Appropriate growth of organs is essential for life and can go awry in diseases such as cancer. A crucial regulator of organ size and cancer that I co-discovered is the Hippo pathway. I aim to understand how this pathway relays information and controls gene expression to regulate organ size, and its role in mesothelioma and other human cancers. A better understanding of Hippo’s role in organ growth and cancer will allow it to be targeted for therapeutic benefit in human diseases.
The Hippo Pathway, Neural Stem Cells And Brain Growth
Funder
National Health and Medical Research Council
Funding Amount
$363,137.00
Summary
During organism development, the brain grows to the right size without overgrowing. Neural stem cells are key regulators of brain size. We will define how the Hippo pathway crosstalks with nutrition-induced signals to control proliferation of neural stem cells and brain size. As well as producing important insights into normal growth, we will increase our understanding of brain diseases associated with aberrant brain growth, such as cancer.
Characterisation Of Two New Kinases In The Hippo Tumour Suppressor Pathway
Funder
National Health and Medical Research Council
Funding Amount
$550,602.00
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 Gish and Fray kinases control 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.
Wbp2, A New Regulator Of The Hippo Tumor Suppressor Pathway
Funder
National Health and Medical Research Council
Funding Amount
$585,860.00
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 a newly-identified Hippo pathway protein, Wbp2, functions to control growth. These studies will be performed in flies and confirmed in mammalian cells. Ultimately, 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 Mediators Of Bone Catch-up Growth
Funder
National Health and Medical Research Council
Funding Amount
$1,043,810.00
Summary
Musculoskeletal growth disorders cause significant suffering in children and impair new workforce generations before their working life starts. Despite this relevance, non-invasive methods to induce growth recovery of impaired bones are an unmet need, as we lack sufficient understanding of how this process works. To address this knowledge gap, we generated mouse models that will allow us to reveal foetal mediators of compensatory growth that could be reactivated postnatally to boost bone growth.
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.
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.
Defining The Molecular Regulation Of Muscle Stem Cell Action During Organ Growth
Funder
National Health and Medical Research Council
Funding Amount
$738,259.00
Summary
How do organs grow to develop a complex cellular structure. Organ growth needs a careful balance between cell commitment and stem cell self renewal to maintain tissue growth trajectories. How this balance is achieved at the cellular and molecular level remains unresolved for most organ systems. This application studies a specific stem cell pool within the zebrafish myotome and how it is used to drive organ growth.
Novel Methods For Promoting Organ Development And Growth
Funder
National Health and Medical Research Council
Funding Amount
$390,203.00
Summary
A revolutionary new therapy for treatment of growth restricted fetuses and premature babies is being developed through the administration of Colony Stimulating Factor (CSF-1). We have evidence that CSF-1 therapy can promote kidneys and lungs to continue development and maturation after birth. This exciting new finding allows for the application of CSF-1 therapy for both the treatment of premature babies and unborn babies with kidney defects.