Investigating the beneficial traits of Trichoderma hamatum GD12 for sustainable agriculture—insights from genomics

Studholme, David J.; Harris, Beverley D.; Cocq, Kate Le; Winsbury, Rebecca; Perera, Venura; Ryder, Lauren S.; Ward, Jane L.; Beale, Michael H.; Thornton, Chris R.; Grant, Murray

doi:10.3389/fpls.2013.00258

Cited by 100 publications

(89 citation statements)

References 77 publications

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“…In particular this result has been noted in terms of root growth promotion, although significant increases have also been observed in aboveground vegetative growth such as stem length and thickness, leaf area, chlorophyll content and yield (size and/or number of flowers and/or fruits) [5,13,21,27,77]. Numerous hypothesis have been proposed to explain this observation including the improvement of chemical solubilisation, sequester, availability (i.e.…”

Section: Introductionmentioning

confidence: 90%

“…Modern scientific technology provides the possibility to conduct pre-field selection for suitable BCAs based on various studied genetic and biochemical characters known to be involved in the biological processes important and useful for crop protection. Screening is performed on the microorganism extracts by using high throughput screening, analysis of the proteome, metabolome transcriptome and other 'omics, microbiome and metagenomic analysis of "stimulating" plant-microbe environments, whole genome next generation sequencing [6,8,77,101,102]. Based on known desirable characteristics, new strains can be designed and developed by using hybrid technology (i.e.…”

Section: Introductionmentioning

confidence: 99%

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Trichoderma-based Products and their Widespread Use in Agriculture

Woo¹,

Ruocco²,

Vinale³

et al. 2014

TOMYCJ

480

297

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Governing bodies throughout the world, particularly in Europe, are now implementing legislative mandates with the objective of decreasing dependence on pesticides in agriculture to increase consumer and environmental safety. In order to reduce the risks associated with pesticide applications and reduce dependency on their use, Directives will promote low pesticide-input by implementing integrated pest management (IPM), and provide the means to establish the necessary conditions and measures to employ these practices, as well as to ensure security of commercial products. One approach includes the use of biological control agents and their products as alternatives to synthetic agro-chemicals. Trichoderma spp. are widely studied fungi and are among the most commonly used microbial biological control agents (MBCAs) in agriculture. They are presently marketed as bio-pesticides, biofertilizers, growth enhancers and stimulants of natural resistance. The efficacy of this fungus can be attributed to their ability to protect plants, enhance vegetative growth and contain pathogen populations under numerous agricultural conditions, as well as to act as soil amendments/inoculants for improvement of nutrient ability, decomposition and biodegradation. The living fungal spores (active substance) are incorporated in various formulations, both traditional and innovative, for applications as foliar sprays, pre-planting applications to seed or propagation material, post-pruning treatments, incorporation in the soil during seeding or transplant, watering by irrigation or applied as a root drench or dip. Trichoderma-based preparations are marketed worldwide and used for crop protection of various plant pathogens or increase the plant growth and productivity in diverse cultivated environments such as fields, greenhouses, nurseries; in the production of a variety of horticultural, fruits, trees and ornamental crops. A survey was conducted of Trichoderma-containing products found on the international market to obtain an overall perspective of the: 1) geographical distribution, 2) product composition and identity of Trichoderma species selected, 3) contents combined with Trichoderma in the products -other microbial species or substances in the mix, 4) number of products available globally and geographically, 5) number of products registered or having use specifications, 6) product formulations and applications, 7) manufacturer claims -target use, target pests, product type and effects of applications. The largest distribution of Trichoderma bioproducts is found in Asia, succeeded by Europe, SouthCentral America and North America. The majority of the labels indicated fungicidal properties, but only 38% of the marketed merchandise are registered. Ten Trichoderma species are specifically indicated, but many labels indicate a generic Trichoderma sp. or spp. mix in the list of ingredients. The most common formulation is a wettable powder, followed by granules. Generally, Trichoderma are applied to the seed or propagation material at...

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Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Trichoderma-based Products and their Widespread Use in Agriculture

Woo¹,

Ruocco²,

Vinale³

et al. 2014

TOMYCJ

480

297

View full text Add to dashboard Cite

show abstract

“…Trichoderma hamatum T382 induced systemic resistance against Botrytis cin erea in Arabidopsis thaliana which involved the triggering of defense enzymes, including glucanases, chitinases and other pathogenesis related proteins of the SA and Et-pathways (Mathys et al 2012). The ability of T. hamatum strain GD12 to elicit systemic resistance against Magnaporthe oryzae in rice, and S. scle rotiorum in lettuce was traced to its unique genomic regions with the potential to encode novel bioactive metabolites such as defense enzymes and proteins (Studholme et al 2013). Mayo et al (2015) recorded up regulation of seven defense related genes including glucanase during Trichoderma induced resistance against Rhizoctonia solani in beans.…”

Section: Discussionmentioning

confidence: 99%

Systemic protection against pearl millet downy mildew disease induced by cell wall glucan elicitors from Trichoderma hamatum UOM 13

