Investigation of a Novel Protein Implicated in Phosphate Metabolism in Bacteria. Phosphate is an important nutrient for all forms of life on Earth. A novel bacterial protein has been identified that appears to be important for the uptake or processing of phosphate, since mutants lacking the protein grow poorly inside certain cells of the human immune system (where phosphate levels are low) and in media containing low phosphate. The aims of this project are: to determine the role of the protein b ....Investigation of a Novel Protein Implicated in Phosphate Metabolism in Bacteria. Phosphate is an important nutrient for all forms of life on Earth. A novel bacterial protein has been identified that appears to be important for the uptake or processing of phosphate, since mutants lacking the protein grow poorly inside certain cells of the human immune system (where phosphate levels are low) and in media containing low phosphate. The aims of this project are: to determine the role of the protein by examining all phosphate containing molecules in our mutants; to determine its location in bacteria and functional domains; to identify other affected genes in our mutants; and, to find proteins that interact with this new protein. This project expects to demonstrate the importance of this protein in phosphate metabolism in bacteria.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101604
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Novel role for the universal signalling molecule nitric oxide within biofilm communities and across a biofilm-host interface. Biofilms on wet surfaces and tissues cause major problems by resisting antimicrobials. This project aims at exploiting how natural host response control systems alleviate biofilm build up and can be used to control biofilms in a non-toxic fashion. Countless environmental and clinical applications will benefit from reduced usage of antibiotics.
Structural and functional characterisation of compounds that inhibit the malarial aminopeptidases. Malaria is the world's most prevalent parasitic disease. Due to the rapid spread of drug resistant parasites there is a need to develop new antimalarial drugs. In this proposal we will characterise new targets and novel methods of inhibition that will form the basis of a new mechanism for antimalarial drugs.
Regulatory cellular microRNAs and their role in insect anti-viral responses. This project will use cutting edge approaches to reveal fundamental roles of small ribonucleic acid molecules (microRNAs) in insect anti-viral responses and immunity. By manipulating anti-viral immune responses, the project will assist in the design of novel approaches to pest control and abolish/limit transmission of vector-borne viruses such as Dengue virus.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100172
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Comprehensive cell imaging facility. This facility will provide Australian biological science researchers with equipment for in-depth analyses of cell function in vitro and in vivo. It will enable innovative research targeted at important questions in fields including cancer, immunology, stem cell biology, infectious disease and tissue regeneration.
Using viral inhibitors to understand the regualtion of apoptosis. Apoptosis is a form of cell death that is critical for the development and well-being of multicellular organisms. The activity of Bak or Bax, two members of the Bcl-2 family, are essential for apoptosis to proceed, but how the activity of these two proteins is regulated is unclear. Many viruses encode inhibitors of apoptosis and the project will make use of two novel viral inhibitors that specifically target Bak. The project aims ....Using viral inhibitors to understand the regualtion of apoptosis. Apoptosis is a form of cell death that is critical for the development and well-being of multicellular organisms. The activity of Bak or Bax, two members of the Bcl-2 family, are essential for apoptosis to proceed, but how the activity of these two proteins is regulated is unclear. Many viruses encode inhibitors of apoptosis and the project will make use of two novel viral inhibitors that specifically target Bak. The project aims to determine how the Bak inhibitors function and to provide valuable insights into the normal mechanisms regulating Bak activity.Read moreRead less
Programmed cell death in host-microbe interactions. This project aims to address how host cell death, as part of the immune defence system, controls invading microbes. By following host-microbe interactions at high resolution, the project will generate new knowledge in the area of infection and immunity based on an interdisciplinary approach to discover new cell death factors. The expected outcome of this project will enhance the imaging capacity and develop new technologies in Australia by buil ....Programmed cell death in host-microbe interactions. This project aims to address how host cell death, as part of the immune defence system, controls invading microbes. By following host-microbe interactions at high resolution, the project will generate new knowledge in the area of infection and immunity based on an interdisciplinary approach to discover new cell death factors. The expected outcome of this project will enhance the imaging capacity and develop new technologies in Australia by building on international collaborations, providing significant benefits to the health of the community and potential to develop innovative applications in biomedical industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101035
Funder
Australian Research Council
Funding Amount
$369,500.00
Summary
Ion regulation in Apicomplexan parasites. This project aims to determine how Apicomplexan parasites regulate their sodium and chloride levels to support the development of new parasite control measures. Apicomplexan parasites cause devastating animal and human diseases. Little is known about the physiology of these parasites, and options for controlling them are few. Apicomplexan parasites must precisely control their internal ion compositions in order to survive, but how they do so is not under ....Ion regulation in Apicomplexan parasites. This project aims to determine how Apicomplexan parasites regulate their sodium and chloride levels to support the development of new parasite control measures. Apicomplexan parasites cause devastating animal and human diseases. Little is known about the physiology of these parasites, and options for controlling them are few. Apicomplexan parasites must precisely control their internal ion compositions in order to survive, but how they do so is not understood. Recent work has identified a unique Apicomplexan sodium transporter and revealed a number of chloride transporter candidates. Using a combination of molecular biology and physiological techniques, this project aims to characterise the Apicomplexan sodium transporter in detail and elucidate the molecular mechanisms of chloride transport.Read moreRead less
Regulating nutrient uptake in intracellular parasites. Parasites impose a major economic and medical burden on human societies. In order to grow and reproduce, parasites scavenge nutrients from their animal or human hosts. As they move within and between hosts they encounter different levels of nutrients; how they adapt to these differences is poorly understood. This project aims to investigate the mechanisms by which the model parasite Toxoplasma senses and responds to the nutrients in its envi ....Regulating nutrient uptake in intracellular parasites. Parasites impose a major economic and medical burden on human societies. In order to grow and reproduce, parasites scavenge nutrients from their animal or human hosts. As they move within and between hosts they encounter different levels of nutrients; how they adapt to these differences is poorly understood. This project aims to investigate the mechanisms by which the model parasite Toxoplasma senses and responds to the nutrients in its environment, thereby shedding light on how they adapt to the different environments that they inhabit and, in the longer term, informing novel treatment strategies that aim to limit the parasites’ nutrient supply.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101512
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Investigating the interaction of microRNAs-Wolbachia-Dengue virus in the mosquito vector, Aedes aegypti. This project focuses on using molecular techniques to discover fundamental roles of small RNA molecules (microRNAs) of a key mosquito vector in bacterial symbiosis and Dengue virus infection. It will lead to development of effective approaches in limiting spread of vector and transmission of life threatening viral diseases.