quorum sensing – mycolab.ai

Impact of Volatile Organic Compounds on the Growth of Aspergillus flavus and Related Aflatoxin B1 Production: A Review

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Aspergillus flavus is a dangerous fungus that produces aflatoxin B1, a poison that can cause serious diseases and survives even when food is heated. Scientists have discovered that certain smelly chemicals called volatile organic compounds, produced by other organisms or plants, can stop this fungus from growing and making its toxin. This research suggests these natural chemicals could be used to protect our crops and food supply from contamination.

The role of Micro-biome engineering in enhancing Food safety and quality

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Microbiome engineering uses advanced biotechnology to strategically modify helpful bacteria in food to make it safer and higher quality. By using tools like CRISPR gene editing and engineering beneficial probiotics, scientists can prevent food spoilage, reduce harmful bacteria, improve nutrition, and create better-tasting foods. These innovations could reduce reliance on synthetic preservatives and chemicals while addressing global food safety challenges and helping combat malnutrition.

Bacterial–Fungal Interactions: Mutualism, Antagonism, and Competition

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Bacteria and fungi in animal bodies interact in three main ways: they help each other (mutualism), fight each other (antagonism), or compete for resources. These interactions happen in the gut, rumen, and skin of animals. Understanding how to balance these relationships can help create better probiotics and natural alternatives to antibiotics for treating infections and improving animal health.

Do farnesol and tyrosol production in Candidozyma auris biofilms reflect virulence potential?

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Researchers discovered that a dangerous fungus called Candidozyma auris produces signaling molecules called farnesol and tyrosol in biofilms. These molecules appear to be linked to how dangerous the fungus is—strains that produce more of these molecules were more virulent in infection studies. Understanding these signaling molecules could help develop new strategies to fight this drug-resistant pathogen.

Progress of Antimicrobial Mechanisms of Stilbenoids

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Stilbenoids are natural compounds found in plants that can fight harmful bacteria and fungi in multiple ways. Unlike traditional antibiotics that only kill microbes, stilbenoids can also prevent infections by disrupting biofilm formation and weakening pathogen virulence. These compounds show promise in combating drug-resistant infections without promoting further resistance development, making them valuable candidates for new antibiotic medicines.

Quorum-driven microbial consortium for Bioplastic production from agro-waste

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Scientists created a partnership between a fungus and bacteria to make eco-friendly plastic (PHA) from brewery and cooking waste. The fungus breaks down the tough plant material while the bacteria converts the released compounds into bioplastic. By adding a natural chemical signal (farnesol), they improved the process and scaled it up successfully in a larger reactor without needing expensive pretreatment steps.

Bacillus velezensis CNPMS-22 as biocontrol agent of pathogenic fungi and plant growth promoter

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This research demonstrates that a beneficial bacterium called Bacillus velezensis CNPMS-22 can effectively protect maize plants from fungal diseases caused by Fusarium verticillioides. When used to treat seeds before planting, this bacterium reduced disease symptoms and increased crop yield to levels comparable with chemical fungicides. The bacteria produces natural compounds that kill harmful fungi and promote plant growth, offering a safer and more sustainable alternative to chemical pesticides.

Exploring Fungal Communication Mechanisms in the Rhizosphere Microbiome for a Sustainable Green Agriculture

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Fungi in soil communicate with each other and plants through chemical signals, forming protective layers called biofilms that help them cooperate and survive. These fungal communication networks can be either beneficial, helping plants grow and fight diseases, or harmful, causing crop infections and producing toxins. By better understanding how fungi talk to each other, scientists can develop natural ways to improve agriculture and clean up polluted soils without using harmful chemicals.

Biofilms and Chronic Wounds: Pathogenesis and Treatment Options

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Chronic wounds, such as diabetic foot ulcers and burn injuries, are often complicated by bacterial and fungal biofilms—protective communities of microorganisms that resist antibiotics and delay healing. This review summarizes how biofilms form, why they are difficult to treat with standard approaches, and discusses new therapeutic strategies. While debridement and antiseptics remain important, combining them with novel treatments like bacteriophages, enzyme therapies, and nanotechnology offers better chances for healing these stubborn wounds.

Microbes as Teachers: Rethinking Knowledge in the Anthropocene

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Microbes have been the architects of life on Earth for nearly 4 billion years, managing oxygen production, nutrient cycles, and climate stability—yet we rarely recognize their wisdom. This paper argues we should treat microbes as teachers rather than mere subjects of study or exploitation. By reforming education, policy, and how we think about our relationship with microbial life, we can solve modern challenges like climate change and disease while learning to coexist with the microscopic majority that sustains all life.

Research Keyword: quorum sensing