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Towards understanding the impact of mycorrhizal fungal environments on the functioning of terrestrial ecosystems

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This research examines how different types of fungal partners of plants affect soil health and function. Scientists propose a new framework called mycorrhizal fungal environments (MyFE) to better understand how these underground fungi influence carbon storage, nutrient cycling, and overall soil properties. They introduced a large-scale experiment called Mycotron to study three main types of mycorrhizal fungi and their distinct impacts on soil processes, which could help us better manage soils in response to climate change.

The addition of six novel species and a new record of Amphisphaeria from northern Thailand

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Scientists discovered six new species of fungi called Amphisphaeria in northern Thailand, all found on dead wood. These fungi play an important role in decomposing woody materials in nature. By examining both their physical characteristics and genetic material, researchers confirmed these are distinct species previously unknown to science. One previously known species was also found on a new type of host plant.

Catalogue of fungi in China 1. New taxa of plant-inhabiting fungi

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Scientists in China have discovered 33 new types of fungi, including 2 entirely new genera and 18 previously unknown species. These fungi were found growing on dead wood, leaves, and plant materials across different regions of China. By combining detailed microscopic observations with DNA analysis, researchers confirmed these are genuinely new species distinct from known types. This work is part of an ongoing effort to catalog and document all the diverse fungi living in China’s varied landscapes.

Effective Regulation of ZnO Surface Facets for Enhanced Photoluminescence Properties Assisted by Zinc Quaternary Ammonium Salts

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Researchers developed a simple method to create special zinc oxide (ZnO) structures shaped like mushrooms with enhanced light-emitting properties. By adjusting the ratio of methanol to water in a heating process and using a special zinc-based chemical as a building block controller, they achieved structures with specific crystal surface exposures. These twined-mushroom structures showed significantly brighter light emission, making them promising candidates for use in light-emitting devices that require single-color output.

Morphological and molecular identification of endophytic fungi from roots of epiphyte orchid Aerides odorata Lour in Sabah

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Scientists studied fungi living inside the roots of a rare fragrant orchid called Aerides odorata. Using advanced microscopy and DNA analysis, they identified seven different types of fungi that help the orchid absorb nutrients and grow. These fungi form special structures called pelotons inside the plant’s root cells. This research helps scientists understand how to better grow and protect endangered orchids.

Bioinformatics-aided identification, characterization and applications of mushroom linalool synthases

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Scientists discovered a special enzyme from mushrooms that efficiently produces linalool, a fragrance ingredient found in most perfumes and cosmetics. This fungal enzyme is much more efficient and selective than similar enzymes from plants or bacteria, making it ideal for mass-producing natural linalool through fermentation. The study used advanced computer analysis to identify the enzyme and revealed specific parts of the enzyme responsible for its excellent performance, which could help design even better enzymes in the future.

High-Resolution Core Gene-Associated Multiple Nucleotide Polymorphism (cgMNP) Markers for Strain Identification in the Wine Cap Mushroom Stropharia rugosoannulata

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Scientists developed a new genetic tool called cgMNP markers to accurately identify different strains of wine cap mushrooms (Stropharia rugosoannulata). By analyzing the DNA of 105 mushroom strains collected from across China, they discovered that a single gene containing 865 genetic variations was sufficient to distinguish between all cultivated varieties. This breakthrough provides a practical way for mushroom farmers and researchers to identify specific strains quickly, which is important for breeding better mushrooms and maintaining quality in commercial production.

In Vitro and Computational Response of Differential Catalysis by Phlebia brevispora BAFC 633 Laccase in Interaction with 2,4-D and Chlorpyrifos

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Scientists studied how two common pesticides (2,4-D and chlorpyrifos) interact with an enzyme called laccase produced by a white rot fungus. Using laboratory tests and computer simulations, they found that the fungus can survive exposure to these pesticides while still producing active laccase. Importantly, chlorpyrifos actually increased the enzyme’s activity, suggesting it could be useful for breaking down pesticide-contaminated soil and water.

Growth Propagation of Liquid Spawn on Non-Woven Hemp Mats to Inform Digital Biofabrication of Mycelium-Based Composites

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Researchers developed a method to grow mushroom mycelium (fungal threads) in liquid form and apply it to hemp mats to create sustainable building materials. By testing different growth conditions and concentrations, they found ways to control how fast the mycelium spreads and covers the surface. This liquid-based approach offers advantages over traditional methods because it allows for more precise application and better control of material properties.

Diverse nitrogen acquisition strategies of conifer-associated ectomycorrhizal fungi shape unique responses to changing nitrogen regimes

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This research examines how different types of mushroom fungi that partner with conifer trees acquire nitrogen in different ways. Using genomic analysis, lab experiments, and historical mushroom samples from the past 60 years, scientists found that even closely related fungal species have distinct strategies for obtaining nitrogen from different sources. These findings suggest that coniferous forests may respond quite differently to changes in nitrogen availability compared to forests with broadleaf trees.

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