Investigate The Role For Dok Adapter Proteins In Thrombosis And Haemostasis.
Funder
National Health and Medical Research Council
Funding Amount
$161,737.00
Summary
Blood platelets play a key role in blood clot formation, prevention of bleeding and are the principal elements contributing to thrombosis leading to heart attack and stroke. Numerous studies have defined pathways promoting platelet activity, however less is known about their negative regulation. In this fellowship I will examine the role for proteins, Dok2 and Dok1, in the negative regulation of platelets, hoping this leads to development of novel therapeutics for prevention of cardiac disease.
Investigating B Cell Development, Maintenance And High-affinity Antibody Production By ENU Mutagenesis
Funder
National Health and Medical Research Council
Funding Amount
$408,388.00
Summary
B cells are essential for the protection against infections. This application aims to identify new genes that are crucial for the development or function of B cells and will investigate how mutations in newly discovered genes contribute to defects in the development and function of B cells and the pathogenesis of B cell leukaemia.
How Sweet It Is: Diagnostic Clinical And Experimental Glycoproteomics
Funder
National Health and Medical Research Council
Funding Amount
$473,477.00
Summary
Most human proteins are modified by the addition of complex sugar groups, which are important for the correct function of these key biological molecules. This fellowship will develop a suite of robust mass spectrometry glycoproteomic analytics for use in conjunction with clinical cohorts, model systems and in vitro biochemistry to investigate fundamental aspects controlling N-glycosylation in disease and translation to clinical diagnostics.
The pathology of many acute and chronic diseases associated with the inappropriate activation of genetically encoded programmed cell death pathways, such as sepsis, stroke, diabetes and neurodegeneration, is linked to detrimental inflammation. This project will accurately define at the molecular level how programmed cell death triggers inflammatory responses, and use this knowledge to test novel and next-generation therapeutic strategies in inflammatory-driven diseases.
Defining The Mechanisms That Control Exocytosis And Cell Signalling In Health And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$473,477.00
Summary
This research focuses on pathways regulating nervous communication and hormone release. It centres on proteins that regulate this process and on the function of specific endocrine cells in health and disease. It uses unique research tools developed in this laboratory enabling the study of mechanisms regulating cell signalling. Through this research I aim to identify how the cells in our body communicate with each other and how this relates to diseases such as type 2 diabetes.
Understanding Allosteric Modulation And Biased Signalling At Family B GPCRs
Funder
National Health and Medical Research Council
Funding Amount
$428,065.00
Summary
Family B GPCRs are therapeutic targets for drugs treating osteoporosis, hypercalcaemia, Paget’s disease, type II diabetes and are being actively pursued for other diseases that represent major global health burdens. Despite huge financial input, there are no orally available drugs that act on these receptors. This speaks to a lack of mechanistic understanding of how they work. My research focuses on addressing this question and how to exploit these receptors to design and identify better drugs.
The Molecular Mechanisms Of Abscission To Complete Cytokinesis
Funder
National Health and Medical Research Council
Funding Amount
$380,558.00
Summary
Cytokinesis is the final stage of cell division that produces two daughter cells. Incorrect localisation and modification of proteins that regulate this process cause cell division errors potentially leading to cancer. This project will characterise how key cytokinesis proteins co-operatively function to complete cytokinesis. This research will increase our understanding of the cell division errors that contribute to cancer development, ultimately identifying new targets for cancer therapy.
During injury or infection, our body’s immune system protects us by launching inflammation. But uncontrolled inflammation drives common diseases such as cancer, diabetes, Alzheimer’s and Parkinson's. This research program will reveal how the body deactivates inflammasomes – protein complexes at the heart of inflammation and disease – so we can design better drugs for treating patients with inflammation-driven disease.
Cell death is a normal process that permits the growth and defense of our vital tissues. One kind of cell death, necroptosis, is characterised by the swelling and bursting of cells, triggering inflammation. Necroptosis is a key feature of illnesses ranging from colitis to arthritis, and contributes to the brain and heart damage that follows strokes and heart attacks. Understanding necroptotic cell death will pave the way for new therapies for those who suffer from these devastating conditions.
Identification Of Novel Targeted Therapies For JAK2-driven Leukemogenesis
Funder
National Health and Medical Research Council
Funding Amount
$392,717.00
Summary
Many leukemias are caused by particular signalling molecules becoming too active in blood cells. My research focusses on the molecules that are required by leukemic cells for their growth and survival. I will use mice that are prone to developing leukemia to study how these leukemias can be treated with drugs that block specific molecules. My goal is to discover new ways to treat leukemias that work better and have fewer side effects than current treatments.