PdbSPL28基因过量表达提高山新杨对叶斑病的抗性

doi:10.11707/j.1001-7488.LYKX20230530

摘要/Abstract

摘要：

目的: SPL（SQUAMOSA promoter-binding protein-like）是植物特有的一类转录因子，对植物生长发育以及天然免疫反应至关重要。本研究通过在山新杨中过表达PdbSPL28基因，分析比较野生型和转基因山新杨在抗病方面的表型差异，探究PdbSPL28基因的生物学功能及其对杨树抗病性的影响，为深入解析该基因调控杨树抗病性的分子机制提供基础。方法: 利用同源克隆获得山新杨PdbSPL28基因完整ORF序列，并利用DNA人工合成技术对该基因ORF中的miR156作用位点进行序列改造，采用酶切、连接反应分别将改造前和改造后的PdbSPL28基因序列构建过表达载体；采用Gateway技术构建亚细胞定位载体，利用烟草叶片瞬时转化系统分析PdbSPL28蛋白亚细胞定位；利用农杆菌介导的叶盘转化法获得PdbSPL28基因过量表达的转基因山新杨，基于刺伤接种法和石蜡切片技术，观察野生型和转基因山新杨对2种间座壳属病原菌（Diaporthe nobilis和D. cercidis）的抗性差异及叶片解剖结构变化并测定病情指数；制备病原菌D. nobilis孢子悬浮液，接种野生型和2个过表达株系的离体叶片，在接种后不同时间点采集样品，通过液质联用方法检测茉莉酸含量变化。结果: 山新杨PdbSPL28基因ORF全长1 341 bp，序列中含有1个miR156作用位点；PdbSPL28蛋白含有保守的SBP结构域，定位于细胞核。对PdbSPL28基因ORF中miR156作用位点改造后，成功获得6个该基因过量表达的转基因株系。与野生型相比，PdbSPL28过表达山新杨对2种间座壳属病原菌的抗性明显增强。茉莉酸测定结果显示：在接种前，PdbSPL28过表达株系叶片中茉莉酸含量高于WT；但在接种96 h时，过表达株系茉莉酸含量极显著低于WT。结论: 对miR156作用位点进行序列改造，可以提高获得PdbSPL28基因过量表达转基因山新杨的概率；PdbSPL28基因过表达可以提高山新杨对间座壳属真菌引起的叶斑病抗性，茉莉酸信号途径可能在过表达株系响应D. nobilis侵染过程中发挥重要作用。

关键词: 山新杨, SPL28基因, 过量表达, 叶斑病, 间座壳属

Abstract:

Objective: SPL (SQUAMOSA promoter-binding protein-like) is a class of plant specific transcription factors. They play important roles in plant growth and innate immune responses. Studies that focused on dissecting SPL gene function in poplar by using genetic transformation are still very limited. In order to explore the biological function of PdbSPL28 and its effects on disease resistance, the gene was overexpressed in Populus davidiana× P. bolleana, and differences in disease resistance between wild type (WT) and transgenic poplar were investigated. Results of this study would provide a basis for comprehensive understanding of the molecular mechanism by which the PdbSPL28 regulates disease resistance in poplar. Method: The full-length ORF of P. davidiana× P. bolleana PdbSPL28 was obtained by using homologous cloning method, and the miR156 binding site within the ORF was modified via artificial DNA synthesis technology. The pre- and post-modified PdbSPL28 were separately used to construct overexpression vector through enzymatic cleavage and ligation reactions. A vector was constructed by using the Gateway strategy, transiently transformed with tobacco epidermal cells, and used for sub-cellular localization analysis of PdbSPL28 protein. PdbSPL28 overexpression transgenic P. davidiana× P. bolleana was obtained with the method of agrobacteria-mediated leaf disc transformation, and the differences between WT and transgenic P. davidiana× P. bolleana in their resistance, leaf structure and disease index to two Diaporthe pathogens (Diaporthe nobilis and D. cercidis) were investigated with the combination of stab-injured inoculation and paraffin section technique. The urediniospore suspension of D. nobilis was sprayed on detached leaves of WT and transgenic P. davidiana × P. bolleana, and the leaves were sampled at different time after inoculation. The variations of jasmonic acid (JA) content were measured using liquid chromatography-mass spectrometry. Result: The ORF of PdbSPL28 is 1 341 bp in length and harbors one miR156 binding site. The PdbSPL28 protein has the conserved SBP domain and is localized in nuclear. Six PdbSPL28 overexpression transgenic lines were successfully obtained using the modified ORF within which the miR156 binding site was mutated. Compared with WT, transgenic P. davidiana× P. bolleana overexpressing PdbSPL28 was more resistant to two Diaporthe pathogens. Results of JA measurement indicated that the JA contents in the leaves of PdbSPL28 overexpression lines were higher than that of WT before inoculation. However, at 96 h after inoculation, the JA contents in the leaves of PdbSPL28 overexpression lines were significantly lower than that of WT. Conclusion: Sequence modification of miR156 action site can improve the probability of obtaining PdbSPL28 gene overexpression transgenic P. davidiana× P. bolleana. Overexpression of PdbSPL28 gene can enhance the resistance of P. davidiana× P. bolleana to leaf spot disease caused by Diaporthe pathogens. JA signaling pathway may play an important role in regulating the defense responses of overexpression lines during the D. nobilis infection. Results of this study forms a basis for further revealing the molecular mechanism of resistance to Diaporthe pathogens regulated by PdbSPL28 in P. davidiana× P. bolleana.

