沙棘转录因子HrWRKY53基因分离及其参与抵御绕实蝇的作用分析

doi:10.11707/j.1001-7488.20220513

摘要/Abstract

摘要：

目的: 明确HrWRKY53基因的生物信息学及其参与沙棘抗绕实蝇功能，为解析沙棘等胡颓子科植物抗虫机制及分子育种奠定基础。方法: 基于绕实蝇危害前后沙棘果实转录组数据，挖掘HrWRKY基因家族成员中参与绕实蝇危害的关键差异表达基因HrWRKY53，进一步分析该基因的二级结构、亲疏水性及预测磷酸化位点等。利用BLASTP检索同源性高的其他物种蛋白序列进行比对并构建系统发育树；利用qRT-PCR检测该基因的组织表达特异性，绕实蝇危害前后以及脱落酸(Abscisic acid，ABA)、茉莉酸甲酯(Methyl jasmonate，MeJA)、乙烯(Ethylene，ETH)处理下的该基因表达模式；并进一步分析响应绕实蝇危害的茉莉酸(Jasmonic acid，JA)信号途径上关键基因HrJA2、HrLOX1、HrAOS和HrAOC的表达水平，分析其与HrWRKY53基因表达的相关性。结果: 基于沙棘转录组获得HrWRKY53的开放阅读框(Open reading frame，ORF)全长为1 302 bp，编码433个氨基酸残基的蛋白，该基因含有2个WRKY保守结构域和1个C₂H₂型锌指结构，属于第Ⅰ类WRKY转录因子家族；二级结构预测其编码的蛋白主要由无规则卷曲构成，含有141个磷酸化位点，推测可能与磷酸化有密切的关系，亲疏水性预测表明该蛋白属于疏水性蛋白；系统发育树分析显示该蛋白与蔷薇科野草莓FvWRKY25同源性最高。qRT-PCR显示该基因具有明显的组织表达特异性，其在沙棘果实中的表达量最高；绕实蝇危害与机械损伤后该基因的表达量均显著上升，激素ABA、MeJA、ET处理后，基因的表达量也呈明显上升的趋势，其中MeJA诱导后，该基因的表达量上升最显著；另外，基于转录组数据及荧光定量数据对JA信号通路的关键差异表达基因分析发现，其通路上的HrJA2基因表达量提高最显著，且HrWRKY53与HrJA2基因表达量变化呈明显的正相关。结论: 沙棘HrWRKY53属于第Ⅰ类WRKY转录因子家族，且与蔷薇科草莓FvWRKY25同源性最高；同时该转录因子参与了沙棘抵御绕实蝇危害的应答过程。此外，沙棘受绕实蝇取食后诱导了HrJA2基因的表达进而促进JA合成，而JA又进一步诱导了HrWRKY53基因表达，最终提高了沙棘抗绕实蝇危害的能力。

关键词: 沙棘, 绕实蝇, HrWRKY转录因子家族, HrWRKY53, 激素处理

Abstract:

