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The Plasmalemmal Calcium Pump And Vascular Smooth Muscle Cell Proliferation.
Funder
National Health and Medical Research Council
Funding Amount
$179,593.00
Summary
Excessive growth of smooth muscle cells can lead to adverse effects in our arteries. The level of calcium inside the muscle cells that line our arteries appears to regulate their growth. In these studies we will assess the changes in the synthesis (expression) of a pump which removes calcium from cells. We will also characterise the effects of modifiers of cell growth on the expression of the calcium pump. The effect of directly inhibiting the production of the calcium pump, on the growth of smo ....Excessive growth of smooth muscle cells can lead to adverse effects in our arteries. The level of calcium inside the muscle cells that line our arteries appears to regulate their growth. In these studies we will assess the changes in the synthesis (expression) of a pump which removes calcium from cells. We will also characterise the effects of modifiers of cell growth on the expression of the calcium pump. The effect of directly inhibiting the production of the calcium pump, on the growth of smooth muscle cells and the regulation of calcium will be determined for the first time.Read moreRead less
Early Events In Arteriolar Remodeling: Adaptation To Prolonged Vasoconstriction
Funder
National Health and Medical Research Council
Funding Amount
$415,750.00
Summary
Small arteries, while acutely responding to their environment with changes in diameter to regulate local blood flow and pressure, also undergo structural adaptation or remodelling. These events occur over a range of time-frames and involve both non-genetically and genetically regulated events. Thus a contractile event, while initially decreasing vessel diameter, also activates longer time frame processes which can span from rearrangment of cellular junctions-contacts to overt structural changes ....Small arteries, while acutely responding to their environment with changes in diameter to regulate local blood flow and pressure, also undergo structural adaptation or remodelling. These events occur over a range of time-frames and involve both non-genetically and genetically regulated events. Thus a contractile event, while initially decreasing vessel diameter, also activates longer time frame processes which can span from rearrangment of cellular junctions-contacts to overt structural changes within the vessel wall (for example thickening of the muscle layer). These adaptive processes may enable the forces of contraction to be maintained without continued energy expenditure and damage to the vessel per se. However, they can also contribute to long-term alterations in the control of blood pressure and perhaps contribute to states of hypertension as well as other common vascular diseases. For these studies we will use arterioles, isolated by microsurgical techniques, together with sophisticated computer and video-based approaches. These techniques allow arterioles to be studied under controlled conditions and relevant biochemical measurements performed. We will also use a cell model where cultured cells will be studied after defined periods of mechanical stimulation (for example stretch). Cells will be probed using a novel microscopic technique (atomic force microscopy) which enables the cell membrane to be studied with respect to changes in composition as well as physical characteristics (for example stiffness). The studies are relevant to our understanding of the normal adaptive processes occurring within blood vessels to control blood flow and pressure. The studies are also of direct relevance to our understanding of common vascular disease states including hypertension, complications of diabetes and chronic inflammatory disorders.Read moreRead less
Local Microvascular Regulatory Mechanisms In Diabetes: Relevance To Neuropathy
Funder
National Health and Medical Research Council
Funding Amount
$212,036.00
Summary
In diabetes mellitus, the excessive levels of sugar in the blood may cause changes in metabolic processes within cells that lead to disturbances in the function of the circulatory and nervous systems. Such disturbances have been shown to occur in the early stages of diabetes and ultimately lead to longterm consequences including poor wound healing (often culminating in limb amputations), increased risk of blindness, kidney disease and heart failure. At present it is not possible to restore norma ....In diabetes mellitus, the excessive levels of sugar in the blood may cause changes in metabolic processes within cells that lead to disturbances in the function of the circulatory and nervous systems. Such disturbances have been shown to occur in the early stages of diabetes and ultimately lead to longterm consequences including poor wound healing (often culminating in limb amputations), increased risk of blindness, kidney disease and heart failure. At present it is not possible to restore normal metabolism, leaving patients at risk of developing complications involving the circulatory and nervous systems. An understanding of the processes involved in the development of such complications would allow alternate treatment strategies to be devised in order to improve the quality of life and life expectancy of diabetic patients. The events leading to abnormalities in the function of the circulatory and nervous systems are uncertain, however, studies have demonstrated that in diabetes there may be an insufficient blood supply to nerves and this would be expected to cause nerve damage. At present, our understanding of the factors involved in regulating blood flow to nerves is limited. The studies described in this proposal are aimed at testing the hypothesis that nerve blood vessels are themselves involved in the regulation of flow through an intrinsic ability to change their diameter in response to tissue demands and that in diabetes alterations in the capacity of nerve blood vessels to constrict or dilate compromises their role in the control of nerve blood flow . Information obtained from these studies will improve our understanding of the early disturbances in the function of circulatory and nervous systems leading to alterations in blood flow which precede the development of overt changes characteristic of the complications associated with diabetes. This will provide insight into developing new treatment strategies for diabetic patients.Read moreRead less
