Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others a ....Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others are used in biotechnology for biosynthetic chemical production or bioremediation. This project expects to help the future development of new antibiotics and assist in the design of strains to be used in biotechnological applications.Read moreRead less
Microbe-produced repellents and their roles in marine pathogen behaviours. Economic losses caused by disease outbreaks in marine fisheries and aquaculture exceed US$6 billion per year globally. Decades of research in human and plant pathogens have revealed that the ability of pathogens to infect their host is governed by behaviours; however our understanding of the chemical cues affecting the behaviour of marine pathogens is very poor. This research program aims to combine new approaches in micr ....Microbe-produced repellents and their roles in marine pathogen behaviours. Economic losses caused by disease outbreaks in marine fisheries and aquaculture exceed US$6 billion per year globally. Decades of research in human and plant pathogens have revealed that the ability of pathogens to infect their host is governed by behaviours; however our understanding of the chemical cues affecting the behaviour of marine pathogens is very poor. This research program aims to combine new approaches in microfluidics and chemical imaging to identify the cues that govern the behaviour of marine pathogens. Expected outcomes include an improved capacity to predict, monitor and manage marine diseases, as well as novel strategies to prevent disease outbreaks, helping to protect Australia’s valuable marine estate.Read moreRead less
Untangling environmental effects on bee health in the face of Varroa . This project aims to assess bee health, disease and evolution in European honeybees and bumblebees. Bee viruses transmitted by the destructive Varroa mite cause worldwide pollinator declines. Factors determining bee health will be identified across Australia, New Zealand and the United Kingdom, which differ in Varroa impact and bee introduction histories. Harnessing Australia’s currently threatened Varroa-free status, the bum ....Untangling environmental effects on bee health in the face of Varroa . This project aims to assess bee health, disease and evolution in European honeybees and bumblebees. Bee viruses transmitted by the destructive Varroa mite cause worldwide pollinator declines. Factors determining bee health will be identified across Australia, New Zealand and the United Kingdom, which differ in Varroa impact and bee introduction histories. Harnessing Australia’s currently threatened Varroa-free status, the bumblebee invasion in Tasmania, and cutting-edge multi-omics techniques (for microbiomes, viruses and genomes), predictors of disease dynamics will be identified for two globally important bee pollinators. The project outcomes will boost Australia's capacity to manage threats to pollination services at landscape scales.Read moreRead less
Time to prime: using silicon to activate grass resistance under higher CO2. This project aims to deliver insight into how CO2 affects defence trade-offs in Australian grasses and establish if silicon (Si) supplementation with an industrial by-product restores resistance. Grasses contain more Si than nearly any other plant, resulting in multiple beneficial functions, including increasing resistance to disease and herbivory. However, increasing atmospheric CO2 reduces Si uptake in some grasses and ....Time to prime: using silicon to activate grass resistance under higher CO2. This project aims to deliver insight into how CO2 affects defence trade-offs in Australian grasses and establish if silicon (Si) supplementation with an industrial by-product restores resistance. Grasses contain more Si than nearly any other plant, resulting in multiple beneficial functions, including increasing resistance to disease and herbivory. However, increasing atmospheric CO2 reduces Si uptake in some grasses and frequently compromises plant defensive responses/signalling to herbivore attack. A key outcome will be identifying and maximising silicon-based resistance in vulnerable grasses against the threat of climate change and invasive herbivores. This will provide benefits such as increased productivity of Australian grasslands using a pollution-free, broad-spectrum and environmentally safer pest control approach.Read moreRead less