The proposed research project involves a fundamental biochemical and biophysical investigation of a protein (ABCA4) intimately involved in the visual process. The precise role of ABCA4 in vision has not yet been elucidated, although evidence suggests a role as a lipid translocase in the retinal regenerative pathway. Our primary objective is to provide direct evidence for this putative role.
Atherosclerosis is the disease which narrows arteries and causes heart attacks and stroke. It is one of the major causes of death in Australia. Although certain treatments, such as lowering blood cholesterol levels, reduce the incidence of atherosclerosis, current motality rates from this disease indicate that there is still a great need to improve our understanding and treament of the condition. In the development of atherosclerosis, some of the cells in the vessel wall accumulate large deposit ....Atherosclerosis is the disease which narrows arteries and causes heart attacks and stroke. It is one of the major causes of death in Australia. Although certain treatments, such as lowering blood cholesterol levels, reduce the incidence of atherosclerosis, current motality rates from this disease indicate that there is still a great need to improve our understanding and treament of the condition. In the development of atherosclerosis, some of the cells in the vessel wall accumulate large deposits of cholesterol. These cells are macrophages, derived from circulating white blood cells that have migrated into the vessel wall. Normally these cells are able to efficiently export excess cholesterol, but this process seems to fail in atherosclerosis. This project will study the molecular mechanism for cholesterol export from macrophages, concentrating on a the mechnisms by which recently identified cholesterol pumps operate. These are located in cell membranes, including at the cell surface, which is the site at which cholesterol is transferred to acceptors such as HDL and apoAI. By understanding how these pumps work, and how their activities are controlled, we will be better able to devise ways to increase their efficiency in atherosclerosis, and so to prevent the tissue cholesterol accumulation that drives this disease.Read moreRead less
To Biochemically Trick P-Glycoprotein (Pgp) To Target Resistance Via Lysosomal Pgp
Funder
National Health and Medical Research Council
Funding Amount
$603,848.00
Summary
We have discovered an innovative biochemical strategy whereby our novel compounds exploit and trick a part of the detoxification machinery, that is the transporter, P-glycoprotein, to specifically kill drug resistant cancer cells. Herein, we take advantage of this biochemical mechanism to design novel and safe drugs to selectively target resistant tumours.
Mechanism Of Action And Targeting Of RAGE In Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$386,423.00
Summary
Humans have evolved defense and repair mechanisms to counteract threats such as tissue injury and infection. The immune system first must detect the potential life-threatening event and it does so by recognizing danger signals. RAGE is a key cell-surface receptor that recognises these danger signals. Despite its important role in health and disease our understanding of how RAGE works is very limited. We will discover how RAGE works and how to manipulate its function for new infection therapies.
Control of selective microRNA release via exosomes and microvesicles. This project aims to improve our understanding of cell-to-cell communication. Cells release genetic material including microRNAs in lipid membrane-enclosed vesicles (called exosomes and microvesicles) to alter neighbouring and distant cells. Recent research shows that the contents of these vesicles are regulated by cell state, however, the molecular mechanisms are not yet known. This project will investigate the hypothesis tha ....Control of selective microRNA release via exosomes and microvesicles. This project aims to improve our understanding of cell-to-cell communication. Cells release genetic material including microRNAs in lipid membrane-enclosed vesicles (called exosomes and microvesicles) to alter neighbouring and distant cells. Recent research shows that the contents of these vesicles are regulated by cell state, however, the molecular mechanisms are not yet known. This project will investigate the hypothesis that changes in the RNA-binding protein composition of cholesterol-rich membranes mediate the selection of miRNA loaded in the vesicles. This knowledge may increase our understanding of mechanisms of disease because this mode of cell-to-cell communication is disrupted or hijacked in pathologies. Future translation in diverse applications may improve human, animal and plant health.Read moreRead less
Understanding how cells regulate self eating during starvation and stress. This project aims to investigate how autophagosomes are built during autophagy by using advanced multi-modal imaging and unique gene-edited human cell lines. This project expects to generate new knowledge on how a family of evolutionary conserved proteins regulate autophagosome formation during starvation and stress conditions. Expected outcomes include the development of frontier imaging technologies that can be subseque ....Understanding how cells regulate self eating during starvation and stress. This project aims to investigate how autophagosomes are built during autophagy by using advanced multi-modal imaging and unique gene-edited human cell lines. This project expects to generate new knowledge on how a family of evolutionary conserved proteins regulate autophagosome formation during starvation and stress conditions. Expected outcomes include the development of frontier imaging technologies that can be subsequently utilised for the advancement of any field of cell biology. This should provide significant benefits by placing Australia at the forefront of cell biology technologies and increasing our understanding of how plant and human cells can protect themselves during starvation and stress.
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Characterising the transport and delivery of oligonucleotides . Short RNA and DNA molecules represent a class of macromolecules that have great potential, but to facilitate their trafficking across cellular and membrane barriers into specific sites of action is challenging. This project aims to develop and apply novel imaging approaches to track them in cells and tissues. Expected outcomes include better understanding of the trafficking across cellular and membrane barriers, and improved imaging ....Characterising the transport and delivery of oligonucleotides . Short RNA and DNA molecules represent a class of macromolecules that have great potential, but to facilitate their trafficking across cellular and membrane barriers into specific sites of action is challenging. This project aims to develop and apply novel imaging approaches to track them in cells and tissues. Expected outcomes include better understanding of the trafficking across cellular and membrane barriers, and improved imaging tools that could be used to further study the molecular mechanisms of accumulation, metabolism and trafficking of these molecules. This project should provide new strategies to target these molecules to specific cells and tissues, which have significant social and economic benefits to the Australian community.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
All-in-vitro engineering and single molecule analysis of protein complexes. The production and engineering of proteins are key methodologies in life sciences. The current project aims to develop new approaches to accelerate the production and analysis of proteins and to apply them to increase our understanding of the basic mechanisms of cell self-maintenance.