Objective: This study aims to clarify the bioinformatics of HrWRKY53 gene and its role in sea-buckthorn resisting Rhagoletis batava obseuriosa(RBO), so as to lay a foundation for the analysis of insect resistance mechanism and molecular breeding of Elaeagnaceae such as Hippophae rhamnoides. Method: Based on the transcriptome data of sea-buckthorn fruits before and after RBO infestation, the key differentially expressed gene HrWRKY53 involved in the damage of sea-buckthorn were explored from members of HrWRKY gene family. Bioinformatics analysis was carried out to analyze the secondary structure and hydrophobicity and to predict the phosphorylation sites. In the NCBI website, the protein sequences with high homology were searched by BLASTP for sequence alignment, and the phylogenetic tree was constructed. qRT-PCR was used to detect the tissue expression specificity of the gene and the gene expression pattern before and after RBO infestation and under the treatment of abscisic acid (ABA), methyl jasmonate (MeJA) and ethylene (ET). The expression levels of HrJA2, HrLOX1, HrAOS and HrAOC in the JA signal pathway in response to the damage of RBO were analyzed, and their correlation with the expression of HrWRKY53 was was analyzed. Result: The open reading frame (ORF) of HrWRKY53 gene obtained from sea-buckthorn transcriptome was 1 302 bp, which encoded 433 amino acid residues. HrWRKY53 protein included two WRKY conserved domains and C2H2 zinc finger structures, and belonged to the family of type I WRKY transcription factors. The secondary structure prediction showed that HrWRKY53 was mainly composed of random curl and contained 141 threonine phosphorylation sites, which could be closely related to phosphorylation. The hydrophobicity prediction showed that the protein belonged to a hydrophobic protein. Phylogenetic tree analysis displayed that the gene had the highest homology with FvWRKY25. qRT-PCR showed that the gene had obvious tissue expression specificity, and its expression was the highest in sea-buckthorn fruit. The gene expression increased significantly under RBO infestation, mechanical injury, treatments with ABA, MeJA and ET, among which the expression increased most significantly after JA induction. In addition, the analysis of key differentially expressed genes involved in JA signal pathway based on transcriptome data and fluorescence quantitative data showed that the expression of HrJA2 gene in JA signal pathway increased most significantly, and there was a significant positive correlation between HrWRKY53 and HrJA2. Conclusion: HrWRKY53 of Hippophae rhamnoides belongs to the family of type I WRKY transcription factors and has the highest homology with FvWRKY25 of strawberry in Rosaceae. This gene is involved in the response to RBO and hormone-induced. The expression of HrJA2 can be induced to promote JA synthesis, and then increase the expresses of HrWRKY53 in sea-buckthorn, to further improve the ability of seabuckthorn to resist RBO.

Key words: Hippophae rhamnoides, RBO, HrWRKY transcription factor family, HrWRKY53, hormone treatment

中图分类号:

S718.46

姚莹,曹金峰,陆世曈,丁文彬,张一文,魏建荣,刘建凤. 沙棘转录因子HrWRKY53基因分离及其参与抵御绕实蝇的作用分析[J]. 林业科学, 2022, 58(5): 121-130.

Ying Yao,Jinfeng Cao,Shitong Lu,Wenbin Ding,Yiwen Zhang,Jianrong Wei,Jianfeng Liu. Isolation of Transcription Factor HRWRKY53 Gene from Hippophae rhamnoides and Analysis of Its Role in Resisting Rhagoletis batava obseuriosa[J]. Scientia Silvae Sinicae, 2022, 58(5): 121-130.

