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.
Elucidating The Tumour Suppressor Behaviour Of FUBP1 In Glioma
Funder
National Health and Medical Research Council
Funding Amount
$940,780.00
Summary
Treatment strategies for patients with invasive brain tumours are based on a WHO tumour grading system. This system does not account for differences within tumour types, although these can significantly affect treatment outcomes. This project aims to investigate new drug therapies for specific brain tumour types, and to identify new prognostic markers for these tumours. These studies will lead to more individualised treatments, which is critical to improving patient survival and quality of life.
Targeting Chromosomal Instability By Metabolic Stress
Funder
National Health and Medical Research Council
Funding Amount
$612,652.00
Summary
The most intractable cancers gain and lose DNA as they grow, making them highly variable and drug resistant. We have found that mild disruptions to their use of energy can specifically kill cells with this kind of genetic instability. In this project we will characterize the mechanism by which metabolic stress affects cell division and the survival of genetically unstable cells. Our objective is to find treatments with no effects on normal cells that eliminate unstably dividing cancer cells.
Regulation Of Cell Proliferation By The Actin Cytoskeleton
Funder
National Health and Medical Research Council
Funding Amount
$607,795.00
Summary
The architecture of cells defines both their shape and function. It has been known for a long time that cell architecture controls the growth of cells and in particular their capacity to proliferate. We have identified part of the architectural system which controls this process. In this project we will establish how this works and its role in the body. This research will test whether this part of the cell�s architecture is a suitable drug target for the treatment of disorders in cell growth.
Role of suppressor of cytokine signalling proteins (SOCS3) in defective muscle repair and ageing. Old muscles are slower and weaker than young muscles, they are injured more easily and they repair less successfully. This proposal investigates the role of SOCS3-signalling in muscle repair, ultimately to improve healing and to promote healthy ageing that will enable older Australians to enjoy a better quality of life.
Developing Cancer Therapies That Target Chromosomal Instability
Funder
National Health and Medical Research Council
Funding Amount
$644,126.00
Summary
A significant reason why late-stage cancers are hard to treat with drugs is because the tumour cells show genetic variability, always producing new variants that sooner or later get around the drugs. We intend to combat this by targeting the ability of cancer cells to vary genetically - we are discovering ways to specifically kill genetically unstable cells. This prevents the cancer from developing drug resistance as well as having less side effects on the patient's normal cells.
Characterising The Mechanisms That Control Blood Cell Development
Funder
National Health and Medical Research Council
Funding Amount
$335,616.00
Summary
Hematopoiesis is a tightly regulated process that provides the body with a constant supply of all the cells of the blood system. My studies aim to characterize the molecular mechanisms that regulate the expansion and differentiation of hematopoietic stem cells (HSCs) into each cell lineage. These studies will be key to the effective use of cellular transplantation therapeutic strategies and aim to provide a greater understanding of the mechanisms that underpin proliferative disorders such as can ....Hematopoiesis is a tightly regulated process that provides the body with a constant supply of all the cells of the blood system. My studies aim to characterize the molecular mechanisms that regulate the expansion and differentiation of hematopoietic stem cells (HSCs) into each cell lineage. These studies will be key to the effective use of cellular transplantation therapeutic strategies and aim to provide a greater understanding of the mechanisms that underpin proliferative disorders such as cancer.Read moreRead less
Investigating Hippo-regulated transcription at single molecule resolution. Signalling pathways operate throughout life to relay signals from the extracellular world to the cellular nucleus, to control transcription and elicit a response. This project aims to understand how the Hippo growth control pathway regulates transcription. Using a combination of biology, biophysics and computational biology, this project aims to quantify behaviour of the Hippo pathway transcription factors at sub-micron r ....Investigating Hippo-regulated transcription at single molecule resolution. Signalling pathways operate throughout life to relay signals from the extracellular world to the cellular nucleus, to control transcription and elicit a response. This project aims to understand how the Hippo growth control pathway regulates transcription. Using a combination of biology, biophysics and computational biology, this project aims to quantify behaviour of the Hippo pathway transcription factors at sub-micron resolution, and how Hippo signalling modulates their behaviour, interaction with the genome and function. We anticipate our discoveries will stimulate new research, e.g. testing of how other signaling pathways regulate transcription. Intended benefits are creation of jobs and new knowledge on fundamental principles of life.Read moreRead less
Quantifying yeast cell mechanisms: filamentous growth and biofilm formation. This project aims to quantify the cellular mechanisms of yeast growth to advance our understanding of these organisms and support strategies to prevent and treat disease. Although yeasts are some of the most studied organisms in biology, their modes of filamentous growth and biofilm formation are not fully understood. Yeasts such as the Candida species cause potentially lethal infections through filamentous invasion of ....Quantifying yeast cell mechanisms: filamentous growth and biofilm formation. This project aims to quantify the cellular mechanisms of yeast growth to advance our understanding of these organisms and support strategies to prevent and treat disease. Although yeasts are some of the most studied organisms in biology, their modes of filamentous growth and biofilm formation are not fully understood. Yeasts such as the Candida species cause potentially lethal infections through filamentous invasion of tissues. The project plans to develop methods to quantify the mechanisms driving these growth processes. These methods will be designed to permit classification and selection of strain-specific properties of yeasts, providing a deeper understanding of the mechanisms controlling cellular and colonial morphology in the growth of Saccharomyces cerevisiae, the most important yeast in both biotechnology and bioscience.Read moreRead less
Examination Of The Mechanism By Which The Salvador/warts/hippo Complex Restricts Cell Growth And Number
Funder
National Health and Medical Research Council
Funding Amount
$283,767.00
Summary
Cancer is a disease that results from the generation of surplus cells. These extra unwanted cells are produced as a result of excess cell proliferation and impaired programmed cell death. These important processes can be deregulated in cancers as a result of mutations in many different genes. Many genetic lesions have been reported in different types of cancers but many of the genes that are mutated in these diseases have yet to be identified. To isolate new genes involved in cancer we created r ....Cancer is a disease that results from the generation of surplus cells. These extra unwanted cells are produced as a result of excess cell proliferation and impaired programmed cell death. These important processes can be deregulated in cancers as a result of mutations in many different genes. Many genetic lesions have been reported in different types of cancers but many of the genes that are mutated in these diseases have yet to be identified. To isolate new genes involved in cancer we created random mutations in the vinegar fly, Drosophila, and tested their ability to cause solid cancers. Drosophila is an excellent model organism for this study because many of the pathways that are often perturbed in cancer are conserved between humans and flies. Using this approach we identified several known and novel genes that cause cancerous growths. By studying the human counterparts of these novel genes we identified a potential role for some of these genes in the generation of human cancer. Three of these genes, hippo, salvador and warts, appear to act in concert to restrict cell number. In this study we aim to understand the mechanism by which these genes restrict cell number. To do this we will analyze how the activity of this pathway is controlled and in what tissues it functions. We also plan to discover other key components of this pathway that function downstream of hippo, salvador and warts. To perform these experiments we will use a variety in vitro biochemical techniques as well as experiments in tissue culture cells. We will then verify the results of these experiments in the context of a whole animal. By performing these experiments we hope to gain greater insight into the genesis of cancer.Read moreRead less