Defining The Mechanisms That Regulate Effective Long-term Anti-viral Immunity
Funder
National Health and Medical Research Council
Funding Amount
$547,315.00
Summary
Human cytomegalovirus (HCMV) is a common human pathogen which normally causes a mild or even asymptomatic infection. However, in immunocompromised individuals, HCMV causes severe disease whose manifestations include chorioretinitis, interstitial pneumonia and hepatitis. Similarly, in neonates lacking a fully mature immune system, HCMV causes severe morbidity. Vaccines that protect against HCMV induced cytomegalic inclusion disease have been designated Level I (most favourable) due to the predict ....Human cytomegalovirus (HCMV) is a common human pathogen which normally causes a mild or even asymptomatic infection. However, in immunocompromised individuals, HCMV causes severe disease whose manifestations include chorioretinitis, interstitial pneumonia and hepatitis. Similarly, in neonates lacking a fully mature immune system, HCMV causes severe morbidity. Vaccines that protect against HCMV induced cytomegalic inclusion disease have been designated Level I (most favourable) due to the prediction that they could save lives and prevent life-long disability. Similarly, therapies that prevent and-or reduce HCMV reactivation will significantly improve the prognosis of transplant and AIDS patients. The murine CMV (MCMV) infection model has provided important insights as to how the immune system controls infection, and the mechanisms utilized by the virus to circumvent these processes. The design of effective therapies and vaccines requires a thorough understanding of the mechanisms required to generate and maintain long-lasting anti-viral responses. The studies outlined in this proposal aim to define the impact of specific components of the immune system n the generation, maintenance and effectiveness of anti-viral immunity. The well characterized MCMV model will be used to address these issues.Read moreRead less
Dengue Host-cell Signalling Interactions: Novel Insights And Interventions
Funder
National Health and Medical Research Council
Funding Amount
$124,676.00
Summary
Dengue is a virus transmitted by mosquitoes that occurs in many tropical and subtropical regions. Approximately 40% of the world's population is at risk of this infection. Sometimes it can be mild but it can lead to severe illness and death especially with second infections. The body produces a response that over-reacts to the virus in these severe infections. The project aims to understand why the body does this and what parts of the immune system are affected using a model in mice.
The Role Of Dendritic Cells In Sexual Transmission Of HIV And Viral Reservoir Formation
Funder
National Health and Medical Research Council
Funding Amount
$654,296.00
Summary
This grant aims to determine the subsets of dendritic cells found in the different tissue of the anogenital tracts and to determine which ones play the key roles in HIV transmission. The relative ability of these cells to transfer the virus to activated T cells leading to productive infection and resting memory T cells leading to latent infection will be investigated. Finally the key receptors which mediate this process will be determined and strategies to block this transfer developed.
Production Of Interferon Lambda By Dendritic Cell Subsets And Role In Adjuvant Effects Of Poly I:C
Funder
National Health and Medical Research Council
Funding Amount
$396,541.00
Summary
This proposal describes the identification of specific cells in mouse and humans that produce the anti-viral compound interferon-lambda. We propose to further characterise the mechanisms that induce interferon-lambda expression by these cell types and to decipher how this is controlled at the genetic level. We also aim to determine how the production of interferon lambda by these cell types can influence the immune response to viral infection.
Where It All Begins- Exploring Dendritic Cell Control Of Viral Infection And Cell Development In The Bone Marrow Of Mice And Man.
Funder
National Health and Medical Research Council
Funding Amount
$96,335.00
Summary
The bone marrow (bm) is the birthplace of all blood cells that fight infection in the body. Dendritic cells (DC), essential for starting immune responses, are found in the bm but the exact types and their functions are unknown. I plan to investigate the DC types that reside in the bm and explore their role in inducing immune responses and in influencing the development of cells from the bm with potential attributable benefits for stem cell transplant and vaccine design.
