提高木霉逆境适应性与生物防治效果的基因工程研究进展

木霉生存范围广、生长繁殖迅速,对其他真菌有一定的拮抗能力,并能促进植物生长、诱导植物对病原菌产生抗性,是迄今开发最成功的植物病害生防真菌。目前,运用基因工程的方法对木霉进行遗传改良,提高它对环境的适应性与对致病菌的防治能力,已经取得了很大的进展,就近年来采用基因工程的方法对木霉进行改良的研究进行综述。     

木霉菌防治植物真菌病害研究进展

木霉菌是一种重要的植物病害生防因子,尤其在防治植物病原真菌病害中一直受到极大的关注。木霉菌依靠其菌株在包括趋向生长、识别、接触、缠绕与穿透等步骤的真菌寄生过程中分泌产生的几丁质酶、葡聚糖酶、纤维素酶、蛋白酶等一系列细胞壁降解酶,进行重寄生作用,拮抗其他植物病原菌,行使其生防功能。我们简要概述了木霉菌的种类、拮抗对象、抑菌机制、诱导抗性、促生作用、基于分子生物学的转基因工程研究,以及木霉菌在植物病原真菌生物防治中的应用。     

拮抗木霉耐多菌灵菌株的筛选

该文进行了耐多菌灵生防木霉菌株的筛选和生防效果的测定研究。为获得对灰葡萄孢霉等病原菌有显著拮抗能力的耐多菌灵木霉菌株,通过含药平板诱导和紫外线诱变,获得5株耐药性菌株,在多菌灵2.0g/L浓度下生长较好,Ec50值提高了40多倍;抗性菌株在含药培养基上连续继代转移培养10次,抗性程度未见下降;经过平板对峙和活体拮抗性测定,确定T42-2为最佳拮抗性耐多菌灵菌株,其对黄瓜灰霉病的防效达92.13%,并且对多菌灵、速克灵和三唑铜存在交互抗性。     

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。     

硼抑制植物病害作用及机制的研究进展

硼不仅是植物生长必需的营养元素,也可减少和降低植物病害的发生。本文总结了硼抑制植物病害发生的作用机制：参与植物细胞壁和膜形成,增强植物细胞稳定性;诱导植物产生系统获得性抗性;诱导植物细胞产生适量的酚类和过氧化物;抑制病原菌菌丝生长,扭曲病原菌菌丝结构形态;破坏病原茵活性氧代谢系统,加快膜脂过氧化作用;与生防菌协同控制植物病害发生等。另外,还探讨了矿质元素防治植物病害可能存在的问题以及应用前景,以期为进一步的研究提供参考。     

贝莱斯芽孢杆菌生防次级代谢产物研究进展

贝莱斯芽孢杆菌（Bacillus velezensis）是生防芽孢杆菌中的重要代表,作为微生物农药的核心菌种,已被广泛应用于作物病害生物防治。贝莱斯芽孢杆菌具有植物内生性,其生防作用机制主要包括产生次级代谢产物对抗植物病原物;改善宿主植物根际微生物群落,促进宿主营养和生长;激发宿主植物产生防御反应,诱导植物获得系统抗性。其中,产生次级代谢产物是其最重要的生防作用机制。贝莱斯芽孢杆菌含有多个编码生物合成次级代谢产物的基因簇,其中包括编码聚酮化合物合酶（PKS）和非核糖体肽合成酶（NRPS）的基因簇,同时存在核糖体途径合成次级代谢产物基因簇。通过非核糖体途径可产生脂肽类化合物、聚酮类化合物、二肽和铁载体;通过核糖体途径产生小菌素、细菌素、羊毛硫抗生素。这些具有生物活性的次级代谢产物成为了天然新药和候选抗生素的储存库,对于解析生防菌作用机制具有重要意义。本文综述了贝莱斯芽孢杆菌的命名与更迭,产生次级代谢产物的类型、合成与调控基因以及靶标病原菌,以期为生防菌株的改良和生物农药的研发提供参考。     

