nitrogen fixation – mycolab.ai

Role of Azolla in sustainable agriculture and climate resilience: a comprehensive review

mycolabadmin

Azolla is a fast-growing water fern that can help farms become more sustainable by naturally fertilizing soil with nitrogen, reducing the need for chemical fertilizers. It also helps control weeds, conserve water, and provides nutritious feed for livestock and fish. Beyond agriculture, Azolla can help reduce greenhouse gas emissions and clean polluted water, making it valuable for both farming and environmental protection.

Actinorhizal plants and Frankiaceae: The overlooked future of phytoremediation

mycolabadmin

Actinorhizal plants are special trees and shrubs that team up with beneficial bacteria called Frankiaceae to clean up polluted and degraded soils. This natural partnership helps these plants survive harsh conditions like salty or heavy metal-contaminated soil while also cleaning up the environment. The bacteria help the plants by providing essential nitrogen and improving their ability to tolerate pollution, making them an inexpensive and sustainable solution for restoring degraded farmland.

Tackling Conifer Needle Cast and Ash Dieback with Host-Derived Microbial Antagonists Exhibiting Plant Growth-Promoting Traits

mycolabadmin

Scientists discovered native bacteria from European ash and Scots pine trees that can fight two destructive forest diseases: ash dieback and needle cast. These bacteria not only inhibit the disease-causing fungi but also help trees grow better by improving nutrient uptake. This natural approach offers an eco-friendly alternative to fungicide sprays for protecting forests.

Endophytic Diversity in Sicilian Olive Trees: Identifying Optimal Conditions for a Functional Microbial Collection

mycolabadmin

Researchers studied beneficial bacteria and fungi living inside olive trees from Sicily to create a collection of microorganisms that could improve olive farming. They found that wild olive trees and samples collected in winter had the most diverse and beneficial microbes, and that organic farming practices supported greater microbial diversity. Some of these microbes, especially Bacillus bacteria, showed promise in fighting fungal diseases and promoting plant growth, offering potential for developing natural fertilizers and disease control methods.

Endophytic Diversity in Sicilian Olive Trees: Identifying Optimal Conditions for a Functional Microbial Collection

mycolabadmin

Researchers studied beneficial microorganisms living inside olive trees in Sicily to understand how to boost plant health and disease resistance. They found that wild olive trees and woody twigs harbor more diverse and beneficial microbes than cultivated varieties. Bacillus bacteria were particularly valuable, producing compounds that protect plants and promote growth. These findings could help farmers reduce chemical inputs while improving olive production.

The Structural and Functional Diversities of Bacteria Inhabiting Plant Woody Tissues and Their Interactions with Fungi

mycolabadmin

Bacteria living in tree wood work together with fungi to break down wood and nutrients, which is important for forest health. Some bacteria can protect trees from harmful fungi by fighting them off, making them useful for controlling plant diseases. Understanding how bacteria and fungi interact in wood can help us grow healthier plants, manage tree diseases better, and improve wood decomposition processes.

Metagenomics and In Vitro Growth-Promoting Experiments Revealed the Potential Roles of Mycorrhizal Fungus Humicolopsis cephalosporioides and Helper Bacteria in Cheilotheca humilis Growth

mycolabadmin

Scientists studied a rare white plant called Cheilotheca humilis that cannot make its own food through photosynthesis and instead relies on fungi to survive. Using advanced DNA sequencing and laboratory experiments, they discovered that a special fungus called Humicolopsis cephalosporioides and several types of helpful bacteria work together to provide the plant with essential carbon and nutrients. This research reveals how these invisible microbial partners make it possible for this unusual plant to grow and thrive.

Isolation and identification of antagonistic fungi for biocontrol of Impatiens hawkeri leaf spot disease and their growth-promoting potential

mycolabadmin

Researchers discovered a beneficial fungus called Fusarium solani that prevents leaf spot disease in ornamental Impatiens hawkeri plants. This fungus not only fights the disease-causing pathogen but also promotes seed germination and plant growth. The findings suggest this fungus could replace harmful chemical pesticides while simultaneously acting as a natural fertilizer, benefiting both plant health and the environment.

therapeutic action: nitrogen fixation