Critical Role Of TNF In Host-virus Interactions And Outcome Of Infection: Involvement Of Reverse Signalling Through MTNF
Funder
National Health and Medical Research Council
Funding Amount
$496,500.00
Summary
Cytokines are molecules produced by cells that take part in the immune response. They coordinate the activities of leukocytes and are important in the host response to virus infections. For their part, viruses have evolved strategies to try and evade the host response. The analysis of these strategies in the context of a viral infection will lead to a better understanding of the immune system and host-virus interactions. Tumour necrosis factor is a cytokine made by specific leukocytes, in two st ....Cytokines are molecules produced by cells that take part in the immune response. They coordinate the activities of leukocytes and are important in the host response to virus infections. For their part, viruses have evolved strategies to try and evade the host response. The analysis of these strategies in the context of a viral infection will lead to a better understanding of the immune system and host-virus interactions. Tumour necrosis factor is a cytokine made by specific leukocytes, in two stages: First, the cytokine is exposed on the surface of the cell and then it is clipped off and released as a soluble form. In either form it can interact with specific receptors on other cells and, in this way, change the cells' activities. We have found that binding of tumour necrosis factor receptors to the cytokine, while it is in its membrane form, can also send a message backwards into the cell bearing the tumour necrosis factor. This process, known as reverse signalling, then changes the activity of this cell and constitutes a major new route through which information transfer can occur. In this project we will characterize the biological changes that result from reverse signalling in specific types of leukocytes. We will be looking at the role of membrane tumour necrosis factor in two separate models of viral disease. The first is influenza pneumonia that is responsible for a great deal of morbidity and mortality worldwide. The second is a model of poxvirus infection (mousepox) that mimics the disease smallpox in humans. Human poxvirus infections are on the rise (e.g. monkeypox) and there is an increased threat of smallpox as a weapon of bioterrorism. Mousepox is a good model for the study of generalized viral infections and is also an excellent example of a virus that encodes proteins specifically designed to interfere with host tumour necrosis factor. Our studies will focus on the role of this cytokine in host-virus interactions and the outcome of infection.Read moreRead less
A Novel Viral Modifier Of TNF Family Receptor Signalling: Elucidation Of Mechanisms Of Action
Funder
National Health and Medical Research Council
Funding Amount
$453,727.00
Summary
Over millions of years, viruses have evolved a great number of strategies to allow them to subvert the effectiveness of the host response. We have discovered that one of these viral strategies seems designed to block the synthesis of an important anti-viral factor, called tumour necrosis factor. In this project, we aim to work out how the viral factor blocks tumour necrosis factor production inside the cell, at the level of the molecules involved. The second aspect of this project concerns the i ....Over millions of years, viruses have evolved a great number of strategies to allow them to subvert the effectiveness of the host response. We have discovered that one of these viral strategies seems designed to block the synthesis of an important anti-viral factor, called tumour necrosis factor. In this project, we aim to work out how the viral factor blocks tumour necrosis factor production inside the cell, at the level of the molecules involved. The second aspect of this project concerns the identification of the types of cells and responses which the viral factor acts upon to manipulate the host response. We reason that this information will improve our understanding of how tumour necrosis factor production is regulated and the significance of this type of response in virus infection and physiology, more generally. The application of this research will be to aid the design of better drugs for the treatment of many conditions where tumour necrosis factor production contributes significantly to pathology, eg rheumatoid arthritis and autoimmunity. In some conditions, it may be a therapeutic advantage to selectively turn on tumour necrosis factor, eg for treatment of infections or cancer.Read moreRead less
Needle Free Delivery Of Dengue And Zika Vaccines To The Skin
Funder
National Health and Medical Research Council
Funding Amount
$642,792.00
Summary
There is no Zika vaccine and only one licensed dengue vaccine, which is age and region restricted because of poor efficacy. We have developed safe subunit vaccine candidates capable of inducing potent virus neutralizing antibodies and demonstrated protection from lethal dengue challenge in a mouse model. Here we are partnering with Vaxxas to undertake preclinical development and GLP toxicity trials for microarray patches delivering dengue and zika virus subunit vaccines.
