polyene resistance – mycolab.ai

Fungal Δ9-fatty acid desaturase: a unique enzyme at the core of lipid metabolism in Aspergillus fumigatus and a promising target for the search for antifungal strategies

mycolabadmin

Certain dangerous fungal infections like aspergillosis are difficult to treat because current antifungal drugs have significant side effects or the fungi are developing resistance. Scientists have discovered that a specific enzyme called Δ9-fatty acid desaturase, which fungi need to make fats for their cell membranes, has a unique structure different from human cells. This structural difference offers a new opportunity to design antifungal drugs that could kill fungi without harming human cells, potentially providing safer and more effective treatments for serious fungal infections.

Breaking down biofilms across critical priority fungal pathogens: proteomics and computational innovation for mechanistic insights and new target discovery

mycolabadmin

Fungal infections like cryptococcal meningitis and invasive aspergillosis are becoming increasingly difficult to treat because fungi form protective structures called biofilms that resist our current medications. Researchers are using advanced techniques like mass spectrometry to identify the proteins that help fungi build these biofilms, combined with artificial intelligence tools to design new drugs that could break down these protective shields. This combined approach offers hope for developing better antifungal treatments that could save millions of lives.

Anti-Therapeutic Action: polyene resistance

Fungal Δ9-fatty acid desaturase: a unique enzyme at the core of lipid metabolism in Aspergillus fumigatus and a promising target for the search for antifungal strategies

Breaking down biofilms across critical priority fungal pathogens: proteomics and computational innovation for mechanistic insights and new target discovery