Research Keyword: solid-state NMR

Solid-state NMR spectroscopy reveals unique properties of Trichoderma harzianum cell wall components

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Scientists used advanced spectroscopy techniques to examine the cell wall structure of Trichoderma harzianum, a beneficial fungus used to protect crops from harmful fungi. They discovered that this fungus has a uniquely organized cell wall composed of tough chitin layers inside and flexible sugar polymers outside. This special arrangement helps protect the fungus from dissolving itself with its own powerful enzymes while allowing it to attack pest fungi effectively.

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Mushroom and cereal β-D-glucan solid state NMR and FTIR datasets

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This research provides a large database of spectroscopic measurements from β-D-glucans extracted from various mushrooms and cereal grains. The data includes detailed chemical fingerprints obtained through two analytical techniques (NMR and infrared spectroscopy) that can help researchers understand the structure and properties of these beneficial compounds. The dataset is freely available for other scientists to analyze and use for developing new methods or understanding how different mushroom and cereal sources vary in their chemical composition.

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Kre6-dependent β-1,6-glucan biosynthesis only occurs in the conidium of Aspergillus fumigatus

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Researchers discovered that a specific sugar compound called β-1,6-glucan is found in the spore-like reproductive structures (conidia) of the fungus Aspergillus fumigatus but not in its growing filaments (mycelium). Using advanced nuclear magnetic resonance technology, they identified the KRE6 gene as responsible for making this sugar and found that removing this gene makes the fungus more vulnerable to certain chemicals that damage fungal cell walls.

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Revealing structure and shaping priorities in plant and fungal cell wall architecture via solid-state NMR

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This review explains how scientists use a special type of microscopy called solid-state NMR to study the protective outer layers of fungi and plants. The research shows that fungal pathogens can cleverly rearrange their cell walls to resist antifungal medicines, and that plants carefully organize their cell walls during growth by forming specific connections between different molecules. Understanding these structures at the molecular level could help develop better antifungal treatments and improve how we use plant biomass for biofuels and materials.

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Wood decay under anoxia by the brown-rot fungus Fomitopsis pinicola

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Researchers discovered that a common wood-decaying fungus called Fomitopsis pinicola can break down wood even when there is no oxygen present, which happens in the interior of fallen trees. Instead of using the chemical process it normally uses in oxygen-rich conditions, the fungus switches to releasing powerful digestive enzymes that break down plant fibers. This finding explains how wood continues to decompose deep inside tree trunks and could inspire new industrial processes for breaking down plant material without oxygen.

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Breaking down the wall: Solid-state NMR illuminates how fungi build and remodel diverse cell walls

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Scientists have developed a new technique called solid-state NMR that can examine fungal cell walls without damaging them, revealing how these structures are built and reorganized. This research shows that different fungi have different wall architectures made of sugar-like molecules including chitin and various glucans, and that fungi can quickly adapt their walls when exposed to antifungal drugs. These findings could help develop better antifungal treatments by targeting the specific structural features that different fungi rely on for survival.

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