图/表 8

表1

表2

图1

图2

图3

图4

表3

图5

参考文献 0

	葛葆蔚, 李桂和, 张玉伟, 等. 沙棘果实蝇的初步研究. 辽宁林业科技, 1988, (3): 45- 46. 45-46, 61
	Ge B W , Li G H , Zhang Y W , et al. Preliminary study on fruit fly of Seabuckthorn. Liaoning Forestry Science and Technology, 1988, (3): 45- 46. 45-46, 61
	孔维龙, 于坤, 但乃震, 等. 甜菜WRKY转录因子全基因组鉴定及其在非生物胁迫下的表达分析. 中国农业科学, 2017, 50 (17): 3259- 3273.
	Kong W L , Yu K , Dan N Z , et al. Genome-wide identification and expression analysis of WRKY transcription factor under abiotic stress in Beta vulgaris. Scientia Agricultura Sinica, 2017, 50 (17): 3259- 3273.
	汪兴鉴. 重要果蔬类有害实蝇概论(双翅目: 实蝇科). 植物检疫, 1995, 9 (1): 20- 30.
	Wang X J . Introduction to harmful fruit and vegetable flies. Plant Quarantine, 1995, 9 (1): 20- 30.
	文锋, 吴小祝, 廖亮, 等. WRKY转录因子在植物抗逆生理中的研究进展. 广西植物, 2017, 37 (1): 69- 79. 69-79, 68
	Wen F , Wu X Z , Liao L , et al. Research advances on physiological function of WRKY transcription factor in plant stress resistance. Guihaia, 2017, 37 (1): 69- 79. 69-79, 68
	魏建荣, 苏智, 刘明虎, 等. 沙棘果实的重要检疫害虫-沙棘绕实蝇的发生与危害. 内蒙古林业科技, 2012, 38 (4): 55- 57.
	Wei J R , Su Z , Liu M H , et al. Occurrence and damage of Rhagoletis batava obseuriosa. Journal of Inner Mongolia Forestry Science & Technology, 2012, 38 (4): 55- 57.
	徐伟, 付晓霞, 田径, 等. 诱导因子对苜蓿夜蛾和大豆食心虫嗅觉与产卵选择的影响. 吉林农业大学学报, 2010, 32 (5): 488- 491. 488-491, 497
	Xu W , Fu X X , Tian J , et al. Effects of different elicitors on olfactory responses and ovipositive selection of Heliothis viriplaca and Leguminivora glycinivorella. Journal of Jilin Agricultural University, 2010, 32 (5): 488- 491. 488-491, 497
	徐惠娟, 郑蕊, 陈任, 等. 枸杞WRKY3基因克隆及组织表达分析. 西北植物学报, 2016, (36): 1721- 1727.
	Xu H J , Zheng R , Chen R , et al. Cloning and tissue expression analysis of WRKY3 gene in Lycium barbarum L. Acta Botanica Boreali-Occidentalia Sinica, 2016, (36): 1721- 1727.
	Bari R , Jones J D G . Role of plant hormones in plant defence responses. Plant Molecular Biology, 2009, 69 (4): 473- 488. doi: 10.1007/s11103-008-9435-0
	Chen J N , Nolan T M , Ye H X , et al. Arabidopsis WRKY46, WRKY54, and WRKY70 transcription factors are involved in brassinosteroid-regulated plant growth and drought responses. The Plant Cell, 2017, 29 (6): 1425- 1439.
	Erb M , Meldau S , Howe G A . Role of phytohormones in insect-specific plant reactions. Trends in Plant Science, 2012, 17 (5): 250- 259. doi: 10.1016/j.tplants.2012.01.003
	Eulgem T , Rushton P J , Schmelzer E , et al. Early nuclear events in plant defence signalling: rapid gene activation by WRKY transcription factors. The EMBO Journal, 1999, 18 (17): 4689- 4699. doi: 10.1093/emboj/18.17.4689
	Eulgem T , Somssich I E . Networks of WRKY transcription factors in defense signaling. Current Opinion in Plant Biology, 2007, 10 (4): 366- 371. doi: 10.1016/j.pbi.2007.04.020
	Hou Y X , Wang Y F , Tang L Q , et al. SAPK10-mediated phosphorylation on WRKY72 releases its suppression on Jasmonic acid biosynthesis and bacterial blight resistance. iScience, 2019, 16 (6): 499- 510.
	Hu L F , Ye M , Li R , et al. The rice transcription factor WRKY53 suppresses herbivore-induced defenses by acting as a negative feedback modulator of mitogen-activated protein kinase activity. Plant Physiology, 2015, 169 (4): 2907- 2921.
	Howe G A , Jander G . Plant immunity to insect herbivores. Annual Review of Plant Biology, 2008, 59 (1): 41- 66. doi: 10.1146/annurev.arplant.59.032607.092825
	Li C L , Li D Q , Shao F J , et al. Molecular cloning and expression analysis of WRKY transcription factor genes in Salvia miltiorrhiza. BMC Genomics, 2015, 16 (1): 200. doi: 10.1186/s12864-015-1411-x
	Li J Y , Zhu L Z , Hull J J , et al. Transcriptome analysis reveals a comprehensive insect resistance response mechanism in cotton to infestation by the phloem feeding insect Bemisia tabaci (whitefly). Plant Biotechnology Journal, 2016, 14 (10): 1956- 1975. doi: 10.1111/pbi.12554
	Lu J , Li J C , Ju H P , et al. Contrasting effects of ethylene biosynthesis on induced plant resistance against a chewing and a piercing-sucking herbivore in rice. Molecular Plant, 2014, 7 (11): 1670- 1682. doi: 10.1093/mp/ssu085
	Maeo K , Hayashi S , Kojima-Suzuki H , et al. Role of conserved residues of the WRKY domain in the DNA-binding of tobacco WRKY family proteins. Bioscience, Biotechnology, and Biochemistry, 2001, 65 (11): 2428- 2436. doi: 10.1271/bbb.65.2428
	Pandey S P , Somssich I E . The role of WRKY transcription factors in plant immunity. Plant Physiology, 2009, 150 (4): 1648- 1655. doi: 10.1104/pp.109.138990
	Shamanskaya L D , Zubareva E N . Resistance estimation of seabuckthorn varieties to seabuckthorn fly (Rhagoletis batava obscuriosa Kol.). Research and Technical Advances of Agribusiness Sector, 2011, (3): 37- 40.
	Stam J M , Kroes A , Li Y H , et al. Plant interactions with multiple insect herbivores: from community to genes. Annual Review of Plant Biology, 2014, 65 (1): 689- 713. doi: 10.1146/annurev-arplant-050213-035937
	Teng B S , Lu Y H , Wang Z T , et al. In vitro anti-tumor activity of isorhamnetin isolated from Hippophae rhamnoides L.against BEL-7402 cells. Pharmacological Research, 2006, 54 (3): 186- 194. doi: 10.1016/j.phrs.2006.04.007
	Wu J Q , Baldwin I T . New insights into plant responses to the attack from insect herbivores. Annual Review of Genetics, 2010, 44 (1): 1- 24. doi: 10.1146/annurev-genet-102209-163500
	Wang Z Y , Feng R X , Zhang X , et al. Characterization of the Hippophae rhamnoides WRKY gene family and functional analysis of the role of the HrWRKY21 gene in resistance to abiotic stresses. Genome, 2019, 62 (10): 689- 703. doi: 10.1139/gen-2019-0024
	Yang Y , Zhou Y , Chi Y J , et al. Characterization of soybean WRKY gene family and identification of soybean WRKY genes that promote resistance to soybean Cyst Nematode. Scientific Reports, 2017, 7 (1): 17804. doi: 10.1038/s41598-017-18235-8
	Zhang W W , Gao T W , Li P L , et al. Chrysanthemum CmWRKY53 negatively regulates the resistance of chrysanthemum to the aphid Macrosiphoniella sanborni. Horticulture Research, 2020, 7 (1): 109. doi: 10.1038/s41438-020-0334-0
	Zhang L Y , Gu L K , Ringler P , et al. Three WRKY transcription factors additively repress abscisic acid and gibberellin signaling in aleurone cells. Plant Science, 2015, 236, 214- 222. doi: 10.1016/j.plantsci.2015.04.014

