毒死蜱降解木霉菌对几种重要植物病原真菌的生防活性

木霉菌既是广泛应用的防治植物病害的生防菌,又是一类很有应用潜力的环境污染修复菌。针对分离筛选出的6株高效降解毒死蜱的木霉菌株,进行了土传植物真菌病害的生防活性试验。结果表明,在对峙培养条件下,供试木霉菌株对几种病原真菌均具有较为显著的抑制率,发酵滤液对多数病原真菌具有明显的抑菌作用。所有供试木霉菌株能在立枯丝核菌、灰霉、终极腐霉菌落上着生,并逐渐覆盖全部菌落;但不能在茄腐镰孢菌、尖孢镰孢菌、大丽轮枝菌上生长。真菌重寄生现象观察结果表明,供试木霉菌仅对立枯丝核菌具有明显的重寄生现象。研究结果表明,筛选出的高效降解毒死蜱的木霉菌菌株可对多种土传植物病原真菌具有良好的生防潜力。     

T90-1木霉菌的筛选和对草莓灰霉病菌作用机制的研究

木霉菌（Trichoderma）作为一种重要的生防因子,可以产生几丁质酶降解植物的多种病原真菌细胞壁。利用低能离子束注入木霉菌使其产生变异,再通过初筛选和复筛选两个过程,获得T90_1木霉菌株,并用草莓灰霉病菌（Botrytis cinerea Pers.）来检验T90_1防治真菌病害的能力。发现该菌株通过侵染、缠绕等多种重寄生方式,并分泌降解病原真菌细胞壁的物质,使病原菌原生质外渗,改变细胞内有序的代谢状况,从而抑制或杀死病原菌。初步揭示该菌株抗真菌的相关机制。     

拮抗植物病原真菌链霉菌菌株ZH-356的鉴定及其生防评价

[目的]对实验室分离到的菌株ZH-356进行鉴定并评价其对植物病原真菌的生物防治效果,为研发针对植物真菌病害的生防菌剂提供理论指导。[方法]通过平板对峙法确定菌株ZH-356抗菌谱,并通过16S rRNA基因序列分析确定其种属,利用离体枝条的苹果树腐烂病菌感染预防试验和患腐烂病苹果树的防治试验评价其生防效果。[结果]菌株ZH-356鉴定为链霉菌属,与直丝紫链霉菌(Streptomyces rectiviolaceus)相似性最高,为99.71%。抗菌谱试验表明,菌株ZH-356对苹果树腐烂病菌、小麦赤霉病菌、小麦根腐病菌和番茄早疫病菌等多种植物病原真菌均具有较强的抑制作用,这种抑制作用可导致苹果树腐烂病菌菌丝变粗、交叉扭曲、分支变少且容易断裂。此外,ZH-356产生的抑菌活性物质对温度和酸碱度具有高度稳定性,并且该活性物质只存在于其胞内,只有当ZH-356遇到植物病原真菌时才会被分泌出来以抑制它们的生长。在离体枝条的苹果树腐烂病菌感染预防试验中,ZH-356对苹果树腐烂病防效可达94%以上,而在患腐烂病苹果树的防治试验中,ZH-356菌制剂对苹果树腐烂病的防效高达100%。[结论]链霉菌ZH-356抑菌谱广,对多种植物病原真菌均具有良好的拮抗活性,可作为防治植物真菌病害的生防菌株,为基于ZH-356菌株的生防菌剂的开发和防治苹果树腐烂病等植物真菌病害奠定了基础。     

木霉菌对3种致病真菌的作用关系研究

采用室内生长速率法测定了木霉菌 (Trichodermaspp .)与 3种致病真菌的互作关系 ,结果表明 ,木霉菌与 3种致病真菌间均存在明显的互作关系 ,但其互作类型与作用强度各不相同 :木霉菌与立枯丝核菌 (Rhi zoctoniasolani)间存在拮抗作用 ,但抑制强度不大 ;木霉菌与腐霉菌 (Pythiumaphanidermatum)不仅存在拮抗作用 ,且对腐霉菌的抑制强度较大 ;木霉菌与镰刀菌 (Fuariumspp .)间存在明显的协生作用。经进一步多方面考察后 ,有可能将该木霉菌用于病害防治     

两株生防芽孢细菌筛选、鉴定及拮抗研究

【目的】筛选出广谱、高效的生防芽孢细菌,并对其拮抗作用进行研究。【方法】以8种植物病原真菌为靶标菌,通过皿内拮抗和发酵液拮抗能力的测定筛选出2株广谱性和高效性的芽孢细菌B06和B07。【结果】B06对8种植物病原真菌的R2/R1为0.4-1.8,无菌滤液对8种植物病原真菌的抑制率为66.7%-87.5%。B07对8种植物病原真菌的R2/R1为0.23-1.21,无菌滤液对8种植物病原真菌的抑制率为55.56%-81.25%。经16S rRNA序列鉴定,菌株B06和B07都被鉴定为解淀粉芽孢杆菌。【结论】芽孢细菌能够抑制多种植物病原真菌,具有较好的抑病作用。广谱和高效芽孢细菌的筛选在农业生物防治方面具有很大的开发和应用价值。     

