Plant-parasitic-nematodes represent a major threat to the agricultural production of different crops worldwide. Due to the high toxicity of chemical nematicides, it is necessary to develop new control strategies against nematodes. In this respect, filamentous fungi can be an interesting biocontrol alternative. The genus Trichoderma, mycorrhizal and endophytic fungi are the main groups of filamentous fungi studied and used as biological control agents (BCAs) against nematodes as resistance inducers. They are able to reduce the damage caused by plant-parasitic nematodes directly by parasitism, antibiosis, paralysis and by the production of lytic enzymes. But they also minimize harm by space and resource-competition, by providing higher nutrient and water uptake to the plant, or by modifying the root morphology, and/or rhizosphere interactions, that constitutes an advantage for the plant-growth. Besides, filamentous fungi are able to induce resistance against nematodes by activating hormone-mediated (salicylic and jasmonic acid, strigolactones among others) plant-defense mechanisms. Additionally, the alteration of the transport of chemical defense components through the plant or the synthesis of plant secondary metabolites and different enzymes can also contribute to enhancing plant defenses. Therefore, the use of filamentous fungi of the mentioned groups as BCAs is a promising durable biocontrol strategy in agriculture against plant-parasitic nematodes.
The family Brassicaceae includes plants that are non-host for arbuscular mycorrhizal fungi (AMF) such as the model plant
Arabidopsis thaliana
(arabidopsis) and the economically important crop plant
Brassica napus
(rapeseed). It is well known that
Trichoderma
species have the ability to colonize the rhizosphere of Brassicaceae plants, promoting growth and development as well as stimulating systemic defenses. The aim of the present work is to ascertain that Brassicaceae plants increase productivity when AMF and
Trichoderma
are combinedly applied, and how such an effect can be ruled. This simultaneous application of a
Trichoderma harzianum
biocontrol strain and an AMF formulation produces a significant increase in the colonization by
Trichoderma
and the presence of AMF in arabidopsis and rapeseed roots, such colonization accompanied by improved productivity in both Brassicaceae species. Expression profiling of defense-related marker genes suggests that the phytohormone salicylic acid plays a key role in the modulation of the root colonization process when both fungi are jointly applied.
Given the current rate of human population growth, the mass breeding of insects for feed and food is in full industrial development, as a more efficient and effective alternative to conventional livestock for the production of animal protein. In these industries, the production of insect excreta (frass) represents one of the main outputs of the process, being up to 40 times greater than the production of animal biomass, which is why its use as organic fertilizer to replace the use of agrochemicals is considered a viable alternative in the development of sustainable agriculture and a circular economy. Through a review of all the existing literature, this article highlights the following benefits of the use of insect frass as organic fertilizer in sustainable agriculture: (1) contribution of nutrients to the soil, mainly nitrogen, easily assimilated by plant tissues; (2) addition of biomolecules and microorganisms that promote plant growth; and (3) increased tolerance to abiotic stresses and resistance to pathogens and pests due to the presence of different compounds and microorganisms. Therefore, insect frass from the mass breeding of insects for feed and food represents an important source of effective organic fertilizer for use in sustainable agriculture.
KeywordsInsect frass . Fertilizer . Sustainable agriculture . Nitrogen . Plant growth . Mealworm Contents 1 Introduction 2. Mass insect breeding industry 3. Insect frass and gut microbiota 4. Insect frass and agriculture 4.1. As a source of nutrients and compounds of interest for plant growth 4.2. As a generator of tolerance to abiotic stress and resistance to biotic stresses 5. Conclusion Acknowledgements References
Trichoderma is a soil-borne fungal genus that includes species with a significant impact on agriculture and industrial processes. Some Trichoderma strains exert beneficial effects in plants through root colonization, although little is known about how this interaction takes place. To better understand this process, the root colonization of wild-type Arabidopsis and the salicylic acid (SA)-impaired mutant sid2 by a green fluorescent protein (GFP)-marked Trichoderma harzianum strain was followed under confocal microscopy. Trichoderma harzianum GFP22 was able to penetrate the vascular tissue of the sid2 mutant because of the absence of callose deposition in the cell wall of root cells. In addition, a higher colonization of sid2 roots by GFP22 compared with that in Arabidopsis wild-type roots was detected by real-time polymerase chain reaction. These results, together with differences in the expression levels of plant defence genes in the roots of both interactions, support a key role for SA in Trichoderma early root colonization stages. We observed that, without the support of SA, plants were unable to prevent the arrival of the fungus in the vascular system and its spread into aerial parts, leading to later collapse.
Both drought and salinity represent the greatest plant abiotic stresses in crops. Increasing plant tolerance against these environmental conditions must be a key strategy in the development of future agriculture. The genus of Trichoderma filament fungi includes several species widely used as biocontrol agents for plant diseases but also some with the ability to increase plant tolerance against abiotic stresses. In this sense, using the species T. parareesei and T. harzianum, we have verified the differences between the two after their application in rapeseed (Brassica napus) root inoculation, with T. parareesei being a more efficient alternative to increase rapeseed productivity under drought or salinity conditions. In addition, we have determined the role that T. parareesei chorismate mutase plays in its ability to promote tolerance to salinity and drought in plants by increasing the expression of genes related to the hormonal pathways of abscisic acid (ABA) under drought stress, and ethylene (ET) under salt stress.
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