贝莱斯芽胞杆菌EEAM 10B对花生白绢病的防治效果及全基因组测序分析

doi:10.16409/j.cnki.2095-039x.2025.02.023

摘要/Abstract

摘要： 为了挖掘生物防治新的菌种资源，本文从黑水虻虫卵表面分离鉴定出一株贝莱斯芽胞杆菌，命名为Bacillus velezensis EEAM 10B（以下简称EEAM 10B），以花生白绢病为靶标菌株，探究其对花生白绢病原菌Sclerotium rolfsii的拮抗作用及防治机理。花生白绢病是由齐整小核菌Sclerotium rolfsii Sacc.侵染引起的一种危害严重的花生土传病害。通过拮抗试验发现菌株EEAM 10B发酵菌液、上清液和挥发性物质均能抑制花生白绢病原菌的生长，且发酵菌液抑制效果优于上清液和挥发性物质。通过盆栽试验探究EEAM 10B菌株对花生白绢病的防治效果及植株促生作用，结果显示，菌液处理过的花生幼苗病情指数明显降低，并且对幼苗生长有一定促进作用；在接种病原菌前2 d以喷洒EEAM 10B菌株发酵液的处理方式对花生白绢病的防治效果最佳，可达65.80%。对EEAM 10B菌株进行全基因组测序，结果显示EEAM 10B基因组大小为3929786 bp，测序深度为1089.2，GC含量为46.5%。通过功能基因注释、代谢系统和致病系统分析发掘EEAM 10B存在一些与真菌细胞壁降解相关的酶，次级代谢产物基因簇中存在抑制病原菌活性的物质、以及促进植物生长和拮抗植物病原菌的相关基因，推测这些基因可能在EEAM 10B抑制花生白绢病过程中存在至关重要的作用。综上所述，EEAM 10B菌株具备作为生防菌的潜能，为新型抗菌剂的研发提供参考。

关键词: 花生白绢病, 贝莱斯芽胞杆菌, 抑菌, 生物防治, 全基因组测序

Abstract: To explore novel biocontrol microbial resources, a strain of Bacillus velezensis, designated as EEAM 10B, was isolated and identified from the surface of black soldier fly (Hermetia illucens) eggs. This study investigated its antagonistic effects and mechanisms against Sclerotium rolfsii Sacc, the pathogen of peanut southern blight. Peanut southern blight is a serious soil-borne fungal disease caused by Sclerotium rolfsii Sacc.Antagonism assays demonstrated that the fermentation broth, supernatant, and volatile organic compounds (VOCs) of EEAM 10B significantly inhibited the mycelial growth of peanut southern blight with the fermentation broth exhibiting the strongest suppression. Pot experiments revealed that EEAM 10B treatment notably reduced the disease index of infected peanut seedlings and exhibited plant growth-promoting effects. The optimal biocontrol efficacy (65.80%) was achieved when peanut plants were sprayed with EEAM 10B fermentation broth two days prior to pathogen inoculation. Whole-genome sequencing of EEAM 10B revealed a genome size of 3,929,786 bp with 1089.2×sequencing depth and a GC content of 46.5%. Functional annotation identified key genes encoding enzymes for fungal cell wall degradation (e.g., chitinases and β-1,3-glucanases) and secondary metabolite gene clusters responsible for antifungal compounds (e.g., surfactin, fengycin, and bacillibactin). Additionally, genes associated with plant growth promotion (e.g., indole-3-acetic acid synthesis) and pathogen antagonism were detected, suggesting their critical roles in suppressing peanut southern blight. These findings highlight the potential of EEAM 10B as a biocontrol agent and provide a foundation for developing novel antimicrobial formulations.

Key words: peanut southern blight, Bacillus velezensis, antibacterial, biological control, whole genome sequencing

中图分类号:

S476

谢久凤, 陈梦晓, 王勃, 裴亚欣, 张继冉, 陈红歌, 杨森. 贝莱斯芽胞杆菌EEAM 10B对花生白绢病的防治效果及全基因组测序分析[J]. 中国生物防治学报, 2025, 41(2): 347-361.

XIE Jiufeng, CHEN Mengxiao, WANG Bo, PEI Yaxin, ZHANG Jiran, CHEN Hongge, YANG Sen. Effect of Bacillus velezensis EEAM 10B on Peanut Southern Blight and Whole Genome Sequencing Analysis[J]. Chinese Journal of Biological Control, 2025, 41(2): 347-361.

