设施番茄根围土样中木霉菌多样性及功能活性分析

doi:10.13560/j.cnki.biotech.bull.1985.2017-0690

生物技术通报 ›› 2018, Vol. 34 ›› Issue (4): 179-185.doi: 10.13560/j.cnki.biotech.bull.1985.2017-0690

设施番茄根围土样中木霉菌多样性及功能活性分析

张广志, 王加宁, 吴晓青, 周方园, 张新建, 赵晓燕, 谢雪迎, 周红姿

山东省应用微生物重点实验室齐鲁工业大学（山东省科学院）山东省科学院生态研究所,济南 250014

收稿日期:2017-08-22 出版日期:2018-04-20 发布日期:2018-05-04
作者简介:张广志,男,副研究员,研究方向：农业微生物资源挖掘及利用;E-mail：zhanggzh@sdas.org
基金资助:
国家自然科学基金项目（31572044）,山东省科技发展计划（2014GSF121028）

Diversity and Functional Activity of Trichoderma in the Rhizosphere Soil from Facility Tomato Production

ZHANG Guang-zhi, WANG Jia-ning, WU Xiao-qing, ZHOU Fang-yuan, ZHANG Xin-jian, ZHAO Xiao-yan, XIE Xue-ying, ZHOU Hong-zi

Shandong Provincial Key Lab for Applied Microbiology,Ecology Institute,Qilu University of Technology（Shandong Academy of Sciences）,Ji’nan 250014

Received:2017-08-22 Published:2018-04-20 Online:2018-05-04

摘要/Abstract

摘要： 为探索设施栽培条件下蔬菜根围土壤中木霉种群多样性特征及其抗常见植物病原真菌及有机磷农药降解活性,从连续20多年种植番茄的设施大棚根围土样中以及番茄根系内部分离木霉菌,并以tef1-α序列和系统发育分析进行种类鉴定,估算各菌株的相对种群密度;对其生防和农残降解活性进行了测定。结果共分离不同木霉菌株27株,结合形态学特征和tef1-α序列分析,鉴定出分属6个不同的木霉种,即绿色木霉（Trichoderma virens）、深褐木霉（T. atrobrunneum）、西蒙斯木霉（T. simmonsii）、深绿木霉（T. atroviride）、厚木霉（T. crassum）和1个疑似木霉新种（T. sp. nov.）;木霉各菌株产孢簇常呈鲜绿色到暗绿色,分布不均匀,常形成同心圆结构。对峙条件下这些木霉对土壤中常见土传病原菌立枯丝核菌（Rhizoctonia solani）、大丽轮枝菌（Verticillium dahliae）、尖孢镰孢菌（Fusarium oxysporum）均有普遍的不同程度的抑菌活性;除深褐木霉两个菌株对毒死蜱的降解效果不明显外,其它种类的木霉均有菌株能有效降解毒死蜱,木霉菌株在根围土壤中的相对种群密度仅为104 cfu/g,且菌株间差异较大。研究结果表明设施农业土壤中木霉菌具有丰富的种质资源多样性,在形态特征及功能活性方面表现明显的菌株差异;木霉对3种常见植物病原真菌有普遍的抑菌作用,少数菌株对常用有机磷农药降解作用明显,可以发挥生防和农化残留降解方面的协同效应。该结果对于研究设施农业土壤中木霉的多样性,指导功能菌株筛选及应用,更好挖掘利用木霉菌资源有着较好的借鉴意义。

关键词: 设施农业, 木霉, 系统发育分析, 生防活性, 生物修复

Abstract: This work aimed to explore the diversity of Trichoderma from the rhizosphere soil of vegetables under facility culture as well as their aniti-phytopathogenic fungi and organophosphorus-degrading activity. Trichoderma were isolated from the rhizosphere soil and the roots of the sampled tomato from facility culture fields for more than 20 years of cultivation,and were identified by tef1-α sequencing combined with phylogenetic analysis. Besides,the relative population density of each strain was estimated,and the biocontrol activity and the degradation activity were further studied. Results showed that 27 different strains were isolated,and then identified based on the morphological characteristics and tef1-α,they belonged to T. virens,T. atrobrunneum,T. simmonsii,T. atroviride,T. crassum and one suspected new species T. sp. nov. Conidiation of Trichoderma strains usually was distributed unevenly,more or less concentric,and bright green to dull green. All the strains showed varied levels of inhibiting activity to several plant pathogenic fungi such as Rhizoctoma solani,Fusarium oxysporum and Verticillium dahlia. In the degradation experiment of chlorpyrifos,except strains belonging to T. atrobrunneum,strains in other Trichoderma species effectively degraded chlorpyrifos. The relative population density of Trichoderma in the rhizosphere soil was 104 cfu/g,and there was significant difference among different strains. The results indicate that there is rich Trichoderma germplasm diversity in the soil under facility culture,and they show obvious strain difference in morphological characteristics and functional activities. Trichoderma strains have general inhibiting activity to three plant pathogenic fungi,and some of them can effectively degrade organophosphorus pesticide. Thus,they play a synergistic effect of biocontrol and biodegradation of pesticides and fertilizers. The results of this paper are of great significance for the study of the adaptability of Trichodema in the soil of facility agriculture and the exploitation and utilization of Trichoderma resources.

Key words: facility agriculture, Trichoderma, phylogenetic analysis, biocontrol activity, bioremediation

张广志, 王加宁, 吴晓青, 周方园, 张新建, 赵晓燕, 谢雪迎, 周红姿. 设施番茄根围土样中木霉菌多样性及功能活性分析[J]. 生物技术通报, 2018, 34(4): 179-185.

ZHANG Guang-zhi, WANG Jia-ning, WU Xiao-qing, ZHOU Fang-yuan, ZHANG Xin-jian, ZHAO Xiao-yan, XIE Xue-ying, ZHOU Hong-zi. Diversity and Functional Activity of Trichoderma in the Rhizosphere Soil from Facility Tomato Production[J]. Biotechnology Bulletin, 2018, 34(4): 179-185.

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设施番茄根围土样中木霉菌多样性及功能活性分析

Diversity and Functional Activity of Trichoderma in the Rhizosphere Soil from Facility Tomato Production

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