4种芳香植物精油对竹林病原真菌的抗菌性

doi:10.11707/j.1001-7488.20200606

摘要/Abstract

摘要：

目的: 研究肉桂、香茅、大蒜和互叶白千层4种芳香植物精油对12种竹林病原真菌的抗菌性能和4种精油的有效抗菌成分，以期将芳香植物精油利用到竹林病害防治中，开发出高效、经济、无污染的竹用生物农药。方法: 试验用3%聚乙烯醇乳化肉桂、香茅、大蒜和互叶白千层4种植物精油，利用含不同体积分数（0.005%~2.0%）精油的PDA培养基测试4种精油对12种竹林病原真菌（裂褶菌、暗色节菱孢、丝核菌、长蠕孢、尖孢镰刀菌、尖孢枝孢、腐皮镰刀菌、链格孢、出芽短梗霉、黑附球菌、竹针孢座囊菌和竹黄）的MIC（最小抑菌浓度）和MFC（最小杀真菌浓度）。根据MIC和MFC的结果，选择不同体积分数的精油：肉桂0.01%（黑附球菌与竹针孢座囊菌采用肉桂0.02%），大蒜0.05%，香茅0.1%（链格孢菌采用香茅0.03%），互叶白千层0.1%（包括尖孢枝孢、链格孢菌、出芽短梗霉、黑附球菌与竹针孢座囊菌）和0.5%（其余7种菌）及不同体积分数的化学成分（反式肉桂醛、二烯丙基硫醚、二烯丙基二硫醚、香茅醛、松油烯-4-醇体积分数与对应精油相同，香茅醇和香叶醇体积分数为香茅的25%）；通过连续记录菌体的生长直径，评估各成分抗菌能力。结果: 肉桂、香茅、大蒜和互叶白千层精油均对12种供试病原菌有不同程度的抑制作用。肉桂精油对12种真菌的MIC多为0.005%（2个菌为0.010%），MFC为0.01%~0.10%；大蒜精油的MIC为0.005%~0.01%（1个菌为0.200%），MFC为0.1%~1.5%（有2个菌超过供试体积分数2.0%）；香茅精油的MIC为0.005%~0.03%，MFC为0.04%~0.50%；互叶白千层精油的MIC为0.03%~0.2%，MFC为0.2%~1.5%。经过耐药性分析（MFC/MIC比值），肉桂和互叶白千层精油耐药性较好，香茅精油次之，大蒜精油最差。此外经过验证，肉桂精油的抗菌有效成分是反式肉桂醛，香茅精油的有效抗菌成分是香茅醇和香叶醇，互叶白千层精油的有效抗菌成分是松油烯-4-醇，大蒜的抗菌成分为二烯丙基硫化物。结论: 肉桂、香茅、大蒜和互叶白千层精油均可以抑制竹林病原真菌的生长。综合MIC、MFC和耐药性分析结果，肉桂精油抗菌效果最佳；其次是香茅精油和互叶白千层精油，但互叶白千层精油价格昂贵，应用的经济价值较低；大蒜精油MFC过高且耐药性差，不适合开发利用。

关键词: 植物精油, 竹林病原真菌, 生物农药, 有效化学成分

Abstract:

Objective: In this study, the antifungal activity of essential oils (EOs) of cinnamon(Cinnamomum cassia), citronella(Cymbopogon nardus var. lenabatu), garlic(Allium sativum) and tea tree(Melaleuca alternifolia) against 12 kinds of pathogenic fungi of bamboo was investigated, and the effective antibacterial components of the four kinds of essential oils were compared. The purpose of this study are to make a good use of EOs in preventing and controlling bamboo forest diseases and developing an efficient, economical and pollution-free biological pesticide for bamboo. Method: Four essential oils of cinnamon, citronella, garlic and tea were emulsified with 3% polyvinyl alcohol, and PDA medium containing essential oils of different concentrations (0.005%-2.0%) was used to test the effects of four essential oils on 12 kinds of pathogenic fungi. MIC (minimum inhibitory concentration) and MFC (minimal fungicidal concentration) of 4 EOs to 12 bamboo pathogenic fungi (Schizophyllum commune, Arthrinium phaeospermum, Rhizoctonia sp., Helminthosporium sp., Fusarium oxysporum, Cladosporium oxysporium, Fusarium solani, Alternaria alternate, Aureobasidium pullulans, Epicoccum nigrum, Aciculosporium take, Shiraia bambusicola) were detected. According to the result of MIC and MFC, different concentrations of essential oil were selected:0.01% cinnamon (0.02% cinnamon for Epicoccum nigrum and Aciculosporium take), 0.05% garlic, 0.1% citronella (0.03% citronella for Alternaria alternate used), 0.1% tea tree for Cladosporium oxysporium, Alternaria alternate, Aureobasidium pullulans, Epicoccum nigrum and Aciculosporium take and 0.5% tea tree for other 7 kinds of fungi. The concentration of trans-cinnamaldehyde, diallyl disulfide, diallyl sulfide, citronellal and terpine-4-ol was the same as the corresponding EOs, and the concentration of citronellol and geraniol was 25% of citronella EO. The antifungal ability was evaluated by continuously recording the growth diameter of the fungus. Result: The EOs of cinnamon, citronella, garlic and tea tree all had to different degrees inhibitory effects on 12 tested pathogens. MIC of cinnamon EO was mainly 0.005% to 10 fungi (0.010% to 2 pathogen fungi), and the MFC was 0.01%-0.10%. MIC of garlic EO was 0.005%-0.010% to 11 fungi (0.200% to 1 pathogen fungus), and the MFC was 0.1% -1.5% (2 fungi exceeded the test concentration by 2.0%). MIC of citronella EO was 0.005%-0.030%, and the MFC is 0.04%-0.50%. MIC of tea tree EO was 0.03%-0.20%, and MFC is 0.2%-1.5%. According to the analysis of drug resistance (MFC/MIC), cinnamon and tea tree EOs had better drug resistance, followed by citronella EO, and garlic EO was the worst. In addition, it has been verified that the effective antifungal components of cinnamon, citronella, tea tree and garlic EOs were trans-cinnamaldehyde, citronella and geraniol, terpine-4-alcohol, and diallyl sulfide, respectively. Conclusion: Cinnamon, citronella, tea tree and garlic EOs have antifungal effect of pathogenic fungi from bamboo. Comprehensive assessment of 4 EOs, cinnamon EO is the best; citronella and tea tree EOs followed, but tea tree EO has low economic value for biological pesticide due to its expensive price; garlic EO is not suitable for development and utilization due to its high MFC and drug resistance.

