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Copyright © 2024 CGTN. 京ICP备20000184号
Disinformation report hotline: 010-85061466
Chinese researchers have decoded a novel salt-tolerance gene in wheat, resulting in yield increases of 5 to 9 percent in experimental varieties grown in saline-alkali soils.
The study findings have been published in the journal Nature Genetics.
Chinese researchers have decoded a novel salt-tolerance gene in wheat, resulting in yield increases of 5 to 9 percent in experimental varieties grown in saline-alkali soils. /CFP
Wang Meng, corresponding author of the study, from the Institute of Soil Science (ISS), Chinese Academy of Sciences (CAS), said that China's primary wheat-growing regions coincide with high occurrences of soil salinization. Spring marks a crucial growth period for wheat, characterized by jointing and grain filling, yet it aligns with peak soil salinity, severely impacting wheat growth and yield.
Researchers from the ISS, Northwest A&F University and Qingdao Agricultural University analyzed over 500 wheat varieties and lines cultivated for years in saline-alkali fields and identified TaSPL6-D, a transcriptional suppressor of critical salt-tolerance genes in wheat.
Using a molecular-assisted breeding method, researchers introduced TaSPL6-D-In from a landrace into a leading wheat cultivar, successfully improving the yield in saline-alkali soils. /CFP
The research team found that due to natural genetic variation, there exists a natural variant of TaSPL6-D, termed TaSPL6-D-In in landraces, which loses its ability to suppress key salt-tolerance genes in wheat.
Using a molecular-assisted breeding method, researchers introduced TaSPL6-D-In from a landrace into a leading wheat cultivar, successfully improving the yield in saline-alkali soils.
Zhao Zhendong, an academician with Chinese Academy of Engineering, and Cao Xiaofeng, an academician with CAS, both said that this research provides pivotal design targets for advancing molecular breeding in salt-tolerant wheat and other crops.