{"title":"绿木霉Tv911对部分蔬菜的促生作用及其对番茄枯萎病的拮抗作用","authors":"Myo Zaw, M. Matsumoto","doi":"10.2525/ecb.58.7","DOIUrl":null,"url":null,"abstract":"Application of synthetic agro-chemicals for plant growth enhancement and weeds, pest and disease control would cause negative impacts on biodiversity, environment and human health (Debenest et al., 2010; Geiger et al., 2010). Accordingly, organic agriculture has become popular with rising trend throughout the world (Willer et al., 2009). Nowadays, many microbial products are available for pest and disease management in crop production (Berg, 2009), and also available for plant growth promotion as a biofertilizer (Rodríguez and Fraga, 1999; Vessey, 2003). The genus Trichoderma (Teleomorph Hypocrea) has attracted an increasing attention and interest because of their economic value, and it is widely used not only as a biocontrol agent especially for soil borne plant pathogenic fungi (Qualhato et al., 2013) but also for enzyme production in industrial usage (Ahamed and Vermette, 2008). Additionally, it has the potential to degrade environmental hazardous chemical residue from the contaminated agricultural soil (Arfarita et al., 2013). Antagonist mechanisms of Trichoderma spp. are competition for nutrient and space, and direct mycoparasitism with antibiosis such as cell wall degrading enzymes to inhibit the growth of plant pathogens (Benítez et al., 2004). Moreover, these species are common and persistent fungi in the rhizosphere soil microbial community in a natural ecosystem (Lidia et al., 2011). Among them, T. harzianum, T. virens, T. asperellum, T. koningii and T. hamatum were colonizing to the roots and rhizosphere and some strains of each species have been identified as a plant growth promoter of the early growth stage of bean plants (Hoyos-Carvajal et al., 2009). Isolates of T. harzianum increased plant height and leaf area of pepper and cucumber seedlings and reduced damping-off disease significantly under commercial growing conditions (Inbar et al., 1994). Isolates of T. virens produced plant growth regulator, the auxin-related compounds, and enhanced biomass and root growth of Arabidopsis (Arabidopsis thaliana) seedlings (ContrerasCornejo et al., 2009). The morphological and cultural properties of T. harzianum and T. vriens were not obviously different (Sharma and Singh, 2014), and it can be accurately identified by molecular sequencing of ITS gene (White et al., 1990). In our previous study, several Trichoderma species isolated from waste paper sludge compost abandoned by paper manufacturing company in Saga, Japan during 2014― 2016 were characterized by their paper degradation ability. As the results, these isolates are potentially responsible for production of cellulose degrading enzyme (cellulase) and total crude protein in treated paper wastes (Peng et al., 2016). Remarkably, there is no report concerned to the characterization of Trichoderma spp. derived from such paper sludge compost and possibility of usage of these isolates as a biological resource of plant growth promotion and antagonist of the plant pathogenic fungi. Although, cel-","PeriodicalId":11762,"journal":{"name":"Environmental Control in Biology","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2020-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":"{\"title\":\"Plant Growth Promotion of Trichoderma virens, Tv911 on Some Vegetables and Its Antagonistic Effect on Fusarium Wilt of Tomato\",\"authors\":\"Myo Zaw, M. Matsumoto\",\"doi\":\"10.2525/ecb.58.7\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Application of synthetic agro-chemicals for plant growth enhancement and weeds, pest and disease control would cause negative impacts on biodiversity, environment and human health (Debenest et al., 2010; Geiger et al., 2010). Accordingly, organic agriculture has become popular with rising trend throughout the world (Willer et al., 2009). Nowadays, many microbial products are available for pest and disease management in crop production (Berg, 2009), and also available for plant growth promotion as a biofertilizer (Rodríguez and Fraga, 1999; Vessey, 2003). The genus Trichoderma (Teleomorph Hypocrea) has attracted an increasing attention and interest because of their economic value, and it is widely used not only as a biocontrol agent especially for soil borne plant pathogenic fungi (Qualhato et al., 2013) but also for enzyme production in industrial usage (Ahamed and Vermette, 2008). Additionally, it has the potential to degrade environmental hazardous chemical residue from the contaminated agricultural soil (Arfarita et al., 2013). Antagonist mechanisms of Trichoderma spp. are competition for nutrient and space, and direct mycoparasitism with antibiosis such as cell wall degrading enzymes to inhibit the growth of plant pathogens (Benítez et al., 2004). Moreover, these species are common and persistent fungi in the rhizosphere soil microbial community in a natural ecosystem (Lidia et al., 2011). Among them, T. harzianum, T. virens, T. asperellum, T. koningii and T. hamatum were colonizing to the roots and rhizosphere and some strains of each species have been identified as a plant growth promoter of the early growth stage of bean plants (Hoyos-Carvajal et al., 2009). Isolates of T. harzianum increased plant height and leaf area of pepper and cucumber seedlings and reduced damping-off disease significantly under commercial