Cell-cell fusion is critical for the development and transport capacity of the placenta during pregnancy. Impairments in this process occur in pregnancy complications such as preeclampsia (PE). We have identified a novel pathway (LY6E) regulating placental cell-cell fusion which is also dysregulated in human pregnancies complicated by PE. In the current proposal we will investigate the mechanisms by which LY6E mediates cell-cell fusion and examine its role in the development of PE.
Dissecting A Serial Killer: Investigating The Degranulation Pathways In Cytotoxic Lymphocytes
Funder
National Health and Medical Research Council
Funding Amount
$604,459.00
Summary
When cells of the human body become cancerous or infected with virus, the body's immune system engages cytotoxic lymphocytes, known as "killer cells", that secrete an auxiliary of toxic proteins to eliminate these cells. The aim of this study is to investigate the mechanisms by which these critical immune cells accomplish this task. Importantly, humans who are genetically lacking in critical constituents of the cytotoxic lymphocyte are less able to fight off a viral infection and may be at a hig ....When cells of the human body become cancerous or infected with virus, the body's immune system engages cytotoxic lymphocytes, known as "killer cells", that secrete an auxiliary of toxic proteins to eliminate these cells. The aim of this study is to investigate the mechanisms by which these critical immune cells accomplish this task. Importantly, humans who are genetically lacking in critical constituents of the cytotoxic lymphocyte are less able to fight off a viral infection and may be at a higher risk of developing cancer.Read moreRead less
Cytoskeletal Remodeling Of The Erythrocyte During Malaria Parasite Invasion
Funder
National Health and Medical Research Council
Funding Amount
$559,807.00
Summary
Malaria parasites cause profound human disease through infection of the red blood cell. How parasites break into the red cell is incompletely understood. Foremost, the parasite must induce radical changes in its structural integrity to enter, but to date no study has been able to precisely map these cellular events. In this research program we aim to dissect the entire process using state-of-the-art imaging, molecular biology and proteomics to shine new light on this key step in malaria disease ....Malaria parasites cause profound human disease through infection of the red blood cell. How parasites break into the red cell is incompletely understood. Foremost, the parasite must induce radical changes in its structural integrity to enter, but to date no study has been able to precisely map these cellular events. In this research program we aim to dissect the entire process using state-of-the-art imaging, molecular biology and proteomics to shine new light on this key step in malaria disease establishment.Read moreRead less
Histone Demethylase KDM6A Is A Novel Target For Treating Craniosynostosis In Children With Saethre-Chotzen Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$548,854.00
Summary
Children with Saethre-Chotzen syndrome exhibit premature fused coronal sutures, and other skull/ skeletal malformations. Surgical intervention is the only treatment option to ensure optimal cognitive and skeletal development. Our studies have identified a candidate molecular pathway that regulates bone formation by cranial bone cells from these patients. Targeting this key molecular regulator with chemical inhibitors will help prevent the premature fusion of cranial sutures.
Tyrosine Kinase Receptor C-ros-oncogene 1 Mediates Twist-1 Haploinsufficiency Induced Craniosynostosis In Children: A Novel Therapeutic Target
Funder
National Health and Medical Research Council
Funding Amount
$562,863.00
Summary
Children with Saethre-Chotzen syndrome exhibit premature fussed coronal sutures, and other skull/ skeletal malformations. Surgical intervention is the only treatment option to ensure optimal cognitive and skeletal development. Our studies have identified a candidate molecular pathway that regulates bone formation by cranial bone cells from these patients. Targeting these key molecular signalling components with chemical inhibitors will help prevent the premature fusion of cranial sutures.
The neuronal synapse is very tightly regulated by proteins that control both the timing and the amount of neurotransmitter release and neuronal stimulation. Defects in this synaptic signal are linked to diseases including epilepsy, autism and dementia. In this study we will determine the molecular details of how proteins called SNAREs control neurotransmission in the human brain.
Virus Vaccines That Ensure Preparedness Against Future Public Health Emergencies
Funder
National Health and Medical Research Council
Funding Amount
$862,061.00
Summary
In this proposal, we will utilize novel technology we have developed (the molecular clamp) to generate candidate subunit vaccines and therapeutic antibody treatments against four highly pathogenic viruses identified by the World Health Organization as requiring urgent R&D to prepare for future epidemics; Ebola virus, Middle East Respiratory Coronavirus, Nipah virus and Lassa fever virus. Resulting vaccines are expected to provide advantages including safety, efficacy, and thermal stability.
Activation Of The Respiratory Syncytial Virus Fusion Protein
Funder
National Health and Medical Research Council
Funding Amount
$582,072.00
Summary
Respiratory Syncytial Virus (RSV) is the most important viral cause of respiratory tract disease in both infants and the elderly. However, there are few available options for control, whether by vaccination or therapeutic intervention. This proposal investigates the way RSV infects cells. A clearer understanding of the molecular basis of this process should provide potential targets for new drugs that can block this process and new insights for the generation of vaccine candidates.
Dysferlinopathy: A Genetic Disease Sheds Light On Membrane Repair For Muscle And Cardiac Injury
Funder
National Health and Medical Research Council
Funding Amount
$782,806.00
Summary
Muscles are damaged all of the time, as we stretch and contract them, but we don't fully understand how they repair themselves. We are studying the molecular steps taken by a muscle cell to repair membrane damage. Our research will provide valuable insights into how to treat muscular dystrophy and other conditions characterised by membrane damage to cells, such as heart attack and stroke.
Mitochondria are both the powerhouses and the poison cupboard of our cells. They have evolved from bacteria and still possess the ability to grow and divide. Unregulated mitochondrial division is seen in dying cells and in cells from patients with neurodegenerative diseases. We have identified new molecules involved in mitochondrial division and are investigating how they function in normal and unhealthy cells.