horizontal gene transfer – Page 3

Gene transfer between fungal species triggers repeated coffee wilt disease outbreaks

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A new study found that coffee wilt disease, which has caused major crop losses in Africa, has repeatedly emerged due to genes jumping between different fungal species. These genes travel via special mobile DNA elements called Starships, which act like genetic vehicles carrying pathogenic genes from one fungus to another. When Fusarium fungi exchanged genes this way, they became better at infecting different varieties of coffee plants. Understanding how these genes move is crucial for protecting coffee crops from future disease outbreaks.

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.

Discovery of a New Starship Transposon Driving the Horizontal Transfer of the ToxA Virulence Gene in Alternaria ventricosa

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Scientists discovered that a disease-causing gene called ToxA, previously found only in three wheat-infecting fungi, is also present in a fourth fungal species called Alternaria ventricosa. This gene travels between fungal species through special jumping DNA elements called Starships. The study reveals how fungi share dangerous genes through a process called horizontal gene transfer, which helps them become better at attacking crops. Understanding this process could help farmers and scientists develop better ways to prevent fungal diseases.

Microbes as Teachers: Rethinking Knowledge in the Anthropocene

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This paper argues that microbes should be viewed as teachers offering crucial wisdom about how to solve today’s environmental crises. Rather than seeing microbes as passive subjects to be studied, the author proposes recognizing them as intelligent, collaborative partners that have successfully managed Earth’s systems for billions of years. The paper provides practical suggestions for changing education, policy, and how we design cities and agriculture to work with microbial processes rather than against them.

A broadly conserved fungal chorismate mutase targets the plant shikimate pathway to regulate salicylic acid production and other secondary metabolites

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Fungal pathogens produce proteins called effectors that help them infect plants. This study discovered that a fungus called Sclerotinia sclerotiorum produces an effector that enters plant cells and travels to chloroplasts. Unlike similar effectors in other fungi, this protein increases the production of salicylic acid, a plant defense hormone, while reducing other protective compounds. This creates conditions favorable for the fungus to establish infection.

A mycovirus enhances fitness of an insect pathogenic fungus and potentially modulates virulence through interactions between viral and host proteins

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Scientists discovered a virus that infects Beauveria bassiana, a fungus used to control pests naturally. This virus actually helps the fungus by making it produce more spores, survive harsh conditions like sunlight and heat, and kill target insects faster. The virus does this by interacting with specific fungal proteins that control reproduction, stress response, and virulence. This discovery could lead to better biological pest control products that are more effective and reliable than current options.

Tracing the Origin and Evolution of the Fungal Mycophenolic Acid Biosynthesis Pathway

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Scientists studied how different fungal species produce mycophenolic acid, a drug used to prevent transplant rejection in millions of patients worldwide. By analyzing the genomes of many fungal species, they found that only a few fungi can make this important drug, and they discovered that these fungi have different ways of protecting themselves from being poisoned by their own medicine. This research helps us understand how fungi evolve to produce valuable medicines and could lead to better ways to produce immunosuppressants.

Gene duplication, horizontal gene transfer, and trait trade-offs drive evolution of postfire resource acquisition in pyrophilous fungi

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Scientists studied fungi that thrive in burned soils after wildfires. They discovered these ‘fire-loving’ fungi have special genes for breaking down charcoal and acquiring nutrients, but this specialization comes at a cost—they grow more slowly than other fungi. The research identified three main evolutionary strategies these fungi use: duplicating useful genes, sexually reproducing to create genetic diversity, and occasionally borrowing genes from bacteria. These findings could help develop treatments to restore polluted or fire-damaged soils.

Accessory Chromosome Contributes to Virulence of Banana Infecting Fusarium oxysporum Tropical Race 4

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Fusarium wilt Tropical Race 4 is a devastating fungal disease that destroys banana crops worldwide, particularly the commercially important Cavendish variety. Researchers discovered that this fungus carries a special accessory chromosome that is not essential for basic fungal survival but is critical for its ability to infect and damage banana plants. By removing this chromosome in laboratory studies, scientists found that infected bananas suffered significantly less damage, suggesting that understanding this chromosome could lead to better strategies for protecting banana crops from this destructive disease.

Gene transfer between fungal species triggers repeated coffee wilt disease outbreaks

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A new study reveals that coffee wilt disease, which has destroyed coffee crops across Africa, emerges repeatedly because of gene-swapping between different fungal species. Scientists discovered that large chunks of DNA called ‘Starships’ act like genetic delivery vehicles, transferring disease-causing genes from one fungus to another. This genetic exchange allows the pathogen to adapt and infect different coffee plant species, causing successive outbreaks. Understanding this mechanism could help protect global coffee production in the future.

Research Keyword: horizontal gene transfer