The Role Of Apoptotic Caspases In Regulating Type I Interferon Production
Funder
National Health and Medical Research Council
Funding Amount
$791,746.00
Summary
Type I interferons (IFNs) are potent anti-viral cytokines. Dysregulated type I IFN responses result in major pathologies, e.g., embryonic lethality and defects in tissue homeostasis. We have identified a novel molecular mechanism regulating IFN production that relies on the host’s own apoptotic caspases. We hypothesize that apoptotic caspases critically regulate IFN responses during the process of cell death, with implications for tissue homeostasis and host responses to infection.
microRNAs (miRNAs) constitute a novel mechanism used by cells and viruses to regulate gene expression. Studies carried out in non-human primates demonstrated great potential for miRNA-inhibiting drugs as novel antiviral agents against hepatitis C virus infection. By characterising how miRNAs control the antiviral state, we will gain new insights into how miRNA-modulating drugs could present novel strategies to treat viral infections.
Respiratory Syncytial Virus Matrix Protein-Host Protein Interactions As Targets For Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$686,885.00
Summary
Respiratory syncytial virus (RSV) causes more deaths in winter than influenza, being the major cause of viral pneumonia in infants worldwide, and a potent lower respiratory pathogen in the elderly and immunosuppressed adults. The present proposal will apply a range of techniques to search for new inhibitors of viral infection which target host-virus interactions, as the first step towards new generation anti-viral agents to treat RSV infection.
Type I Interferon Signalling In Bacterial Infection
Funder
National Health and Medical Research Council
Funding Amount
$738,274.00
Summary
Infectious diseases are a leading cause of death in Australia. Activation of disease-fighting inflammasomes sets in motion rapid immune defenses against pathogens. In this project, we explore how cell-cell communication molecules known as type I interferons communicate with inflammasomes to achieve the best outcome in the body in response to deadly bacterial infection. Understanding how these signals communicate with one another could reveal new ways to fight infectious diseases.
Understanding Neuroinflammation In Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,043,216.00
Summary
This project opens a new line of enquiry into the cellular signalling mechanisms involved in the progression of AD and establishes whether targeting the involvement of type-1 IFN signalling influences the evolution of AD. New and novel approaches are clearly required to treat AD. Importantly, we believe that neuroinflammation is common to all causes of dementia and targeting the neuroinflammatory pathways has much wider implications than targeting the primary causative pathway.
Targeting Cancer-initiating Cells With DNA Methyltransferase Inhibitors: Single-cell Analysis To Decipher Molecular Mechanisms And Improve Efficacy.
Funder
National Health and Medical Research Council
Funding Amount
$175,000.00
Summary
Certain cancer cells, termed cancer-initiating cells (CICs), have special properties allowing them to drive cancer growth and disease progression. These cells are particularly sensitive to low-dose treatment with drugs called DNA methyltransferase inhibitors. Using cutting-edge "single-cell" technologies this project will determine how these drugs target CICs and identify new ways to increase treatment efficacy. This work will identify new clinical opportunities for prevention of cancer relapse.
Retargeting The Antibiotic Azithromycin As An Antimalarial With Dual Modality.
Funder
National Health and Medical Research Council
Funding Amount
$773,613.00
Summary
Malaria parasites resistant to first-line treatments continue to spread in South East Asia. New drugs need to be developed urgently to ensure alternative treatment strategies are available. We will retarget the safe and widely used antibiotic azithromycin as an antimalarial with dual modalities against parasite invasion and growth inside the host red blood cell. This strategy has significant potential to increase drug efficacy while reducing the chances for the development of resistance.
Understanding And Targeting Coenzyme A Biosynthesis And Utilisation In Plasmodium Falciparum.
Funder
National Health and Medical Research Council
Funding Amount
$556,114.00
Summary
This grant describes a series of studies designed to understand how the human malaria parasite P. falciparum metabolises vitamin B5, an essential molecule for the parasite. We will also carry out experiments to determine how a new series of vitamin B5 analogues we have developed kill the parasite and aim to start developing these compounds into new and much needed antimalarial medications.
Octapeptin-based Antibiotics Against Multi-drug Resistant Gram-negative Bacteria
Funder
National Health and Medical Research Council
Funding Amount
$767,504.00
Summary
Infectious disease is a leading cause of death, and the emergence of "superbugs" in the community and hospitals is of grave concern. We have resurrected a ‘forgotten’ antibiotic from the 1970s that kills superbugs causing pneumonia, skin and urinary track infections; diseases that cause death and discomfort for thousands of Australians today. We will determine how the original antibiotic works against superbugs, and use this information to design better drugs for the future.
The Structure And Function Of The Apical Domain In Insulin Secreting Beta Cells.
Funder
National Health and Medical Research Council
Funding Amount
$571,741.00
Summary
Loss of control of insulin secretion is causal in diabetes and therefore its understanding is a key goal to shed light on the disease. We have recently identified a new domain in the insulin secreting cells, called the apical domain. This proposal will define the role of this apical domain in controlling insulin secretion. The outcomes could provide new insights into how diabetes develops and new targets for therapies.