laccase – mycolab.ai

Enhancing the Substrate Adaptability of Laccase through Ancestral Sequence Reconstruction for Applications in Mycotoxin Detoxification

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Researchers used evolutionary analysis to redesign a fungal enzyme called laccase to better detoxify harmful mold toxins found in grains. The new engineered enzyme (LacANC278) can break down both aflatoxin and zearalenone toxins much more effectively than the original enzyme, and converts them into less harmful substances. This enzyme works without expensive helper chemicals and works well at room temperature, making it practical for treating contaminated corn and other grains.

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.

Biotransformation of the Fluoroquinolone Antibiotic, Levofloxacin, by the Free and Immobilized Secretome of Coriolopsis gallica

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Researchers discovered that a type of fungus called Coriolopsis gallica can break down the antibiotic levofloxacin, which persists in the environment and contributes to antibiotic resistance. They tested both free enzymes from the fungus and enzymes trapped in alginate beads to see which worked better. The study found that free enzymes degraded more of the antibiotic when a chemical helper molecule called HBT was added, while immobilized enzymes were more stable and could be reused multiple times.

Evaluation of the Influence of Varied Juncao Grass Substrates on Physiological and Enzymatic Reactions of Pleurotus ostreatus

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This study tested three types of Juncao grass as growing materials for oyster mushrooms as an eco-friendly alternative to using wood. Researchers measured how well the mushrooms grew, their nutritional value, and the enzymes produced during cultivation. The grass called Cenchrus fungigraminus produced the best results with the highest yield and quality, making it a promising sustainable solution for mushroom farming that helps reduce deforestation.

Techno-economic analysis of a novel laccase production process utilizing perennial biomass and the aqueous phase of bio-oil

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Researchers developed a new method to produce laccase, a useful enzyme with many industrial applications, by growing oyster mushrooms on prairie plants and waste materials from bio-oil production. Through optimization experiments and economic modeling, they found that this process could produce laccase at prices significantly lower than current commercial enzyme products, making it economically viable at small to moderate production scales. The method has the added benefit of providing farmers with a financial incentive to grow perennial prairie plants instead of traditional crops, supporting ecological and soil health improvements.

High Potential Decolourisation of Textile Dyes from Wastewater by Manganese Peroxidase Production of Newly Immobilised Trametes hirsuta PW17-41 and FTIR Analysis

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This research shows that a fungus called Trametes hirsuta can effectively clean textile industry wastewater by breaking down colorful dyes that pollute the environment. The scientists attached the fungus to nylon sponges and optimized the treatment conditions to achieve over 95% color removal within just two days. The fungus produces special enzymes, particularly manganese peroxidase, that degrade the harmful dyes into safer substances, and the system can be reused repeatedly for continuous wastewater treatment.

Fungal Ligninolytic Enzymes and Their Application in Biomass Lignin Pretreatment

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Scientists tested ten different types of fungi to see which ones could best break down lignin, a tough natural material found in plants. Four fungi species showed exceptional ability to produce special enzymes that decompose lignin. These findings could help develop new eco-friendly industrial processes for converting plant waste into useful products, potentially reducing reliance on chemical treatments and fossil fuels.

Degradation of High Concentrations of Anthracene Using White-Rot Wood-Inhabiting Fungi and Investigation of Enzyme Activities

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Scientists in Iran discovered that certain wood-decay fungi, particularly Trametes versicolor mushrooms, can effectively break down anthracene, a toxic pollutant from oil and gas industries. These fungi produce special enzymes that degrade the harmful chemical into less toxic substances. In laboratory tests, these indigenous Iranian fungi successfully removed 20-64% of high-concentration anthracene over four weeks, showing promise for cleaning up contaminated sites.

Comparative Characterization of Oxidative Enzymes for Arabinoxylan and Protein Cross-Linking via Ferulic Acid and Tyrosine in Model Systems

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Scientists tested different enzymes to see which ones work best at linking proteins and fiber molecules together in bread dough. They found that combining certain enzymes, especially peroxidase with glucose oxidase, works better than using them alone. By adjusting the amounts of ferulic acid and tyrosine (compounds in food), they could control whether the cross-links formed within the same molecule or between different molecules. This research helps food makers choose the right enzymes to improve bread texture without extra processing steps.

Antimicrobial Activity and Barrier Properties against UV Radiation of Alkaline and Enzymatically Treated Linen Woven Fabrics Coated with Inorganic Hybrid Material

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Scientists treated linen fabric with an enzyme from a fungus called Cerrena unicolor combined with copper and silica particles to create advanced protective textiles. The resulting fabrics provide excellent protection against harmful UV radiation and kill dangerous bacteria and fungi like E. coli, Staph, and Candida. This eco-friendly approach could be used for protective clothing, outdoor gear, and medical textiles requiring both UV and microbial resistance.

Research Keyword: laccase