growing conditions (Inbar et al., 1994). Isolates of T. virens produced plant growth regulator, the auxin-related compounds, and enhanced biomass and root growth of Arabidopsis (Arabidopsis thaliana) seedlings (ContrerasCornejo et al., 2009). The morphological and cultural properties of T. harzianum and T. vriens were not obviously different (Sharma and Singh, 2014), and it can be accurately identified by molecular sequencing of ITS gene (White et al., 1990). In our previous study, several Trichoderma species isolated from waste paper sludge compost abandoned by paper manufacturing company in Saga, Japan during 2014― 2016 were characterized by their paper degradation ability. As the results, these isolates are potentially responsible for production of cellulose degrading enzyme (cellulase) and total crude protein in treated paper wastes (Peng et al., 2016). Remarkably, there is no report concerned to the characterization of Trichoderma spp. derived from such paper sludge compost and possibility of usage of these isolates as a biological resource of plant growth promotion and antagonist of the plant pathogenic fungi. 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引用次数: 2
摘要
应用合成农用化学品促进植物生长和防治杂草、病虫害将对生物多样性、环境和人类健康造成负面影响(Debenest等,2010;Geiger et al., 2010)。因此,有机农业在世界范围内日益流行(Willer et al., 2009)。如今,许多微生物产品可用于作物生产中的病虫害管理(Berg, 2009),也可作为生物肥料用于促进植物生长(Rodríguez和Fraga, 1999;Vessey, 2003)。木霉属(Teleomorph Hypocrea)因其经济价值而引起了越来越多的关注和兴趣,它不仅被广泛用作生物防治剂,特别是土壤传播的植物病原真菌(Qualhato等人,2013),而且还被广泛用于工业用途的酶生产(Ahamed和Vermette, 2008)。此外,它还具有降解受污染农业土壤中的环境有害化学残留物的潜力(Arfarita et al., 2013)。木霉的拮抗机制是争夺养分和空间,并直接与抗生素(如细胞壁降解酶)进行真菌寄生,以抑制植物病原体的生长(Benítez et al., 2004)。此外,这些物种是自然生态系统根际土壤微生物群落中常见的持久真菌(Lidia et al., 2011)。其中,T. harzianum、T. virens、T. asperellum、T. koningii和T. hamatum定殖于根和根际,每个物种的一些菌株被鉴定为豆类植物生长早期的植物生长促进剂(Hoyos-Carvajal et al., 2009)。在商业种植条件下,哈兹菌的分离株增加了辣椒和黄瓜幼苗的株高和叶面积,并显著减少了干枯病(Inbar等,1994)。T. virens分离物产生植物生长调节剂、生长素相关化合物,并增强拟南芥(Arabidopsis thaliana)幼苗的生物量和根系生长(ContrerasCornejo等,2009)。T. harzianum和T. vriens的形态和培养特性没有明显差异(Sharma and Singh, 2014),可以通过ITS基因的分子测序进行准确鉴定(White et al., 1990)。在我们之前的研究中,从日本佐贺造纸公司2014 - 2016年废弃的废纸污泥堆肥中分离出几种木霉,对它们的纸张降解能力进行了表征。因此,这些分离株可能负责在处理过的废纸中产生纤维素降解酶(纤维素酶)和总粗蛋白质(Peng et al., 2016)。值得注意的是,目前还没有关于从这种纸污泥堆肥中提取的木霉的特性和利用这些分离物作为促进植物生长和拮抗植物病原真菌的生物资源的可能性的报道。尽管如此,移动电话,
Plant Growth Promotion of Trichoderma virens, Tv911 on Some Vegetables and Its Antagonistic Effect on Fusarium Wilt of Tomato
Application of synthetic agro-chemicals for plant growth enhancement and weeds, pest and disease control would cause negative impacts on biodiversity, environment and human health (Debenest et al., 2010; Geiger et al., 2010). Accordingly, organic agriculture has become popular with rising trend throughout the world (Willer et al., 2009). Nowadays, many microbial products are available for pest and disease management in crop production (Berg, 2009), and also available for plant growth promotion as a biofertilizer (Rodríguez and Fraga, 1999; Vessey, 2003). The genus Trichoderma (Teleomorph Hypocrea) has attracted an increasing attention and interest because of their economic value, and it is widely used not only as a biocontrol agent especially for soil borne plant pathogenic fungi (Qualhato et al., 2013) but also for enzyme production in industrial usage (Ahamed and Vermette, 2008). Additionally, it has the potential to degrade environmental hazardous chemical residue from the contaminated agricultural soil (Arfarita et al., 2013). Antagonist mechanisms of Trichoderma spp. are competition for nutrient and space, and direct mycoparasitism with antibiosis such as cell wall degrading enzymes to inhibit the growth of plant pathogens (Benítez et al., 2004). Moreover, these species are common and persistent fungi in the rhizosphere soil microbial community in a natural ecosystem (Lidia et al., 2011). Among them, T. harzianum, T. virens, T. asperellum, T. koningii and T. hamatum were colonizing to the roots and rhizosphere and some strains of each species have been identified as a plant growth promoter of the early growth stage of bean plants (Hoyos-Carvajal et al., 2009). Isolates of T. harzianum increased plant height and leaf area of pepper and cucumber seedlings and reduced damping-off disease significantly under commercial growing conditions (Inbar et al., 1994). Isolates of T. virens produced plant growth regulator, the auxin-related compounds, and enhanced biomass and root growth of Arabidopsis (Arabidopsis thaliana) seedlings (ContrerasCornejo et al., 2009). The morphological and cultural properties of T. harzianum and T. vriens were not obviously different (Sharma and Singh, 2014), and it can be accurately identified by molecular sequencing of ITS gene (White et al., 1990). In our previous study, several Trichoderma species isolated from waste paper sludge compost abandoned by paper manufacturing company in Saga, Japan during 2014― 2016 were characterized by their paper degradation ability. As the results, these isolates are potentially responsible for production of cellulose degrading enzyme (cellulase) and total crude protein in treated paper wastes (Peng et al., 2016). Remarkably, there is no report concerned to the characterization of Trichoderma spp. derived from such paper sludge compost and possibility of usage of these isolates as a biological resource of plant growth promotion and antagonist of the plant pathogenic fungi. Although, cel-