Prophylactic Vaccine Development For The Elimination Of Hepatitis C
Funder
National Health and Medical Research Council
Funding Amount
$936,752.00
Summary
A vaccine that prevents Hepatitis C is urgently needed to prevent infection and assist with global HCV elimination targets. This project grant will advance world-leading HCV vaccine candidates that generate both humoral and cellular immunity for clinical development.
Novel HIV-1 Glycoprotein Vaccines With Enhanced Presentation Of Broad Neutralization Epitopes
Funder
National Health and Medical Research Council
Funding Amount
$743,682.00
Summary
A prophylactic vaccine represents the best strategy for blocking HIV-1 transmission but one is not yet available. Current antiviral vaccines rely on neutralizing antibodies (NAbs) that block infection, however, current HIV-1 vaccine formulations do not induce broadly reactive NAbs (bNAbs). We have discovered a novel HIV-1 glycoprotein vaccination candidate with enhanced presentation of bNAb epitopes. We propose to determine if this vaccine induces effective bNAbs in experimental animals.
A Novel Vaccine Platform For Trimeric Envelope Proteins: HIV-1 Envelope
Funder
National Health and Medical Research Council
Funding Amount
$139,250.00
Summary
Vaccines are urgently needed for the prevention of HIV/AIDS. The design of this vaccine candidate is based on the display of HIV-1 envelope spikes using a related primate retrovirus envelope with a more stable assembly to anchor the the spikes in a particle.
Investigations Into Supraphysiologic T Cell Receptors And T Cell Agonists.
Funder
National Health and Medical Research Council
Funding Amount
$408,388.00
Summary
T cells are critical in controlling infection and important for the natural eradication of cancer. Through shape recognition, T cells identify dangerous antigens via the surface-bound T cell receptor (TCR). Using new technologies this project aims to "tune up" the strength of this molecular interaction and create a new generation of high affinity TCR and antigens for use as therapeutic and prophylactic drugs in the battle against infectious disease and cancer.
Novel Immune Evasion Strategy Of CMV: Targeting Of An Adhesion Molecule Involved In Leukocyte Recruitment/activation.
Funder
National Health and Medical Research Council
Funding Amount
$391,650.00
Summary
Herpesviruses cause persistent lifelong infection. To achieve this they have evolved a variety of mechanisms to evade the immune response mounted to combat them. They also minimise the expression of their gene products to a minimal suite of latency associated proteins. One member of the herpesvirus family is cytomegalovirus. While in healthy individuals it causes aymptomatic infection, it causes significant disease and mortality in individuals whose immune systems are suppressed such as transpla ....Herpesviruses cause persistent lifelong infection. To achieve this they have evolved a variety of mechanisms to evade the immune response mounted to combat them. They also minimise the expression of their gene products to a minimal suite of latency associated proteins. One member of the herpesvirus family is cytomegalovirus. While in healthy individuals it causes aymptomatic infection, it causes significant disease and mortality in individuals whose immune systems are suppressed such as transplant and AIDS patients, and also in the fetus which has a poorly developed immune system. Cytomegaloviruses set up persistent and latent lifelong infections. In the current proposal we will be assessing a viral gene present in mouse cytomegalovirus that codes for a protein that binds to a cellular adhesion molecule. This adhesion molecule called CD44 is involved in the migration of immune effector cell to sites of infection and in their activation. The viral gene thus represents a potential immune evasion molecule with the ability to subvert the host's immune response by reducing the infiltration and-or activation of cells that clear virus infection. The results from these studies could help us design anti-viral drugs that interfere with the effect of this viral protein, thus providing a novel anti-viral treatment strategy.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