Beijing Advanced Innovation Center for Tree Breeding by Molecular Design, National Engineering Laboratory for Tree Breeding, College of Biological Sciences and Biotechnology, Beijing Forestry University, Beijing, 100083, P. R. China.
Physiol Plant. 2018 Jan;162(1):73-97. doi: 10.1111/ppl.12613. Epub 2017 Nov 7.
Stress-responsive NAM, Arabidopsis transcription activation factor 1/2 (ATAF1/2) and CUC2 (SNAC) genes are being used to alter stress tolerance in Arabidopsis or grasses through genetic engineering. However, limited reports are available about the functional characteristics of SNAC in trees. In this study, three putative NAC proteins were identified from Populus euphratica. PeNAC034 and PeNAC045 were classified into the ATAF subgroup and PeNAC036 into the ANAC072 subgroup. These three SNAC transcription factors were localized in the nucleus and contained the transcription activation domain in their C-terminal. Under drought and salt stresses, PeNAC036 was strongly induced in the whole plant, but PeNAC034 was significantly suppressed in the roots and stems, and PeNAC045 was inhibited in the roots. PeNAC036 overexpression in Arabidopsis wild-type (WT) (OEPeNAC036) and PeNAC036 complementation in mutant anac072 (anac072/PeNAC036) lines increased tolerance to salt and drought, whereas PeNAC034 overexpression in WT (OEPeNAC034) and PeNAC034 complementation in mutant ataf1 (ataf1/PeNAC034) lines enhanced salt and drought sensitivity. After drought and salt treatments, the expression levels of COR47, RD29B, ERD11, RD22 and DREB2A were upregulated in OEPeNAC036 and anac072/PeNAC036 lines, but were downregulated in OEPeNAC034 and ataf1/PeNAC034 plants. Compared with WT and Vector lines, PeNAC045 overexpression in poplar WT (OEPeNAC045) led to a significant decrease in the net photosynthesis rate, stomatal conductance and transpiration rate under salinity and drought conditions. These results suggest that P. euphratica can adapt to the environment of high salinity and drought, which may be related to the differential expression patterns of SNAC genes.
应激响应的 NAM、拟南芥转录激活因子 1/2(ATAF1/2)和 CUC2(SNAC)基因正被用于通过基因工程改变拟南芥或禾本科植物的胁迫耐受性。然而,关于 SNAC 在树木中的功能特征的报道有限。在这项研究中,从胡杨中鉴定出三个假定的 NAC 蛋白。PeNAC034 和 PeNAC045 被分类为 ATAF 亚组,而 PeNAC036 被分类为 ANAC072 亚组。这三个 SNAC 转录因子定位于细胞核内,并且在其 C 末端含有转录激活结构域。在干旱和盐胁迫下,PeNAC036 在整个植物中强烈诱导,但 PeNAC034 在根和茎中显著受抑制,而 PeNAC045 在根中被抑制。在拟南芥野生型(WT)(OEPeNAC036)中过表达 PeNAC036 和在突变体 anac072(anac072/PeNAC036)中互补 PeNAC036 增加了对盐和干旱的耐受性,而在 WT(OEPeNAC034)中过表达 PeNAC034 和在突变体 ataf1(ataf1/PeNAC034)中互补 PeNAC034 增加了对盐和干旱的敏感性。在干旱和盐处理后,OEPeNAC036 和 anac072/PeNAC036 系中的 COR47、RD29B、ERD11、RD22 和 DREB2A 的表达水平上调,但 OEPeNAC034 和 ataf1/PeNAC034 植物中的表达水平下调。与 WT 和载体系相比,在杨树 WT(OEPeNAC045)中过表达 PeNAC045 导致在盐度和干旱条件下净光合速率、气孔导度和蒸腾速率显著降低。这些结果表明,胡杨可以适应高盐和干旱的环境,这可能与 SNAC 基因的差异表达模式有关。