天然海鱼共附生放线菌抑菌和抗病毒活性筛选研究

从台湾海峡天然海鱼共附生微生物群落分离得到29株放线菌,通过抗病毒和抑菌活性筛选,分别得到6株对烟草花叶病毒和植物病原真菌具有较强抑制作用的天然菌株.其中,菌株030603对供试植物病原真菌拮抗作用尤为显著,其发酵产物具有广谱抑菌活性,可以作为广谱性植物病原真菌拮抗菌株进行生防菌产业化开发及发酵产物活性成分的化学研究.该菌株形态特征、培养特性、生理生化特性与微白黄链霉菌基本一致,16 S rDNA序列同源性达99.5 %.实验结果表明,利用天然海洋鱼类共附生微生物群落获取植物病原菌拮抗菌株具有取样便捷和活性菌株检出率高的特点.     

对峙培养条件下木霉拮抗植物病原真菌能力的评价(英文)

木霉属真菌因具有拮抗植物病原真菌的能力而广泛用于农业生物防治。为提高初步筛选的效率,在对峙培养条件下探讨了不同木霉菌株的拮抗能力,将其分为强、中等、弱和无拮抗能力4种类型。在对峙培养中,具有强拮抗能力的木霉菌株生长速度快于植病菌,产生大量缠绕菌丝缠绕在植病菌的菌丝上,12d内在植病菌的菌落上大量产孢。具中等拮抗能力的木霉菌株表现为(1)生长速度较快或与植病菌相似,缠绕菌丝丰富,30d内在植病菌的菌落上少量产孢;(2)生长速度快,但缠绕菌丝较少或几近缺乏,12d内在植病菌的菌落上产孢丰富。具有弱拮抗能力的木霉菌株生长速度与植病菌的大致相同,缠绕菌丝较少,30d后在植病菌的菌落上少量产孢或不产孢。无拮抗能力的木霉菌株生长速度慢,常受植病菌菌落的限制,甚至被植病菌的菌落覆盖。上述分型和评价方法综合考虑了竞争和寄生等拮抗机制,可用于实验室内对木霉拮抗能力的快速初筛。     

猕猴桃采后真菌病害生物防治研究进展

猕猴桃果实易受多种病原真菌的侵染,采后易发生软腐病、灰霉病、青霉病等严重危害果实品质的真菌性病害。传统的有效防治方法主要为采前使用化学杀菌剂,但其易污染环境并可能危害人类健康。目前,已有一系列生物防治方法被研究并报道,这些方法可有效防控猕猴桃采后真菌病害：第一类为天然抑菌物质,包括植物提取物和其他天然物质;第二类为拮抗微生物,包括生防酵母、生防细菌、生防木霉,生防菌也能与物理及化学方法协同发挥作用。本文概述了各类生物防治方法在猕猴桃采后真菌病害绿色防控方面的研究进展及生防机理,并提出了目前存在的问题,最后展望了这一领域今后的研究方向。     

芽胞杆菌代谢产物防治三种常见植物病原真菌的研究进展

植物病原真菌是农业生产的主要威胁之一,使用生物制剂防治病原真菌被认为是更安全和可持续的方式。芽胞杆菌能产生多种抗真菌活性物质（脂肽、细菌素和酶等）,是目前应用最广泛的生防菌。基于芽胞杆菌及其代谢产物的生物防治剂,可有效防治植物病原真菌,在农业生产中发挥着重要的作用。本文聚焦于芽胞杆菌代谢产物的生物防治潜力及其对抗3种常见植物病原真菌（稻瘟菌、尖孢镰刀菌、灰葡萄孢菌）的拮抗属性和机理研究等,通过调研近年来已发表的芽胞杆菌代谢产物抗菌的相关文献,对几种重要的芽胞杆菌代谢产物进行介绍,并总结了芽胞杆菌代谢产物对重要植物病原真菌的抗菌效果及其机制,同时对芽胞杆菌代谢产物对病原真菌的壁膜损伤、抑制真菌孢子萌发和菌丝生长以及竞争性结合真菌DNA等机制的研究手段和效果进行了总结,期望为今后芽胞杆菌类生防制剂的制备和应用提供指导策略。     

