cell wall disruption – Page 2

Comparative Study and Transcriptomic Analysis on the Antifungal Mechanism of Ag Nanoparticles and Nanowires Against Trichosporon asahii

mycolabadmin

Researchers compared two types of tiny silver particles (nanoparticles and nanowires) as potential treatments for a dangerous fungal infection caused by Trichosporon asahii. Silver nanowires were found to be more effective than nanoparticles at killing the fungus by damaging its cell membranes and disrupting its energy production. The study identified 15 key genes involved in how silver nanowires attack the fungus, suggesting these nanomaterials could become useful alternatives to traditional antifungal drugs.

Past, present and future of antifungals: Advancements in mechanisms of action and resistance

mycolabadmin

Fungal infections are a growing global health problem, particularly for people with weakened immune systems, causing millions of deaths annually. Current antifungal medications are limited and increasingly ineffective due to drug-resistant fungi. This special issue explores new treatment strategies including novel drugs, combination therapies, and innovative approaches like nanoparticles and antimicrobial peptides to combat these serious infections.

Novel secondary metabolite from a new species of Hypoxylon saxatilis sp. nov. for suppressing bacterial wilt in tomato

mycolabadmin

Researchers discovered a new fungus species (Hypoxylon saxatilis) living inside medicinal plants that produces a novel compound called tetrahydrofuran. This compound kills the bacterium that causes tomato wilt disease by damaging bacterial cell walls. In greenhouse tests, extract from this fungus reduced wilt disease severity by over 83%, suggesting it could be developed as an eco-friendly alternative to chemical pesticides for protecting tomato crops.

Drug repurposing to fight resistant fungal species: Recent developments as novel therapeutic strategies

mycolabadmin

This editorial highlights the growing problem of fungal infections that resist current treatments, causing millions of deaths worldwide each year. Researchers are finding new ways to fight these resistant infections by repurposing existing drugs in new combinations and discovering novel compounds from natural sources. The collection of studies presented shows promising results using combinations like minocycline with antifungal drugs, natural compounds like baicalin, and AI technology to predict resistance patterns. These innovative approaches offer hope for better treatment options for patients suffering from serious fungal infections.

Cell Wall-Mediated Antifungal Activity of the Aqueous Extract of Hedera helix L. Leaves Against Diplodia corticola

mycolabadmin

Scientists discovered that extract from ivy leaves can effectively kill a fungus called Diplodia corticola that damages cork oak trees. The extract works by damaging the fungus’s protective cell wall rather than interfering with its internal chemistry. This natural alternative to chemical fungicides could help protect cork production worldwide while being safer for human health and the environment.

therapeutic action: cell wall disruption

Comparative Study and Transcriptomic Analysis on the Antifungal Mechanism of Ag Nanoparticles and Nanowires Against Trichosporon asahii

Past, present and future of antifungals: Advancements in mechanisms of action and resistance

Novel secondary metabolite from a new species of Hypoxylon saxatilis sp. nov. for suppressing bacterial wilt in tomato

Drug repurposing to fight resistant fungal species: Recent developments as novel therapeutic strategies

Cell Wall-Mediated Antifungal Activity of the Aqueous Extract of Hedera helix L. Leaves Against Diplodia corticola