芽胞杆菌在防治水稻稻瘟病中的应用及生防机制

芽胞杆菌具有人畜安全、不污染环境、病原菌不易产生抗药性、抗逆性强和促进植物生长等优点,是稻瘟病防治上的重要生防菌。芽胞杆菌的生防机制主要包括竞争作用、拮抗作用和诱导抗病性。芽胞杆菌定殖在水稻植株上,产生抗菌活性物质抑制稻瘟病菌的生长,诱导水稻产生抗病性,对水稻植株具有促生作用,可以挽回水稻产量损失。芽胞杆菌可以制备生防制剂用来防治我国南方稻区和北方稻区的稻瘟病危害,在水稻产业的可持续发展中对稻瘟病的生物防治具有指导意义。本文主要综述芽胞杆菌在防治水稻稻瘟病中的应用研究、芽胞杆菌在防治水稻稻瘟病中的生防机制、影响稻瘟病生防芽胞杆菌防效的因素。     

枯草芽孢杆菌在抑制植物病原菌中的研究进展

枯草芽孢杆菌是芽孢杆菌中比较具应用潜力的菌种之一。近年来国内外对于芽孢杆菌各方面应用的研究日益增多,枯草芽孢杆菌作为一种生防细菌越来越引起人们的关注。主要综述了枯草芽孢杆菌在抑制植物病原菌生物防治领域的研究进展,阐述了枯草芽孢杆菌的控病作用机制,包括竞争作用、拮抗作用、溶茵作用、诱导植物产生抗性及促进植物生长5个方面。简要介绍了枯草芽孢杆菌及其制剂在国内外的应用情况及在植物病害防治应用中存在的问题、解决措施及发展前景。     

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。     

生防菌诱导植物系统抗性及其生化和细胞学机制

生防菌通常可利用竞争、抗生、寄生和交叉保护等直接的拮抗机制抑制植物病害;同时某些生防菌还能促进植物生长,诱导植物对真菌、细菌和病毒引起的病害乃至对线虫和昆虫为害的抗性,称为诱导系统抗性(ISR).ISR具有非特异性、广谱性和系统性,其在表型上与病原菌侵染激发的系统获得抗性(SAR)相似,具有同样的效率;但在寄主植物上不发生过敏性坏死反应(HR),无可见症状,为发展和改善更加安全而环境友好的植物保护策略开辟了新的思路.本文总结了生防真菌和细菌诱导系统抗性及其激发子和信号转导途径等方面的研究进展,重点阐述了寄主防御反应的生化和细胞学机制,并对ISR在植物病害生物防治中的应用前景进行了展望.     

The beneficial effect of Trichoderma spp. on tomato is modulated by the plant genotype

Rhizosphere-competent fungi of the genus Trichoderma are widely used as biofertilizers and biopesticides in commercial formulates because of the multiple beneficial effects on plant growth and disease resistance. In this work, we demonstrate that genetic variability among wild and cultivated tomato lines affects the outcome of the interaction with two 'elite' biocontrol strains of T. atroviride and T. harzianum. The beneficial response, which included enhanced growth and systemic resistance against Botrytis cinerea, was clearly evident for some, but not all, the tested lines. At least in one case (line M82), treatment with the biocontrol agents had no effect or was even detrimental. Expression studies on defence-related genes suggested that the fungus is able to trigger, in the responsive lines, a long-lasting up-regulation of the salicylic acid pathway in the absence of a pathogen, possibly activating a priming mechanism in the plant. Consequently, infection with B. cinerea on plants pretreated with Trichoderma is followed by enhanced activation of jasmonate-responsive genes, eventually boosting systemic resistance to the pathogen in a plant genotype-dependent manner. Our data indicate that, at least in tomato, the Trichoderma induced systemic resistance mechanism is much more complex than considered so far, and the ability of the plant to benefit from this symbiotic-like interaction can be genetically improved.     

Biocontrol mechanisms of Trichoderma strains.

The genus Trichoderma comprises a great number of fungal strains that act as biological control agents, the antagonistic properties of which are based on the activation of multiple mechanisms. Trichoderma strains exert biocontrol against fungal phytopathogens either indirectly, by competing for nutrients and space, modifying the environmental conditions, or promoting plant growth and plant defensive mechanisms and antibiosis, or directly, by mechanisms such as mycoparasitism. These indirect and direct mechanisms may act coordinately and their importance in the biocontrol process depends on the Trichoderma strain, the antagonized fungus, the crop plant, and the environmental conditions, including nutrient availability, pH, temperature, and iron concentration. Activation of each mechanism implies the production of specific compounds and metabolites, such as plant growth factors, hydrolytic enzymes, siderophores, antibiotics, and carbon and nitrogen permeases. These metabolites can be either overproduced or combined with appropriate biocontrol strains in order to obtain new formulations for use in more efficient control of plant diseases and postharvest applications.     

