail millet by improving the photochemical efficiency of photosystem Ⅱ and the activity of antioxidant enzymes.
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