参考文献

[1] Jacob S, Sajjalaguddam R R, Sudini H K, et al. RP1A-12 mediated control of peanut stem rot caused by Sclerotium rolfsii[J]. Journal of integrative agriculture, 2018, 17(4): 892-900.
[2] Han Z,Cui K,Wang M, et al. Bioactivity of DMI fungicide mefentrifluconazole against Sclerotium rolfsii, the causal agent of peanut southern blight[J]. Pest Management Science, 2023, 79(6): 2126-2134.
[3] 孙海燕, 万书波, 李林, 等. 我国花生生产区域比较优势分析[J]. 中国油脂, 2014, 39(6): 6-11.
[4] 张立伟, 王辽卫. 我国花生产业发展状况、存在问题及政策建议[J]. 中国油脂, 2020, 45(11): 116-122.
[5] 陈坤荣, 任莉, 徐理, 等. 花生白绢病研究进展[J]. 中国油料作物学报, 2018, 40(2): 302-308.
[6] 于东洋, 晏立英, 宋万朵, 等. 花生白绢病病原菌致病力分化的研究进展[J]. 中国油料作物学报, 2022, 44(5): 930-936.
[7] 付静, 付伟, 仁众, 等. 5种杀菌剂对花生白绢病菌的室内毒力与田间防病效果[J]. 中国植保导刊, 2022, 42(7): 82-85.
[8] 杨珊. 绿针假单胞菌zm-1生物防治花生白绢病的作用机理研究[D]. 郑州: 河南大学, 2022.
[9] 李佳昕, 蔡晨亮, 王琰, 等. 棘胞木霉菌鉴定及其对花生白绢病生防机制的研究[J]. 中国生物防治学报, 2022, 38(6): 1534-1544.
[10] Rabbee M F, Ali M S, Choi J, et al. Bacillus velezensis: a valuable member of bioactive molecules within plant microbiomes[J]. Molecules, 2019, 24(6): 1046.
[11] Chandrashekar B S, Prasannakumar M K, Venkateshbabu Gopal, et al. Bacillus velezensis (strains A6& P42) as a potential biocontrol agent against Klebsiella variicola, a new causal agent of soft rot disease in carrot[J]. Letters in Applied Microbiology, 2023, 76(1): ovac029.
[12] 彭启超, 黄德龙, 张志鹏, 等. 贝莱斯芽孢杆菌DPT-03对花生白绢病菌的防控效果[J]. 河南农业科学, 2022, 51(2): 97-103.
[13] Zhao J, Zhou Z, Bai X, et al. A novel of new class II bacteriocin from Bacillus velezensis HN-Q-8 and its antibacterial activity on Streptomyces scabies[J]. Frontiers in Microbiology, 2022, 13: 943232.
[14] 赵艳丽, 郭立, 惠祥海, 等. 微生物菌剂拌种对花生土传病害的防治效果及产量影响[J]. 中国生物防治学报, 2021, 37(6): 1250-1255.
[15] Liu H Y, Zeng Q C, Yalimaimaiti N, et al. Comprehensive genomic analysis of Bacillus velezensis AL7 reveals its biocontrol potential against Verticillium wilt of cotton[J]. Molecular Genetics and Genomics, 2021, 296: 1287-1298.
[16] 方园, 彭勇政, 廖长贵, 等. 一株具有防病促生功能的贝莱斯芽孢杆菌SF327[J]. 微生物学报, 2022, 62(10): 4071-4088.
[17] Han X S, Shen D X, Xiong Q, et al. The plant–beneficial rhizobacterium Bacillus velezensis FZB42 controls the soybean pathogen Phytophthora sojae due to bacilysin production[J]. Applied and Environmental Microbiology, 2021, 87(23): e0160121.
[18] Shi Z, Hong W, Wang Q. Complete genome resource of Bacillus velezensis J17-4, an endophyte isolated from stem tissues of rice[J]. Plant Disease, 2022, 106(2): 727-729.
[19] Xu W, Yang Q, Xie X, et al. Genomic and phenotypic insights into the potential of Bacillus subtilis YB-15 isolated from rhizosphere to biocontrol against crown rot and promote growth of wheat[J]. Biology, 2022, 11(5): 778.
[20] Yin X, Li T, Jiang X, et al. Suppression of grape white rot caused by Coniella vitis using the potential biocontrol agent Bacillus velezensis GSBZ09[J]. Pathogens, 2022, 11(2): 248.
