The Effects Of Human Epilepsy Mutations On Synaptic GABA-A Receptors Studied By Localization-based Superresolution Microscopy
Funder
National Health and Medical Research Council
Funding Amount
$524,215.00
Summary
The genetic epilepsies are debilitating neurological disorders that are frequently associated with mutations in genes encoding neurotransmitter-gated receptors in the brain. The goal of this project is to understand mechanisms that cause changes in neuronal communication and lead to epilepsy on a single receptor level. This will lead to an improved understanding of the mechanisms of epileptogenesis and new insights into ways of treating different epilepsies.
Regulation Of RyR2 Channels By Calmodulin In Healthy And Diseased Hearts
Funder
National Health and Medical Research Council
Funding Amount
$614,421.00
Summary
In the heart, RyR2 is responsible for intracellular Ca2+ release. The RyR2 is comprised of a Ca2+ channel and accessory proteins such as CaM that regulate channel activity. Evidence suggests that RyR2 regulation by CaM is altered in heart failure and human arrhythmia syndromes, but there has been no direct evidence for this. We will provide this direct evidence plus determine how CaM regulates RyR2 channels and intracellular Ca2+ release and how this leads to cardiac arrhythmias.
Sudden Cardiac Arrest: Improving Detection Of Patients At Risk
Funder
National Health and Medical Research Council
Funding Amount
$838,845.00
Summary
Sudden cardiac death accounts for ~10% of deaths in our community. Many of these deaths occur in people who could otherwise have had many more years of productive life ahead of them. The aim of our research is to determine the underlying mechanisms so that we can develop better tools for detecting underlying problems before they become life threatening and potentially develop new treatments to modify the underlying causes.
Role Of Non-Invasive Imaging Using Speckle Tracking Echocardiography In The Identification And Treatment Of Patients At Risk Of Arrhythmias And Consequent Sudden Cardiac Arrest
Funder
National Health and Medical Research Council
Funding Amount
$437,034.00
Summary
Every year, 15,000 Australians die from sudden cardiac arrest. Identifying individuals at risk is a major challenge. We will investigate whether a heart ultrasound technique called speckle tracking allows clinicians to rapidly identify changes in heart muscle that are associated with cardiac arrest. If found to be positive, the technique may be broadly applied to large populations, identifying at risk individuals, potentially rescuing them before cardiac arrest occurs.
Mechanisms Of Ion Channel Dysfunction In Hereditary And Acquired Neuropathies
Funder
National Health and Medical Research Council
Funding Amount
$404,869.00
Summary
Nerve function is dependent on ion channels, which provide the basis for neurotransmission. Inherited or acquired abnormalities in ion channel function are important in diseases including epilepsy, pain disorders, neuromuscular diseases and toxic neuropathy. This project will use a combination of techniques to study mechanisms underlying nerve dysfunction to compare genetic nerve problems and acquired nerve damage to understand how damage occurs and develop new therapies and diagnostic tests.
The Final Common Channel: Measurement Of Nerve Excitability In Epilepsy.
Funder
National Health and Medical Research Council
Funding Amount
$301,376.00
Summary
Epilepsy may be due to either one single genetic mutation or a combination of several gene-environment interactions, affecting how ion channels function. It is not possible to directly interrogate channels in the living human brain but, because similar channels are found in peripheral nerve, much may be learned about aberrant channel function from peripheral nerve. This project aims to measure peripheral nerve excitability in epilepsy patients, using it as a marker of the final common pathway of ....Epilepsy may be due to either one single genetic mutation or a combination of several gene-environment interactions, affecting how ion channels function. It is not possible to directly interrogate channels in the living human brain but, because similar channels are found in peripheral nerve, much may be learned about aberrant channel function from peripheral nerve. This project aims to measure peripheral nerve excitability in epilepsy patients, using it as a marker of the final common pathway of channel dysfunction.Read moreRead less
Epilepsy is a serious condition having a massive impact on individuals and the community at large. Our understanding of the genetic causes of epilepsy is growing rapidly. We have created new animal models based on human mutations. We have shown that mutations can change the wiring of the brain during development so that the adult brain is more likely to become epileptic. Projects in this grant test if we can stop this developmental impact- allowing us to treat epilepsy before seizures occur.
Professor Lewis is a molecular pharmacologist interested in discovering new venom peptides and ciguatoxins and determining how they interact with the membrane proteins they target using advanced biochemical and spectroscopic methods. Peptides of interest are then modified to improve potency and selectivity. Those with appropriate properties are patented and developed for clinical applications using approaches successfully applied to Xen2174, a conopeptide analogue I co-discovered that is now in ....Professor Lewis is a molecular pharmacologist interested in discovering new venom peptides and ciguatoxins and determining how they interact with the membrane proteins they target using advanced biochemical and spectroscopic methods. Peptides of interest are then modified to improve potency and selectivity. Those with appropriate properties are patented and developed for clinical applications using approaches successfully applied to Xen2174, a conopeptide analogue I co-discovered that is now in Phase II clinical trials for severe pain.Read moreRead less
Development Of Membrane Protein Structural Biology In Australia
Funder
National Health and Medical Research Council
Funding Amount
$601,484.00
Summary
Membrane proteins are key components of all living organisms, constituting more than 30% of cellular proteins and representing more than 50% of all drug targets. Despite their medical importance our knowledge of membrane proteins is still extremely limited and requires further technological advances. This work will firmly establish membrane protein crystallography in Australia and provide a basis for training of new researchers in this important field.
Inactivation Of HERG Potassium Channels: Dynamic Changes In The Outer Pore Structure
Funder
National Health and Medical Research Council
Funding Amount
$422,716.00
Summary
Sudden cardiac death, due to disturbances in the normal electrical activity of the heart, is one of the leading causes of death in Australia and its incidence is increasing. Tackling the problem of cardiac arrhythmias is therefore one of the major challenges for cardiology in the 21st century. Two factors are greatly limiting progress in this area, the inability to predict who is most at risk and a paucity of treatment options. To address these problems, we need to better understand the basic me ....Sudden cardiac death, due to disturbances in the normal electrical activity of the heart, is one of the leading causes of death in Australia and its incidence is increasing. Tackling the problem of cardiac arrhythmias is therefore one of the major challenges for cardiology in the 21st century. Two factors are greatly limiting progress in this area, the inability to predict who is most at risk and a paucity of treatment options. To address these problems, we need to better understand the basic mechanisms underlying arrhythmias. The rhythm of the heart beat is controlled by electrical signals mediated by the flow of ions through specialised proteins called ion channels. Of the channels that contribute to cardiac electrical activity, potassium ion channels encoded by the Human ether-a-go-go-related gene (HERG) have been of particular interest for three reasons. Firstly, mutations in HERG are the cause of one third of cases of congenital long QT syndrome, an inherited cause of sudden cardiac death. Secondly, HERG is the molecular target for the vast majority of drugs that cause drug-induced long QT syndrome, the commonest cause of drug-induced arrhythmias and cardiac death. Thirdly, HERG channels have very unusual biophysical properties, which has led to the suggestion that they may act as an endogenous anti-arrhythmic agent . Accordingly, the major objective of the proposed research program is to understand the molecular and structural basis of the unusual properties of HERG channels. We will use a combination of molecular and electrical techiques in conjunction with computer modeling to probe the micoscopic motions in the channel that underly the unusual biophyscial properties of these channels. This work will facilitate a better understanding of how clinically identified mutations in HERG contribute to the increased risk of cardiac arrhythmias. More generally, it will improve our understanding of how cardiac ion channels maintain the normal rhythm of the heart.Read moreRead less