sustainable agriculture – Page 6

Algae and Cyanobacteria Fatty Acids and Bioactive Metabolites: Natural Antifungal Alternative Against Fusarium sp

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This review examines how fatty acids and other compounds from algae and cyanobacteria can naturally fight Fusarium fungus, which damages crops like wheat, corn, and tomatoes. Traditional chemical fungicides harm the environment and can make fungi resistant, so scientists are exploring algae-based alternatives that work sustainably. The research shows these algal compounds can damage fungal cell membranes and boost plant defenses against infection. While promising, more work is needed to develop these natural solutions for practical farm use.

Novel chia (Salvia Hispanica L.) residue-based substrate formulations for oyster mushroom (Pleurotus ostreatus) cultivation

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Researchers discovered that leftover plant material from chia seed production can be used to grow oyster mushrooms with excellent nutritional value. When chia residues were combined with rice straw in the right proportions, they produced mushrooms with higher protein content, more beneficial compounds, and better yields than traditional growing methods. This finding helps solve two problems at once: it creates a valuable use for chia farming waste while producing highly nutritious mushrooms for human consumption.

Synthesis of zinc oxide nanoparticles using Trichoderma harzianum and its bio-efficacy on Alternaria brassicae

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Scientists have developed an eco-friendly way to create zinc oxide nanoparticles using a beneficial fungus called Trichoderma harzianum. These nanoparticles effectively kill Alternaria brassicae, a fungus that damages mustard crops and can reduce yields by up to 57%. The nanoparticles work better and at lower doses than traditional chemical fungicides, making them a promising sustainable solution for farmers. This represents an important advancement in protecting crops without harming the environment.

Study of the Herbicidal Potential and Infestation Mechanism of Fusarium oxysporum JZ-5 on Six Broadleaved Weeds

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Scientists isolated a fungus called Fusarium oxysporum from diseased weeds and tested whether it could help farmers control unwanted plants naturally. The fungus showed strong promise against several common weeds, especially henbit deadnettle, while remaining safe for important crops like barley, wheat, and potatoes. Electron microscope observations revealed that the fungus invades weeds through tiny pores on leaves and spreads across the leaf surface. This discovery offers farmers an environmentally friendly alternative to chemical herbicides for sustainable agriculture.

Bio-stimulants for plant growth promotion and sustainable management of Rhizoctonia Solani causing black scurf of potato tubers

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Researchers tested natural treatments called bio-stimulants to help potato plants fight black scurf disease caused by a fungus called Rhizoctonia solani. They found that combining mycorrhizal fungi with seaweed extract was the most effective at reducing disease and improving potato quality. These natural treatments can enhance plant growth and tuber yield while reducing the need for chemical fungicides, making them valuable for sustainable potato farming.

Fruit and Vegetable Production

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This editorial reviews research on improving how fruits and vegetables are grown, harvested, and stored. Scientists studied various methods like using special water treatments, different soil mixtures, and natural soil microbes to help plants grow better and produce more nutritious food. New technologies like special cameras can now check fruit quality without damaging them. The research shows that by working together, farmers and scientists can grow healthier, more nutritious fruits and vegetables while reducing the need for chemical inputs.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

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Scientists discovered that a liquid extract from Cinchona bark, which contains quinine, can effectively kill a fungus that damages rice crops. The treatment works by blocking the fungus’s ability to absorb tryptophan (an important amino acid) and damaging its energy-producing mitochondria. When tryptophan was added back to the treatment, the fungus recovered, confirming this is the main way the extract works. This natural, plant-based approach could provide an eco-friendly alternative to chemical fungicides while reducing the risk of the fungus developing resistance.

Antifungal and other bioactive properties of the volatilome of Streptomyces scabiei

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Researchers discovered that Streptomyces scabiei, a bacterium that causes common scab disease in potatoes and other root crops, produces numerous airborne chemical compounds with surprising benefits. Using advanced chemical analysis, they identified 36 different volatile molecules, many of which can kill harmful fungi and promote plant health. This discovery suggests the bacterium’s role in nature is more complex than previously thought, as it may actually help protect plants while causing disease, opening new possibilities for developing natural pest control solutions.

Trichoderma tlahuicanensis sp. nov. (Hypocreaceae), a novel mycoparasite of Fusarium oxysporum and Phytophthora capsici isolated from a traditional Mexican milpa

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Scientists discovered and formally named a new fungal species called Trichoderma tlahuicanensis, found in traditional Mexican farming fields. This fungus naturally attacks harmful plant diseases like those caused by Fusarium and Phytophthora, making it valuable for protecting crops without synthetic chemicals. The researchers used advanced DNA sequencing to confirm it was indeed a new species, distinct from known Trichoderma relatives.

Native Bacteria Are Effective Biocontrol Agents at a Wide Range of Temperatures of Neofusicoccum parvum, Associated with Botryosphaeria Dieback on Grapevine

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Scientists discovered that native bacteria from Chile, particularly Pseudomonas strains, can effectively control a serious fungus that damages grapevines. These bacteria work across a range of temperatures and successfully reduced fungal growth both in laboratory tests and in actual vineyards. This discovery offers a natural, environmentally-friendly alternative to chemical fungicides for protecting grape crops.

Research Keyword: sustainable agriculture