host-pathogen interactions – Page 2

Exploring fungal pathogens to control the plant invasive Rubus niveus on Galapagos Island San Cristobal

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Scientists in the Galapagos Islands are working to control an invasive raspberry plant (Rubus niveus) that has taken over about 30,000 hectares and is damaging native species. Rather than using costly manual removal or herbicides, researchers isolated and tested five different fungi found naturally on diseased raspberry plants to see if they could be used as biological control agents. These five fungi—including species like Colletotrichum and Fusarium—showed promise by causing leaf damage to the raspberry plant, offering hope for a more sustainable pest management solution.

Argonaute1-Dependent LtmilR2 Negatively Regulated Infection of Lasiodiplodia theobromae by Targeting a Guanine Nucleotide Exchange Factor in RAS Signalling

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Scientists discovered a tiny regulatory RNA molecule called LtmilR2 in a fungus that causes grape disease. This molecule naturally suppresses the fungus’s ability to cause infection by shutting down a gene called LtRASGEF. When researchers delivered LtmilR2 using specially designed nanoparticles, it successfully stopped the fungus from growing. This discovery could lead to a new type of biological fungicide for protecting grapes and vineyards.

Editorial: Fungal virulence

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This editorial discusses how fungi are becoming more dangerous to human health due to climate change and rising temperatures. Researchers are studying the specific mechanisms that make fungi harmful, including how they stick to human cells and form protective biofilms. The review highlights several important discoveries about different pathogenic fungi and suggests better ways to diagnose and treat fungal infections through understanding how environmental factors influence fungal behavior.

A human-relevant alternative infection model for mucormycosis using the silkworm Bombyx mori

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Scientists developed a new way to test antifungal drugs using silkworms instead of expensive and ethically problematic mammal studies. They infected silkworms with mucormycosis-causing fungi and found that the infections behaved similarly to human cases, especially when they simulated human risk factors like steroid use and iron overload. The silkworm model successfully demonstrated that existing antifungal drugs work, while also revealing differences in fungal virulence that were linked to specific surface proteins.

The fungal STRIPAK complex: Cellular conductor orchestrating growth and pathogenicity

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The STRIPAK complex is a cellular control hub found in fungi that acts like a conductor orchestrating multiple cellular processes essential for fungal growth and the ability to cause disease. Scientists have discovered that this complex is highly conserved across different fungal species and regulates critical virulence factors like melanin production and capsule formation in pathogenic fungi. Because the fungal version differs from the human version, it presents a promising target for developing selective antifungal medications. Understanding how STRIPAK works provides insights into how fungi cause infections and could lead to new treatment strategies.

Research Keyword: host-pathogen interactions

Exploring fungal pathogens to control the plant invasive Rubus niveus on Galapagos Island San Cristobal

Argonaute1-Dependent LtmilR2 Negatively Regulated Infection of Lasiodiplodia theobromae by Targeting a Guanine Nucleotide Exchange Factor in RAS Signalling

Editorial: Fungal virulence

A human-relevant alternative infection model for mucormycosis using the silkworm Bombyx mori

The fungal STRIPAK complex: Cellular conductor orchestrating growth and pathogenicity