To study the genetic alterations that give rise to cancer. In particular, exploring how too little death of cells can lead to a tumour. If too few cells in a tissue die, a tumour may develop there. The team is exploring how the cell death process is normally controlled. They plan to characterise the molecules inside cells that determine whether a cell lives or dies and hope that better understanding of those molecules will help to explain how tumours arise. It could also lead to new drugs that c ....To study the genetic alterations that give rise to cancer. In particular, exploring how too little death of cells can lead to a tumour. If too few cells in a tissue die, a tumour may develop there. The team is exploring how the cell death process is normally controlled. They plan to characterise the molecules inside cells that determine whether a cell lives or dies and hope that better understanding of those molecules will help to explain how tumours arise. It could also lead to new drugs that can kill tumour cells more effectively by directly triggering the normal death switch of the cell.Read moreRead less
Differential roles of gene family members in development of a cell lineage. This project aims to investigate how a family of genes influence cells in the testis to become mature sperm. Testicular cells regulate gene activity via the Snail family of proteins during sperm development, and interruption of their activities reduces fertility in mice and fruit flies. The project aims to use genetic, cell biological and biochemical studies in Drosophila and mice to compare different Snail family protei ....Differential roles of gene family members in development of a cell lineage. This project aims to investigate how a family of genes influence cells in the testis to become mature sperm. Testicular cells regulate gene activity via the Snail family of proteins during sperm development, and interruption of their activities reduces fertility in mice and fruit flies. The project aims to use genetic, cell biological and biochemical studies in Drosophila and mice to compare different Snail family proteins in spermatogenesis. The outcomes will define the different roles of highly similar proteins from the same family in differentiation of a single cell lineage. This is important in generating functional tissues using in vitro laboratory approaches or understanding how normal development and developmental disorders arise.Read moreRead less
Throughout our lives cells must die and be replenished. One way multicellular organisms remove unwanted cells is through a process called programmed cell death. This process eliminates redundant, damaged or infected cells by a program of cell suicide. We are studying the underlying molecular mechanisms of this cell suicide in order to design new pharmaceuticals to treat illnesses caused by a disruption in programmed cell death. The fine balance between living and dying cells must be maintained a ....Throughout our lives cells must die and be replenished. One way multicellular organisms remove unwanted cells is through a process called programmed cell death. This process eliminates redundant, damaged or infected cells by a program of cell suicide. We are studying the underlying molecular mechanisms of this cell suicide in order to design new pharmaceuticals to treat illnesses caused by a disruption in programmed cell death. The fine balance between living and dying cells must be maintained and if this balance is lost then disease may result. A reduced level of cell death may result in cancers while too many dying can contribute to degenerative diseases such as Alzheimer's disease and stroke. Currently many of these diseases do not have effective treatments. We will determine the three-dimensional structures of key proteins involved in programmed cell death and use this information to design drugs that can interfere with the molecular processes involved in signalling cell death. Such drugs may prove useful new therapies in a wide range of diseases caused by a breakdown in the biochemical paths to cell death.Read moreRead less
Learning The Mechanisms Of Programmed Cell Death And Tumour Suppression To Develop Novel Cancer Therapies
Funder
National Health and Medical Research Council
Funding Amount
$863,910.00
Summary
Our bodies prevent the development of cancer through tumour suppressive processes, which also affect the outcome of cancer therapy. Programmed cell death (apoptosis) is one such process, and defects in apoptosis promote cancer development and impair the response of tumour cells to anti-cancer therapies. My laboratory uses molecular biology and cell biology approaches to investigate the mechanisms of cell death and tumour suppression, partnering with pharma to develop novel cancer therapies.
Mechanism and function of cell asymmetry during cell death. This project aims to investigate how dying cells rearrange their cellular contents to aid their removal.
More than 200 billions cells die daily in the human body. It is critical that dying cells are rapidly cleared as their buildup can interfere with normal tissue functions. This project will use a suite of contemporary molecular/cell biological approaches to study a newly identified process that occurs during cell death. Expected outc ....Mechanism and function of cell asymmetry during cell death. This project aims to investigate how dying cells rearrange their cellular contents to aid their removal.
More than 200 billions cells die daily in the human body. It is critical that dying cells are rapidly cleared as their buildup can interfere with normal tissue functions. This project will use a suite of contemporary molecular/cell biological approaches to study a newly identified process that occurs during cell death. Expected outcomes include a paradigm-shift in understanding the process of cell clearance.
