Protective memory T cell immune responses defend our body against pathogens by the rapid induction of killer T cells. This protects us from severe or perhaps even fatal disease. Our work will provide insights to how the body makes these potent ‘footsoldiers’. This work will have important implications for identifying how these immune cells can be manipulated to prevent and treat pathogenic and autoimmune disease and for optimising approaches to vaccination.
Transcriptional Regulation Of Specialized Subsets Of Dendritic Cells In Control Of Infection
Funder
National Health and Medical Research Council
Funding Amount
$616,912.00
Summary
Immune protection against viruses and bacteria depends on specialized cells called dendritic cells that display components of the invading organisms on their surface. There are multiple different types of dendritic cell and each population plays a specialized role in defending the body against infection. Our work will provide the framework for directly targeting these cells for novel vaccines to re-program the immune system for clinical conditions such as cancer, allergy and autoimmunity.
Functional Assays Of Immunity To Malaria In Pregnant Women
Funder
National Health and Medical Research Council
Funding Amount
$578,905.00
Summary
Pregnant women are highly susceptible to malaria due to the adhesion of infected erythrocytes to the placenta. Antibodies to these infected erythrocytes can block their placental adhesion and/or facilitate their clearance by immune cells, improving pregnancy outcomes. We aim at informing vaccine design by better understanding the placental adhesion mechanisms and identifying targets of protective immunity as well as antibody correlates of protection from placental malaria and its consequences.
RZR-alpha In The Control Of Proliferative Vascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$521,706.00
Summary
Four million Australians have cardiovascular disease accounting for 35% of all deaths. CVD is the most expensive disease burden and a National Health Priority. Smooth muscle cell growth is a cause of CVD. However, the mechanisms controlling SMC hyperplasia are poorly understood. This project will provide key insights on the role of RZR-alpha in the pathogenesis of blood vessel disease, and develop novel gene-targeting approaches for new opportunities to control complications of CVD.
Therapeutic Potential Of Transforming Growth Factor-beta Proteins For The Diagnosis And Treatment Of Female Infertility
Funder
National Health and Medical Research Council
Funding Amount
$942,961.00
Summary
We discovered and manufactured a growth factor produced uniquely by the egg. We named this growth factor cumulin. It is a powerful regulator of ovarian function and egg quality. This project will study the basic mechanisms of how cumulin works in the ovary. We will then develop an assay to measure it as a biomarker of human egg quality and quantity. New approaches in fertility preservation for cancer survivors will be developed using cumulin.
Mapping The TNF Pathway: A Qualitative And Quantative Molecular Analysis Of The Components And Post-translational Modifications Involved In Physiological And Pathological TNFR1 Signalling
Funder
National Health and Medical Research Council
Funding Amount
$636,258.00
Summary
TNF is a master regulator of the inflammation response and dysregulated TNF signalling causes many human diseases. We will use a cutting edge mass spectrometry technique that we have developed to analyse molecules required for TNF signalling. Understanding how the TNF signalling works in all cell types and with different forms of ligands will open up therapeutic opportunities to selectively target TNF signalling in inflammatory diseases, such as Rheumatoid Arthritis and Cancer.
Activation Of GDF9 Regulates Human Folliculogenesis
Funder
National Health and Medical Research Council
Funding Amount
$531,690.00
Summary
GDF9 is a key regulator of fertility in female mammals, as it controls the process of folliculogenesis. In this grant, we will demonstrate the importance of GDF9 in human folliculogenesis, determine the mechanisms that activate GDF9 and show why aberrant GDF9 activation leads to ovarian disorders. Collectively, the outcomes of this proposal will increase our understanding of the fundamental mechanisms that regulate ovarian folliculogenesis and provide new avenues to manipulate this process.
Characterising Signals Important For Lymphangiogenesis During Development And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$604,938.00
Summary
Lymphatic vessels are a vital component of the cardiovascular system. Abnormalities in the growth and development of lymphatic vessels are associated with human disorders including cancer, lymphoedema and inflammatory diseases. The focus of this application is to characterise signals that direct the construction of lymphatic vessels, with the aim of identifying targets to which novel therapeutics for the treatment of lymphatic vascular diseases could be generated.
We will investigate how the master control gene, Kruppel-like factor 1, orchestrates production of red blood cells. We will use genetic and cell biology approaches to determine exactly how this factor interprets the genome blueprint in a cell specific manner. We will also determine how mutations in KLF1 cause human diseases such as congenital dyserythropoietic anemia and hereditary persistence of fetal haemoglobin. This has implications for reactivation of HbF in adults with sickle cell disease.
Novel Transcription Factor Regulation Of Lymphatic Vascular Angiogenesis In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$831,568.00
Summary
Lymphatic vessels control tissue fluid drainage, inflammatory processes and cancer progression. We have used genetic approaches to discover an unexpected role for a family of factors (transcription factors) that regulate new lymphatic vessel formation. This project will investigate this biological function of these genes in detail in vascular formation. The project aims to generate important knowledge for vascular biology, vascular pathologies, cancer spread and future therapeutics.