Our studies are aimed at examining how blood flow and pressure is controlled in the various tissues of the body. In particular, we hope to improve our understanding of how blood flow is matched to local metabolic requirements and how a constancy of conditions can be maintained despite changes in overall blood pressure. This ability to control local blood flow occurs through the ability of very small arteries to rapidly adjust their diameters through vasoconstriction or vasodilatation. The vessel ....Our studies are aimed at examining how blood flow and pressure is controlled in the various tissues of the body. In particular, we hope to improve our understanding of how blood flow is matched to local metabolic requirements and how a constancy of conditions can be maintained despite changes in overall blood pressure. This ability to control local blood flow occurs through the ability of very small arteries to rapidly adjust their diameters through vasoconstriction or vasodilatation. The vessels can thus act as valves regulating the transfer of blood flow and pressure to smaller vessels downstream. One particular response that small arteries exhibit is the ability to constrict when pressure within the vessels increases. The increase in pressure appears to stretch the vessel wall which in turn initiates a series of mechanical and biochemical steps that ultimately lead to contraction of muscle cells within the vessel wall. By contracting, the vessels limit the increase in downstream flow and pressure that would be expected to occur. The vessels being studied are very small, typically less than 100 micron. They are studied under isolated and controlled conditions using microscope and computer-based imaging techniques. While this allows us to directly monitor changes in vessel diameter to various stimuli (e.g. a change in pressure) we have also had to miniaturize biochemical measurements so we can understand the chemistry which underlies these vasoconstrictor responses. Understanding of how these local blood regulatory mechanisms occur is not only relevant to our understanding of the normal situation but is also vital to understanding disease states. For example, this work is very relevant to common cardiovascular disorders such as hypertension. It is hoped that a detailed understanding of the biochemical pathways by which small arteries contract will allow the design and targeting of pharmaceutical approaches for treatment of vascular disease states.Read moreRead less
Atherosclerosis (hardening of the arteries) is the principal cause of heart attack, stroke and blockage of blood flow to the lower limbs. However, to date none of the biological or synthetic grafts used to bypass the narrowed regions of arteries is ideal. We have shown that lengths of silicone tubing placed into the peritoneal cavity of rats or rabbits becomes covered within 2 weeks by a capsule of granulation tissue (smooth-muscle-like cells and collagen) and mesothelial (endothelial-like) cell ....Atherosclerosis (hardening of the arteries) is the principal cause of heart attack, stroke and blockage of blood flow to the lower limbs. However, to date none of the biological or synthetic grafts used to bypass the narrowed regions of arteries is ideal. We have shown that lengths of silicone tubing placed into the peritoneal cavity of rats or rabbits becomes covered within 2 weeks by a capsule of granulation tissue (smooth-muscle-like cells and collagen) and mesothelial (endothelial-like) cells. The silicone tubing can be removed and the tissue turned inside out such that the endothelial-like cells now line the inside of the tube of living tissue, which resembles a blood vessel. These artificial blood vessels will be grown in the peritoneal cavity of rabbits, then grafted into the right carotid artery to replace a length of removed vessel. Their long-term (3,6,9 and 12 months) patency, reactivity, tensile strength and resistance to clot development will be assessed. Their susceptibility to atherosclerotic plaque development and blockage (as compared with natural carotid artery) will be examined in rabbits fed a cholesterol-enriched diet. Changes in gene expression as the artificial artery progressively develops will be examined, as will the potential to genetically manipulate the artificial artery to improve its functioning. Finally, attempts will be made to grow the vessels entirely in vitro. This novel vascular graft may open new options in the field of arterial reconstructive surgery for replacing or bypassing diseased vessels or as an access vessel for haemodialysis patients with end stage renal failure. This study will also provide new information on the biology of cells found in the peritoneal cavity and their alternative pathways for differentiation.Read moreRead less
Ionic Conductances In Arterioles Modulated By Endothelium-derived Factors
Funder
National Health and Medical Research Council
Funding Amount
$67,828.00
Summary
The endothelial cells which form the inside lining of blood vessels can release a number of chemicals, some of which can relax the muscle in the wall of the blood vessels, while other chemicals can make the blood vessels contract. The correct balance between the contracting chemicals and the relaxing chemicals is essential for normal healthy functioning of the vessels and therefore proper blood flow through the organs of the body, and for the maintenance of normal blood pressure. If an imbalance ....The endothelial cells which form the inside lining of blood vessels can release a number of chemicals, some of which can relax the muscle in the wall of the blood vessels, while other chemicals can make the blood vessels contract. The correct balance between the contracting chemicals and the relaxing chemicals is essential for normal healthy functioning of the vessels and therefore proper blood flow through the organs of the body, and for the maintenance of normal blood pressure. If an imbalance occurs, such as a decrease in the effectiveness of the relaxing chemicals, then