Alternate Signalling Pathways Regulating The Human Arachidonate Epoxygenase CYP2J2 In Response To Stress Stimuli
Funder
National Health and Medical Research Council
Funding Amount
$369,000.00
Summary
Hypoxia, or oxygen deprivation, is caused by the decreased supply of blood to cells and is a component of ischaemic injury to the cardiovascular system (e.g. stroke, atherosclerosis) and numerous other organs (e.g. cancer and chemical mediated injury). It is now known that an important group of proteins that switch on specialised target genes in response to hypoxia is Activator-Protein-1 (AP-1). We have found that cytochrome P450 2J2 (CYP2J2), which is an enzyme that forms beneficial fatty acid ....Hypoxia, or oxygen deprivation, is caused by the decreased supply of blood to cells and is a component of ischaemic injury to the cardiovascular system (e.g. stroke, atherosclerosis) and numerous other organs (e.g. cancer and chemical mediated injury). It is now known that an important group of proteins that switch on specialised target genes in response to hypoxia is Activator-Protein-1 (AP-1). We have found that cytochrome P450 2J2 (CYP2J2), which is an enzyme that forms beneficial fatty acid products inside cells, is decreased in hypoxia and that this is due to increased activity of AP-1. We know that similar stressful stimuli can also result in a loss of CYP2J2. Again, AP-1 is involved but we have further evidence for the role of another pathway. This project will explore how these pathways operate individually and together to decrease CYP2J2. Studying the regulation of human genes is difficult because we can not readily monitor their levels in cells in either healthy or sick individuals. So we will make transgenic mouse models to study human CYP2J2 regulation, which will provide information on the human situation. In this project we will identify which factors switch off the CYP2J2 transgene and will analyse the signalling pathways within cells that control this response. The importance of these studies is that they will help us to design pharmacological strategies to prevent the loss of CYP2J2 in cells that are stressed. Such agents may be effective in the treatment of ischaemic injury seen in stroke and atherosclerosis. If we can maintain CYP2J2 levels we may be able to maintain the beneficial fatty acid levels in cells and have a novel therapeutic approach for keeping cells alive.Read moreRead less
Neurons are highly compartmentalized cell-types. In neurodegenerative diseases such as Alzheimer's disease, the protein Tau that serves a distinct function in one cellular compartment (the axon) accumulates in a massively phosphorylated form elsewhere (somatodendritic compartments and their spines) which is believed to impair neuronal functions. We will investigate how Tau is distributed in health and disease, and determine how this distribution is regulated.
Site-specific Tau Phosphorylation To Treat And Understand Alzheimer’s Disease
Funder
National Health and Medical Research Council
Funding Amount
$943,902.00
Summary
Alzheimer’s disease (AD) is the most common form of dementia. Unfortunately, current therapies are ineffective. Our laboratory has made an important contribution to understanding the events that lead to brain cell malfunction in AD. I recently found a novel concept that changes the view of AD completely. In the next 3 years, I aim to develop therapeutic tools based on this novel concept and find out more about how it can protect brains from AD.
Melanoma Resistance To Combination BRAF And MEK Inhibition Is Driven By Reprogramming Of MAPK Signaling
Funder
National Health and Medical Research Council
Funding Amount
$745,082.00
Summary
Until recently, patients with metastatic melanoma were treated with single agent chemotherapy drugs that produce response rates of less than 10%. New drugs targeting the mitogen activated protein kinase (MAPK) pathway have now shown significant activity, but nearly all patients treated with these new inhibitors eventually develop resistance and progress. This project utilises patient tumour samples to examine the mechanisms of resistance and ways of enhancing the targeted inhibition of the MAPK ....Until recently, patients with metastatic melanoma were treated with single agent chemotherapy drugs that produce response rates of less than 10%. New drugs targeting the mitogen activated protein kinase (MAPK) pathway have now shown significant activity, but nearly all patients treated with these new inhibitors eventually develop resistance and progress. This project utilises patient tumour samples to examine the mechanisms of resistance and ways of enhancing the targeted inhibition of the MAPK signaling cascade.Read moreRead less
New drugs targeting the immune system have dramatically improved the survival of melanoma patients. Nevertheless, 30-40% of patients responding to these new inhibitor will develop drug resistance. This project utilizes patient tumour samples to examine the mechanisms of acquired resistance to immune checkpoint inhibitors. This information will accelerate the identification of novel combination therapies to improve patient outcomes.
Manipulating Oncogene Addiction And Immunity In The Treatment Of Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$687,975.00
Summary
Melanoma is a major Australian health problem and a common cause of cancer death in young adults. Treatment of melanoma has been revolutionised in the last few years, but many patients fail to respond to new therapies or rapidly progress on treatment. This proposal examines the mechanisms that drive resistance to therapy and identifies markers predictive of clinical response. This approach will accelerate the development of new strategies and improve patient care by personalising treatment.