Zhang Weixi, Wang Yanbo, Zhang Tengqian, Zhang Jing, Shen Le, Zhang Bingyu, Ding Changjun, Su Xiaohua
State Key Laboratory of Tree Genetics and Breeding, Research Institute of Forestry, Chinese Academy of Forestry, Beijing, China.
Key Laboratory of Tree Breeding and Cultivation, National Forestry and Grassland Administration, Beijing, China.
Front Bioeng Biotechnol. 2022 Jun 14;10:929681. doi: 10.3389/fbioe.2022.929681. eCollection 2022.
During the last several decades, a number of transgenic or genetically modified tree varieties with enhanced characteristics and new traits have been produced. These trees have become associated with generally unsubstantiated concerns over health and environmental safety. We conducted transcriptome sequencing of transgenic × expressing the transcription factor JERF36 gene (ABJ01) and the non-transgenic progenitor line (9#) to compare the transcriptional changes in the apical buds. We found that 0.77% and 1.31% of the total expressed genes were significant differentially expressed in ABJ01 at the Daqing and Qiqihar sites, respectively. Among them, 30%-50% of the DEGs contained cis-elements recognized by . Approximately 5% of the total number of expressed genes showed significant differential expression between Daqing and Qiqihar in both ABJ01 and 9#. 10 DEGs resulting from foreign gene introduction, 394 DEGs that resulted solely from the environmental differences, and 47 DEGs that resulted from the combination of foreign gene introduction and the environment were identified. The number of DEGs resulting from environmental factors was significantly greater than that resulting from foreign gene introduction, and the combined effect of the environmental effects with foreign gene introduction was significantly greater than resulting from the introduction of alone. GO and KEGG annotation showed that the DEGs mainly participate in the photosynthesis, oxidative phosphorylation, plant hormone signaling, ribosome, endocytosis, and plant-pathogen interaction pathways, which play important roles in the responses to biotic and abiotic stresses ins plant. To enhance its adaptability to salt-alkali stress, the transgenic poplar line may regulate the expression of genes that participate in the photosynthesis, oxidative phosphorylation, MAPK, and plant hormone signaling pathways. The crosstalk between biotic and abiotic stress responses by plant hormones may improve the ability of both transgenic and non-transgenic poplars to defend against pathogens. The results of our study provide a basis for further studies on the molecular mechanisms behind improved stress resistance and the unexpected effects of transgenic gene expression in poplars, which will be significant for improving the biosafety evaluation of transgenic trees and accelerating the breeding of new varieties of forest trees resistant to environmental stresses.
在过去几十年中,已经培育出了许多具有增强特性和新性状的转基因或基因编辑树木品种。这些树木引发了人们对健康和环境安全的普遍担忧,而这些担忧往往缺乏事实依据。我们对过表达转录因子JERF36基因(ABJ01)的转基因杨树及其非转基因亲本系(9#)进行了转录组测序,以比较顶芽中的转录变化。我们发现,在大庆和齐齐哈尔试验点,ABJ01中分别有0.77%和1.31%的总表达基因存在显著差异表达。其中,30%-50%的差异表达基因含有可被[具体转录因子名称未给出]识别的顺式作用元件。在ABJ01和9#中,大庆和齐齐哈尔两地间约5%的总表达基因显示出显著差异表达。我们鉴定出了10个由外源基因导入导致的差异表达基因、394个仅由环境差异导致的差异表达基因以及47个由外源基因导入与环境共同作用导致的差异表达基因。由环境因素导致的差异表达基因数量显著多于由外源基因导入导致的,且环境效应与外源基因导入的联合效应显著大于仅由外源基因导入导致的效应。基因本体(GO)和京都基因与基因组百科全书(KEGG)注释显示,差异表达基因主要参与光合作用、氧化磷酸化、植物激素信号传导、核糖体、胞吞作用以及植物-病原体相互作用途径,这些途径在植物对生物和非生物胁迫的响应中发挥着重要作用。为增强其对盐碱胁迫的适应性,转基因杨树品系可能会调节参与光合作用、氧化磷酸化、促分裂原活化蛋白激酶(MAPK)和植物激素信号传导途径的基因表达。植物激素介导的生物和非生物胁迫响应之间的相互作用可能会提高转基因和非转基因杨树抵御病原体的能力。我们的研究结果为进一步研究杨树抗逆性提高背后的分子机制以及转基因基因表达的意外效应提供了依据,这对于改进转基因树木的生物安全性评估以及加速抗环境胁迫林木新品种的培育具有重要意义。
