Imaging Neutrophil And Endothelial Function In Acute Glomerulonephritis
Funder
National Health and Medical Research Council
Funding Amount
$545,517.00
Summary
The glomerulus is a group of small blood vessels which form the filtering component of the kidney. In many diseases, it can be the target of an inappropriate inflammatory response during which white blood cells accumulate in the glomerular blood vessels and cause damage. In this project, we will visualise the blood vessel lining of the glomerulus in order to understand how white blood cells damage this region and cause leakage of protein leak into the urine.
Endothelial Development From Pluripotent Stem Cells As A Means To Study Pathology In Pulmonary Artery Hypertension
Funder
National Health and Medical Research Council
Funding Amount
$613,311.00
Summary
Pulmonary artery hypertension (PAH) is a fatal disease primarily affecting young adults. It is caused by a defect in cells that form the vessel that carries blood from the heart to the lungs. We will use stem cells made from the skin of PAH patients to examine why the blood vessel cells from these patients fail to function normally.
Understanding How GATA2 Controls Lymphatic Vessel Valve Development
Funder
National Health and Medical Research Council
Funding Amount
$697,942.00
Summary
Mutations in the GATA2 gene cause human lymphoedema as a result of the crucial role that GATA2 plays in controlling the expression of genes important for building functional lymphatic vessels. Here we aim to gain a complete picture of the cellular and molecular events that are controlled by GATA2 in lymphatic vessels and in particular, in lymphatic vessel valves.
Deciphering The Transcriptional Program That Instructs Lymphatic Endothelial Cell Fate.
Funder
National Health and Medical Research Council
Funding Amount
$541,950.00
Summary
Lymphatic vessels are essential to maintain fluid balance in most tissues of the human body. Further the lymphatic vasculature plays a central role during cancer and contributes to tumour metastasis. Despite this integral function in health and disease little is known about the molecular programs that coordinate gene expression to build a functional vasculature. This research project will address this gap in our knowledge and will open up new therapeutic avenues for lymphatic vascular disorders
Transplantation of pancreatic islets is the only cure for type 1 diabetes (T1D). Unfortunately, many of the transplanted islet cells die quickly due to an inadequate supply of blood. Herein, we investigate a novel cell surface protein for its role in islet and blood vessel survival and function. Furthermore, we use nanotechnology to provide said protein to the islet cells during transplantation for increased survival and function. Ultimately, this work may cure more patients with diabetes.
Cryptococcal Meningoencephalitis - Fungal Determinants Of Invasion Of The CNS
Funder
National Health and Medical Research Council
Funding Amount
$587,634.00
Summary
Meningitis and brain infection (meningoencephalitis) due to the fungus Cryptococcus, affect over 1 million patients with AIDS annually, especially in developing countries; with more than 600,000 deaths. It is not known how Cryptococci cross from the blood stream into the brain; this must be elucidated in order to prevent and/or control this devastating infection. This project will determine how cryptococci influence host blood cells to act as “Trojan horses” and/or release products that initiate ....Meningitis and brain infection (meningoencephalitis) due to the fungus Cryptococcus, affect over 1 million patients with AIDS annually, especially in developing countries; with more than 600,000 deaths. It is not known how Cryptococci cross from the blood stream into the brain; this must be elucidated in order to prevent and/or control this devastating infection. This project will determine how cryptococci influence host blood cells to act as “Trojan horses” and/or release products that initiate invasion of brain tissue and meningitis.Read moreRead less
Transcriptional Control Of Blood Vessel Development By Sox18
Funder
National Health and Medical Research Council
Funding Amount
$468,564.00
Summary
Blood vessels play an essential role in maintaining the supply of nutrients to every organ and tissue in the body. Improper development of blood vessels in the embryo can compromise survival of the embryo, and defects in the ability of blood vessels to grow, regenerate and adapt to change during adult life can be life-threatening. The growth of new blood vessels (angiogenesis) is also an important factor in the ability of solid tumours to grow during the progression of cancer. It is therefore of ....Blood vessels play an essential role in maintaining the supply of nutrients to every organ and tissue in the body. Improper development of blood vessels in the embryo can compromise survival of the embryo, and defects in the ability of blood vessels to grow, regenerate and adapt to change during adult life can be life-threatening. The growth of new blood vessels (angiogenesis) is also an important factor in the ability of solid tumours to grow during the progression of cancer. It is therefore of fundamental importance in the health sciences to gain an understanding of how blood vessels form and regenerate. As a result of our collaborative research efforts, we have