Key words: plant essential oils, pathogenic fungi of bamboo, biological pesticides, chemical composition

中图分类号:

S763.11

王安可,毕毓芳,温星,王玉魁,蔡函江. 4种芳香植物精油对竹林病原真菌的抗菌性[J]. 林业科学, 2020, 56(6): 59-67.

Anke Wang,Yufang Bi,Xing Wen,Yukui Wang,Hanjiang Cai. Antifungal Activity of 4 Kinds of Aromatic Essential Oil Derived from Plants to Pathogenic Fungi of Bamboo[J]. Scientia Silvae Sinicae, 2020, 56(6): 59-67.

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真菌种类Fungi species	CFCC编号CFCC No.	病害名称Name of disease
裂褶菌Schizophyllum commune	51701	白色腐朽病White rot
暗色节菱孢Arthrinium phaeospermum	50513	毛竹基腐病Foot rot of moso bamboo
丝核菌Rhizoctonia sp.	88740	竹苗立枯病Bamboo seedling blight
长蠕孢Helminthosporium sp.	84467	毛竹麻点病Pocking mark of moso bamboo
尖孢镰刀菌Fusarium oxysporum	84715	枯萎病Blight
尖孢枝孢Cladosporium oxysporum	89895	簕竹黑斑病Black spot of Bambusa
腐皮镰刀菌Fusarium solani	86805	刚竹秆褐腐病Culm brown rot of Phyllostachys
链格孢Alternaria alternata	88501	毛竹叶斑病Leaf spot of moso bamboo
出芽短梗霉Aureobasidium pullulans	84164	毛竹基腐病Foot rot of moso bamboo
黑附球菌Epicoccum nigrum	50443	毛竹烟煤病Sooty mold of moso bamboo
竹针孢座囊菌Aciculosporium take	89286	竹丛枝病Witch’s broom of bamboo
竹黄Shiraia bambusicola	84681	竹赤团子Bamboo yellow or red ball

组分名称 Compound name	质量分数 Mass fraction(%)	CAS号 CAS No.
异松油烯Terpinolene	9.36	586-62-9
m-伞花烃m-Cymene	10.23	535-77-3
1，8-桉叶素1, 8-Cineole	2.56	470-82-6
γ-松油烯γ-Terpinene	20.45	99-85-4
α-松油烯α-Terpinene	4.34	99-86-5
松油烯-4-醇Terpinen-4-ol	53.06	562-74-3

组分名称 Compound name	质量分数 Mass fraction(%)	CAS号 CAS No.
柠檬烯Limonene	7.69	5989-27-5
香茅醛Citronellal	44.52	106-23-0
香茅醇Citronellol	14.56	106-22-9
香叶醇Geraniol	22.81	106-24-1
乙酸香茅酯Citronella acetate	4.32	150-84-5
丁香酚Eugenol	1.47	97-53-0
乙酸香叶酯Geranyl acetate	4.63	105-87-3

组分名称 Compound name	质量分数 Mass fraction(%)	CAS号 CAS No.
二烯丙基硫醚Diallyl sulfide	7.67	592-88-1
二烯丙基二硫醚Diallyl disulfide	32.06	2179-57-9
二烯丙基三硫醚Diallyl trisulfide	60.27	2050-87-5

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