核桃JrNPR1基因的克隆与抗病响应潜力

doi:10.7525/j.issn.1673-5102.2022.01.005

植物研究 ›› 2022, Vol. 42 ›› Issue (1): 39-46.doi: 10.7525/j.issn.1673-5102.2022.01.005

核桃JrNPR1基因的克隆与抗病响应潜力

马凯恒¹^,², 何佳凝¹^,², 谢牧洪¹, 任斌¹^,², 黄倩雪¹, 杨桂燕¹^,²()

^1.西北农林科技大学林学院陕西省核桃工程技术研究中心，杨凌 712100
^2.西北农林科技大学林学院陕西省经济植物资源开发利用重点实验室，杨凌 712100

收稿日期:2020-11-13 出版日期:2022-01-20 发布日期:2021-12-30
通讯作者: 杨桂燕 E-mail:yangguiyan@nwsuaf.edu.cn
作者简介:马凯恒（1983—），女，实验师，硕士，主要从事林木遗传育种研究及实验室管理。
基金资助:
国家自然科学基金(31800510)

Cloning and Disease Resistance Response Potential of Walnut JrNPR1 Gene

Kaiheng Ma¹^,², Jianing He¹^,², Muhong Xie¹, Bin Ren¹^,², Qianxue Huang¹, Guiyan Yang¹^,²()

^1.Shaanxi Walnut Engineering Technology Research Center，College of Forestry，Northwest A&F University，Yangling 712100
^2.Key Laboratory of Economic Plant Resources Development and Utilization in Shaanxi Province，College of Forestry，Northwest A&F University，Yangling 712100

Received:2020-11-13 Online:2022-01-20 Published:2021-12-30
Contact: Guiyan Yang E-mail:yangguiyan@nwsuaf.edu.cn
About author:Ma Kaiheng（1983—），female，master，technician，mainly engaged in forest genetic breeding research and laboratory management.
Supported by:
National Natural Science Foundation of China(31800510)

摘要/Abstract

摘要：

病程相关基因非表达子NPR1（Nonexpressor of pathogenesis-related gene 1）基因，在植物抗病过程中起核心调控作用。核桃（Juglans regia）是我国乡村振兴的重要经济油料树种，其生长和产量严重受病虫害制约。为探索核桃抗病生理机制，筛选抗病基因，以‘香玲’核桃为试材，克隆获得JrNPR1基因，对其基本生物信息和病害响应进行分析，预测JrNPR1响应病害的功能。结果显示：JrNPR1基因开放读码框（ORF）长1 782 bp，包含593个氨基酸，理论等电点为6.40；与杨梅（Morella rubra）、蓖麻（Ricinus communis）等同源蛋白进行多序列比对，发现均有NPR1-like-C保守结构域，且JrNPR1与杨梅和欧洲栓皮栎（Quercus suber）等的同源蛋白具有较近的进化关系。其上游1 233 bp启动子中含有多种与植物抗病相关的顺式作用元件，如，WRKY71OS。在胶孢炭疽菌（Colletotrichum gloeosporioides）、矩圆黑盘孢菌（Melanconium oblongum）、黄单胞菌（Xanthomonas campestris）等病原处理下，JrNPR1被显著诱导，且其表达在水杨酸（Salicylic acid，SA）存在下高出单一病原处理的1.31~178.89倍。表明JrNPR1基因可能是抵抗核桃炭疽病、枝枯病、细菌性黑斑病的重要基因，且涉及SA信号通路。

关键词: 核桃, NPR1基因, 基因表达, 抗病性

Abstract:

Nonexpressor of pathogenesis-related gene 1（NPR1） played a key role in regulating plant disease resistance. Walnut（Juglans regia） was an important economic oil tree for rural revitalization in China， and its growth and yield were severely restricted by pests and diseases. In order to explore the physiological mechanism of walnut disease resistance and screen disease resistance genes， the JrNPR1 gene was cloned from ‘Xiangling’ walnut， and its basic biological information and disease response were analyzed to predict the function of JrNPR1. The results showed that the ORF of JrNPR1 gene was 1 782 bp， encoded 593 amino acids， and the theoretical isoelectric point was 6.40. Multi-sequence comparison with Morella rubra， Ricinus communis and other homologous proteins showed that they all had NPR1-like-C conserved domains， and JrNPR1 had a relatively close evolution with M. rubra and Quercus suber. The upstream 1 233 bp promoter contained a variety of cis-acting elements related to plant disease resistance， such as WRKY71OS. Under treatment with pathogens such as Colletotrichum gloeosporioides， Melanconium oblongum， and Xanthomonas campestris， JrNPR1 was significantly induced， and its expression was up-regulated by salicylic acid（SA）. The expression level of JrNPR1 under CgTJ+SA， MoZK+SA， XcHB+SA was 1.31~178.89 fold of that under single stress of CgTJ， MoZK， XcHB， respectively. These results suggested that JrNPR1 might be an important disease resistance gene against walnut anthracnose， branch blight and bacterial black spot， and might be involved in the SA signal pathway.

