Nano-ZnO priming induces salt tolerance by promoting photosynthetic carbon assimilation in wheat

High salt seriously reduces plant growth in wheat by depressing photosynthetic carbon assimilation. In this study, wheat plants were firstly primed with nano-ZnO (50 mg L −1 ), and after 20-day recovery, the plants were then exposed to a 10-day salt stress (200 mM NaCl). The nano-ZnO priming signifi...

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Published inArchiv für Acker- und Pflanzenbau und Bodenkunde Vol. 66; no. 9; pp. 1259 - 1273
Main Authors Wang, Zongshuai, Li, Hui, Li, Xiangnan, Xin, Caiyun, Si, Jisheng, Li, Shengdong, Li, Yujie, Zheng, Xinxin, Li, Huawei, Wei, Xiuhua, Zhang, Zhiwei, Kong, Lingan, Wang, Fahong
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis 28.07.2020
Taylor & Francis Ltd
Subjects
Abiotic stress
Antioxidants
Assimilation
Biological assimilation
Biosynthesis
carbohydrate metabolism
Carbon
Chlorophyll fluorescence
Electron transport
Homeostasis
Invertase
Leaves
Phosphoglucomutase
Photosynthesis
Photosynthetic apparatus
Plant growth
Plants
Priming
salinity
Salinity tolerance
Salt tolerance
Scavenging
Sodium chloride
Stress
Sucrose
Sugar
Triticum aestivum
Water potential
Wheat
Zinc oxide
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Summary:High salt seriously reduces plant growth in wheat by depressing photosynthetic carbon assimilation. In this study, wheat plants were firstly primed with nano-ZnO (50 mg L −1 ), and after 20-day recovery, the plants were then exposed to a 10-day salt stress (200 mM NaCl). The nano-ZnO priming significantly reduced Na concentration and increased leaf water potential under salt stress. In relation to the non-primed plants, the nano-ZnO primed plants possessed more effective oxygen scavenging system as exemplified by the enhanced activities of SOD, APX and CAT, leading to a better maintenance in homeostasis of ROS production under salt stress. The nano-ZnO priming benefited the tolerance of photosynthetic apparatus to subsequent salt stress, which was mainly due to the enhanced trapped energy flux and electron transport flux. The nano-ZnO priming increased the activities of phosphoglucomutase and cytoplasmic invertase, which promoted the sucrose biosynthesis in leaves under salt stress. In addition, the nano-ZnO primed plants had higher shoot dry weight than the non-primed plants under salt stress. Collectively, nano-ZnO priming activated the antioxidant system to depress the oxidative burst and enhanced the efficiency of photosynthetic electron transport and sucrose biosynthesis in leaves under salt stress, hereby improved the salt tolerance in wheat.
ISSN:0365-0340
1476-3567
DOI:10.1080/03650340.2019.1663508