Fungal Species: Trametes betulina

Repeated measures of decaying wood reveal the success and influence of fungal wood endophytes

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Scientists tracked how fungi and bacteria decompose fallen tree logs over five years in a Minnesota forest. They discovered that fungi living dormant inside healthy wood trees become the dominant decomposers when wood begins to decay, outcompeting fungi arriving from soil and air. Wet, ground-contact conditions and bark coverage changed which fungi dominated, but bacterial communities followed a different pattern, remaining diverse regardless of conditions.

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Potential environmental impact of mycelium composites on African communities

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Scientists studied how mushroom-based building blocks made from agricultural waste affect the environment in Africa. They found these eco-friendly materials can be better for the planet than concrete if produced with renewable energy like solar power or firewood. The biggest environmental cost comes from the energy used in growing and drying the mushroom composites, so using cleaner energy sources could make them much more sustainable.

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Strongest untreated mycelium materials produced by Schizophyllum commune dikaryons

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Researchers found that mushroom mycelium grown from dikaryotic strains (with two nuclei) produces stronger, stiffer materials than traditional monokaryon strains used in mycelium-based products. These dikaryotic materials show tensile strength values comparable to some polymers, making them promising for creating sustainable alternatives to leather and textiles. The improved strength comes from differences in cell wall composition and lower expression of a hydrophobin gene, offering new possibilities for bio-based material development.

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Strongest untreated mycelium materials produced by Schizophyllum commune dikaryons

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Scientists have developed a new method to produce exceptionally strong mushroom-based materials by using dikaryotic strains of Schizophyllum commune instead of monokaryotic strains. These new materials achieved record-breaking strength of 47 MPa, making them stronger than existing mycelium materials while maintaining flexibility. The enhanced strength comes from differences in cell wall composition and lower expression of a specific gene that normally affects material density. This breakthrough could lead to improved fungal-based alternatives for leather and textiles.

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