Lavanya¹,

Niranjan-Raj²,

Nayaka³

et al. 2017

Journal of Plant Protection Research

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The obligate oomycete Sclerospora graminicola (Sacc.) Schroet, is the incitant of downy mildew disease, which is the main constraint in pearl millet production worldwide. Different elicitors from Trichoderma hamatum UOM 13, e.g. mycelial extract and cell wall glucans, were assessed for their resistance elicitation efficiency and the possible underlying mechanisms. Both mycelial extract and cell wall glucans of T. hamatum UOM 13 positively influenced seed quality parameters of pearl millet, significantly enhanced seed germination and seedling vigor in comparison to the untreated control. Seed priming with cell wall glucan elicitors of T. hamatum UOM 13 suppressed downy mildew on susceptible pearl millet seedlings under greenhouse conditions by induction of systemic host resistance. Of the different elicitor delivery methods tested, transplant root dip was more effective than seed treatment and foliar spray. A combination of transplant root dip + seed treatment + foliar spray was significantly more effective than the single delivery methods. The induced resistance corresponded to up regulation of genes of important defense proteins upon pathogen inoculation. Transcripts of genes of defense enzymes glucanase, phenylalanine ammonia lyase, peroxidase and polyphenoloxidase were significantly increased due to the T. hamatum UOM elicitor effect. Expression of hydroxyproline-rich glycoprotein genes, known to play an important role in cell wall cross-linking, were also up regulated in response to T. hamatum UOM cell wall glucan treatment. This study emphasizes the role of T. hamatum UOM as a potential elicitor of downy mildew resistance in pearl millet and presents novel insights into the involvement of important defense proteins mediating such as resistance trigger.

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“…Over the last decade, there has been an increasing demand in the agricultural market for biological agents that work with similar or possibly better efficacy than chemical agents at defending against a wide range of plant pathogens (Yedidia et al, 1999;Harman et al, 2004).Consequently, the search for Trichoderma species with high antagonistic potential against plant pathogens has become more attractive in recent years for the development of environment friendly agricultural practices. Recently, T. hamatum has gained interest in both academia and industry for its ability to enhance a plant's biomass and control pathogenic fungi (Studholme et al, 2013). This species' efficient control of plant pathogens depends on several physiological properties such as a rapid growth rate, ability to utilize various substrates, resistance to noxious chemicals, and production of antibiotics and extracellular hydrolytic enzymes (Carsolio et al, 1994;Lorito et al, 1996a, b;Kullnig et al, 2000;Harman et al, 2004;Chase and Fay, 2009;Studholme et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Recently, T. hamatum has gained interest in both academia and industry for its ability to enhance a plant's biomass and control pathogenic fungi (Studholme et al, 2013). This species' efficient control of plant pathogens depends on several physiological properties such as a rapid growth rate, ability to utilize various substrates, resistance to noxious chemicals, and production of antibiotics and extracellular hydrolytic enzymes (Carsolio et al, 1994;Lorito et al, 1996a, b;Kullnig et al, 2000;Harman et al, 2004;Chase and Fay, 2009;Studholme et al, 2013). Wang et al (2013) showed that T. hamatum could restrict the growth of bacterial wilt pathogens in ginger.…”

Section: Introductionmentioning

confidence: 99%

Proteomic Approaches of Trichoderma hamatum to Control Ralstonia solanacearum Causing Pepper Bacterial Wilt

Cheng¹,

Song²,

Gong³

et al. 2015

IJAB

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Hunan province has the largest pepper cultivation and highest pepper consumption in China. In recent years, peppers (Capsicum frutescens L.) cultivated in Hunan province have been infected by Ralstonia solanacearum, causing bacterial wilt thus inducing vast economic losses. Twenty-two strains of Trichoderma were isolated from soil samples near the pepper cultivation area in LiLing, Hunan province, PR China. Phylogenetic analysis based on the ITS region of the isolated strains detected three species including Trichoderma hamatum, T. asperellum, and T. virens. An antimicrobial test showed that T. hamatum strain YYH13 had the greatest antimicrobial activity against the bacterial wilt pathogen and that proteins in the liquid metabolites played a major role in this activity. A 1D-shotgun proteomics approach, in conjunction with LC-MS/MS, identified 125 different secreted proteins. Most of the antimicrobial proteins contain several specific chitinases that play an important role as hydrolytic enzymes during cell wall degradation.

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Investigating the beneficial traits of Trichoderma hamatum GD12 for sustainable agriculture—insights from genomics

Cited by 100 publications

References 77 publications

Trichoderma-based Products and their Widespread Use in Agriculture

Trichoderma-based Products and their Widespread Use in Agriculture

Systemic protection against pearl millet downy mildew disease induced by cell wall glucan elicitors from Trichoderma hamatum UOM 13

Proteomic Approaches of Trichoderma hamatum to Control Ralstonia solanacearum Causing Pepper Bacterial Wilt

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