Influenza A Viral Infection And Pregnancy Complications
Funder
National Health and Medical Research Council
Funding Amount
$1,346,858.00
Summary
Pregnant women who contract influenza are 5 times more likely to be hospitalised than the general population. Babies of mothers with influenza are also associated with increased perinatal mortality rates. We hypothesise that influenza infection in pregnancy significantly impairs the maternal vascular system resulting in maternal and foetal morbidity. Outcomes from this research may change current treatment modalities to improve maternal and foetal outcomes complicated by influenza infection.
A Novel Interaction Between The Immune And Vascular Systems In Early-onset Preeclampsia; An Opportunity For New Treatments?
Funder
National Health and Medical Research Council
Funding Amount
$921,623.00
Summary
Preeclampsia is a pregnancy complication that leads to poor birth outcomes and elevated lifelong cardiovascular disease risk in 4 million women each year. It has no cure and treatments are limited because the causal mechanisms are not understood. We have identified a specialised immune cell in the mother's blood that assists blood vessels to function properly in pregnancy. We will assess whether interventions to enhance these cells can improve poor blood vessel function and pregnancy outcomes.
Identification Of Novel Mediators Of Bone Catch-up Growth
Funder
National Health and Medical Research Council
Funding Amount
$1,043,810.00
Summary
Musculoskeletal growth disorders cause significant suffering in children and impair new workforce generations before their working life starts. Despite this relevance, non-invasive methods to induce growth recovery of impaired bones are an unmet need, as we lack sufficient understanding of how this process works. To address this knowledge gap, we generated mouse models that will allow us to reveal foetal mediators of compensatory growth that could be reactivated postnatally to boost bone growth.
A New Mechanism Of Tissue Fibrosis - A Small Peptide Regulator Of The TGF-beta1/Smad Pathway
Funder
National Health and Medical Research Council
Funding Amount
$768,757.00
Summary
Progressive scarring, or fibrosis, of organs leads to their loss of function. Fibrotic diseases are devastating to both the individual and our community and we lack effective therapies. We have identified a small protein, named SPRF, which represents a new mechanism in tissue fibrosis. These studies will examine the role of the SRPF protein in models of kidney, heart and lung fibrosis and its underlying mechanism of action. We will also test a therapy based on inhibiting SPRF function.
Investigating The Consequences Of Dysregulated Lipogenesis In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$600,647.00
Summary
Reprogramming of cellular metabolism is a hallmark of cancer. As such, there has been growing interest in developing strategies to exploit metabolism for therapeutic gain. Our ability to do this is dependent on a thorough understanding of the mechanisms by which dysregulation of cellular metabolism contributes to tumour progression. In this project, we seek to the investigate the fundamental mechanisms by which aberrant activation of lipid metabolism contributes to the tumourigenic process.
Reprogramming Human Fibroblasts Into Induced Trophoblast Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$889,064.00
Summary
We have been able to generate artificial human trophectoderm which is the tissue that creates the placenta. This will allow us to do research in how the genes control the fate of these cells without the need of human embryos or placenta. We anticipate that the derivation and characterising these cells will revolutionise placenta research, which in turn will contribute to the establishment of new therapies for placenta disease and infertility.
Advancing The Spatial Analysis Of Cells In Tissues To Profile The Tumour Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$187,918.00
Summary
Tumours are composed of a mix of different cells, including cancer cells, immune cells and other cells supporting tumour growth. These cells are not organised randomly, but rather are distributed in specific patterns. Here we will develop computational methods to detect these patterns and determine what statistical tests should be used to compare samples. This project will give us the tools to investigate how the location of cells in tissues relates to treatment response and survival.
Stopping Breast Cancer Progression By Targeting Tumour Stroma
Funder
National Health and Medical Research Council
Funding Amount
$772,877.00
Summary
Our latest research demonstrated that CRELD2 protein that is secreted by breast cancer cells alters normal cells surrounding tumour. CRELD2 represents an ideal therapeutic target as it is not important for normal cells and it is a secreted protein and thus can be targeted by numerous means. Successful completion of this research proposal will provide foundation to find new targets for combining therapies affecting both tumour and it's altered environment in breast and potentially other cancers.
Understanding The Molecular Mechanisms Of Cell Death In Radiotherapy
Funder
National Health and Medical Research Council
Funding Amount
$643,856.00
Summary
Radiotherapy (RT) is responsible for 40% of cancer cures. New technology enables RT delivery in fewer treatments using higher radiation dosages through a technique called 'ART'. While ART is effective in the clinic, the underlying mechanisms of cancer cell death are unclear. Here we show that ART induces two distinct waves of cancer cell death. We will characterize these waves of cell death and determine how to enhance tumour cell killing with pharmacological intervention.
Dendritic Cells Govern The Balance Between Immunity And Homeostasis To Inhaled Antigen
Funder
National Health and Medical Research Council
Funding Amount
$816,131.00
Summary
The development of better intranasal vaccines hinges on the improved understanding of how the immune response is initiated following vaccine delivery into the upper airways. In this project we will provide fundamental understanding of how immune responses to inhaled antigens are regulated; this considerable conceptual advance will lay the foundation for which new intranasally delivered immunotherapies will ultimately emerge.