No specific diseases

Environmental and molecular approach to dye industry waste degradation by the ascomycete fungus Nectriella pironii

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Researchers found that a specific fungus called Nectriella pironii can effectively break down toxic chemicals from textile industry waste, including harmful dyes and cancer-causing compounds found in landfill leachate. The fungus uses special enzymes to transform these dangerous chemicals into less toxic forms. This discovery offers hope for cleaning up contaminated areas around old textile factories and treating wastewater more effectively and affordably than current methods.

Assessment of Heavy Metal Contamination, Distribution, and Source Identification in Surface Sediments from the Mid–Upper Reaches of the Yellow River

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Scientists studied pollution in sediments from China’s Yellow River and found high levels of chromium and cadmium, especially in cities. They determined that most of the pollution comes from human activities like industrial emissions and agriculture rather than natural sources. The research shows different areas of the river have different pollution levels, with the most polluted areas being major cities. This study helps identify where pollution comes from and guides efforts to clean up the river.

Transcriptomic insights into the molecular mechanism of abietic acid promoting growth and branching in Armillaria gallica

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Scientists discovered that abietic acid, a natural compound from pine trees, significantly boosts the growth of Armillaria gallica mushrooms by up to 302% in just three days. This fungus is important because it helps grow Gastrodia elata, a valuable traditional Chinese medicinal herb. By studying which genes turned on in response to abietic acid, researchers found it works by helping the fungus break down nutrients more efficiently and remodel its cell walls for better growth. This discovery could improve cultivation techniques for medicinal mushrooms and their plant partners.

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

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Two types of fungi, Aspergillus flavus and Cunninghamella elegans, can effectively break down pharmaceutical pollutants commonly found in wastewater, such as antidepressants and antibiotics. When grown as biofilms on foam carriers, these fungi removed over 90% of the target pharmaceuticals very quickly. The fungi accomplish this primarily through enzymatic breakdown rather than absorption, making them promising candidates for cleaning wastewater at treatment plants.

Mushroom stem-based diets elicit region-specific shifts in rainbow trout gut microbiota

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Researchers fed rainbow trout different diets containing mushroom stem waste from grocery stores for six weeks and studied how the mushroom ingredients affected the fish’s gut bacteria. They found that mushroom diets promoted beneficial bacteria in different parts of the fish’s intestine without harming the fish. This research shows that mushroom waste can be recycled into healthy fish feed while supporting the fish’s digestive health and supporting a more circular food system.

Disease: No specific diseases

Environmental and molecular approach to dye industry waste degradation by the ascomycete fungus Nectriella pironii

Assessment of Heavy Metal Contamination, Distribution, and Source Identification in Surface Sediments from the Mid–Upper Reaches of the Yellow River

Transcriptomic insights into the molecular mechanism of abietic acid promoting growth and branching in Armillaria gallica

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

Mushroom stem-based diets elicit region-specific shifts in rainbow trout gut microbiota