GTPase Regulation Of The Hippo Organ Size-control Pathway
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
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 two proteins, Pix and Git, control tissue growth by regulating the Hippo pathway. These studies will be performed in flies. 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.
Tao Kinase, A New Member Of The Hippo Tumour Suppressor Pathway
Funder
National Health and Medical Research Council
Funding Amount
$605,190.00
Summary
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 Tao kinase controls tissue growth by regulating the Hippo pathway. 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.
Stem cell to differentiation occurs in a bi-directional fashion. Dedifferentiation which allows specialized cells to become stem cells has been found to be important in both cancer and regeneration. In this proposal, we will investigate the metabolic reprogramming of neuronal dedifferentiation. The findings from this study will better inform us on how to specifically target tumours that arise from dedifferentiation.
Mammalian cells have developed a complex signalling network responsible for monitoring and responding to changes in the levels of growth factors and the availability of nutrients, energy and oxygen in their environment. Deregulation of this network often results in uncontrolled cell growth and diseases including cardiac hypertrophy and cancer. This proposal aims to understand how this network controls cell growth and identify potential targets for diseases driven by uncontrolled growth.
Targeting Homeobox Genes In Acute Myeloid Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$658,739.00
Summary
Acute myeloid leukaemia (AML) is a common blood cancer with dire clinical prognosis due to a lack of targeted molecular therapies. In this proposal we will identify new ways of targeting transcription factor proteins that are overexpressed in AML and promote leukaemia by repressing normal cellular growth controls. This may lead to novel methods to target leukaemic stem cells to specifically eliminate myeloid leukemia
Constitutive Activation Of The Growth Hormone Receptor
Funder
National Health and Medical Research Council
Funding Amount
$566,277.00
Summary
Growth hormone regulates growth, metabolism, bone, stem cells and longevity, and cancer. These actions are mediated by the GH receptor, and here we seek to understand how it is activated by the hormone through receptor constructs which are active without hormone, to different degrees. We will use these to elucidate its signaling properties, its ability to promote cancer, to grow muscle, and whether cases of giantism and cancer are a consequence of the activating mutations we have identified.
A major feature of tumour progression and cardiac hypertrophy (enlarged heart) is accelerated cell growth and protein synthesis. Moreover, increased synthesis of ribosomes (the protein synthetic machinery) is associated with malignancy and hypertrophy suggesting that it may play a causal role in tumour formation and cardiac disease. In support of this, specific inhibitors of both ribosome biogenesis and function are extremely effective at inhibiting the growth of some tumours and vascular smooth ....A major feature of tumour progression and cardiac hypertrophy (enlarged heart) is accelerated cell growth and protein synthesis. Moreover, increased synthesis of ribosomes (the protein synthetic machinery) is associated with malignancy and hypertrophy suggesting that it may play a causal role in tumour formation and cardiac disease. In support of this, specific inhibitors of both ribosome biogenesis and function are extremely effective at inhibiting the growth of some tumours and vascular smooth muscle. This study will examine the mechanisms that regulate ribosome synthesis. Specifically it focuses on a transcription factor termed UBF whose activity we think is critical for the regulation of the synthesis of the ribosomal RNA, the catalytic backbone of the ribosomes. Understanding the molecular mechanism(s) controlling UBF function will lead to a better comprehension of how cells modulate synthesis of functional ribosomes and how this process is deregulated during disease states associated with deregulated protein synthesis and growth such as cardiac hypertrophy and cancer.Read moreRead less