fungal engineering – mycolab.ai

Quantitative Characterization of Gene Regulatory Circuits Associated With Fungal Secondary Metabolism to Discover Novel Natural Products

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Scientists developed a special technology using tiny channels and fluorescent markers to understand how fungi control their genes that produce valuable compounds. By precisely measuring how different genes turn on and off in individual fungal cells, they can now predict and control when and how much of useful medicines and other bioactive molecules are made. They successfully used this knowledge to create new pathways that produce novel compounds, including new types of dendrobine molecules never seen before.

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.

Research Topic: fungal engineering

Quantitative Characterization of Gene Regulatory Circuits Associated With Fungal Secondary Metabolism to Discover Novel Natural Products

Strongest untreated mycelium materials produced by Schizophyllum commune dikaryons