三个木霉菌株防病促生效应

【背景】木霉(Trichoderma sp.)是重要的生防微生物资源,对不同的木霉菌株进行生物学特性比较,可为获得功能较广的复配型生防菌剂提供参考信息。【目的】通过对绿木霉(Trichoderma virens) T23、哈茨木霉(Trichoderma harzianum) T22、G30的防病效果及对作物的促生潜力等生物学特性进行比较分析,明确不同菌株的生物功能差异。【方法】用平板拮抗法比较分析菌株T23、T22、G30对植物病原真菌的拮抗效果;用乙酸乙酯萃取法对菌株T23、T22、G30培养液中的胶毒素进行提取并通过高效液相色谱法(high-performance liquid chromatography, HPLC)检测胶毒素;用打孔法比较分析培养液萃取物对植物病原真菌的拮抗效果;通过温室接种验证菌株T23、T22、G30的防病效果;分别以磷酸钙、卵磷脂为唯一磷源检测菌株T23、T22、G30对难溶性磷的转化利用潜力,用电感耦合等离子发射光谱法(inductively coupled plasma-atomic emission spectrometry, ICP-AES)检...     

木霉防治灰霉病的研究进展

植物病害的生物防治是降低化学农药用量、减少环境污染的一种有效方式,木霉是现在普遍应用且生防潜力巨大的灰霉病防治真菌。目前,已经对防治灰霉的木霉菌株的筛选、应用及生防机制进行了大量而深入的研究。木霉的生防机制分为直接生防机制和间接生防机制,前者主要指木霉与灰霉病菌直接作用过程中所涉及的重寄生、抗生和营养竞争,后者是木霉通过诱导植物产生系统抗性来防治灰霉。本文对木霉直接防治灰霉病以及诱导植物产生系统抗性防治灰霉病所涉及的互作模式、信号传导途径以及所引起的防御反应进行综述,旨在通过机制的深入研究能够找到进一步提高木霉生防效果的技术方案。     

A novel, image analysis-based method for the evaluation of in vitro antagonism

A novel method is proposed for the accurate evaluation of in vitro antagonism. Based on the measurement of areas of the fungal colonies, biocontrol indices were calculated, which are characteristic to the antagonistic Trichoderma strains. These indices provide a useful tool to describe the biocontrol abilities of fungi.     

Isolation and characterization of protease overproducing mutants of Trichoderma harzianum

Several Trichoderma strains have been reported to be effective in controlling plant diseases, and the action of fungal hydrolytic enzymes is considered as the main mechanism involved in the antagonistic process. Strain Trichoderma harzianum T334 is a potential biocontrol agent against plant pathogenic fungi with the ability to produce low levels of proteases constitutively. To improve its fungal antagonistic capacity, mutagenetic program was undertaken for the construction of protease overproducing derivates. The mutant strains were obtained by means of UV-irradiation and were selected for p-fluorophenyl-alanine resistance or altered colony morphology. It was revealed by means of specific chromogenic protease substrates that both trypsin-like and chymotrypsin-like protease secretion was elevated in most of the mutant strains. The profiles of isoenzymes were different between the mutants and the wild-type strain, when examined by gel filtration chromatography. Certain mutants proved to be better antagonists against plant pathogens in in vitro antagonism experiments. This study suggests the possibility of using mutants with improved constitutive extracellular protease secretion against plant pathogenic fungi.     

中国木霉属内生真菌一个新记录种 Trichoderma chlorosporum

<正>1 INTRODUCTION Typically, Trichoderma spp. are free-living fungi most frequently isolated from soils and have been extensively studied due to their remarkable biocontrol and plant-growth promoting capacity.     

Friends and foes: streptomycetes as modulators of plant disease and symbiosis

The ecological role of soil streptomycetes within the plant root environment is currently gaining increased attention. This review describes our recent advances in elucidating the complex interactions between streptomycetes, plants, pathogenic and symbiotic microorganisms. Streptomycetes play diverse roles in plant-associated microbial communities. Some act as biocontrol agents, inhibiting plant interactions with pathogenic organisms. Owing to the antagonistic properties of streptomycetes, they exert a selective pressure on soil microbes, which may not always be for plant benefit. Others promote the formation of symbioses between plant roots and microbes, and this is in part due to their direct positive influence on the symbiotic partner, expressed as, e.g., promotion of hyphal elongation of symbiotic fungi. Recently, streptomycetes have been identified as modulators of plant defence. By repressing plant responses to pathogens they facilitate root colonisation with pathogenic fungi. In contrast, other strains induce local and systemic resistance against pathogens or enhance plant growth. In conclusion, while streptomycetes have a clear potential of acting as biocontrol agents, care has to be taken to avoid strains that select for virulent pathogens or enhance disease development. We argue towards the use of an integrated screening approach in the search for efficient biocontrol agents, including assays on in vitro antagonism, plant growth, and disease suppression.     

