In a human body, about a million cells are born every second, and a million die by activating a physiological cell death mechanism. If cell death fails to occur, cells accumulate and can develop into cancers. Determining the mechanism and regulation of physiological cell death will provide novel approaches to treat cancers and auto-immune diseases, both of which are characterised by failure of certain cells to die.
Regulation And Mechanisms Of Cell Cycling, Cell Senescence And Cell Death
Funder
National Health and Medical Research Council
Funding Amount
$876,005.00
Summary
Most of our cells are not dividing, but persist in a stable arrested state, yet little is known of the molecular mechanisms that regulate and maintain permanent arrest, or that go wrong when cells start proliferating and turn into cancers. This proposal addresses an area of fundamental, basic biology, that has been largely overlooked. A better understanding of the molecules that regulate cell stability might provide new drug targets so that tumour cell proliferation can be stopped.
Exploring The Inflammatory Signature Of The Anti-cancer Smac-mimetic, Birinapant, And The Contribution Of This Signature To Birinapant Anti-Tumour Activity
Funder
National Health and Medical Research Council
Funding Amount
$192,322.00
Summary
Programmed cell death (PCD) is an essential process for the removal of cancer cells. Defects in PCD are now known to be a causal factor in cancer initiation and chemotherapeutic resistance. Proteins called IAPs protect cancer cells from PCD, however, inhibitors of IAPs have been developed to kill cancer cells in this respect. Indeed, IAP inhibitors can also promote inflammation, which may improve or hamper their efficacy in killing cancer cells, an issue we now wish to explore and exploit.
Hormone-dependent Autophagy And Growth Signalling In Developmental Cell Death
Funder
National Health and Medical Research Council
Funding Amount
$613,447.00
Summary
Cell death is essential for cell and tissue homeostasis and its dysregulation is associated with many diseases. We discovered a new mode of cell death that involves autophagy. We have now identified that TGF-? signalling pathway, which has roles in numerous human pathologies, is involved in autophagy-dependent cell death. Our proposed studies will further characterise this important signalling axis and study its significance in development, normal physiology and 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.
Understanding The Biological Regulation Of MLKL And Its Role In Necroptotic Cell Death
Funder
National Health and Medical Research Council
Funding Amount
$656,979.00
Summary
Cell death is a normal process that permits the growth and defence of our vital tissues. One kind of cell death, necroptosis, is characterized by the swelling and bursting of cells. When cells ‘explode’ in this uncontrolled way they provoke an inflammatory response. This may be a factor behind illnesses ranging from colitis to cardiovascular disease. Understanding necroptotic cell death may pave the way for new therapies for those that suffer from these devastating conditions.
A New Signaling Interface Shapes Cystic Kidney Disease
Funder
National Health and Medical Research Council
Funding Amount
$586,846.00
Summary
This grant investigates the previously uncharacterised association between the INPP5E and AURKA proteins. Both are involved in cell signaling and the development of cystic kidney disease. We will study the nature of this interaction and investigate whether it is possible to ameliorate kidney disease by inhibiting their actions in the developing and adult kidney.
The Hippo pathway is a key regulator of tissue growth. It was first discovered in vinegar flies and plays a similar role in mammals. We aim to define the mechanism by which the different transcription factors in the Hippo pathway operate to control tissue growth. These studies will be performed in flies and mammalian cell culture. Our studies will shed light on how tissue growth is controlled, and have the potential to inform the way that we treat human cancers and tissue growth disorders.
Identification Of Novel Tumour Suppressors In Ras-mediated Tumourigenesis
Funder
National Health and Medical Research Council
Funding Amount
$580,504.00
Summary
Cancer is a cooperative process, involving mutations in several genes. Activation of the signaling protein, Ras, contributes to ~30% of human cancers, but alone is not sufficient for tumour formation. The identification of cooperating Tumour Suppressors (TSs), and their analysis in the vinegar fly, Drosophila, mammalian cells and mouse models is key to understanding cancer progression and for the development of therapeutic regimes
Mechanisms For Regulation Of Myc Transcription And Cell Growth
Funder
National Health and Medical Research Council
Funding Amount
$645,347.00
Summary
We aim to use the animal model system, the vinegar fly, to investigate mechanism for cancer initiation. The fly has been studied for over 90 years and has proved an excellent genetic model for understanding the complex processes leading to abnormal cell growth, which is associated with the early stages of human cancer. The high level of conservation between fly genes and human cancer genes means these studies will provide novel insights into the genetic mechanisms underlying tumour formation.