[21] Pei Y X, Zhao S, Chen X, et al. Bacillus velezensis EEAM 10B strengthens nutrient metabolic process in black soldier fly larvae (Hermetia illucens) via changing gut microbiome and metabolic pathways[J]. Frontiers in Nutrition, 2022, 9: 880488.
[22] 潘梦诗,郭文阳,张宗源,等.贝莱斯芽孢杆菌对花生白绢病的防治效果[J]. 生物学杂志, 2022, 39(1): 37-41.
[23] Luo L, Zhao C, Wang E, et al. Bacillus amyloliquefaciens as an excellent agent for biofertilizer and biocontrol in agriculture: An overview for its mechanisms[J]. Microbiological Research, 2022, 259: 127016.
[24] Zaid D S, Cai S, Hu C, et al. Comparative genome analysis reveals phylogenetic identity of Bacillus velezensis HNA3 and genomic insights into its plant growth promotion and biocontrol effects[J]. Microbiology Spectrum, 2022, 10(1): e02169-21.
[25] 朱信霖, 扈东营, 陈显振, 等. 作用于细胞壁的抗真菌药物研究进展[J]. 菌物学报, 2022, 41(6): 871-877.
[26] Chen L, Wang X H, Liu Y P. Contribution of macrolactin in Bacillus velezensis CLA178 to the antagonistic activities against Agrobacterium tumefaciens C58[J]. Archives of Microbiology, 2021, 203(4): 1-10.
[27] 李铮, 王金辉, 丁丽丽, 等. 贝莱斯芽孢杆菌菌株NZ-4生防潜能及基因组学分析[J]. 江苏农业科学, 2023, 51(2): 117-125.
[28] 李小杰, 邱睿, 刘畅, 等. 基于全基因组测序的贝莱斯芽孢杆菌Ba-0321抑菌机制分析及相关功能验证[J]. 中国生物防治学报, 2023, 39(4): 885-894.
[29] Wang Y, Zhang C, Liang J, et al. Surfactin and fengycin B extracted from Bacillus pumilus W-7 provide protection against potato late blight via distinct and synergistic mechanisms[J]. Applied Microbiology and Biotechnology, 2020, 104(17): 7467-7481.
[30] Han X, Shen D, Xiong Q, et al. The plant-beneficial rhizobacterium Bacillus velezensis FZB42 controls the soybean pathogen Phytophthora sojae due to bacilysin production[J]. Applied and Environmental Microbiology, 2021, 87(23): e0160121.
[31] Gu S, Wei Z, Shao Z, et al. Competition for iron drives phytopathogen control by natural rhizosphere microbiomes[J]. Nature Microbiology, 2020, 5(8): 1002-1010.
[32] Dimopoulou A, Theologidis I, Benaki D, et al. Directantibiotic activity of bacillibactin broadens the biocontrol range of Bacillus amyloliquefaciens MBI600[J]. mSphere, 2021, 6(4): e0037621.
[33] Cui K, Xu T, Chen J, et al. Siderophores, a potential phosphate solubilizer from the endophyte Streptomyces sp. CoT10, improved phosphorus mobilization for host plant growth and rhizosphere modulation[J]. Journal of Cleaner Production, 2022, 367: 133110.
[34] Arnison P G ， Bibb M J ， Bierbaum G. Ribosomally synthesized and post-translationally modified peptide natural products: overview and recommendations for a universal nomenclature[J]. Natural Product Reports, 2013, 30(1): 108-160.
[35] Wu J J, Chou H P, Huang J W, et al. Genomic and biochemical characterization of antifungal compounds produced by Bacillus subtilis PMB102 against Alternaria brassicicola[J]. Microbiological Research, 2021, 251: 126815.
[36] 郭佳, 王娉, 周继福, 等. 乳源蜡样芽胞杆菌耐药性、毒力因子检测及分子特征研究[J]. 中国农业科技导报, 2022, 13(11): 131-138.