THE CMRF-35 FAMILY OF MOLECULES: GENE STRUCTURE, EXPRESSION AND FUNCTION
Funder
National Health and Medical Research Council
Funding Amount
$367,669.00
Summary
White blood cells are the army which fights invasion by foreign organisms or cancer cells. Their main artillery and communication systems are located on the cell surface as protein molecules. These recognize foreign material and danger signals, and signal into the cell to direct interactions with other cells- soluble molecules in the immune system. We have discovered a new group of molecules called the CMRF-35 family which are found on the surface of different white blood cells. We have characte ....White blood cells are the army which fights invasion by foreign organisms or cancer cells. Their main artillery and communication systems are located on the cell surface as protein molecules. These recognize foreign material and danger signals, and signal into the cell to direct interactions with other cells- soluble molecules in the immune system. We have discovered a new group of molecules called the CMRF-35 family which are found on the surface of different white blood cells. We have characterized two members of the CMRF-35 family by studying the structure of their genes and the cells which express them. These studies will determine if the known CMRF-35 molecules are able to send signals from the cell surface into the cell to activate or inhibit a functional response by cells that express them. We hope to identify the triggers that initiate a signal from CMRF-35 molecules into the cell and whether there are molecules which bind CMRF-35 molecules and then get moved from the surface to inside the cell. Our data suggests that there are other unknown members of this family. We will determine how many members there are in this family by studying the DNA of genes that are related to the known CMRF-35 molecules. This will allow us to charactertize novel molecules that may be important for white cell function. Discovering new white cell surface molecules and determining their function increases our understanding of how the immune response works. If these CMRF-35 molecules represent a large family, it is highly likely that they have important roles in the immune response. By understanding the signals these molecules send to the cell nucleus we may be able to exploit their function to fight disease. For example where the immune system has not recognized cancer cells as dangerous, we might use the activating CMRF-35 molecules to stimulate a response. In the case of auto-immunity we may be able to reduce the responses via inhibitory CMRF-35 molecules.Read moreRead less
Inhibition Of Endothelial Cell Adhesion Molecule Expression By High Density Lipoproteins
Funder
National Health and Medical Research Council
Funding Amount
$80,550.00
Summary
It is well known that high levels of cholesterol in blood cause coronary heart disease. However, it is also known that not all of the blood cholesterol is bad. If it is carried in particles called low density lipoproteins or LDLs it causes heart disease. But if it is carried in other particles known as high density lipoproteins or HDLs it does not. In fact, it is now well known that HDLs actually protect against the development of coronary heart disease. There are two main actions of HDLs that c ....It is well known that high levels of cholesterol in blood cause coronary heart disease. However, it is also known that not all of the blood cholesterol is bad. If it is carried in particles called low density lipoproteins or LDLs it causes heart disease. But if it is carried in other particles known as high density lipoproteins or HDLs it does not. In fact, it is now well known that HDLs actually protect against the development of coronary heart disease. There are two main actions of HDLs that contribute to their ability to protect. Firstly, they are known to drain cholesterol out of coronary arteries. We have recently shown that they have a second action. The end result of this second action is a slowing down of the entry into coronary arteries of cells called monocytes that are necessary for the development of the atherosclerosis that causes the heart disease. This project is concerned with this ability of HDLs to slow down the development of atherosclerosis by the second action. We have found that this second action of HDLs is influenced by the type of fats they carry. We propose now to investigate the mechanism by which different fats influence this action of HDLs with a view to devising new strategies for the prevention of heart disease.Read moreRead less
The Putative Drug Metabolising Enzyme SULT4A1 Is A Sulfotransferase Inhibitor
Funder
National Health and Medical Research Council
Funding Amount
$467,851.00
Summary
The sulfotransferase SULT4A1 is a novel protein found predominantly in neurons but its function is unknown. This project will investigate the mechanisms that the body uses to regulate the levels of this protein and how it may interfere with other enzymes essential for metabolising hormones and neurotransmitters.
Characterising The Novel Signalling Mechanism For A New Interferon
Funder
National Health and Medical Research Council
Funding Amount
$525,485.00
Summary
We have discovered a new regulatory protein called interferon epsilon, made in the female reproductive tract and is crucial for protection against bacterial( Chlamydia) and viral (Herpes Simplex Virus) infections. However, we are yet to understand how it interacts with target cells. This grant will study how IFN? binds to cells and the nature of the signals it transmits. This will help us understand its role in disease and its clinical potential