Discovery Early Career Researcher Award - Grant ID: DE120102263
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Export of effector proteins by P. falciparum to the infected red blood cell. Infection by the malaria parasite has lethal consequences for humans. The parasite exports hundreds of proteins via a translocon to commandeer the red blood cell. This project aims to determine the function of one of the major translocon components and determine if it is a viable target for anti-malarial drug development.
Molecular basis of the antifungal and antimalarial activity of a plant defensin. The plant defensin NaD1 has potent inhibitory activity against a number of agronomically important fungal pathogens. These species are major pathogens of cotton and other important agricultural crops such as canola and potatoes. These pathogens cause serious economic losses and threaten the future of the cotton industry in Australia. NaD1 also has potential as a new antibiotic for treatment of infections in human ....Molecular basis of the antifungal and antimalarial activity of a plant defensin. The plant defensin NaD1 has potent inhibitory activity against a number of agronomically important fungal pathogens. These species are major pathogens of cotton and other important agricultural crops such as canola and potatoes. These pathogens cause serious economic losses and threaten the future of the cotton industry in Australia. NaD1 also has potential as a new antibiotic for treatment of infections in humans.Read moreRead less
Ion transport in the malaria parasite and parasitised erythrocyte. This work will contribute to the national research effort in parasitology (an area in which the ARC has established a Research Network), as well as laying the groundwork for subsequent efforts (not part of this grant) to develop new antimalarial strategies. Although not yet endemic in Australia, malaria is a serious problem in the local region and, as the major developed nation in the region Australia has an obligation to make ....Ion transport in the malaria parasite and parasitised erythrocyte. This work will contribute to the national research effort in parasitology (an area in which the ARC has established a Research Network), as well as laying the groundwork for subsequent efforts (not part of this grant) to develop new antimalarial strategies. Although not yet endemic in Australia, malaria is a serious problem in the local region and, as the major developed nation in the region Australia has an obligation to make a significant contribution to research in this area. The work proposed here will contribute to Australia's meeting this obligation.Read moreRead less
Amino acid transporters and the chloroquine resistance transporter of the intracellular malaria parasite. This work entails an ongoing collaboration between three independent research groups with highly complementary expertise and experience. It will make a significant contribution to the maintenance of Australia's scientific capabilities and training opportunities. The project will yield important insights into the biology of the causative agent of a major human disease, and the mechanism by ....Amino acid transporters and the chloroquine resistance transporter of the intracellular malaria parasite. This work entails an ongoing collaboration between three independent research groups with highly complementary expertise and experience. It will make a significant contribution to the maintenance of Australia's scientific capabilities and training opportunities. The project will yield important insights into the biology of the causative agent of a major human disease, and the mechanism by which the malaria parasite has developed resistance to antimalarial drugs. Although not yet endemic in Australia, malaria is a serious problem in the local region and this work will help Australia meet its obligations to carry out high-quality research that advances our knowledge in this area.
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Functional proteomics of Giardia. This project will use the latest tools for dissecting and comparing genes and their protein products from one of the most common parasites infecting people, their pets, livestock and wildlife. This protozoan parasite Giardia is also of evolutionary and biological significance in terms of understanding the origin of higher animals from bacteria as well as fundamental questions about the parasitic way of life. Giardia proteins will be identified and characterised ....Functional proteomics of Giardia. This project will use the latest tools for dissecting and comparing genes and their protein products from one of the most common parasites infecting people, their pets, livestock and wildlife. This protozoan parasite Giardia is also of evolutionary and biological significance in terms of understanding the origin of higher animals from bacteria as well as fundamental questions about the parasitic way of life. Giardia proteins will be identified and characterised on the basis of their value in understanding disease processes and treatment, and by working with appropriate industry partners, proteins of commercial value will be exploited.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102321
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Exploiting pathogen-host interactions to dissect the mammalian endocytic pathway. Salmonella manipulates the cells of the human body to cause disease. Understanding the molecular machinery that controls this process will provide profound insight into how the bacteria orchestrates this manipulation as well as provide possible avenues for intervention and even cures for diseases like typhoid fever.
Australian Laureate Fellowships - Grant ID: FL0992138
Funder
Australian Research Council
Funding Amount
$3,100,000.00
Summary
Towards antibacterials without resistance. Innovative automation technologies will be used to create and investigate a revolutionary new approach to disable pathogenic superbugs, bacteria resistant to multiple antibiotics. The chemicals created and proteins evaluated in this research program will advance fundamental knowledge about the molecular weapons that bacteria produce to cause disease; deliver social and economic benefits to Australia through the development of potential new antibacterial ....Towards antibacterials without resistance. Innovative automation technologies will be used to create and investigate a revolutionary new approach to disable pathogenic superbugs, bacteria resistant to multiple antibiotics. The chemicals created and proteins evaluated in this research program will advance fundamental knowledge about the molecular weapons that bacteria produce to cause disease; deliver social and economic benefits to Australia through the development of potential new antibacterial treatments; contribute to Australia's continued international leading role in drug discovery research; enhance international links and attract industry investment in Australia; and provide a stimulating research training environment to inspire and motivate the next generation of scientists.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
The natural function and evolution of an essential parasite transporter. This project aims to resolve the natural function and evolution of a transporter essential to the survival of malaria and other parasites. Malaria and its sibling Apicomplexan parasites cause devastating diseases in humans and livestock across the world. Much remains to be understood about these parasites, and options for controlling them are diminishing. The project will interrogate the functions of the transporter protein ....The natural function and evolution of an essential parasite transporter. This project aims to resolve the natural function and evolution of a transporter essential to the survival of malaria and other parasites. Malaria and its sibling Apicomplexan parasites cause devastating diseases in humans and livestock across the world. Much remains to be understood about these parasites, and options for controlling them are diminishing. The project will interrogate the functions of the transporter proteins. The knowledge gained might help to combat Apicomplexan parasites by targeting these transporters’ native functions.Read moreRead less