KEGG pathway analysis

Metagenomic Analysis: Alterations of Soil Microbial Community and Function due to the Disturbance of Collecting Cordyceps sinensis

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This research examines how harvesting Cordyceps sinensis (a valuable medicinal fungus) affects the soil’s microscopic organisms on the Tibetan Plateau. While collection doesn’t reduce the total number of microbes, it significantly changes which types live in the soil and how they function. The study found that collection alters important soil processes related to carbon, nitrogen, and phosphorus cycling, suggesting that harvesting practices need to balance economic benefits with environmental health.

Leucocalocybe mongolica Fungus Enhances Rice Growth by Reshaping Root Metabolism, and Hormone-Associated Pathways

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Researchers discovered that a special fungus called Leucocalocybe mongolica, when added to soil, significantly improves rice plant growth without requiring chemical fertilizers. Plants grown in fungus-treated soil developed more branches (tillers), had longer roots, and contained more chlorophyll, making them greener and healthier. The study revealed that the fungus works by altering soil nutrients and triggering specific genes in rice roots that boost growth-promoting hormones and improve how plants process energy.

Chromosome-Scale Genome and Transcriptomic Analyses Reveal Differential Regulation of Terpenoid Secondary Metabolites in Hericium coralloides

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Researchers sequenced the complete genome of Hericium coralloides, an edible medicinal mushroom, at the chromosome level for the first time. They identified genes responsible for producing terpenoids, which are beneficial compounds with antioxidant, anti-inflammatory, and anti-tumor properties. The study found that these beneficial compounds are produced in higher amounts in the mushroom’s mycelium (root-like structure) compared to fruiting bodies, which could help optimize mushroom cultivation for medicinal use.

The Effect of Pseudomonas putida on the Microbial Community in Casing Soil for the Cultivation of Morchella sextelata

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Morel mushrooms are prized edible fungi, but growing them repeatedly in the same soil causes problems because toxic ethylene gas builds up and the soil microbiome becomes unbalanced. Scientists found that a beneficial soil bacterium called Pseudomonas putida can break down the ethylene precursor and improve the soil microbial community, making morels grow better and faster. This natural approach using microbial inoculation offers a practical solution to help farmers overcome these continuous cropping challenges.

Glycosylation and sugar variations in tyrosol yield promising prebiotic-like effects

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This study tested whether chemically modified versions of tyrosol, a natural compound found in olives and red wine, could boost beneficial gut bacteria better than the original form. Researchers gave mice three different versions: plain tyrosol, natural salidroside (tyrosol with glucose attached), and a lab-created version with galactose attached instead. The galactose version worked best, promoting the most beneficial bacteria like Bifidobacteria and reducing harmful bacteria, potentially offering health benefits similar to prebiotic supplements.

Non-Targeted Metabolomics Analysis Reveals Metabolite Profiles Change During Whey Fermentation with Kluyveromyces marxianus

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Scientists fermented whey (a dairy byproduct) using a special yeast called Kluyveromyces marxianus to create a nutrient-rich food. Using advanced analysis, they found that fermentation breaks down large proteins and fats into smaller, more beneficial compounds including amino acids and omega-3 fatty acids. The fermented whey showed significant increases in health-promoting substances that could help reduce inflammation, prevent disease, and improve overall nutrition.

Transcriptome Analysis of Dimethyl Fumarate Inhibiting the Growth of Aspergillus carbonarius

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Researchers studied how a chemical called dimethyl fumarate stops the growth of a dangerous fungus (Aspergillus carbonarius) that damages grapes and produces a toxin called ochratoxin A. By analyzing which genes were turned on and off when the fungus was exposed to this chemical, they found that it works by damaging the fungus’s cell walls and disrupting its normal development. This discovery could help protect fruit crops and food safety by providing a natural and non-toxic way to prevent mold growth.

Dynamic proteomic changes and ultrastructural insights into Pochonia chlamydosporia’s parasitism of Parascaris equorum eggs

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Scientists studied how a special fungus called Pochonia chlamydosporia attacks and destroys parasitic worm eggs. Using advanced microscopy and protein analysis, they tracked the fungus through three stages of infection and identified the specific proteins and processes it uses to break down the worm eggs. This research helps us understand how this fungus works so it can be better used as a natural pest control method to protect animals from harmful parasites.

Comparative phosphoproteome analysis to identify candidate phosphoproteins involved in blue light-induced brown film formation in Lentinula edodes

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Researchers studied how blue light triggers brown film formation on shiitake mushroom mycelia by analyzing protein modifications called phosphorylation. Using advanced mass spectrometry techniques, they identified thousands of phosphorylation changes in proteins when mushroom mycelia are exposed to blue light. The findings revealed that blue light activates several important processes including light sensing, pigment production, and cell wall degradation, providing insights into how mushrooms develop fruiting bodies in response to light signals.

Transcriptome Analysis of Dimethyl Fumarate Inhibiting the Growth of Aspergillus carbonarius

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Researchers found that dimethyl fumarate, a chemical preservative, can effectively stop the growth of a common fruit fungus called Aspergillus carbonarius that causes rot and produces a harmful toxin in grapes. By studying how the fungus responds to this treatment at the genetic level, scientists discovered that the chemical damages the fungus’s protective outer layer and interferes with its ability to develop and reproduce. This research could lead to better ways to preserve fruit and prevent toxin contamination in the food industry.

Research Keyword: KEGG pathway analysis