Key words: Juglans regia, NPR1 gene, gene expression, disease resistance

中图分类号:

S664.1

马凯恒, 何佳凝, 谢牧洪, 任斌, 黄倩雪, 杨桂燕. 核桃JrNPR1基因的克隆与抗病响应潜力[J]. 植物研究, 2022, 42(1): 39-46.

Kaiheng Ma, Jianing He, Muhong Xie, Bin Ren, Qianxue Huang, Guiyan Yang. Cloning and Disease Resistance Response Potential of Walnut JrNPR1 Gene[J]. Bulletin of Botanical Research, 2022, 42(1): 39-46.

图/表 6

图1

图2

图3

表1

JrNPR1启动子正向包含的主要顺式作用元件

顺势作用元件 Cis-element	起始位点 Start position	序列 Sequence	特征 Characteristic
WRKY71OS	430	TGAC	W-BOX、WRKY识别，病害响应 W-BOX，WRKY binding，pathogen response
ARR1AT	122/187/192/201/339	NGATT	响应调节因子ARR1相关 Response regulator ARR1 related
ABRELATERD1	334	ACGTG	ABRE识别 ABRErecognition
ABRERATCAL	333	MACGYGB	ABRE识别 ABRErecognition
ACGTATERD1	81/334//364	ACGT	干旱早期响应 Early drought response
AMYBOX1	546	TAACARA	α-淀粉酶基因相关 Alpha-amylase gene related
CAATBOX1	57/633/761/890/932/979/1017	CAAT	组织特异表达 Tissue specific expression
OSE2ROOTNODULE	115	CTCTT
ROOTMOTIFTAPOX1	37/48/263/298/416/424/540/553/596/638/682/724/766/810/854/895/ 937/981/1022/1210	ATATT
CACTFTPPCA1	498/524/589/604/646/675/690/719/732/774/803/818/847/862/903/ 945/974/989/1060/1091/1101/1130/1145/1174/1203/1218	YACT	CACT关键组成部分 Key components of CACT
CCAATBOX1	1947	CCAAT	热激蛋白、热胁迫响应相关 Heat shock protein，heat stress response related
CURECORECR	87/523/1090/	GTAC	铜响应元件 Copper response element
DOFCOREZM	68/156/454/1087	AAAG	Dof转录因子识别 Dof transcription factor recognition
GAREAT	546	TAACAAR	诱导子响应元件 Elicitor response element
GT1CONSENSUS	214	GRWAAW	GT1结合元件、光调控 GT1 binding element，light control
GTGANTG10	5/96/329/338/429	GTGA	果胶酸裂解酶相关 Pectate Lyase related
INRNTPSADB	55/	YTCANTYY	光调控相关 Light control
-10PEHVPSBD	132/137	TATTCT
SORLIP5AT	3	GAGTGAG
NAPINMOTIFBN	269	TACACAT	2S白蛋白 2S Albumin
NODCON2GM	115	CTCTT	结瘤素Nodulin
POLASIG1	575/582/618/624/660/667/704/788/795/876/959/966/1003/1044/ 1052/1074/1115/1122/1159/1188	AATAAA	淀粉酶相关 Amylase related
POLASIG2	710/746/752/832/838/881/917/923/1009	AATTAAA
POLASIG3	309/634/762/891/933/1018	AATAAT
SEF1MOTIF	48/298	ATATTTAWW	SEF结合位点 SEF binding site
SEF4MOTIFGM7S	194/291/444	RTTTTTR	SEF4结合位点 SEF4 binding site
SURECOREATSULTR11	480	GAGAC	硫响应Sulfur response
TAAAGSTKST1	155	TAAAG	保卫细胞特异性基因表达 Guard cell specific gene expression
TATABOX2	281/571/614/656/700/742/784/828/872/913/955/999/1040/1070/ 1111/1155/1184	TATAAAT	精确起始Precise start
TATABOX4	612/698/740/826/870/911/953/997/1038/1068/1109/1153/1182	TATATAA	贮藏蛋白A基因相关 Storage protein A gene related

表1

图4

图5

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核桃JrNPR1基因的克隆与抗病响应潜力

Cloning and Disease Resistance Response Potential of Walnut JrNPR1 Gene

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