secondary metabolites – Page 13

Antifungal and other bioactive properties of the volatilome of Streptomyces scabiei

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Researchers discovered that Streptomyces scabiei, a bacterium that causes common scab disease in potatoes and other root crops, produces numerous airborne chemical compounds with surprising benefits. Using advanced chemical analysis, they identified 36 different volatile molecules, many of which can kill harmful fungi and promote plant health. This discovery suggests the bacterium’s role in nature is more complex than previously thought, as it may actually help protect plants while causing disease, opening new possibilities for developing natural pest control solutions.

The Zn(II)2-Cys6-type zinc finger protein AoKap7 is involved in the growth, oxidative stress and kojic acid synthesis in Aspergillus oryzae

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Scientists studied a protein called AoKap7 in a fungus (Aspergillus oryzae) that produces kojic acid, a substance used in cosmetics and medicine. When they removed this protein, the fungus grew faster but made less kojic acid and became more vulnerable to stress. The researchers found that AoKap7 controls several genes that help the fungus protect itself from harmful molecules and produce kojic acid efficiently.

Metabolic fingerprinting to elucidate the biodegradation of phosphonoacetic acid and its impact on Penicillium metabolism

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Scientists studied how three types of mold fungi break down and use a phosphorus-containing compound called phosphonoacetic acid. Using advanced chemical analysis, they identified unique metabolic patterns in each fungal strain depending on whether they were given regular phosphorus or the more challenging phosphonoacetic acid. These findings reveal how fungi adapt their internal chemistry to handle different phosphorus sources and could help identify which fungi are best at breaking down harmful phosphorus-containing chemicals in the environment.

Potential of Indonesian Herbal as an Anti-Cancer Therapy: A Systemic Review of in vitro Studies

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This review examined eight Indonesian herbal plants that show promise in laboratory studies for fighting various types of cancer. Soursop leaves were the most researched and consistently showed the ability to kill or slow cancer cells in test tubes by triggering natural cell death pathways. The herbs work through bioactive compounds like flavonoids and alkaloids that can interfere with how cancer cells divide and survive. While these results are encouraging, more research is needed to confirm effectiveness in humans.

Modern Pro-Health Applications of Medicinal Mushrooms: Insights into the Polyporaceae Family, with a Focus on Cerrena unicolor

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This review explores how medicinal mushrooms, particularly Cerrena unicolor, can be used to improve health through functional foods and supplements. The mushroom contains natural compounds with powerful properties including fighting cancer cells, killing harmful bacteria and viruses, and protecting the body from oxidative stress. Research shows these mushrooms could be incorporated into dairy products and other foods to create innovative health-promoting products for consumers.

Bacillus subtilis ED24 Controls Fusarium culmorum in Wheat Through Bioactive Metabolite Secretion and Modulation of Rhizosphere Microbiome

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A beneficial bacteria called Bacillus subtilis ED24 was found to effectively protect wheat plants from a destructive fungal disease called Fusarium culmorum. When applied to wheat seeds, this bacteria improved seed germination and plant growth better than a commercial chemical fungicide, while also promoting helpful microorganisms in the soil around the plant roots. The bacteria works by producing special chemical compounds that kill the harmful fungus and by enriching the soil microbiome with beneficial organisms.

The Antimicrobial Extract Derived from Pseudomonas sp. HP-1 for Inhibition of Aspergillus flavus Growth and Prolongation of Maize Seed Storage

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Researchers discovered that a beneficial bacterium called Pseudomonas sp. HP-1 can produce a natural compound that effectively prevents mold contamination in stored maize seeds. The extract from this bacterium showed strong antifungal activity against Aspergillus flavus, a major cause of aflatoxin contamination in grain storage. The main protective compound was identified as phenazinecarboxylic acid, which works by damaging the cell membranes of fungal cells. This finding offers a promising eco-friendly alternative to synthetic chemical fungicides for protecting stored crops.

Chemical clues to infection: A pilot study on the differential secondary metabolite production during the life cycle of selected Cordyceps species

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This study examined two types of parasitic fungi (Cordyceps javanica and Cordyceps blackwelliae) that infect insects, comparing how they kill their hosts and what chemical compounds they produce during infection. Researchers found that each species uses different toxic molecules to infect insects, with C. javanica being more deadly and producing diverse compounds called beauveriolides. By analyzing infected insect corpses, scientists provided the first direct evidence that these toxic compounds are actually made during real infections, not just in laboratory cultures.

Characterizing antimicrobial activity of environmental Streptomyces spp. and oral bacterial and fungal isolates from Canis familiaris and Felis catus

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Researchers collected bacteria and fungi from the mouths of pet dogs and cats, as well as environmental soil bacteria, to search for natural antimicrobial compounds. They found that some of these microorganisms produce substances that can kill harmful bacteria like E. coli and fungi like Candida albicans, especially when combined with existing antifungal medications. Notably, one environmental bacterium (Streptomyces) produced a compound that was even effective against fungal strains resistant to common antifungal drugs, suggesting promising new treatment possibilities.

Secretion of antifungal metabolites contributes to the antagonistic activity of Talaromyces oaxaquensis

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Researchers discovered that a fungus called Talaromyces oaxaquensis, found naturally in banana plants, produces powerful antifungal chemicals that kill the banana disease pathogen Fusarium oxysporum. The study identified specific compounds, particularly one called 15G256α, that damage the fungal cell wall of the pathogen. This discovery suggests a natural way to protect banana crops from a devastating disease that threatens global banana production.

Research Keyword: secondary metabolites