Role Of Adhesion Molecules In Autoimmune Vasculitis
Funder
National Health and Medical Research Council
Funding Amount
$377,036.00
Summary
Lupus is a disease which causes inflammation and pain throughout the body. The inflammation is caused by white blood cells attacking the lining of blood vessels in tissues. The aim of this project is to understand the reasons why these white blood cells attack the blood vessel lining. This process is impossible to study in humans. However, there is a strain of mouse which is affected by a disease which is very similar to human lupus. This disease occurs spontaneously in these mice. Using a micro ....Lupus is a disease which causes inflammation and pain throughout the body. The inflammation is caused by white blood cells attacking the lining of blood vessels in tissues. The aim of this project is to understand the reasons why these white blood cells attack the blood vessel lining. This process is impossible to study in humans. However, there is a strain of mouse which is affected by a disease which is very similar to human lupus. This disease occurs spontaneously in these mice. Using a microscope, it is possible to study the tiny blood vessels which are affected by this disease in these mice . Under the microscope, it is possible to see the white blood cells as they undergo the process of attacking the blood vessel lining. Visualizing this attack then allows us to study it and determine which molecules are important in causing this damaging inflammatory response. Specifically I will examine diseased blood vessels in the skin and brain of these mice, two of the tissues most dramatically affected by this disease. This information should help us gain an increased understanding of lupus as it affects humans.Read moreRead less
This project will characterise the biological and functional properties of a novel human pro-inflammatory S100 protein. The protein is a natural component of the innate immune system and is regulated in cells by mediators of inflammation and infection. Our preliminary experiments indicate that this protein can activate mast cells. These cells reside in almost all body tissue and are located close to blood vessels and nerves. This location makes them prime targets to trigger vascular and inflamma ....This project will characterise the biological and functional properties of a novel human pro-inflammatory S100 protein. The protein is a natural component of the innate immune system and is regulated in cells by mediators of inflammation and infection. Our preliminary experiments indicate that this protein can activate mast cells. These cells reside in almost all body tissue and are located close to blood vessels and nerves. This location makes them prime targets to trigger vascular and inflammatory events. They are known to be important in allergy and infection and have a proposed role in chronic inflammatory processes. Although the mechanisms of mast cell activation contributing to acute responses in allergic reactions are well accepted, ways in which they are activated in asthma and other chronic inflammatory disease are virtually unknown. We will use lung biopsies from patients with asthma to detect patterns of expression of the protein and determine its effects on lung mast cells. A murine model will be used to define the characteristics of inflammation induced by the S100 protein and the role of mast cells in this process. Structural studies will define the parts of the protein necessary for mast cell activation. We will attempt to identify its receptor on mast cells to enable future studies to define how the protein triggers the cells to produce mediators such as histamine and those causing blood vessel changes. This knowledge could lead to design of novel drugs that could regulate this process. Results from this project will provide new knowledge of chronic inflammatory processes and could result in designing novel strategies to regulate these. Studies are relevant to infectious diseases and many other conditions with a chronic inflammatory basis, including asthma, rheumatoid arthritis, cardiovascular disease, cystic fibrosis and infection.Read moreRead less
Nutrient And Hormone Delivery To Muscle: Interactions Between Insulin And Exercise
Funder
National Health and Medical Research Council
Funding Amount
$304,375.00
Summary
Exercise is known to be beneficial in the treatment and prevention of Type 2 diabetes and in particular muscle insulin resistance. Also, exercise and insulin share similar acute actions on muscle. Firstly, muscle contraction has a well established action to increase glucose uptake, and secondly, both muscle contraction and insulin act to increase capillary recruitment. This latter phenomenon is thought to enhance nutrient delivery and waste product removal. There is evidence that the increase in ....Exercise is known to be beneficial in the treatment and prevention of Type 2 diabetes and in particular muscle insulin resistance. Also, exercise and insulin share similar acute actions on muscle. Firstly, muscle contraction has a well established action to increase glucose uptake, and secondly, both muscle contraction and insulin act to increase capillary recruitment. This latter phenomenon is thought to enhance nutrient delivery and waste product removal. There is evidence that the increase in capillary flow due to muscle contraction is accompanied by increases in total blood flow. For insulin action we now have preliminary data to indicate that capillary recruitment occurs within a 5-10 min application of a physiologic dose of insulin independent of a change in total blood flow suggesting a redistribution of flow. Muscle contraction also increases capillary recruitment and it raises the question of whether similar mechanisms underlie insulin- and muscle contraction-induced capillary recruitment or whether there are distinct and complementary pathways. In this project we plan to define the mechanisms responsible for contraction- and insulin-induced capillary recruitment in muscle. We hypothesize that similar mechanisms are operative, with both insulin and muscle contractions acting via NO-dependent mechanisms. Because of capillary reserve, and different initial steps of the signalling systems stimulated by insulin and exercise, capillary recruitment by combined contraction and insulin stimuli will be additive at both sub maximal and perhaps at maximal insulin pathway stimulation. Signalling mechanisms will be compared and the role of non-nutritive route as a flow reserve assessed.Read moreRead less
Investigate The Role Of PAF And CD40 Ligand In Regulating The Proinflammatory Properties Of Platelets
Funder
National Health and Medical Research Council
Funding Amount
$507,270.00
Summary
The cells of the blood play an important role in maintaining healthy blood vessels. We are interested in two types of blood cells, platelets and leukocytes, which together play a key role in vessel maintenance, by promoting blood clot formation and vessel wall repair following injury. However, while critical for normal blood vessel maintenance, these cells have also been demonstrated to contribute to disease states including atherosclerosis, thrombosis and inflammatory airway diseases. Underlyin ....The cells of the blood play an important role in maintaining healthy blood vessels. We are interested in two types of blood cells, platelets and leukocytes, which together play a key role in vessel maintenance, by promoting blood clot formation and vessel wall repair following injury. However, while critical for normal blood vessel maintenance, these cells have also been demonstrated to contribute to disease states including atherosclerosis, thrombosis and inflammatory airway diseases. Underlying the function of both blood cell types is their ability to stick (or adhere) to each other. However the way in which they coordinate this adhesion is very complex. New information from our laboratory has demonstrated that the sticky behaviour of each cell type is spatially and temporally regulated, and may involve may factors both inside and outside of the cells themselves. Our studies aim to define the key components regulating the 'stickiness' of these blood cells, in order to undertand how they contribute to maintaining healthy vessel walls, but also how their stickiness may also contribute to the promotion of diseased vessels. This information will not only increase our knowledge of the factors that regulate blood clot formation, but may also assist in the development of new therapies to prevent and-or treat vessel disease.Read moreRead less