The Regulation Of Apolipoprotein E Secretion By Human Macrophages
Funder
National Health and Medical Research Council
Funding Amount
$516,078.00
Summary
One of the major inflammatory cells in the body, the macrophage, is involved in a number of diseases, including coronary disease. ApoE is made and released by macrophages and appears to protect against the inflammation of coronary disease and may affect other conditions, including Alzheimer's disease. We have discovered pathways regulating the production and release of apoE by macrophages, and in this project will study these pathways in great detail. By controlling the production of this import ....One of the major inflammatory cells in the body, the macrophage, is involved in a number of diseases, including coronary disease. ApoE is made and released by macrophages and appears to protect against the inflammation of coronary disease and may affect other conditions, including Alzheimer's disease. We have discovered pathways regulating the production and release of apoE by macrophages, and in this project will study these pathways in great detail. By controlling the production of this important molecule we may reduce our risk of heart disease, and may be able to treat a range of inflammatory conditions which currently untreatable.Read moreRead less
This program of research is firmly focussed on the basic mechanisms involved in normal functioning of cells and tissues, followed by a step by step process to understand the abnormal or the diseased. The disease states we are investigating involve the blood and blood vessels, and when there is malfunction it may contribute to conditions as diverse as atherosclerosis, thrombosis, inflammation and cancer. The program thus addresses the fundamentals of diseases which are responsible for most deaths ....This program of research is firmly focussed on the basic mechanisms involved in normal functioning of cells and tissues, followed by a step by step process to understand the abnormal or the diseased. The disease states we are investigating involve the blood and blood vessels, and when there is malfunction it may contribute to conditions as diverse as atherosclerosis, thrombosis, inflammation and cancer. The program thus addresses the fundamentals of diseases which are responsible for most deaths in our society. We will use technology which is proven to provide precise information, the molecular and biochemical processes responsible for cell function (or malfunction). However in each individual project there will be a clear path to a clinical use, diagnostic or therapeutic. Indeed in a number of the components of the program there are already potential treatments and diagnostics in development and trial.Read moreRead less
Cells must regulate the flow of ions and water across their membranes in order to survive and function normally. The balance of ions and water is controlled by ion channels - proteins that control the permeability of the cell membrane. Of the ion channels, chloride channels are the most abundant in cells. They are central to the functioning of normal cells as well as playing a key role in many disease states. Our group was the first to identify and characterise a new class of chloride channel wh ....Cells must regulate the flow of ions and water across their membranes in order to survive and function normally. The balance of ions and water is controlled by ion channels - proteins that control the permeability of the cell membrane. Of the ion channels, chloride channels are the most abundant in cells. They are central to the functioning of normal cells as well as playing a key role in many disease states. Our group was the first to identify and characterise a new class of chloride channel which plays a key roles in the regulation of the immune system. These channels are unusual in that they can move between two states: a soluble state and a state that resides in the cell membrane. We have determined the first structures of this class of channel in both the soluble state and what is believed to be the membrane docking state. This has given us the first atomic picture of how this channel protein can alter its structure so as to carry out its function. In this project, we will determine: how the protein completes the transition into the membrane state; the structures of other key members of this class of channel protein; complexes between channel proteins and other cellular proteins; and the structure of the protein in the membrane state. We will also determine how several drugs control the activity of this channel. The results of our work will have specific implications for our channel and will serve as a paradigm other members of this new class of chloride channel. Understanding how this channel functions and how the current drugs control it will lead to the development of a new class of therapeutic agents that will control these channels by preventing the transition from the soluble to the membrane state.Read moreRead less