基于CEEA等温扩增技术的落叶枯梢病菌快速检测技术体系

刘正强; 裴婷倩; 安文静; 刘蓝泽; 朱烨婷; 梁英梅

doi:10.27035/j.cnki.issn2097−5279.20260205

树木医学 ›› 2026, Vol. 3 ›› Issue (2) : 40 -48. DOI: 10.27035/j.cnki.issn2097−5279.20260205

基于CEEA等温扩增技术的落叶枯梢病菌快速检测技术体系

刘正强 ¹ ,
裴婷倩 ¹ ,
安文静 ³ ,
刘蓝泽 ¹ ,
朱烨婷 ¹ ,
梁英梅 ²^,^*

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Establishment of a rapid detection technology system for Neofusicoccum laricinum based on CEEA isothermal amplification

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摘要

落叶松枯梢病菌 Neofusicoccum laricinum (Sawada) Y. Hattori & C. Nakash 是中国进境植物检疫性有害生物和林业检疫性有害生物,也是《重点管理外来入侵物种名录》中仅有的2种真菌性植物病菌之一。开展快速、准确、直观的检测技术研究,对落叶松枯梢病的有效防治具有重要意义。本研究将复合酶指数扩增技术(CEEA)与侧向流试纸条(LFD)技术相结合,利用落叶松枯梢病菌的特异性CEEA引物组及其探针,在最佳反应温度39 ℃、反应时间15 min的条件下,特异性检测出不同地区来源的落叶松枯梢病菌,最低检测浓度为100.0 fg·µL⁻¹,且整个检测过程可在30 min内完成。同时,该技术无需昂贵仪器,且不识别落叶松上的其他真菌,表现出良好的适用性,具有高效、快速、灵敏等特点,可为林间病原菌的就地快速检测、识别以及病害早期预警提供有力支持。

Abstract

Neofusicoccum laricinum (Sawada) Y. Hattori & C. Nakash is a quarantine pest of imported plants and a forestry quarantine pest in China. It is also one of only two fungal plant pathogens listed in the Catalogue of Key Managed Invasive Alien Species. Developing rapid,accurate,and visual detection method is crucial for effective prevention and control of this disease. In this study,a method combining composite enzyme index amplification (CEEA) technique with lateral flow dipstick (LFD) technology was developed. Using specifically designed CEEA primer sets and probes for N. laricinum,followed by optimization of reaction conditions (39 ℃ for 15 minutes),the method could specifically detect N. laricinum strains from diverse regions with a limit of detection (LOD) as low as 100.0 fg·µL⁻¹,the entire process to be completed in 30 minutes. This technology requires no expensive instruments and does not identify other fungi on Larch,demonstrating good applicability. With its high efficiency,speed,and sensitivity,this technology provides strong support for in-situ rapid detection and identification of pathogens in the forest,as well as for the early warning of disease.

关键词

新壳梭孢菌 / 落叶松 / 复合酶指数扩增 / 侧向流试纸条 / 检测技术

Key words

Neofusicoccum laricinum / Larch / composite enzyme index amplification / lateral flow test strips / detection technology

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刘正强,裴婷倩,安文静,刘蓝泽,朱烨婷,梁英梅. 基于CEEA等温扩增技术的落叶枯梢病菌快速检测技术体系[J]. 树木医学, 2026, 3(2): 40-48 DOI:10.27035/j.cnki.issn2097−5279.20260205

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参考文献

原文顺序 | 出版日期 | 本文引用

[1]	丁亚操 . 2016. 柱花草杂交群体构建、性状分析及遗传图谱引物筛选[D]. 海口: 海南大学.

[2]	Ding Y C . 2016. Character analysis and genetic map primers selection on constructed crossing population of Stylosanthes [D]. Haikou: Hainan University.(in Chinese)

[3]	梁英梅, 伍文慧, 田呈明, 等 . 基于锁式探针的落叶松枯梢病菌滚环扩增引物组及应用:CN202310336499.2[P]. 2023‒07‒14.

[4]	梁英梅, 刘正强, 伍文慧, 等 . 基于超分支滚环扩增检测落叶松枯梢病菌的探针引物组、试剂盒及检测方法:CN202411482036.8[P]. 2025‒04‒04.

[5]	刘秀嶶 . 2009. 落叶松枯梢病的生物防治与分子检测初步研究[D]. 哈尔滨: 东北林业大学.

[6]	Liu X W . 2009. Biocontrol and molecular diagnosis of the larch shoot blight[D]. Harbin: Northeast Forestry University.(in Chinese)

[7]	彭丹丹, 张源明, 舒灿伟, 等 . 2017. 植物病原真菌分子检测技术的研究进展[J]. 基因组学与应用生物学, 36(5): 2015−2022.

[8]	Peng D D , Zhang Y M , Shu C W ,et al. 2017. Research progress on molecular detection techniques of plant pathogenic fungi[J]. Genomics and Applied Biology, 36(5): 2015−2022.(in Chinese)

[9]	尚衍重 . 1991. 落叶松枯梢病菌的学名变更[J]. 森林病虫通讯, 10(2): 17.

