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论文题目: |
Nano-ZnO alleviates drought stress via modulating the plant water use and carbohydrate metabolism in maize |
英文论文题目: |
Nano-ZnO alleviates drought stress via modulating the plant water use and carbohydrate metabolism in maize |
第一作者: |
Sun, Luying |
英文第一作者: |
Sun, Luying |
联系作者: |
宋凤斌,李向楠 |
英文联系作者: |
F. B. Song,X. N. Li |
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发表年度: |
2020 |
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摘要: |
The wide application of zinc oxide (ZnO) nanoparticles inevitably facilities their release into the terrestrial and agricultural ecosystems, severely affecting crop production. The effects of nano-ZnO (100 mg L-1) on stomatal morphology, gas exchange and key carbon metabolism enzyme activities were investigated in drought-stressed and well-watered maize. Drought stress limited the plant growth, caused stomatal closure, decreased the net photosynthetic rate, while increased the osmolyte concentrations. In drought-stressed maize, the application of nano-ZnO (100 mg L-1) alleviated photosynthetic pigment degradation and benefited the stomatal movement, maintained a higher net photosynthetic rate, and enhanced water use efficiency, promoting the drought tolerance in maize. In addition, the nano-ZnO increased the activities of UDP-glucose pyrophosphorylase, phosphoglucoisomerase and cytoplasmic invertase by 17.8%, 391.5% and 126%, respectively, which enhanced the starch and sucrose biosynthesis and glycolysis metabolism in leaves under drought stress. Manipulation of primary carbohydrate metabolism through nano-ZnO induced regulation of the key enzymes activity benefited the drought tolerance in maize. The nano-ZnO application (100 mg L-1) alleviates the negative effect of drought stress via improving photosynthetic carbon assimilation of maize. |
英文摘要: |
The wide application of zinc oxide (ZnO) nanoparticles inevitably facilities their release into the terrestrial and agricultural ecosystems, severely affecting crop production. The effects of nano-ZnO (100 mg L-1) on stomatal morphology, gas exchange and key carbon metabolism enzyme activities were investigated in drought-stressed and well-watered maize. Drought stress limited the plant growth, caused stomatal closure, decreased the net photosynthetic rate, while increased the osmolyte concentrations. In drought-stressed maize, the application of nano-ZnO (100 mg L-1) alleviated photosynthetic pigment degradation and benefited the stomatal movement, maintained a higher net photosynthetic rate, and enhanced water use efficiency, promoting the drought tolerance in maize. In addition, the nano-ZnO increased the activities of UDP-glucose pyrophosphorylase, phosphoglucoisomerase and cytoplasmic invertase by 17.8%, 391.5% and 126%, respectively, which enhanced the starch and sucrose biosynthesis and glycolysis metabolism in leaves under drought stress. Manipulation of primary carbohydrate metabolism through nano-ZnO induced regulation of the key enzymes activity benefited the drought tolerance in maize. The nano-ZnO application (100 mg L-1) alleviates the negative effect of drought stress via improving photosynthetic carbon assimilation of maize. |
刊物名称: |
Archives of Agronomy and Soil Science |
英文刊物名称: |
Archives of Agronomy and Soil Science |
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参与作者: |
L. Y. Sun, F. B. Song, X. C. Zhu, S. Q. Liu, F. L. Liu, Y. J. Wang and X. N. Li |
英文参与作者: |
L. Y. Sun, F. B. Song, X. C. Zhu, S. Q. Liu, F. L. Liu, Y. J. Wang and X. N. Li |
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