discovered a gene, Sox18, that appears to regulate blood vessel development by controlling the formation and-or behaviour of endothelial cells, which line the blood vessels and make them impermeable. Our research so far indicates that MICE WITH DEFECTS IN SOX18 DIE FROM VASCULAR DEFECTS, underlining the importance of this gene. THIS PROJECT IS CONCERNED WITH FINDING OUT HOW SOX18 WORKS - exactly what goes wrong in mice lacking this gene, whether Sox18 can influence endothelial cell behaviour in cell culture, how Sox18 comes to be active in endothelial cells, what genes are switched on by Sox18, and what genes Sox18 co-operates with in its role in endothelial cells. The answers to these questions will not only provide fundamental basic information about how blood vessels development is controlled, but also sow the seeds for possible future therapies in which blood vessel development could be stimulated (eg in wound healing) or suppressed (eg in tumour progression) through pharmaceutical intervention.Read moreRead less
Characterising Signals Important For Lymphangiogenesis During Development And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$604,938.00
Summary
Lymphatic vessels are a vital component of the cardiovascular system. Abnormalities in the growth and development of lymphatic vessels are associated with human disorders including cancer, lymphoedema and inflammatory diseases. The focus of this application is to characterise signals that direct the construction of lymphatic vessels, with the aim of identifying targets to which novel therapeutics for the treatment of lymphatic vascular diseases could be generated.
Suppression Of NADPH Oxidase-derived Oxidative Stress By Anti-sense Probes And HDL In Human Vascular Endothelium
Funder
National Health and Medical Research Council
Funding Amount
$455,250.00
Summary
In Australia, coronary heart disease (CHD) causing heart attacks remains the largest cause of death, claiming a staggering 28,000 lives a year. Oxidative stress, resulting from increased production of oxygen free radicals in arteries, is an important cause of CHD, heart attacks and strokes. We seek to understand how such oxyradicals are produced in the key cells that form the lining of all arteries, known as the vascular endothelium. By using novel DNA-type molecules (known as anti-sense) develo ....In Australia, coronary heart disease (CHD) causing heart attacks remains the largest cause of death, claiming a staggering 28,000 lives a year. Oxidative stress, resulting from increased production of oxygen free radicals in arteries, is an important cause of CHD, heart attacks and strokes. We seek to understand how such oxyradicals are produced in the key cells that form the lining of all arteries, known as the vascular endothelium. By using novel DNA-type molecules (known as anti-sense) developed in our laboratory, which block a particular gene causing oxidative stress, we will determine whether this gene is responsible for the formation of oxyradicals in human and mouse cells grown in culture. In addition, we will explore whether this gene is turned on by factors known to be involved in CHD. Finally, we will also investigate whether the good cholesterol known as HDL can act to prevent oxidative stress in human cells, as we discovered it appears to do in living arteries in vivo. If we find it has the same protective effect in endothelium, we will determine how it does this, and which component proteins of the HDL particle are important. This might suggest new treatments to prevent acute events leading to heart attack and stroke, and possibly new applications where damage appears to result from acute oxidative stress, such as in the brain soon after a stroke has occurred. We also have a plan to develop antisense drugs that will target the important gene specifically in the affected endothelium. In addition, we have other specific new drugs that will block this system in arteries. Simultaneously we will be testing the role of this gene in mouse and rabbit models of artery disease, for both our types of drugs might provide valuable new therapeutic agents to target the underlying cause of CHD and not just its symptoms as current drugs do.Read moreRead less
Mechanisms And Therapies In Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$8,360,700.00
Summary
Cardiovascular disease (CVD) claims 1 person every 10 min in Australia and causes 1 in 3 deaths worldwide. The molecular and cellular processes underlying atherosclerosis, vascular injury and thrombosis are highly complex and not well understood. A multifaceted approach is needed to effectively address these key challenges. This Program brings together world experts in these areas to interrogate gaps in our basic understanding of CVD, and to develop novel therapies for CVD patients by exploiting ....Cardiovascular disease (CVD) claims 1 person every 10 min in Australia and causes 1 in 3 deaths worldwide. The molecular and cellular processes underlying atherosclerosis, vascular injury and thrombosis are highly complex and not well understood. A multifaceted approach is needed to effectively address these key challenges. This Program brings together world experts in these areas to interrogate gaps in our basic understanding of CVD, and to develop novel therapies for CVD patients by exploiting new knowledge through integrated research.Read moreRead less