[10]	Shang Y Z . 1991. Change of scientific name of larch shoot blight pathogen[J]. Forest Pest and Disease, 10(2): 17.(in Chinese)

[11]	汤苗, 叶绍翔, 文景玉, 等 . 2023. 样品预处理对天然橡胶相对分子量测试的影响[J]. 中国热带农业(5): 37‒43.

[12]	Tang M , Ye S X , Wen J Y ,et al. 2023. Effect of sample pretreatment on the relative molecular weight test of natural rubber[J]. China Tropical Agriculture,(5): 37‒43.(in Chinese)

[13]	王帅, 杨艳歌, 吴占文, 等 . 2023. 重组酶聚合酶扩增、重组酶介导等温扩增及酶促重组等温扩增技术在食源性致病菌快速检测中的研究进展[J]. 食品科学, 44(9): 297−305.

[14]	Wang S , Yang Y G , Wu Z W ,et al. 2023. A review of the application of recombinase polymerase amplification,recombinase—aided amplification and enzymatic recombinase amplification in rapid detection of foodborne pathogens[J]. Food Science, 44(9): 297−305.(in Chinese)

[15]	王永民, 刘国荣, 王世君, 等 . 1992. 落叶松枯梢病检疫技术的研究[J]. 林业科学研究, 5(6): 652−658.

[16]	Wang Y M , Liu G R , Wang S J ,et al. 1992. Study of quarantine techniques for larch shoot dieback[J]. Forest Research, 5(6): 652−658.(in Chinese)

[17]	王战役, 师恩帅 . 2006. 落叶松苗期三种主要病害防治技术[J]. 林业勘查设计, 35(3): 47−48.

[18]	Wang Z Y , Shi E S . 2006. Prevention and control techniques of three main diseases in larch seedling stage[J]. Forest Investigation Design, 35(3): 47−48.(in Chinese)

[19]	尤斯涵, 殷宏艳, 杨宋蕊, 等 . 2023. 生物样品的预处理技术研究进展[J]. 神经药理学报, 13(5): 52−59.

[20]	You S H , Yin H Y , Yang S R ,et al. 2023. Advance in pretreatment techniques for biological samples[J]. Acta Neuropharmacologica, 13(5): 52−59.(in Chinese)

[21]	赵娟, 张继澍, 王玉国, 等 . 2010. 致腐真菌侵染对梨果实愈伤组织防御机制的影响[J]. 西北植物学报, 30(11): 2219−2224.

[22]	Zhao J , Zhang J S , Wang Y G ,et al. 2010. Effects of infection of epiphyte caused fruit rot on defense mechanism in pear fruit callus[J]. Acta Botanica Boreali—Occidentalia Sinica, 30(11): 2219−2224.(in Chinese)

[23]	Babu B , Washburn B K , Miller S H ,et al. 2017. A rapid assay for detection of Rose rosette virus using reverse transcription—recombinase polymerase amplification using multiple gene targets[J]. Journal of Virological Methods, 240: 78−84.

[24]	Crannell Z A , Rohrman B , Richards—Kortum R . 2014. Quantification of HIV—1 DNA using real—time recombinase polymerase amplification[J]. Analytical Chemistry, 86(12): 5615−5619.

[25]	Hattori Y , Ando Y , Nakashima C . 2021. Taxonomical re‒examination of the genus Neofusicoccum in Japan[J]. Mycoscience, 62(4): 250−259.

[26]	Ju F Y , Qi Z Q , Tan J J ,et al. 2025. Development of a recombinase polymerase amplification method combined with a lateral flow dipstick assay for rapid detection of the larch pathogen Neofusicoccum laricinum [J]. Plant Disease, 109(2): 278−288.

[27]	Kim J H , Oh S W . 2021. Pretreatment methods for nucleic acid‒based rapid detection of pathogens in food:A review[J]. Food Control, 121: 107575.

[28]	Lobato I M , O’Sullivan C K . 2018. Recombinase polymerase amplification:Basics,applications and recent advances[J]. TrAC Trends in Analytical Chemistry, 98: 19−35.

[29]	Wang J C , Liu L B , Li R W ,et al. 2016. Rapid and sensitive detection of canine parvovirus type 2 by recombinase polymerase amplification[J]. Archives of Virology, 161(4): 1015−1018.

[30]	Yang Y H , Wang F , Xue B Y ,et al. 2023. Field—deployable assay based on CRISPR—Cas13a coupled with RT—RPA in one tube for the detection of SARS—CoV—2 in wastewater[J]. Journal of Hazardous Materials, 459: 132077.

[31]	Zhou H W , Wang C H , Rao J ,et al. 2021. The impact of sample processing on the rapid antigen detection test for SARS—CoV—2:Virus inactivation,VTM selection,and sample preservation[J]. Biosafety and Health, 3(5): 238−243.