葡萄响应灰霉菌侵染的差异microRNA分析及抗灰霉菌相关基因的筛选

doi:10.3969/j.issn.1674-7968.2025.02.006

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (5694 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要 MicroRNA (miRNA)介导的转录后调控在植物对病原体的反应中起着至关重要的作用。为筛选响应灰霉菌(Botrytis cinerea)感染的葡萄(Vitis vinifera) miRNAs,本研究使用灰霉菌孢子悬浮液侵染葡萄叶片,以此构建小RNA文库并进行高通量测序。结果表明,共获得响应灰霉菌的171个已知miRNA和251个新miRNA,其中53个miRNA接菌后表达具有差异,特别是miRNA399家族的miRNA399a、miRNA399b和miRNA399h,表达显著下调。对灰霉菌侵染后的叶片进行表型、病斑面积及致病率分析,明确了葡萄对灰霉菌的易感性。对上述3个关键miRNAs的下游靶基因进行预测,共获得了8个靶标基因。qPCR分析显示,miRNA399b和miRNA399h的靶基因在受到灰霉菌感染时均显著上调表达。本研究为进一步了解果树驯化过程中的灰霉病抗性反应以及选育抗病葡萄品种提供理论参考。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	牛丽丽
	周慧
	武云龙
	韩泽云
	曹红燕
	杜婷婷
	刘丽媛
	郗琳
	孟冬
	杨清
	宋洋波
	何坤祖

关键词 ：葡萄, miRNA, 灰霉菌, 高通量测序

Abstract：MicroRNA (miRNA) mediated post transcriptional regulation plays a crucial role in plant responses to pathogens. In order to screen miRNAs in grapes (Vitis vinifera) that respond to Botrytis cinerea infection, this study infected grape leaves with B. cinerea spore suspension and constructed a small RNA library for high-throughput sequencing. A total of 171 known miRNAs and 251 new miRNAs were obtained in response to B. cinerea, of which 53 miRNAs showed differential expression after inoculation, especially miRNA399a, miRNA399b, and miRNA399h belonging to the miRNA399 family, which showed significant downregulation. The susceptibility of grapes to B. cinerea was determined by analyzing the phenotype, lesion area, and pathogenicity of leaves. 8 key target genes were obtained by predicting the downstream target genes of the 3 key miRNAs mentioned above. qPCR analysis showed that the target genes of miRNA399b and miRNA399h were significantly upregulated when infected with B. cinerea. This study provides a theoretical basis for further understanding the resistance response of fruit trees to B. cinerea during domestication and for breeding resistant grape varieties.

Key words： Grape miRNA Botrytis cinerea High-throughput sequencing

收稿日期: 2024-05-24

中图分类号： S6

基金资助:自治区区域协同创新专项-上海合作组织科技伙伴计划及国际科技合作计划项目(2022E01066); 国家资助博士后研究人员计划B档(GZB20230059)

通讯作者: ** yangbosong792@163.com;493077365@qq.com

作者简介: *同等贡献作者

引用本文:

牛丽丽, 周慧, 武云龙, 韩泽云, 曹红燕, 杜婷婷, 刘丽媛, 郗琳, 孟冬, 杨清, 宋洋波, 何坤祖. 葡萄响应灰霉菌侵染的差异microRNA分析及抗灰霉菌相关基因的筛选[J]. 农业生物技术学报, 2025, 33(2): 303-315.
NIU Li-Li, ZHOU Hui, WU Yun-Long, HAN Ze-Yun, CAO Hong-Yan, DU Ting-Ting, LIU Li-Yuan, XI Lin, MENG Dong, YANG Qing, SONG Yang-Bo, HE Kun-Zu. Differential microRNA Analysis of Response to Botrytis cinerea Infection in Grapes (Vitis vinifera) and Screening of Genes Related to Botrytis cinerea Resistance. 农业生物技术学报, 2025, 33(2): 303-315.

