Characterisation Of The Molecular Mechanisms Of Abeta-induced Proteolysis Of The Neural Cell Adhesion Molecule 2 (NCAM2)
Funder
National Health and Medical Research Council
Funding Amount
$374,666.00
Summary
Neurons in the brain are connected by synaptic contacts. Amyloid beta peptide accumulating in the brain in Alzheimer’s disease destroys synaptic contacts by degrading synaptic cell adhesion molecules which maintain the structure of the contacts. The aim of the project is to characterise the molecular mechanisms of amyloid beta-dependent degradation of synaptic cell adhesion molecules. The project will identify strategies that can be used to inhibit synapse loss in Alzheimer’s disease.
Understanding The Role Of DNMT1 SUMOylation In Acute Myeloid Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$639,290.00
Summary
Most cancers have abnormally high levels of DNA methylation, which turns off cell death genes, making cancer cells immortal. We have a new drug, called DNMT1i, that targets this feature of cancer cells and we recently found a new drug target that enhances the activity of DNMT1i. Our research will determine how these two drugs synergise to effectively kill cancer cells and will justify their use in clinical trials, which we believe will improve outcomes for patients with cancer.
In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, ....In this project we aim to define the role of the Siah proteins in tumour angiogenesis and inflammatory responses. Hypoxia, a decrease in oxygen tension, places constrains on tumour growth where access to oxygen is yet to be established via new blood vessel formation. In addition hypoxia is common in areas of inflammation and wound healing, where blood vessels have been shut down to help in recovery. With the use of our Siah knockout mice we have a unique model that allows us, for the first time, to investigate the role of Siah in the hypoxia signalling cascade. How cells sense and react to low oxygen levels is complex and involves several proteins. A key protein is called Hypoxia induced factor, Hif-1. It accumulates under hypoxia and is responsible for the expression of genes enabling the cell to tolerate and function under hypoxic conditions. tolerate and function under hypoxic conditions, which is involved in new blood vessel formation. PHD protein directs the degradation of Hif1, while Siah directs the degradation of PHD, when oxygen is limiting. Loss of Siah proteins (eg in our knockout models) leads to an increase in PHD proteins under hypoxia thus no stabilisation of Hif-1 and impaired response to hypoxia. Thus, sitting on the top of a cascade, which controls the trashing of proteins in the cell (focus of this year's Nobel price for medicine), Siah has primary control on the response to oxygen deprivation. The relative immunity of multicellular organisms to acquired defects is through redundancy. Oxygen is a unique case, for which organisms can not bypass the defect via redundancy, making it an attractive target for future therapy. Therefore, understanding the molecular and cellular response to hypoxia may allow us to identify key molecules which could be targeted for the development of novel anti inflammatory and cancer drugs. The scope of this study is to understand the key role of Siah utilising our knockout mice in models of inflammation and cancer.Read moreRead less
Exploring The Role Of Arrcd4 In Extracellular Vesicle Biogenesis And Its Implications In Tissue Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$678,742.00
Summary
Most cells in the body release small packages known as extracellular vesicles (or EVs in short), which carry proteins and other cellular material. EVs transport important cellular messages required for the everyday function of cells and play crucial roles both in normal wellbeing and disease. This proposal will investigate how EVs are formed, how they select their protein content and how they contribute to the maturation of some cell types in the body.