Wang Kai, Guo Guanghui, Bai Shenglong, Ma Jianchao, Zhang Zhen, Xing Zeyu, Wang Wei, Li Hao, Liang Huihui, Li Zheng, Si Xiaomin, Wang Jinjin, Liu Qian, Xu Wenyao, Yang Cuicui, Song Ru-Feng, Li Junrong, He Tiantian, Li Jingyao, Zeng Xiaoyu, Liang Jingge, Zhang Fang, Qiu Xiaolong, Li Yuanyuan, Bu Tiantian, Liu Wen-Cheng, Zhao Yusheng, Huang Jinling, Zhou Yun, Song Chun-Peng
State Key Laboratory of Crop Stress Adaptation and Improvement, School of Life Sciences, Henan University, Kaifeng, China.
Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing, China.
Nat Plants. 2025 Apr;11(4):761-774. doi: 10.1038/s41477-025-01952-8. Epub 2025 Mar 27.
Although horizontal gene transfer (HGT) often facilitates environmental adaptation of recipient organisms, whether and how they might affect crop evolution and domestication is unclear. Here we show that three genes encoding cold-shock proteins (CSPs) were transferred from bacteria to Triticeae, a tribe of the grass family that includes several major staple crops such as wheat, barley and rye. The acquired CSP genes in wheat (TaCSPs) are functionally conserved in their bacterial homologues by encoding a nucleic acid-binding protein. Experimental evidence indicates that TaCSP genes positively regulate drought response and improve photosynthetic efficiency under water-deficient conditions by directly targeting a type 1 metallothionein gene to increase reactive oxygen species scavenging, which in turn contributed to the geographic expansion of wheat. We identified an elite CSP haplotype in Aegilops tauschii, introduction of which to wheat significantly increased drought tolerance, photosynthetic efficiency and grain yields. These findings not only provide major insights into the role of HGT in crop adaptation and domestication, but also demonstrate that novel microbial genes introduced through HGT offer a stable and naturally optimized resource for transgenic crop breeding and improvement.
尽管水平基因转移(HGT)通常有助于受体生物适应环境,但它们是否以及如何影响作物进化和驯化尚不清楚。在这里,我们表明,三个编码冷休克蛋白(CSP)的基因从细菌转移到了小麦族,该族是禾本科的一个族,包括几种主要的主食作物,如小麦、大麦和黑麦。小麦中获得的CSP基因(TaCSPs)通过编码一种核酸结合蛋白,在其细菌同源物中功能保守。实验证据表明,TaCSP基因通过直接靶向一种1型金属硫蛋白基因来增加活性氧清除,从而积极调节干旱反应并提高缺水条件下的光合效率,这反过来又促进了小麦的地理扩张。我们在节节麦中鉴定出一种优良的CSP单倍型,将其导入小麦显著提高了耐旱性、光合效率和籽粒产量。这些发现不仅为HGT在作物适应和驯化中的作用提供了重要见解,还表明通过HGT引入的新微生物基因为转基因作物育种和改良提供了稳定且自然优化的资源。