This project is expected to generate fundamental new knowledge of the mechanisms by which dying cells are efficiently removed from tissues. This should provide significant benefits to the cell death and general cell biology fields.Read moreRead less
The lipidomics of cell fate. This project aims to dissect the roles of lipids in cell fate. The study of lipids, or lipidomics, is an emerging and exciting area of biological science. The fundamental roles of lipids in development remain vastly understudied. This project will look at reprogramming of somatic cells into stem cells, their pluripotency and differentiation. This will be complemented with studies in the zebrafish, which permits the direct study of cell fate in vivo. This approach is ....The lipidomics of cell fate. This project aims to dissect the roles of lipids in cell fate. The study of lipids, or lipidomics, is an emerging and exciting area of biological science. The fundamental roles of lipids in development remain vastly understudied. This project will look at reprogramming of somatic cells into stem cells, their pluripotency and differentiation. This will be complemented with studies in the zebrafish, which permits the direct study of cell fate in vivo. This approach is a powerful way to unlock major events involved in development and to unmask the roles of lipids in these fundamental mechanisms.Read moreRead less
Mechanism and function of dying cell disassembly. This project aims to elucidate the molecular machinery that disassembles dying cells, and the role of this process in cell clearance. Billions of cells in the body die daily as part of normal turnover. Dying cells must be rapidly removed, as their accumulation can interfere with normal tissue functions. To efficiently clear dead cells, dying cells can disassemble into smaller fragments that neighbouring cells engulf. Understanding the mechanistic ....Mechanism and function of dying cell disassembly. This project aims to elucidate the molecular machinery that disassembles dying cells, and the role of this process in cell clearance. Billions of cells in the body die daily as part of normal turnover. Dying cells must be rapidly removed, as their accumulation can interfere with normal tissue functions. To efficiently clear dead cells, dying cells can disassemble into smaller fragments that neighbouring cells engulf. Understanding the mechanistic basis and function of dying cell disassembly is expected to generate knowledge of the downstream consequence of cell death. This breakthrough will be important in many fields of research including cell biology and biochemistry, and generate basic knowledge that can ultimately be applied in medical science to understand or treat pathological conditions associated with cell death.Read moreRead less
Mechanisms by which Beclin1 regulates intestinal homeostasis. This project aims to investigate if Beclin1, a protein which has an important and well-accepted role in promoting cell survival through the program of autophagy, has an alternate job mediating trafficking within a cell. Using novel mouse models and innovative techniques, the project aims to demonstrate the physiological importance of this alternate role for Beclin1. Expected outcomes include enhancing Australia's international researc ....Mechanisms by which Beclin1 regulates intestinal homeostasis. This project aims to investigate if Beclin1, a protein which has an important and well-accepted role in promoting cell survival through the program of autophagy, has an alternate job mediating trafficking within a cell. Using novel mouse models and innovative techniques, the project aims to demonstrate the physiological importance of this alternate role for Beclin1. Expected outcomes include enhancing Australia's international research standing, and providing research training for young scientists. Benefits include generation of new knowledge and a rethink of the basis for normal development and diseases where Beclin1 has been implicated.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100500
Funder
Australian Research Council
Funding Amount
$383,066.00
Summary
Unravelling the holistic genetic control of vertebrate development. Understanding the genetic regulation of embryo formation is the cornerstone of developmental biology. As four per cent of Australian children are born with some form of prenatal defect, understanding the basic biology of embryogenesis is paramount for long-range development of future therapies. We have identified a highly conserved transcription factor, Grhl3, which regulates multiple stages of embryonic formation. Using advance ....Unravelling the holistic genetic control of vertebrate development. Understanding the genetic regulation of embryo formation is the cornerstone of developmental biology. As four per cent of Australian children are born with some form of prenatal defect, understanding the basic biology of embryogenesis is paramount for long-range development of future therapies. We have identified a highly conserved transcription factor, Grhl3, which regulates multiple stages of embryonic formation. Using advanced genetic models, this project will characterise the role of Grhl3 in the regulation of cellular migration and craniofacial skeleton and brain development. The project will also identify the target genes which Grhl3 regulates. The identification of such transcriptional networks is imperative to understanding the holistic molecular control of embryogenesis.Read moreRead less