Research Keyword: experimental evolution

Ploidy plasticity drives fungal resistance to azoles used in agriculture and clinics

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Agricultural fungicides called azoles can cause fungi to change their genetic makeup in ways that make them resistant to medical antifungal drugs. Researchers found that when Candida tropicalis (a fungal pathogen) is exposed to tebuconazole, an agricultural fungicide, it can transform into a haploid form (with half the normal chromosomes) that is resistant to both agricultural and clinical azoles. This discovery helps explain why fungal infections are becoming harder to treat in hospitals.

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Transposons and accessory genes drive adaptation in a clonally evolving fungal pathogen

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Researchers studied how a fungal plant pathogen called Fusarium oxysporum rapidly adapts to new environments by analyzing genetic changes during repeated passages through tomato plants and laboratory media. They discovered that jumping genes (transposons) were responsible for most mutations driving adaptation, and surprisingly found that genes located in specialized ‘accessory’ regions of the fungus’s genome controlled important functions like growth and virulence. This research reveals how fungal pathogens can evolve quickly to become better competitors or invaders.

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Unlocking the potential of experimental evolution to study drug resistance in pathogenic fungi

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Fungal infections are becoming harder to treat as fungi develop resistance to antifungal drugs. This review explains how scientists can use experimental evolution—growing fungi in controlled laboratory conditions while exposing them to drugs—to understand how and why resistance develops. By studying these evolutionary processes and using mathematical models to predict outcomes, researchers can develop better treatment strategies, including combination therapies and drug cycling approaches to prevent resistance from emerging.

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