Research Keyword: transposable elements

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

mycolabadmin

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.

Read More »

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

mycolabadmin

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.

Read More »

Integrated genome and transcriptome analysis reveals pathogenic mechanisms of Calonectria eucalypti in Eucalyptus leaf blight

mycolabadmin

Scientists studied a dangerous fungus called Calonectria eucalypti that kills eucalyptus trees worldwide. They sequenced the fungus’s entire genetic code and tracked which genes it turned on during infection. They found that the fungus uses different strategies at different stages of infection, starting with penetration, then breaking down plant cell walls, and finally stealing nutrients. This research helps us understand how the fungus works and develop better ways to protect eucalyptus plantations.

Read More »

Integrated genome and transcriptome analysis reveals pathogenic mechanisms of Calonectria eucalypti in Eucalyptus leaf blight

mycolabadmin

This research examines a dangerous fungus called Calonectria eucalypti that destroys eucalyptus trees worldwide. Scientists sequenced the fungus’s complete genetic code and tracked which genes turn on during infection, discovering that the pathogen uses different sets of genes at different stages of infection. By identifying key virulence genes and understanding how the fungus attacks plant cells, this research provides a foundation for developing better ways to prevent and manage eucalyptus leaf blight disease.

Read More »
Scroll to Top