基因Gene	上游引物Forward-primer (5’-3’)	下游引物Reverse-primer (5’-3’)
HrWRKY53	GCAGAAAGAAAAATGCTTTTCAGG	CATTTCTCCAGCCTCCGAATCG
HrJA2	TGAGTTTATTCCCTTGTGAAGCTTC	TAGTCAATGGTGCAGTTTGAGA
HrLOX1	ACCTATTCTCACTGGTCACCCTG	TTTCTGAAGGCAAAAGCAGTG
HrAOS	AACACAACATACGTGGGCTAATA	GTAAGTCACTGACAATCATCCG
HrAOC	GAGGAGACACCTAAGAAAATCTC	CGCTGTTATATTGTCAGAGGACG
HrUbi	TGCCTGAGGATGTATGCTAC	CCAAATAAGTCGCTGCCT

基因名称 Gene name	抗系植株(危害前后) RI (Harm before/after)		感系植株(危害前后) SI (Harm before/after)		抗/感系植株(未危害) RI/SI (No harm)		抗/感系植株(危害) RI/SI (Harm)
基因名称 Gene name	表达 Regulate	显著性 Significant	表达 Regulate	显著性 Significant	表达 Regulate	显著性 Significant	表达 Regulate	显著性 Significant
HrWRKY1	U	NS	U	S	U	NS	D	NS
HrWRKY17	D	NS	U	NS	D	NS	D	S
HrWRKY18	U	NS	U	S	D	NS	D	S
HrWRKY53	U	S	U	NS	U	S	U	S
HrWRKY33	D	NS	U	NS	U	NS	D	NS
HrWRKY40	D	S	U	NS	D	NS	D	NS
HrWRKY41	U	NS	U	NS	D	NS	D	S
HrWRKY71	D	NS	D	S	U	S	D	S

