News & events
News
Researchers have a new understanding of the genetic makeup of a fungus that causes the disease Wheat Stripe Rust, one of the most destructive wheat diseases globally costing $1 billion annually.
Research that could transform global rice production by increasing yields from the world’s number one food crop has been boosted by five more years of funding.
Esteemed senior ANU biologist and mentor, Professor Barry Pogson, has been awarded the highest accolade for staff, the 2019 Peter Baume Award.
Some clever detective work by an international team of scientists has uncovered how a deadly fungus - a stem rust called Ug99 - came about through some unusual breeding habits. The discovery will help protect wheat crops around the world from devastating fungal diseases.
Australian research could help breeders develop more drought-resilient crops that can produce more food and more profit with less water.
Researchers at The Australian National University (ANU) have shown how Australian wheat crops would cope if a destructive disease that’s yet to hit our shores ever made it into the country.
Events
The wheat necrotrophic fungal pathogen, Parastagonospora nodorum, secretes effector proteins to manipulate host immunity and promote successful infection.
The slow kinetics and poor substrate specificity of the key photosynthetic CO2-fixing enzyme Rubisco have prompted the repeated evolution of Rubisco containing compartments known as pyrenoids in diverse algal lineages and carboxysomes in prokaryotes.
Bipolaris sorokiniana is a hemibiotrophic pathogen causing spot blotch (SB) and common root rot (CRR) in both wheat and barley, and is causal to significant yield and economic losses.
Prior to the discovery of C4 photosynthesis by Hal Hatch and Roger Slack in 1966 there were clues that some plants partitioned photosynthesis between specific leaf cell types.
Mathematical models of leaf photosynthesis provide a mechanistic base for predicting and assessing changes in photosynthetic CO2 fixation in different environments and provide a means of scaling predictions from leaves to canopies and regions.
The root of Arabidopsis thaliana is an excellent model for studying cell differentiation in plants.