Organisation Of The Genome During The Development Of Antibody-secreting Cells
Funder
National Health and Medical Research Council
Funding Amount
$886,155.00
Summary
Each cell of our body contains over two metres of DNA that must be correctly packaged in order for our cells to function. We are using cutting-edge molecular biology techniques to study how this DNA circuitry is established in the white blood cells of our immune system that produce antibodies. Our novel approaches will reveal unique strategies to modulate immune responses to our benefit.
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.
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.
Growth Factor Directed Developmental And Pathological Lymphangiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$1,048,507.00
Summary
The formation of new lymphatic vessels occurs in normal development and in diseased tissues in cancer and cardiovascular disease. We have developed an understanding of how lymphatics form in development but we understand far less about how they form in disease. This project will apply multidisciplinary approaches, including genetics and computational biology, to compare how lymphatics form in development and disease. We hope to uncover new ways to manipulate this process for therapeutic gain.
Tolerising Antigen-specific Immunotherapy For Type 1 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$1,395,549.00
Summary
We have developed a new immunotherapy to treat the underlying causes of type 1 diabetes (T1D) while leaving the rest of the immune system intact. To use this in patients, we need better tests to know when immune therapy is working. We will develop new methods to design the therapy and tools to track the relevant immune cells in T1D that work in variable patient groups. The knowledge gained will speed the pace of development and increase the chance of success of immunotherapy in T1D.
Identifying An Autism Gene Network Governing Stem Cell Division, Neurogenesis And Cortical Malformation
Funder
National Health and Medical Research Council
Funding Amount
$1,003,589.00
Summary
Failure to produce neural stem cells and new neurons in the embryonic cortex results in cortical malformations and autism, and thus has profound consequences for the individual's survival and quality of life. Here we explore how a unique network of autism proteins maintains stem cell activity and neuronal production, thereby ensuring the fidelity of cortical development.
Targeting Inflammatory Skin Disease Using An Immune-modulatory Human Signal Peptide
Funder
National Health and Medical Research Council
Funding Amount
$698,836.00
Summary
Effective drugs are desperately needed for the improved treatment of inflammatory diseases. We will determine how a modified human peptide, which we have discovered and can make, works to suppress harmful skin inflammation. We will design new formulations to deliver our drug to the skin in order to better treat psoriasis, an autoinflammatory skin disease. We will also trial our new drug in models of atopic dermatitis a debilitating skin disease for which there is limited treatment options.
Exploiting Anti-capsid Humoral Immunity Induced In Infants Receiving Gene Therapy For Spinal Muscular Atrophy To Engineer The Next Generation Of Gene Transfer Vectors
Funder
National Health and Medical Research Council
Funding Amount
$1,105,993.00
Summary
After 25 years of incremental progress the possibility of treating genetic disease by gene therapy has become a therapeutic reality. This has been achieved by harnessing the gene transfer power of viruses made harmless by genetic engineering. A major limitation is that up to 50% of patients are currently excluded by pre-existing immunity to these powerful tools. Using 'evolution in a dish', we will engineer a new generation of these tools capable of bypassing pre-existing immunity by stealth.
Antibiotic Conjugates: Joining Together To Fight Antimicrobial Resistance
Funder
National Health and Medical Research Council
Funding Amount
$697,675.00
Summary
New strategies are urgently needed to treat the rise of infections from multidrug-resistant bacteria, with standard antibiotic therapies becoming obsolete. This project will develop multiple innovative approaches to overcome antibiotic resistance, based on a core concept of appending additional functionality to existing antibiotic scaffolds. New conjugates will be synthesized, tested for antimicrobial activity, then optimized via a validated antimicrobial development pipeline.
Immunomodulatory Vaccines In The Treatment Of Peanut Allergy
Funder
National Health and Medical Research Council
Funding Amount
$678,899.00
Summary
Peanut allergy is the most common cause of food-induced anaphylactic reactions in Australia and is a major burden to our healthcare system. Current clinical practice advice dietary avoidance to prevent fatal anaphylactic responses. We propose the use of an immunomodulatory vaccine to re-write the immune response to peanut antigens, from an allergic to a tolerant phenotype. This study will provide novel insights into rational approaches for manipulating immune memory to food allergens.