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
Composition, assembly and functions of the pellicle of apicomplexan parasites: a structure pivotal to disease transmission and progression. Apicomplexan parasites are successful agents of disease (e.g. malaria) due to their superb ability to quickly invade host cells and generate many more parasites. This project will study the dedicated structures beneath the parasite cell covering that are responsible for these abilities to help refine strategies for combating apicomplexan diseases.
New methods for structure analysis of proteins and protein interactions. This project will advance nuclear magnetic resonance (NMR) technologies pioneered at the Australian National University which employ site-specific attachment of paramagnetic metal tags to proteins. A new and diverse set of strategies will dramatically extend the range of applications to targets of interest in the fight against cancer and bacterial infections.
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
Drug discovery and structural biology by NMR spectroscopy. This project aims to extend the use of nuclear magnetic resonance (NMR) spectroscopy in rational drug development and protein structure analysis. A new chemical labelling approach provides detailed three-dimensional structure information of large protein-ligand complexes, needed for structure-based lead-compound development. New chemical and paramagnetic lanthanide tags for site-specific dual labelling of proteins will enhance this techn ....Drug discovery and structural biology by NMR spectroscopy. This project aims to extend the use of nuclear magnetic resonance (NMR) spectroscopy in rational drug development and protein structure analysis. A new chemical labelling approach provides detailed three-dimensional structure information of large protein-ligand complexes, needed for structure-based lead-compound development. New chemical and paramagnetic lanthanide tags for site-specific dual labelling of proteins will enhance this technology, which will assess target-drug interactions by in-cell electron paramagnetic resonance (EPR) spectroscopy. The techniques offer scope for accelerated drug development in the pharmaceutical industries.Read moreRead less
New methods for structural biology and drug discovery by nuclear magnetic resonance spectroscopy. Paramagnetic lanthanide tags offer fresh opportunities in structural biology and for rational drug design. Novel nuclear magnetic resonance (NMR) spectroscopy techniques will selectively detect the NMR signals from protein regions marked by paramagnetic lanthanides, accelerating the structure analysis of protein-ligand complexes. New lanthanide tags will bind to phosphoserine and selenocysteine resi ....New methods for structural biology and drug discovery by nuclear magnetic resonance spectroscopy. Paramagnetic lanthanide tags offer fresh opportunities in structural biology and for rational drug design. Novel nuclear magnetic resonance (NMR) spectroscopy techniques will selectively detect the NMR signals from protein regions marked by paramagnetic lanthanides, accelerating the structure analysis of protein-ligand complexes. New lanthanide tags will bind to phosphoserine and selenocysteine residues site-specifically introduced into proteins. These tags will also enable accurate distance measurements by electron paramagnetic resonance (EPR) spectroscopy in large, biologically important protein systems hitherto not amenable to detailed structural studies and in proteins undergoing conformational changes. Read moreRead less
A novel family of amino acid transporters in Apicomplexan parasites. Apicomplexan parasites are single celled organisms that are the causative agents of major diseases in livestock and humans. However, the basic biochemistry of these intracellular parasites is poorly understood, and there are limited treatments available for the diseases these parasites cause. The project hypothesis is that a novel family of proteins that are unique to apicomplexan parasites play a key role in the uptake of esse ....A novel family of amino acid transporters in Apicomplexan parasites. Apicomplexan parasites are single celled organisms that are the causative agents of major diseases in livestock and humans. However, the basic biochemistry of these intracellular parasites is poorly understood, and there are limited treatments available for the diseases these parasites cause. The project hypothesis is that a novel family of proteins that are unique to apicomplexan parasites play a key role in the uptake of essential nutrients (amino acids) into these organisms. This project aims to use a combination of genetic, biochemical and physiological methods to understand the function of these proteins, the role(s) that they play in apicomplexan biology, and their importance for parasite survival.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102673
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
F420-Reductases from mycobacteria: new opportunities for health care and environmental protection. A new class of enzymes, derived from the bacteria responsible for drug resistant forms of tuberculosis and leprosy, will be studied at a molecular level. New antibiotics will be designed, based on the molecular structures of these proteins. The proteins themselves will be engineered to break down harmful environmental toxins.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100193
Funder
Australian Research Council
Funding Amount
$590,000.00
Summary
Next Generation Mass Spectrometry for Analysis of Biomolecules. Next-generation mass spectrometry for analysis of biomolecules:
This project seeks to establish a next-generation mass spectrometer that represents the most sensitive, accurate and rapid mass spectrometer allowing the simultaneous quantitation of several hundred to several thousand proteins in a single experiment. This is designed to particularly support infection and immunity research. Novel fragmentation capabilities and enhanced ....Next Generation Mass Spectrometry for Analysis of Biomolecules. Next-generation mass spectrometry for analysis of biomolecules:
This project seeks to establish a next-generation mass spectrometer that represents the most sensitive, accurate and rapid mass spectrometer allowing the simultaneous quantitation of several hundred to several thousand proteins in a single experiment. This is designed to particularly support infection and immunity research. Novel fragmentation capabilities and enhanced workflows on this instrument may allow new types of experiments to be conducted providing significant improvements in coverage and depth of analysis.Read moreRead less