链接本文:

https://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2025.02.006 或 https://journal05.magtech.org.cn/Jwk_ny/CN/Y2025/V33/I2/303

[1] 韩丽娟. 2015. 华东葡萄'白河-35-1'抗白粉病相关miRNA的鉴定[D]. 硕士学位论文, 西北农林科技大学, 导师: 徐炎, pp. 1-80.
Identification of microrna involved in powdery mildew resistance from chinese wild Vitis pesudoreticulata[D]. Thesis for M. S. Northwest A＆F University, Supervisor: Xu Y, pp. 1-80.
[2] 张颖, 樊秀彩, 姜建福, 等. 2019. 基于microRNA测序分析miRNA在刺葡萄抗白腐病中的作用[J]. 果树学报, 236(02): 143-152.
Zhang Y, Fan X C, Jiang J F,et al.2019. Analysis of the function of miRNA on the resisitance to white-rot disease in Vitis davidii based on microRNA sequencing[J]. Journal of Fruit Science, 236(02): 143-152.
[3] Agudelo-Romero P, Erban A, Rego C, et al.2015. Transcriptome and metabolome reprogramming in Vitis vinifera cv. Trincadeira berries upon infection with Botrytis cinerea[J]. Journal of Experimental Botany, 66(7): 1769-1785.
[4] Blanco-Ulate B, Amrine K C H, Collins T S, et al.2015. Developmental and metabolic plasticity of white-skinned grape berries in response to Botrytis cinerea during noble rot[J]. Plant Physiology, 169(4): 2422-2443.
[5] Cheng X, He Q, Tang S, et al.2021. The miR172/IDS1 signaling module confers salt tolerance through maintaining ROS homeostasis in cereal crops[J]. New Phytologist, 230: 1017-1033.
[6] Cuperus J, Fahlgren N, Carrington J, et al.2011. Evolution and functional diversification of miRNA genes[J]. Plant Cell, 23: 431-442.
[7] Dabauza M, Velasco L, Pazos-Navarro M, et al.2015. Enhanced resistance to Botrytis cinerea in genetically-modified Vitis vinifera L. plants over-expressing the grapevine stilbene synthase gene[J]. Plant Cell, Tissue and Organ Culture (PCTOC), 120: 229-238.
[8] Dong T, Zheng T, Fu W, et al.2020. The effect of ethylene on the color change and resistance to Botrytis cinerea infection in 'Kyoho' grape fruits[J]. Foods, 9(7): 892.
[9] Feng H, Wang Q, Zhao X, et al.2016. TaULP5 contributes to the compatible interaction of adult plant resistance wheat seedlings-stripe rust pathogen[J]. Physiological and Molecular Plant Pathology, 96: 29-35.
[10] Gupta O, Sharma P, Gupta R, et al.2014. Current status on role of miRNAs during plant-fungus interaction[J]. Physiological and Molecular Plant Pathology, 85: 1-7.
[11] Jagadeeswaran G, Saini A, Sunkar R, et al.2009. Biotic and abiotic stress down-regulate miR398 expression in Arabidopsis[J]. Planta, 229(4): 1009-1014.
[12] Jaillon O, Aury J M, Noel B, et al.2007. The grapevine genome sequence suggests ancestral hexaploidization in major angiosperm phyla[J]. Nature, 449(7161): 463-467.
[13] Jiang L, Qiu Y, Dumlao M, et al.2023. Detection and prediction of Botrytis cinerea infection levels in wine grapes using volatile analysis[J]. Food Chemistry, 421: 136120.
[14] Kamble M V, Shahapurkar A B, Adhikari S, et al.2021. Identification and characterization of downy mildew-responsive microRNAs in Indian Vitis vinifera by high-throughput sequencing[J]. Journal of Fungi, 7(11): 899.
[15] Kasschau K, Xie Z, Allen E, et al.2003. P1/HC-Pro, a viral suppressor of RNA silencing, interferes with Arabidopsis development and miRNA function[J]. Developmental Cell, 4(2): 205-217.
[16] Li J, Wei J, Tusong K, et al.2023. Preharvest Botrytis cinerea infection accelerates postharvest spike-stalk browning in 'Munage' grape[J]. South African Journal of Botany, 154: 1-10.
[17] Li Q, Shen H, Yuan S, et al.2022. miRNAs and lncRNAs in tomato: Roles in biotic and abiotic stress responses[J]. Frontiers in Plant Science, 13: 1094459.
[18] Li Y, Cao X, Zhu Y, et al.2019. Osa‐miR398b boosts H2O2 production and rice blast disease‐resistance via multiple superoxide dismutases[J]. New Phytologist, 222(3): 1507-1522.
[19] Li Z, Liu W, Chen Q, et al.2023. Mdm-miR858 targets MdMYB9 and MdMYBPA1 to participate anthocyanin biosynthesis in red-fleshed apple[J]. Plant Journal, 113(6): 1259-1309.
[20] Liu J, Ren Y, Sun Y, et al.2024. Identification and analysis of the mir399 gene family in grapevine reveal their potential functions in abiotic stress[J]. International Journal of Molecular Sciences, 25(5): 2979.
