Antibiotic resistance is a looming public health crisis. New antibiotics with new mechanisms of action are desperately needed. The long-term goal of this research is to develop new drugs that disarm bacteria to overcome the problem of antibiotic resistance.
Enhancing The Cardioprotective Effect Of Diadenosine Tetraphosphate: Designing Inhibitors Against Ap4A Hydrolase
Funder
National Health and Medical Research Council
Funding Amount
$442,500.00
Summary
Ischemia describes the condition where blood flow in the blood vessels of the heart is decreased or blocked, preventing delivery of oxygen and nutrients to the heart. Ischemic preconditioning is a phenomenon where short bursts of ischemia, followed by reperfusion, actually protect the heart from a subsequent longer period of ischemia. The biochemical signalling events involved in preconditioning are complex and incompletely defined, but most likely involve multiple pathways, although the mitocho ....Ischemia describes the condition where blood flow in the blood vessels of the heart is decreased or blocked, preventing delivery of oxygen and nutrients to the heart. Ischemic preconditioning is a phenomenon where short bursts of ischemia, followed by reperfusion, actually protect the heart from a subsequent longer period of ischemia. The biochemical signalling events involved in preconditioning are complex and incompletely defined, but most likely involve multiple pathways, although the mitochondrial ATP-dependent potassium channel may be in common with most pathways. Pretreatment with the compound diadenosine tetraphosphate (Ap4A) mimics ischemic preconditioning with noticeable reductions in tissue necrosis (cell death). This treatment has been shown in experimental work to protect the heart during periods of stress such as in heart surgery or recovery from an ischemic event. The biological site of action by Ap4A may be the mitochondria ATP-dependent potassium channel or an associated protein. Ap4A can be degraded by enzymes located inside and on the outside of heart cells, notably by two forms of Ap4A hydrolase. We will use antibody assays to understand the specific localization and amount of Ap4A hydrolase before and after ischemia and after ischemic preconditioning in human heart muscle and blood vessels. We propose to determine the structure of the enzyme and use novel computer methods to screen databases for potential inhibitors. These inhibitors of Ap4A hydrolase activity could aid the design of a potent inhibitor that would prevent Ap4A hydrolase from degrading Ap4A and therefore enhance the cardioprotective properties of Ap4A as well as minimizing side effects from the break down of Ap4A. We will also use these inhibitors and other known non-degradable Ap4A analogues in bioassays to test the relative significance of Ap4A hydrolase present in different cellular locations.Read moreRead less
How cholesterol optimises ion pump function in animal membranes. This project aims to determine how cholesterol optimises ion pump function in animal membranes and to identify the major effects of cholesterol and its derivatives on membranes’ physical properties. All animal cells need high levels of cholesterol in the plasma membrane for survival. Insufficient cholesterol biosynthesis leads to severe birth defects. The need for cholesterol is likely linked to its acceleration of sodium pump acti ....How cholesterol optimises ion pump function in animal membranes. This project aims to determine how cholesterol optimises ion pump function in animal membranes and to identify the major effects of cholesterol and its derivatives on membranes’ physical properties. All animal cells need high levels of cholesterol in the plasma membrane for survival. Insufficient cholesterol biosynthesis leads to severe birth defects. The need for cholesterol is likely linked to its acceleration of sodium pump activity, essential to physiological processes including cell division, nerve, muscle and kidney activity. An expected benefit of the project is knowledge on the molecular origin of diseases associated with inhibition of cholesterol production, and a more complete understanding of the crucial role played by cholesterol via its effect on ion pumping towards the healthy functioning of vital organs, particularly in heart muscle and nerves.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100022
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
A 700 MHz Nuclear Magnetic Resonance (NMR) spectrometer for the Melbourne Biomolecular NMR Network: A high throughput resource. The Melbourne Biomolecular Nuclear Magnetic Resonance (NMR) Network will enable NMR experiments aimed at discovering new molecules for diagnosing, treating and preventing disease, and identifying and eradicating pests. The new equipment will allow researchers to work with large numbers of samples, to identify the biomarkers of disease and to find new drug candidates qui ....A 700 MHz Nuclear Magnetic Resonance (NMR) spectrometer for the Melbourne Biomolecular NMR Network: A high throughput resource. The Melbourne Biomolecular Nuclear Magnetic Resonance (NMR) Network will enable NMR experiments aimed at discovering new molecules for diagnosing, treating and preventing disease, and identifying and eradicating pests. The new equipment will allow researchers to work with large numbers of samples, to identify the biomarkers of disease and to find new drug candidates quickly.Read moreRead less