丛枝菌根菌诱导植物抗病的内在机制

应用菌根真菌诱导植物抗病性是近年化学生态学和病害生物防治研究的热点．研究表明,丛枝菌根真菌(AMF)对土传病原物具有一定拮抗或抑制作用,能提高植物对土传病害的抗／耐病性．在菌根根际,各种菌群不断产生相互作用,AMF在其中起着抑制病原菌、促进有益菌生长的作用,可与其他桔抗菌结合,用做生防菌．AMF提高植物抗病性的机制还有这样几种假设：(1)植物营养得到改善;(2)竞争作用;(3)根系形态结构改变;(4)根际微生物区系变化;(5)诱导抗性及诱导系统抗性,即AMF侵染植物根系后,诱导植物体内酚酸类代谢产物增加,使植物产生局部或系统防御反应．深人研究AMF提高植物抗病性的机制,有助于正确理解菌根的抗病作用,使其能尽快地成为植物病害生物防治中的一种新方法,在生态农业中发挥作用。     

Colony morphology mutants of Trichoderma harzianum with increased beta-1,4-N-acetyl-glucosaminidase production

A total of 36 UV-induced mutants with altered colony morphology were isolated from strain Trichoderma harzianum T334, a potential biocontrol agent against plant pathogenic fungi with the ability to produce constitutively low levels of chitinases. The level of constitutive beta-1,4-N-acetyl-glucosaminidase production in standing and shaken cultures under non-inductive conditions was tested in mutants and compared to that of the parental strain. About 30% of the mutants showed significantly increased levels of enzyme production, with strain T334 col26a being the best producer. This mutant and the parental strain were subjected to in vitro confrontation assays with plant pathogenic Fusarium culmorum, Pythium debaryanum and Rhizoctonia solani strains. The mutant derivative could be characterized by significantly higher biocontrol index values than the parental strain in each experiment, suggesting, that mutants with improved constitutive extracellular chitinase secretion could be applied for biocontrol purposes against fungal plant pathogens.     

Purification of a chitinase from Trichoderma sp. and its action on Sclerotium rolfsii and Rhizoctonia solani cell walls

Trichoderma harzianum is an effective biocontrol agent of several important plant pathogenic fungi. This Trichoderma species attacks other fungi by secreting lytic enzymes, including beta-1,3-glucanase and chitinolytic enzymes. Superior biocontrol potential may then be found in strains having a high capacity to produce these enzymes. We have therefore evaluated the capacity of six unidentified Trichoderma spp. isolates to produce chitinolytic enzymes and beta-1,3-glucanases in comparison with T. harzianum 39.1. All six isolates demonstrated substantial enzyme activity. However, while the isolates hereafter called T2, T3, T5, and T7 produced lower amounts of enzymes, the activity of isolates T4 and T6 were 2-3 fold higher than that produced by T. harzianum 39.1. A chitinase produced by the T6 isolate was purified by a single ion-exchange chromatography step and had a molecular mass of 46 kDa. The N-terminal amino-acid sequence showed very high homology with other fungal chitinases. Its true chitinase activity was demonstrated by its action on chitin and the failure to hydrolyze laminarin and p-nitrophenyl-beta-N-acetylglucosaminide. The hydrolytic action of the purified chitinase on the cell wall of Sclerotium rolfsii was convincingly shown by electron microscopy studies. However, the purified enzyme had no effect on the cell wall of Rhizoctonia solani.     

Biological control of anthracnose of chilli with rhizosphere and rhizoplane fungal isolates from grasses

The fungal species from rhizosphere and rhizoplane of perennial grasses of the Western Ghats of India were studied for their pathogenicity, antagonism in vitro, substrate and root colonization abilities, rhizosphere competence, growth in different soil pH and inoculum shelf-life. Out of 138 non-pathogenic fungal isolates tested, 85 were antagonistic in vitro to chilli anthracnose pathogen Colletotrichum capsici. Fifteen isolates with >60% inhibition zone to pathogen culture had saprophytic and root and rhizosphere colonization abilities. The sorghum grain inocula of test antagonistic fungi- Fusarium oxysporum, Chaetomium globosum and Trichoderma harzianum had the shelf-life of 90 days at 20?±?2?°C and required optimum soil pH of 6.5. The above fungal isolates when tested for biocontrol of anthracnose disease in greenhouse and field caused reduction in seedling mortality and decreased disease incidence and severity at various plant growth stages and significant reduction in chilli fruit and seed infection. The test antagonistic fungi promoted seedling and mature plant growth and increased fruit and seed yield. Populations of these antagonistic fungi were fairly high in chilli rhizosphere at harvest. The present study indicated that antagonistic fungi from grass rhizosphere and rhizoplane could be used to control anthracnose and promote plant growth, and increase yield of chilli in field.