Key words: Populus davidiana× P. bolleana, SPL28 gene, overexpression, leaf spot disease, Diaporthe

中图分类号:

S722.3⁺7

韩峭子,陈文文,陈赢男,尹佟明. PdbSPL28基因过量表达提高山新杨对叶斑病的抗性[J]. 林业科学, 2024, 60(10): 56-66.

Qiaozi Han,Wenwen Chen,Yingnan Chen,Tongming Yin. Overexpression of PdbSPL28 Enhances Resistance of Populus davidiana × P. bolleana to Leaf Spot Disease[J]. Scientia Silvae Sinicae, 2024, 60(10): 56-66.

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引物名称 Primer name	引物序列（5′→3′） Primer sequence	产物大小 Product length/bp	PCR反应条件 PCR reaction conditions
PdbSPL28-F	CGGGATCCTGCGATGGACTCTGATTG	1 385	95 ℃、 2 min 94 ℃ 、30 s 60 ℃ 、30 s 72 ℃、 1 min 30 s 72 ℃ 、7 min	$ {\Biggr\}} $30×
PdbSPL28-R	GCTCTAGAGGTGATTGACCGTCTTTAT	1 385		$ {\Biggr\}} $30×
Hyg-F	ATCTTAGCCAGACGAGCGGG	589	95 ℃ 、2 min 94 ℃、 30 s 60 ℃ 、30 s 72 ℃ 、30 s 72 ℃ 、5 min	$ {\Biggr\}} $30×
Hyg-R	ACACAGCCATCGGTCCAGAC	589	95 ℃ 、2 min 94 ℃、 30 s 60 ℃ 、30 s 72 ℃ 、30 s 72 ℃ 、5 min	$ {\Biggr\}} $30×
UBQ-F	GTTGATTTTTGCTGGGAAGC	174	95 ℃ 、1 min 94 ℃ 、20 s 60 ℃ 、20 s 72 ℃ 、20 s 72 ℃ 、5 min	$ {\Biggr\}} $40×
UBQ-R	GATCTTGGCCTTCACGTTGT	174	95 ℃ 、1 min 94 ℃ 、20 s 60 ℃ 、20 s 72 ℃ 、20 s 72 ℃ 、5 min	$ {\Biggr\}} $40×
qSPL28-F	GAGTCATTTAGGTCCAGTTCCG	172	95 ℃ 、1 min 94 ℃ 、20 s 60 ℃、 20 s 72 ℃ 、20 s 72 ℃、 5 min	$ {\Biggr\}} $40×
qSPL28-R	CTTTTGATGTTCCACTCGCTG	172	95 ℃ 、1 min 94 ℃ 、20 s 60 ℃、 20 s 72 ℃ 、20 s 72 ℃、 5 min	$ {\Biggr\}} $40×
5.8S rRNA-F	GTCTGCCTGGGTGTCACGCAA	150~170	95 ℃ 、15 min 94 ℃ 、20 s 60 ℃ 、34 s	$ {\Biggr\}} $40×
PdbmiR156-F	GCGCTGACAGAAGAGAGTGAGCAC	70~80	95 ℃ 、15 min 94 ℃ 、20 s 60 ℃ 、34 s	$ {\Biggr\}} $40×

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