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Regulation Of Secretion Of The Fungal Virulence Determinant, Phospholipase B
Funder
National Health and Medical Research Council
Funding Amount
$487,500.00
Summary
Serious systemic infections due to fungi have increased dramatically in the past few years, especially in people with poorly functioning immune systems. Treatment of these conditions is problematic because the few drugs which are available are not highly effective, and-or cause significant side-effects. Little is understood of how fungi cause disease, and this problem must be addressed if these infections are to be contained. We have discovered that the enzyme, phospholipase B (PLB), is secreted ....Serious systemic infections due to fungi have increased dramatically in the past few years, especially in people with poorly functioning immune systems. Treatment of these conditions is problematic because the few drugs which are available are not highly effective, and-or cause significant side-effects. Little is understood of how fungi cause disease, and this problem must be addressed if these infections are to be contained. We have discovered that the enzyme, phospholipase B (PLB), is secreted by the disease-causing fungus, Cryptococcus neoformans, and that it is important in enabling the fungus to invade the host's cells and spread around the body from the lungs to the brain, where it can cause meningoencephalitis. PLB is also produced by other disease-causing fungi. The mechanism of PLB secretion is completely unknown. In this project we aim to determine the pathways involved in PLB secretion with the intention of exploiting steps unique to pathogenic fungi, for the future design of new anti-fungal drugs.Read moreRead less
Development Of An Intracellular Tau-specific Antibody Therapeutic For The Treatment Of Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$410,378.00
Summary
The protein, tau, is a promising therapeutic target for the treatment of Alzheimer's disease and related dementia's. Targeting tau is a challenge, however, as it is mostly localised within brain cells and a therapeutic must therefore be able to cross multiple barriers to engage and neutralise tau. This project overcomes this hurdle by using virus' to deliver a tau-specific antibody gene across the multiple barriers where it can be produced by brain cells and target intracellular tau.
Dissecting The Central Organisation Of Cough Neural Networks
Funder
National Health and Medical Research Council
Funding Amount
$880,928.00
Summary
Cough is the most prevalent symptom of lung disease and the most common reason for people to seek medical advice. However, cough neural processes are poorly defined and as a result current cough therapies are largely ineffective making cough a significant unmet clinical problem. This project will novel viral strategies to dissect and manipulate cough neural pathways in the brain, providing insights into the neural processing of airway sensations and coughing.
Development Of Lentiviral Vectors For The Treatment Of X-linked Severe Combined Immunodeficiency (SCID-X1)
Funder
National Health and Medical Research Council
Funding Amount
$71,434.00
Summary
The first successful gene therapy clinical trial was reported in 2000 with the treatment of X-linked severe combined immunodeficiency (SCID-X1), commonly known as “bubble-boy” disease. The subsequent development of leukaemia in 3 of 11 patients has prompted the need to develop alternative vectors for gene delivery, such as HIV-1-based lentiviral vectors. This project will evaluate the efficacy and safety of lentiviral vectors in vivo, and hence their therapeutic potential for treating SCID-X1.
Hepatocellular Carcinoma: Understanding The Genotoxic Risks Of Liver-targeted Gene Therapy Using Recombinant AAV Vectors
Funder
National Health and Medical Research Council
Funding Amount
$891,639.00
Summary
Advances in gene transfer technology using an engineered virus known as AAV underpin success in the treatment of haemophila B, and offer the exciting prospect of treating many other liver diseases. While continued improvement of gene transfer efficiency is essential there is an equal need to focus on safety. We have discovered a genetic element in AAV that we believe is a key to unlocking accurate analysis of the safety of AAV-based gene transfer technology. Here we propose to turn the key.
Directed Evolution Of AAV Capsid Variants For Enhanced Targeted Genome Editing In The Human Liver
Funder
National Health and Medical Research Council
Funding Amount
$386,012.00
Summary
Liver transplantation is often the only treatment option available for patients with severe liver disease, and is complicated by a shortage of donor organs and the need for life-long drug therapy to prevent rejection. Repair of a patient’s own liver by gene therapy is a promising alternative. This project focuses on developing the technology required to undertake precise correction of genetic spelling errors in diseased liver cells without the need to first remove them from the body.
Mechanically-restricted Percutaneous Gene Therapeutic Solutions For Heart Failure.
Funder
National Health and Medical Research Council
Funding Amount
$187,000.00
Summary
We have developed a novel system for the localized delivery of specialised genes to the heart in order to improve contractility and function of a failing heart. Many genes, for reasons of toxicity, clearance, or uptake, require direct delivery to the target region without spillover to the systemic circulation. Our system addresses these issues by isolating the local circulation of the target organ and directly delivering the agent with minimal systemic loss and improved delivery and uptake effic ....We have developed a novel system for the localized delivery of specialised genes to the heart in order to improve contractility and function of a failing heart. Many genes, for reasons of toxicity, clearance, or uptake, require direct delivery to the target region without spillover to the systemic circulation. Our system addresses these issues by isolating the local circulation of the target organ and directly delivering the agent with minimal systemic loss and improved delivery and uptake efficiency, while minimizing potentially dangerous and toxic systemic effects.Read moreRead less
A New Scrambled Antigen Vaccine (SAVINE) Approach: Proof-of-concept In Non-human Primates For HIV-1
Funder
National Health and Medical Research Council
Funding Amount
$120,700.00
Summary
The specific aim of this proposal is to demonstrate, in non-human primates, proof–of-concept of a patented new platform vaccine technology (scrambled antigen vaccine or SAVINE) designed to encode all the protein sequences of an infectious agent, in this case HIV-1. These are arranged as equal-sized, overlapping fragments such that all potential T cell epitopes that are needed to induce broad T-cell-mediated immunity are maintained. The synthetically designed vaccine uses consensus sequences of H ....The specific aim of this proposal is to demonstrate, in non-human primates, proof–of-concept of a patented new platform vaccine technology (scrambled antigen vaccine or SAVINE) designed to encode all the protein sequences of an infectious agent, in this case HIV-1. These are arranged as equal-sized, overlapping fragments such that all potential T cell epitopes that are needed to induce broad T-cell-mediated immunity are maintained. The synthetically designed vaccine uses consensus sequences of HIV-1 to provide universal coverage of the major HIV-1 strains for a global population. The synthetic systematically designed HIV-1 vaccine will be delivered using our newly developed prime-boost immunisation regime that induces particularly high levels of cell-mediated immunity.Read moreRead less