Antigen Dose And TCR Repertoire In CD8+ T Cell Immunodominance Hierarchies
Funder
National Health and Medical Research Council
Funding Amount
$558,920.00
Summary
The CD8+, or killer , T lymphocytes (white blood cells) are the hit men of immunity, recirculating continually around the body to eliminate other cells that are dangerous because they are cancerous or infected with a virus. A major difficulty is that killer T cells also exert selective pressures that cause viruses and tumours to mutate and thus avoid immune control. This is a particularly serious problem for RNA viruses that readily mutate as they divide. These include the human immunodeficiency ....The CD8+, or killer , T lymphocytes (white blood cells) are the hit men of immunity, recirculating continually around the body to eliminate other cells that are dangerous because they are cancerous or infected with a virus. A major difficulty is that killer T cells also exert selective pressures that cause viruses and tumours to mutate and thus avoid immune control. This is a particularly serious problem for RNA viruses that readily mutate as they divide. These include the human immunodeficiency virus (HIV) that causes AIDS and, while the mutations that are most important with influenza viruses are those that modify viral surface proteins recognized by antibodies, such T cell escape mutants can also be a problem with influenza. The other reason why there is particular interest in promoting CD8+ T cell-mediated immunity to influenza is that the killer T cells are very cross-reactive. We have shown that vaccination approaches that prime mouse CD8+ T cells to resist influenza A viruses circulating currently in humans will also protect against the highly lethal, and dangerous H5N1 bird 'flu. The present flu vaccines only stimulate antibodies, so there is interest in the possibility of a major re-design. The CD8+ T cells recognize tiny elements (peptides) of the virus or tumour bound in the tip of our own transplantation, or class I major histocompatibility complex (MHCI) molecules. These pMHCI complexes are called epitopes. The focus here is on the use of novel genetic engineering strategies to find out how, when the virus mutates to disrupt the major epitopes seen by killer T cells, other minor epitopes can be abnormally emphasized in a way that promotes effective immune control. As we work on this with the relatively simple and safe influenza model we will concurrently develop strategies that may be of value in HIV and tumour immunity. Solving this problem could prove to be a substantial advance in the design of vaccines and immunotherapy approaches.Read moreRead less
Nuclear Transport In Health And Disease; Towards Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$851,980.00
Summary
This research fellowship will enable new therapeutic approaches to viral disease and cancer that target the transport process. I have already licenced an inhibitory molecule for Dengue virus which is progressing towards the clinic. I will now extend my research into a vibrant translational program of developing anti-viral (HIV, Respiratory Syncytical Virus, VEEV) as well as anti-cancer agents that will represent realistic therapeutic options in the near future.
The Role Of T Cell Receptor Avidity In Determining T Cell Repertoires And Responses
Funder
National Health and Medical Research Council
Funding Amount
$472,500.00
Summary
T cells are an essential component of the immune system. CD8 T cells, in particular, play a vital role in the immune response to viruses and tumors, predominantly via killing of virally infected cells and tumor cells, as well as the release of inflammatory mediators. T cells must be activated before they can mediate such anti-viral or anti-tumor effects and this activation occurs through the binding of pathogen or tumor fragments (peptides) by a receptor on the surface of T cells (T cell recepto ....T cells are an essential component of the immune system. CD8 T cells, in particular, play a vital role in the immune response to viruses and tumors, predominantly via killing of virally infected cells and tumor cells, as well as the release of inflammatory mediators. T cells must be activated before they can mediate such anti-viral or anti-tumor effects and this activation occurs through the binding of pathogen or tumor fragments (peptides) by a receptor on the surface of T cells (T cell receptor). Each individual has an entire repertoire of T cells with unique T cell receptors which interact with peptides with varying binding strengths. After stimulation of T cells by e.g. viral infection, a subset of the T cell repertoire will become expanded and dominate the anti-viral immune response. This study aims to investigate how, during a viral infection, the strength (or 'avidity') of the interaction between the T cell receptor and the peptide influences (i) whether or not a T cell clone is recruited into the immune response and, if so, its dominance over other clones within that response, and (ii) how efficiently a T cell is activated. It is anticipated that particular virus peptide-specific T cell populations with an overall high avidity will be better able to produce inflammatory mediators and kill infected cells compared to lower avidity T cell populations specific for a different virus peptide. It is also expected that the higher avidity populations will exhibit greater diversity of TCRs. Further, within peptide-specific populations, it is anticipated that the relatively high avidity T cell clones will dominate the specific response. This study will contribute to a greater understanding of factors contributing to T cell recruitment and activation. Armed with this knowledge we will be better able to design vaccines to elicit optimal T cell responses to viral infection.Read moreRead less
Structural Basis Of Influenza A Virus-specific CD8+ T Cell Receptor Diversity
Funder
National Health and Medical Research Council
Funding Amount
$469,500.00
Summary
Viral infection results in the activation and proliferation of virus-specific T cells that mediate clearance of virally infected cells. Recognition of virally infected cells is meditated by presentation of peptide fragments complexed to Major histocompatibility complex (MHC) class I glycoproteins. Virus-specific T cells recognise these viral protein fragments via a specific receptor expressed at the T cell surface. This proposal plans to examine the structural factors that determine influenza-sp ....Viral infection results in the activation and proliferation of virus-specific T cells that mediate clearance of virally infected cells. Recognition of virally infected cells is meditated by presentation of peptide fragments complexed to Major histocompatibility complex (MHC) class I glycoproteins. Virus-specific T cells recognise these viral protein fragments via a specific receptor expressed at the T cell surface. This proposal plans to examine the structural factors that determine influenza-specific T cell receptor recognition. From these studies, we plan to determine how these structural factors can influence the diversity of virus-specific T cells that are generated after viral infection. The conclusions from these studies will enable us to determine why some virus-specific T cell responses are not diverse and what are the consequences for virus-specific T cell immunity. This has implications for the development of novel vaccine strategies designed to induce immunity against both viral and tumour challenge.Read moreRead less