[21] Liu Y, Yu Y, Fei S, et al.2023. Overexpression of Sly-miR398b compromises disease resistance against Botrytis cinerea through regulating ROS homeostasis and JA-related defense genes in tomato[J]. Plants, 12: 2572.
[22] Luo Y, Wang L, Zhu J, et al.2024. The grapevine miR827a regulates the synthesis of stilbenes by targeting VqMYB14 and gives rise to susceptibility in plant immunity[J]. Theoretical and Applied Genetics, 137(4): 95.
[23] Ma C, Lu Y, Bai S, et al.2014. Cloning and characterization of miRNAs and their targets, including a novel miRNA-targeted NBS-LRR protein class gene in apple (Golden Delicious)[J]. Molecular Plant, 7(1): 218-230.
[24] Ma X, Denyer T, Javelle M, et al.2021. Genome-wide analysis of plant miRNA action clarifies levels of regulatory dynamics across developmental contexts[J]. Genome Research, 31(5): 811-822.
[25] Miao Y, Chen K, Deng J, et al.2021. miR398b negatively regulates cotton immune responses to Verticillium dahliae via multiple targets[J]. The Crop Journal, 10(4): 1026-1036.
[26] Olmo R, Quijada N, Moran-Diez M, et al.2024. Identification of tomato microRNAs in late response to Trichoderma atroviride[J]. International Journal of Molecular Sciences, 25(3): 1617.
[27] Pei M, Liu H, Wei T, et al.2024. Identification, characterization, and verification of miR399 target gene in grape[J]. Horticultural Plant Journal, 10(1): 91-102.
[28] Qu Q, Liu N, Su Q F, et al.2023. MicroRNAs involved in the trans-kingdom gene regulation in the interaction of maize kernels and?Fusarium verticillioides[J]. International Journal of Biological Macromolecules, 242: 125046.
[29] Wan R, Guo C, Hou X, et al.2021. Comparative transcriptomic analysis highlights contrasting levels of resistance of Vitis vinifera and Vitis amurensis to Botrytis cinerea[J]. Horticulture Research, 8: 103.
[30] Wang Y, Zhang F, Cui W, et al.2018. The FvPHR1 transcription factor control phosphate homeostasis by transcriptionally regulating miR399a in woodland strawberry[J]. Plant Science, 280: 258-268.
[31] Windram O, Madhou P, McHattie S, et al.2012. Arabidopsis defense against Botrytis cinerea: Chronology and regulation deciphered by high-resolution temporal transcriptomic analysis[J]. The Plant Cell, 24(9): 3530-3557.
[32] Wu F, Xu J, Gao T, et al.2021. Molecular mechanism of modulating miR482b level in tomato with Botrytis cinerea infection[J]. BMC Plant Biology, 21: 496.
[33] Wu F, Qi J, Meng X, et al.2020. miR319c acts as a positive regulator of tomato against Botrytis cinerea infection by targeting TCP29[J]. Plant Science, 300:110610.
[34] Yang L, Huang H, et al.2014. Roles of small RNAs in plant disease resistance[J]. Journal of Integrative?Plant?Biology,?56(10): 962-970.
[35] Yu X, Gong H, Cao L, et al.2020. MicroRNA397b negatively regulates resistance of Malus hupehensis to Botryosphaeria dothidea by modulating MhLAC7 involved in lignin biosynthesis[J]. Plant Science, 292: 110390.
[36] Yu Y, Jia R, Chen M, et al.2017. The 'how' and 'where' of plant microRNAs[J]. New Phytologist, 216(4): 1002-1017.
[37] Zhan J, Meyers B.2023. Plant small RNAs: Their biogenesis, regulatory roles, and functions[J]. Annual Review of Plant Biology, 74: 21-51.
[38] Zhang J, Zhang H, Srivastava A, et al.2018. Knockdown of rice microRNA166 confers drought resistance by causing leaf rolling and altering stem xylem development[J]. Plant Physiology, 176(3): 2082-2094.
[39] Zhang L, Li Y, Zheng Y, et al.2020. Expressing a target mimic of miR156fhl-3p enhances rice blast disease resistance without yield penalty by improving SPL14 expression[J]. Frontiers in Genetics, 11: 327.
[40] Zhang T, Zhao Y, Zhao J, et al.2016. Cotton plants export microRNAs to inhibit virulence gene expression in a fungal pathogen[J]. Nature Plants, 2(10): 16153.
[41] Zhang Y, Zhang Q, Hao L, et al.2019. A novel miRNA negatively regulates resistance to Glomerella leaf spot by suppressing expression of an NBS gene in apple[J]. Horticulture Research, 6: 9.