induced systemic resistance

Roles of arbuscular mycorrhizal fungi in plant growth and disease management for sustainable agriculture

mycolabadmin

Arbuscular mycorrhizal fungi are beneficial fungi that live in plant roots and form a mutually beneficial relationship with plants. These fungi help plants absorb more nutrients and water from the soil, strengthen their natural defenses against diseases and pests, and work together with other helpful soil bacteria to create disease-suppressive soil. This makes AMF a promising natural alternative to chemical pesticides and fertilizers for sustainable agriculture.

Microbial-mediated induced resistance: interactive effects for improving crop health

mycolabadmin

This research explores how beneficial microbes like Trichoderma fungi and Bacillus bacteria can help plants naturally defend themselves against diseases. These microbes trigger the plant’s built-in immune system through chemical signals and molecular processes similar to how our immune system responds to threats. The approach offers an eco-friendly alternative to chemical pesticides for protecting crops, though effectiveness varies depending on environmental conditions.

The Biological Product Agricultural Jiaosu Enhances Tomato Resistance to Botrytis cinerea

mycolabadmin

Agricultural Jiaosu is a fermented product made from plant waste that effectively controls gray mold disease in tomatoes through two mechanisms: it directly kills the fungus with organic acids, and it strengthens the plant’s natural defenses. When applied as a spray to tomato leaves once a week, it reduced disease by 55%, made plants grow taller and stronger, and boosted the plants’ protective enzymes. This natural alternative to chemical fungicides offers a sustainable and safe way to protect tomato crops while maintaining environmental health.

Trichoderma: The Current Status of Its Application in Agriculture for the Biocontrol of Fungal Phytopathogens and Stimulation of Plant Growth

mycolabadmin

Trichoderma is a beneficial fungus that grows naturally in soil and can protect crops from harmful fungal diseases while promoting plant growth. It works through multiple mechanisms including directly attacking pathogenic fungi, competing for nutrients, and boosting the plant’s own defense systems. With over 77 commercial products already available, Trichoderma offers a promising sustainable alternative to chemical pesticides for protecting major world crops.

Biology and Application of Chaetomium globosum as a Biocontrol Agent: Current Status and Future Prospects

mycolabadmin

Chaetomium globosum is a fungus that can protect crops from various plant diseases by producing toxic compounds and parasitizing harmful pathogens. It also helps plants defend themselves naturally and improves soil health by promoting beneficial microorganisms. This makes it a promising alternative to chemical pesticides for sustainable farming, though more research is needed to optimize its effectiveness in real field conditions.

Bacillus subtilis Strain TCX1 Isolated from Ambrosia artemisiifolia: Enhancing Cucumber Growth and Biocontrol Against Cucumber Fusarium Wilt

mycolabadmin

Scientists discovered a beneficial bacterium called Bacillus subtilis strain TCX1 that can protect cucumber plants from a devastating fungal disease called Fusarium wilt. This bacterium both kills the fungus directly through special compounds it produces and strengthens the plant’s natural immune system. Additionally, the bacterium helps cucumber plants grow better by producing growth hormones and improving nutrient absorption, making it a promising natural solution for farmers.

Biology and Application of Chaetomium globosum as a Biocontrol Agent: Current Status and Future Prospects

mycolabadmin

Chaetomium globosum is a common soil fungus that shows great potential for protecting crops from diseases and pests naturally. This review explains how it works—by producing toxic compounds against harmful fungi, directly attacking pathogens, and boosting plants’ own defense systems. When applied to seeds or soil, it has reduced crop diseases by up to 73% in field tests while also improving soil health and crop yields, making it a promising alternative to chemical fungicides.

Abscisic Acid Metabolizing Rhodococcus sp. Counteracts Phytopathogenic Effects of Abscisic Acid Producing Botrytis sp. on Sunflower Seedlings

mycolabadmin

Researchers discovered that a beneficial soil bacterium (Rhodococcus sp.) can protect sunflower plants from a harmful fungus (Botrytis sp.) by breaking down a plant stress hormone (ABA) that the fungus produces to weaken plant defenses. Unlike other protection methods that kill the fungus or boost immune responses, this bacterium works by removing the fungus’s chemical weapon. This discovery suggests new ways to protect crops from diseases.

Research Keyword: induced systemic resistance