巨桉EgrZFP6基因在非生物逆境胁迫响应中的功能

doi:10.11707/j.1001-7488.20171107

摘要/Abstract

摘要： [目的]通过对巨桉非生物逆境响应相关基因EgrZFP6（Eucgr.A01232）蛋白结构和基因功能的初步研究，探讨该基因在巨桉非生物逆境响应中所发挥的作用，为桉树抗逆育种提供理论基础。[方法]首先利用CDD在线软件分析EgrZFP6编码蛋白序列的结构域，并利用NCBI中的Blast软件搜索与EgrZFP6蛋白序列相似程度较高的其他物种中ZFP蛋白，用Clustalx进行多序列比对，联合分析、比较它们的结构域。然后，构建EgrZFP6∷sGFP融合载体，采用基因枪轰击洋葱表皮方法对EgrZFP6蛋白表达进行亚细胞定位；同时，构建35S∷EgrZFP6超表达载体，采用花序侵染法进行拟南芥遗传转化；对获得的超表达拟南芥转基因纯合株系，分析其正常条件、低温、干旱和高盐等非生物逆境处理下的表型变化；利用酵母双杂交法筛选到与EgrZFP6互作蛋白EgrERF4（Eucgr.F01164），并对低温、干旱和高盐等非生物胁迫下巨桉植株中EgrERF4的表达情况用实时荧光定量RT-PCR方法进行分析。[结果]巨桉EgrZFP6编码蛋白为1个典型C2H2型锌指结构蛋白，有2个包含QALGGH序列的植物特有锌指结构域，1个乙烯响应元件结合因子相关双性抑制子EAR基序和1个L-box基序；亚细胞定位结果表明EgrZFP6表达蛋白定位在细胞核中；与野生型对照相比，EgrZFP6超表达的拟南芥转化植株中，主根伸长生长受到一定抑制，对低温敏感性增强，PEG（1 g·L^-1以上）处理能促进侧根增加和伸长，植株根伸长对高盐抑制作用的耐受性有一定程度提高。乙烯响应相关转录因子基因EgrERF4编码蛋白能够与EgrZFP6编码蛋白互作；正常巨桉植株不同低温（-8，-4，0，4℃）2 h处理下，除-8℃外，EgrERF4表达均呈现被诱导趋势；4℃低温不同时间（0.5，2，6，12，24，48 h）处理下，基因也被诱导表达；干旱条件下，随处理时间延长，基因表达被严重抑制，而高盐（200 mmol·L^-1）胁迫则能促进EgrERF4表达。[结论]EgrZFP6转录因子可能通过与EgrERF4互作参与巨桉低温、高盐和干旱胁迫响应。在低温胁迫下发挥负调控作用；而在干旱和高盐逆境条件下能通过改变植株根构型，一定程度上提高对逆境的适应能力。

关键词: 巨桉, EgrZFP6, 非生物逆境, 基因功能

Abstract: [Objective] EgrZFP6(Eucgr.A01232)is a gene which is involved in abiotic stresses response in Eucalyptus grandis. With the study of protein structure and function of EgrZFP6, the roles it possibly played in abiotic stress response in E. grandis were discussed in order to provide a basis for stress resistance breeding of Eucalyptus.[Method] The EgrZFP6 protein structure was analyzed with CDD online software. And, sequences of ZFP protein in other plant species that have high similarity with EgrZFP6 were downloaded from NCBI after Blast software was used. Multiple alignments for these sequences were finished with Clustalx and their motifs were analyzed. EgrZFP6∷sGFP fused expression vector was also constructed and transformed into onion epidermal cells via gene gun bombardment to identify subcellular localization of EgrZFP6. Transformation of 35S∷EgrZFP6 into Arabidopsis thaliana was via floral-dip method. Two homozygous lines of EgrZFP6 over-expression in A.thaliana were obtained, their phenotype under normal condition, low temperature, drought and high salinity treatments were evaluated compared to wild type (COL). Based on Yeast 2 Hybridization, EgrERF4 (Eucgr.F01164), a protein can interact with EgrZFP6, was screened from the Yeast 2 Hybridization library. The expression of EgrERF4 under low temperature, drought and salinity in E.grandis seedlings was also analyzed. Protein that can interact with EgrZFP6 were screened and verified by Yeast 2 Hybridization. Gene expression of EgrERF4 under abiotic stresses was analyzed by real time fluorescence quantitative RT-PCR method.[Result] The EgrZFP6 is a classic C2H2 type zinc finger protein. There are 2 zinc finger domains with QALGGH sequence which is specific for plants in it. An ERF (ethylene responsive element binding factor) associated amphiphilic repression (EAR) motif and a L-box motif were also found in the protein sequence.Result of subcellular localization revealed the protein EgrZFP6 encoded was localized in the nuclear. Under normal condition, the two EgrZFP6 over-expression A.thaliana lines showed primary root growth inhibition compared to wide type. However, its sensitivity to the low temperature was increased. PEG treatments can promote lateral root growth and increase the number of them and the transgenic lines showed tolerance to salinity treatment to some extent. EgrERF4, an ethylene responsive factor, can interact with EgrZFP6. For the low temperature treatments to the E. grandis seedlings, EgrERF4 expression can be induced under time course treatments (0.5,2,6,12,24,48 h) at 4℃ and different low temperature (-8,-4,0,4℃,2 h) except for -8℃. EgrERF4 expression induction was also found under high salinity (200 mmol·L^-1), but drought inhibited the EgrERF4 expression.[Conclusion] EgrZFP6 transcriptional factor was possibly involved in the low temperature, high salinity and drought stresses through interacting with EgrERF4 in Eucalyptus grandis. In plants, EgrZFP6 may negatively regulate the sensitivity to cold stress. But for drought and salinity stress responses, it possibly played a positive role via changing the root pattern.

Key words: Eucalyptus grandis, EgrZFP6, abiotic stress, gene function

中图分类号:

S718.46

王晓荣, 程龙军, 徐凤华, 倪晓祥, 陆军. 巨桉EgrZFP6基因在非生物逆境胁迫响应中的功能[J]. 林业科学, 2017, 53(11): 60-68.

Wang Xiaorong, Cheng Longjun, Xu Fenghua, Ni Xiaoxiang, Lu Jun. Function of ZFP6 Gene from Eucalyptus grandis in Response to Abiotic Stresses[J]. Scientia Silvae Sinicae, 2017, 53(11): 60-68.

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