the muscle in the wall of the blood vessels tends to be more contracted, and this may result in decreased blood flow and possibly increased blood pressure. Such imbalances may underlie the vascular complications of diabetes, Raynaud's Phenomenon and essential hypertension. In a recent study on the effects of relaxing chemicals released from the endothelial cells, we have discovered the effects of a chemical which can cause blood vessels to contract. The chemical identity of this factor and the mechanisms by which it causes contraction are not known. Since excess activity of this chemical would tend to contract the blood vessels and therefore raise blood pressure, it is important to determine the chemical identity of this substance, and to determine how it causes contraction. The eventual development of drugs to inhibit the actions of this chemical may be a possible means for treating some diseases of the vascular system. This study is aimed at determining how this factor causes the blood vessels to contract, and takes the first steps towards determining its identity.Read moreRead less
Rhythmicity, Synchronicity And Spasm In Smooth Muscle
Funder
National Health and Medical Research Council
Funding Amount
$614,520.00
Summary
Many cellular systems undergo rhythmical spontaneous chemical and-or electrical activity . This activity, often referred to as pacemaking, is prevalent in many organs underlying brain waves or causing heart beats or rhythmic contractions of smooth muscle. Our studies on pacemaker rhythmicities in smooth muscle have revealed a novel mechanism, one which is entirely different to that responsible for heart pacemaking, the generally held model for electrical pacemakers. We aim to study the mechanism ....Many cellular systems undergo rhythmical spontaneous chemical and-or electrical activity . This activity, often referred to as pacemaking, is prevalent in many organs underlying brain waves or causing heart beats or rhythmic contractions of smooth muscle. Our studies on pacemaker rhythmicities in smooth muscle have revealed a novel mechanism, one which is entirely different to that responsible for heart pacemaking, the generally held model for electrical pacemakers. We aim to study the mechanism in depth so that we can fully describe its operation. This knowledge will provide insight into phenomena such as spontaneous contractions in blood vessels, lymphatic vessels and in the gastrointestinal tract, activities which are the norm and which are likely to have major influence on blood pressure, the propulsion of lymph and gut peristalsis. The knowledge will in the longer term lead to a better understanding of rhythmicities generally as far ranging as uterine contractions during childbirth to brain waves. An understanding of the pacemaker mechanism may also provide a key to understanding debilitating conditions such as vasospasm which can lead to death or serious disability.Read moreRead less
A Novel Ionic Current Contributing To Spasm Of Small Blood Vessels
Funder
National Health and Medical Research Council
Funding Amount
$287,500.00
Summary
Vascular smooth muscle can produce strong constrictions or spasms that can severely limit blood flow. Disorders arising from such spasms include sudden death, neurological deficits, visual and hearing loss or impairment, Raynaud's phenomenon (painful episodic contraction of the fingers and toes) and intestinal necrosis. Common mechanisms are likely to underlie the spasms associated with these disparate disorders. In a recent electrophysiological study of vascular smooth muscle, we discovered a n ....Vascular smooth muscle can produce strong constrictions or spasms that can severely limit blood flow. Disorders arising from such spasms include sudden death, neurological deficits, visual and hearing loss or impairment, Raynaud's phenomenon (painful episodic contraction of the fingers and toes) and intestinal necrosis. Common mechanisms are likely to underlie the spasms associated with these disparate disorders. In a recent electrophysiological study of vascular smooth muscle, we discovered a novel membrane current which we refer to as the plateau current. This current has a strong depolarizing influence that is likely to make a major contribution to the spasms, particularly in arterioles and small arteries which are more dependent on depolarization for contraction. Block of this current is expected to minimize the depolarization and therefore prevent or ameliorate spasm of the vessels. Thus the plateau current represents a new field of therapeutic potential for addressing vascular problems that have significant health implications. However, therapeutic manipulation of the current requires knowledge of its properties. In this project we will determine the biophysical and pharmacological properties of this current using voltage-clamp techniques. We will then use this information to assess its functional significance by recording membrane potential with intracellular microelectrodes simultaneously with contractile activity. We will also compare small vessels obtained from volunteers with or without the vasospastic disorder of Raynaud's phenomenon. Our previous work using these techniques was described in J Physiol as a microelectrode, patch clamp and myograph study of the highest quality and of supreme technical difficulty and scored a Top-Ten hit rate. Since we are the only ones to record the plateau current, we are in a unique position to make significant progress to our understanding of contraction, including spasm, in small blood vessels.Read moreRead less
KIT As A Target For The Modification Of Vascular Proteoglycans And Prevention Of Atherosclerosis
Funder
National Health and Medical Research Council
Funding Amount
$342,864.00
Summary
Heart disease occurs when arteries supplying blood to the heart become blocked. One aspect of this blockage is the capture of fats from the blood, by artery wall structures called proteoglycans. Proteoglycans are made up of a core protein and sugar chains (GAGs). The stickier the GAGs, the more fats that are captured. No drug treatment acts directly on the artery wall to prevent heart disease. This project aims to identify steps that lead to stickier GAGs and therefore a potential drug target.