Improvement of the fungal biocontrol agent Trichoderma atroviride to enhance both antagonism and induction of plant systemic disease resistance

Biocontrol agents generally do not perform well enough under field conditions to compete with chemical fungicides. We determined whether transgenic strain SJ3-4 of Trichoderma atroviride, which expresses the Aspergillus niger glucose oxidase-encoding gene, goxA, under a homologous chitinase (nag1) promoter had increased capabilities as a fungal biocontrol agent. The transgenic strain differed only slightly from the wild-type in sporulation or the growth rate. goxA expression occurred immediately after contact with the plant pathogen, and the glucose oxidase formed was secreted. SJ3-4 had significantly less N-acetylglucosaminidase and endochitinase activities than its nontransformed parent. Glucose oxidase-containing culture filtrates exhibited threefold-greater inhibition of germination of spores of Botrytis cinerea. The transgenic strain also more quickly overgrew and lysed the plant pathogens Rhizoctonia solani and Pythium ultimum. In planta, SJ3-4 had no detectable improved effect against low inoculum levels of these pathogens. Beans planted in heavily infested soil and treated with conidia of the transgenic Trichoderma strain germinated, but beans treated with wild-type spores did not germinate. SJ3-4 also was more effective in inducing systemic resistance in plants. Beans with SJ3-4 root protection were highly resistant to leaf lesions caused by the foliar pathogen B. cinerea. This work demonstrates that heterologous genes driven by pathogen-inducible promoters can increase the biocontrol and systemic resistance-inducing properties of fungal biocontrol agents, such as Trichoderma spp., and that these microbes can be used as vectors to provide plants with useful molecules (e.g., glucose oxidase) that can increase their resistance to pathogens.     

Improved antifungal activity of a mutant of Trichoderma harzianum CECT 2413 which produces more extracellular proteins

Trichoderma harzianum is a well-known biological control agent against fungal plant diseases. In order to select improved biocontrol strains from Trichoderma harzianum CECT 2413, a mutant has been isolated for its ability to produce wider haloes than the wild type, when hydrolysing pustulan, a polymer of beta-1,6-glucan. The mutant possesses between two and four times more chitinase, beta-1,3- and beta-1,6-glucanase activities than the wild type, produces about three times more extracellular proteins and secretes higher amounts of a yellow pigment (alpha-pyrone). This mutant performed better than the wild type during in vitro experiments, overgrowing and sporulating on Rhizoctonia solani earlier, killing this pathogen faster and exerting better protection on grapes against Botrytis cinerea.     

Mode of antagonism of Brevibacillus brevis against Botrytis cinerea in vitro

AIMS: To assess the activity of Brevibacillus brevis (formerly Bacillus brevis) Nagano and the antibiotic it produces, gramicidin S, against the plant pathogen Botrytis cinerea. METHODS AND RESULTS: Germination and growth of Bot. cinerea were assessed in the presence of B. brevis or gramicidin S in liquid media, on solid media and on leaf sections of Chinese cabbage. Germination was 10-fold more sensitive to gramicidin S than growth. Inhibition of Bot. cinerea was greater in liquid media compared with on solid media. Activity of gramicidin S against Bot. cinerea on leaf sections was much lower than in vitro. In vitro inhibition of Bot. cinerea by B. brevis Nagano was similar to equivalent levels of gramicidin. CONCLUSIONS: Antibiosis, via gramicidin S, is the mode of antagonism exhibited by B. brevis Nagano against Bot. cinerea in vitro. SIGNIFICANCE AND IMPACT OF THE STUDY: The mode of antagonism of B. brevis against Bot. cinerea was elucidated. The differing activity of gramicidin S against Bot. Cinerea in vitro and on leaf sections indicates one mechanism by which biocontrol activity may differ between laboratory and field conditions.     

重寄生菌哈茨木霉的研究及其在植病生防中的应用

综述了国内外对哈茨木霉菌产生的抑菌活性物质的研究概况,包括几丁质酶、葡聚糖酶和蛋白酶在内的细胞壁降解酶和抗生素,以及哈茨木霉菌生防产品的应用现状,并提出了其在植病生防中的研究展望。