Laccaria bicolor – Page 2

Haplotype-resolved genomes of Phlebopus portentosus reveal nuclear differentiation, TE-mediated variation, and saprotrophic potential

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Scientists sequenced the complete genomes of two compatible strains of the king bolete mushroom (Phlebopus portentosus), an important edible and medicinal species. The study found that mobile DNA elements called transposons play a major role in creating genetic differences between the two fungal nuclei and in generating the diversity of compounds that give mushrooms their health benefits. The research shows this mushroom can both partner with trees and break down organic material on its own, making it uniquely adaptable.

Impact of sublethal zinc exposure on ectomycorrhizal Laccaria bicolor x poplar symbiosis

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This research examines how a fungus called Laccaria bicolor helps poplar trees survive in soil contaminated with excess zinc. The study found that even under zinc stress, the fungus and tree can maintain their symbiotic partnership, though both grow slower and the fungal layer around roots thins. The fungus activates special defense mechanisms and transporter proteins to manage zinc levels and protect the tree host, demonstrating remarkable resilience of this natural partnership.

Whole-Genome Sequencing and Comparative Genomics Analysis of the Wild Edible Mushroom (Gomphus purpuraceus) Provide Insights into Its Potential Food Application and Artificial Domestication

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Scientists sequenced the complete genetic code of Gomphus purpuraceus, a wild mushroom eaten in southwest China for hundreds of years. By comparing its genes to other edible mushrooms, researchers discovered it likely forms beneficial partnerships with trees and can break down some plant material. The study shows this mushroom can efficiently use simple sugars like sucrose and maltose for growth, which could help farmers grow it commercially while preserving this rare species.

Strain and contact-dependent metabolomic reprogramming reveals distinct interaction strategies between Laccaria bicolor and Trichoderma

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Scientists studied how two types of fungi interact with each other when grown together. One fungus (Trichoderma) is used as a biocontrol agent to fight harmful fungi, while the other (Laccaria) helps trees grow. By analyzing the chemicals these fungi release both as gases and through their growth medium, researchers found that the fungi communicate and compete with each other differently depending on how close they are. These findings help us understand how fungi interact in soil and could improve the use of biocontrol agents in agriculture.

Electrical integrity and week-long oscillation in fungal mycelia

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Researchers monitored electrical signals in fungal mycelial networks over 100 days to understand how fungi coordinate their activities across space. When fungi encountered wood to decompose, they generated a clear, directional electrical signal from the wood toward the rest of the mycelium, acting like a biological command center. Most remarkably, after 60 days, the fungi developed a week-long electrical rhythm at the wood site, the longest oscillation ever recorded in fungi, which may help the fungus remember resource locations and coordinate its decomposition activities.

Electrical integrity and week-long oscillation in fungal mycelia

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Researchers discovered that fungal mycelia (underground networks of fungal threads) use electrical signals to communicate across their bodies when searching for food like wood. When a fungus found a piece of wood to eat, it generated electrical signals that spread throughout its mycelial network, possibly helping coordinate the fungus’s response. Most remarkably, the fungus exhibited a peculiar electrical rhythm at the food location that cycled every week—the longest such pattern ever observed in fungi.

Evolutionary Dynamics and Functional Bifurcation of the C2H2 Gene Family in Basidiomycota

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Researchers studied C2H2 genes, which are master regulators controlling important processes in fungal cells, across 30 different mushroom and fungal species. They found that these genes evolved differently depending on whether fungi were decomposers (saprotrophs) or pathogens, with decomposers maintaining more complex gene structures. During mushroom development in Sarcomyxa edulis, different C2H2 genes became active at different stages, controlling temperature adaptation, fruiting body formation, and other developmental processes.

Unusual genome expansion and transcription suppression in ectomycorrhizal Tricholoma matsutake by insertions of transposable elements

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Scientists sequenced the genome of the prized matsutake mushroom and discovered it has an unusually large genome packed with transposable elements (jumping DNA sequences). These transposable elements act like genetic ‘parasites’ that accumulate over time and actually silence many neighboring genes by preventing them from being expressed. The research shows how mushrooms evolved specialized mechanisms to control these genetic parasites while adapting to living symbiotically with pine tree roots.

A high-quality genome assembly of Lactarius hatsudake strain JH5

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Scientists have completed a detailed genetic blueprint of the red milk mushroom (Lactarius hatsudake), an edible and medicinal fungus that grows in pine forests. This mushroom is nutritious and has been shown to help with diabetes, boost immunity, and fight harmful bacteria. The new genetic map is much more complete and detailed than previous versions, which will help farmers grow these valuable mushrooms more reliably and sustainably, and could lead to developing better varieties.

Strain and contact-dependent metabolomic reprogramming reveals distinct interaction strategies between Laccaria bicolor and Trichoderma

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Scientists studied how two types of soil fungi interact with each other when grown together in laboratory conditions. By analyzing the chemicals these fungi produce and release, they discovered that the fungi actively communicate and compete with each other in different ways depending on how close they are to each other. The findings show that both airborne chemicals and chemicals released into the soil play important roles in how fungi recognize friends from foes, which could help improve the use of beneficial fungi in agriculture.

Fungal Species: Laccaria bicolor