基因名称 Gene name	抗系植株(危害前后) RI (Harm before/after)		感系植株(危害前后) SI (Harm before/after)		抗/感系植株(未危害) RI/SI (No harm)		抗/感系植株(危害) RI/SI (Harm)
基因名称 Gene name	表达 Regulate	显著性 Significant	表达 Regulate	显著性 Significant	表达 Regulate	显著性 Significant	表达 Regulate	显著性 Significant
HrJA2	U	S	U	NS	U	NS	U	S
HrSpr2	U	S	D	NS	D	NS	U	S
HrLOX1	U	S	U	NS	U	NS	U	S
HrLOX2	D	NS	D	NS	D	NS	D	NS
HrAOC	U	S	U	NS	U	NS	U	S
HrAOS	U	S	D	NS	D	NS	U	S

[1]	程态明,李彦艳,魏建荣,苏智. 多杀菌素与碳酸铵复合微球的制备及其对沙棘绕实蝇成虫的防治效果[J]. 林业科学, 2020, 56(8): 191-200.
[2]	刘建凤, 董礼龙, 曹丹丹, 罗红梅, 魏建荣. 抗绕实蝇沙棘无性系的筛选及相关化学物质和酶活性分析[J]. 林业科学, 2018, 54(9): 104-113.
[3]	姜准, 刘丹一, 陈贝贝, 高海银, 刘春红, 张增悦, 邹旭, 李根前. 中国沙棘克隆生长对造林密度的早期响应及其生物量分配调节机制[J]. 林业科学, 2017, 53(10): 29-39.
[4]	段爱国, 崔令军, 张建国, 罗红梅, 单金友, 何彩云. 大果沙棘良种‘橙色’[J]. 林业科学, 2016, 52(9): 157-157.
[5]	陈文思, 朱清科, 刘蕾蕾, 马欢, 赵维军, 王瑜. 陕北半干旱黄土区沙棘人工林的死亡率及适宜地形因子[J]. 林业科学, 2016, 52(5): 9-16.
[6]	崔令军, 段爱国, 张建国, 罗红梅, 单金友, 李健雄, 何彩云. 大果无刺沙棘良种‘楚伊’[J]. 林业科学, 2016, 52(11): 172-172.
[7]	崔令军, 段爱国, 张建国, 罗红梅, 单金友, 何彩云. 大果沙棘良种‘浑金’[J]. 林业科学, 2016, 52(10): 169-169.
[8]	段爱国, 张建国, 罗红梅, 李健雄, 何彩云. 沙棘无刺大果良种‘棕丘'[J]. 林业科学, 2015, 51(6): 164-164.
[9]	段爱国, 张建国, 孙广树, 何彩云. 沙棘良种‘辽阜1号’[J]. 林业科学, 2015, 51(3): 176-176.
[10]	孙妙, 杨周婷, 张存莉, 魏安智, 史伟. 中国沙棘种子的水引发技术及其抗性生理效应[J]. 林业科学, 2014, 50(12): 32-39.
[11]	段爱国, 张建国, 何彩云, 罗红梅, 李健雄. 沙棘良种‘白丘杂’[J]. 林业科学, 2013, 49(11): 196-196.
[12]	段爱国, 张建国, 罗红梅, 单金友. 沙棘良种‘黑棘6号’[J]. 林业科学, 2013, 49(10): 182-182.
[13]	马飞;徐婷婷;张晓玮;赵长明. 肋果沙棘幼苗对CO₂浓度升高的生理生态响应[J]. 林业科学, 2012, 48(10): 30-35.
[14]	宋瑞清;孙海珍;董希文;邓勋;. 黑龙江沙棘干缩病病原菌的研究[J]. 林业科学, 2010, 46(9): 88-95.
[15]	成小芳王金明张金桐. 沙棘木蠹蛾性信息素的合成与林间诱蛾活性试验[J]. 林业科学, 2007, 43(5): 74-77.