State Key Lab of Plant Genomics, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China.
University of Chinese Academy of Sciences, Beijing 100049, China.
Plant Physiol. 2017 Nov;175(3):1304-1320. doi: 10.1104/pp.16.01764. Epub 2017 Sep 5.
Plant homeodomain (PHD) finger proteins are involved in various developmental processes and stress responses. They recognize and bind to epigenetically modified histone H3 tail and function as histone code readers. Here we report that GmPHD6 reads low methylated histone H3K4me0/1/2 but not H3K4me3 with its N-terminal domain instead of the PHD finger. GmPHD6 does not possess transcriptional regulatory ability but has DNA-binding ability. Through the PHD finger, GmPHD6 interacts with its coactivator, LHP1-1/2, to form a transcriptional activation complex. Using a transgenic hairy root system, we demonstrate that overexpression of improves stress tolerance in soybean () plants. Knocking down the expression disrupts this role of , indicating that GmPHD6 requires LHP1 functions during stress response. GmPHD6 influences expression of dozens of stress-related genes. Among these, we identified three targets of GmPHD6, including ABA-stress-ripening-induced and Overexpression of each gene confers stress tolerance in soybean plants. GmPHD6 is recruited to H3K4me0/1/2 marks and recognizes the G-rich elements in target gene promoters, whereas LHP1 activates expression of these targets. Our study reveals a mechanism involving two partners in a complex. Manipulation of the genes in this pathway should improve stress tolerance in soybean or other legumes/crops.
植物同源结构域(PHD)手指蛋白参与各种发育过程和应激反应。它们识别并结合组蛋白 H3 尾部的表观遗传修饰,并作为组蛋白密码读取器发挥作用。在这里,我们报告 GmPHD6 用其 N 端结构域而不是 PHD 手指识别并结合低甲基化组蛋白 H3K4me0/1/2,但不结合 H3K4me3。GmPHD6 不具有转录调控能力,但具有 DNA 结合能力。通过 PHD 手指,GmPHD6 与其共激活因子 LHP1-1/2 相互作用,形成转录激活复合物。通过转基因毛状根系统,我们证明过量表达可提高大豆()植物的胁迫耐受性。敲低的表达破坏了的这种作用,表明 GmPHD6 在应激反应过程中需要 LHP1 发挥作用。GmPHD6 影响数十个与应激相关的基因的表达。在这些基因中,我们鉴定了 GmPHD6 的三个靶标,包括 ABA 应激成熟诱导的和。每个基因的过表达均赋予大豆植物胁迫耐受性。GmPHD6 被募集到 H3K4me0/1/2 标记,并识别靶基因启动子中的 G 富集元件,而 LHP1 则激活这些靶基因的表达。我们的研究揭示了一种涉及复合物中两个伙伴的机制。该途径中基因的操作应能提高大豆或其他豆科作物/作物的胁迫耐受性。