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I am a developmental cell biologist and molecular geneticist focusing on mechanisms controlling cell proliferation and modelling the development of cancer in the vinegar fly, Drosophila.
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
Programmed cell death (PCD), also known as apoptosis, plays a fundamental role in cell and tissue homeostasis and its misregulation is implicated in many human diseases. Many hormones control PCD but their mechanisms of action remain poorly understood. As hormones, in particular the steroid hormones, are directly linked to the pathogenesis of many forms of cancer, including breast, prostate and ovarian cancer, some of the most common malignancies afflicting the society, it is important to study ....Programmed cell death (PCD), also known as apoptosis, plays a fundamental role in cell and tissue homeostasis and its misregulation is implicated in many human diseases. Many hormones control PCD but their mechanisms of action remain poorly understood. As hormones, in particular the steroid hormones, are directly linked to the pathogenesis of many forms of cancer, including breast, prostate and ovarian cancer, some of the most common malignancies afflicting the society, it is important to study the mechanism of hormonal control of apoptosis in order to identify components of the regulatory apparatus. Identification of precise factors that regulate PCD will not only provide basic understanding of hormone-controlled PCD, but any novel factors involved in the control of cellular levels of death activators or death inhibitors are potential targets for anticancer drug development. This proposal is based on our ongoing studies, which combine the powerful biochemical and cellular approaches with the in vivo studies in vinegar fly (Drosophila) to address complex issues that are often difficult to pursue by the direct use of mammalian systems. We believe that the results from this study will provide novel insights into the mechanisms of hormone-regulated control of PCD and how these control mechanisms are disrupted under pathological conditions.Read moreRead less
MRNA Surveillance In Human Disease: Molecular Determinants Of Nonsense-mediated MRNA Decay
Funder
National Health and Medical Research Council
Funding Amount
$474,517.00
Summary
Inherited diseases are a common cause of human disability, illness and suffering. It has been estimated that 5-10% of the population will be affected by disorders with a genetic component. Thus studies on mechanisms of inherited diseases, especially those relating to genetic mechanisms with relevance across a wide range of individual disorders and gene mutations, are of great significance in diagnosis, molecular pathology and the eventual development of therapeutics. While there are many types o ....Inherited diseases are a common cause of human disability, illness and suffering. It has been estimated that 5-10% of the population will be affected by disorders with a genetic component. Thus studies on mechanisms of inherited diseases, especially those relating to genetic mechanisms with relevance across a wide range of individual disorders and gene mutations, are of great significance in diagnosis, molecular pathology and the eventual development of therapeutics. While there are many types of mutations, one relatively common type is called a premature termination mutation. Premature termination mutations introduce an inappropriate genetic signal that tells the cells to stop the formation of proteins before they are complete. This would result in the production of a protein that is shorter than normal, and these short proteins could be quite abnormal and drastically affect the normal function of cells. To overcome this, cells have developed elegant strategies that involve the deployment of quality control, or surveillance, mechanisms to remove the mutant gene product before it can be converted into an abnormal protein. This process is called nonsense mediated decay. Nonsense mediated decay is a complex process and some of the key components have been identified by studies on a small number of genes. However, our studies have identified several previously unknown aspects of the process that suggest that the currently held view of how nonsense mediated decay works is only the beginning of the story and further important complexity exists. The proposed research will explore the basic mechanisms of the surveillance process and determine the signals that initiate nonsense mediated decay. Since premature termination mutations cause one-third of all inherited genetic disorders, our studies will provide new insights into the surveillance mechanisms and will have wide applicability to our understanding of the basis of inherited disease.Read moreRead less
Assembly Of Mitochondrial Respiratory Chain Complexes And Defects Associated With Disease
Funder
National Health and Medical Research Council
Funding Amount
$464,610.00
Summary
A group of protein assemblies termed respiratory complexes are found in the inner membrane of mitochondria in our cells and are responsible for producing most of our energy. These complexes consist of many different protein subunits and are built by the help of numerous known and unknown assembly factors. For example, assembly of Complex I of the respiratory chain requires 39 different proteins that are made outside mitochondria and are then transported inside to be somehow joined together with ....A group of protein assemblies termed respiratory complexes are found in the inner membrane of mitochondria in our cells and are responsible for producing most of our energy. These complexes consist of many different protein subunits and are built by the help of numerous known and unknown assembly factors. For example, assembly of Complex I of the respiratory chain requires 39 different proteins that are made outside mitochondria and are then transported inside to be somehow joined together with the 7 other subunits that are made by mitochondria. This is clearly a complicated procedure and we have little information on how its assembly is achieved. We do know however that mistakes in the assembly of these complexes (particularly Complex I) do happen. In Australia, about 50 children born each year have inherited disorders of mitochondrial energy generation. The most severe disorders cause infant death, while others present later causing a range of degenerative diseases, particularly affecting brain, muscle and heart. Defects in the respiratory chain have also been implicated in Parkinson's disease, Alzheimer's disease, type-2 diabetes and in cell death. In order to understand how respiratory complex defects cause disease, we need to understand more about how these complexes are built. The aim of this proposal is to investigate how Complex I is assembled, how it interacts with other respiratory complexes, and to identify and characterise proteins that aid in its assembly. We will also analyse assembly defects in cells from patients with suspected respiratory complex deficiencies. This work will aid in our understanding of not only how protein complexes are built, but how defects in their assembly can cause disease. This will be informative to families of affected individuals and may aid in future diagnosis and prevention of diseases where defects in mitochondria are implicated.Read moreRead less
Structure And Function Of The Alternative Splicing Factor ZNF265
Funder
National Health and Medical Research Council
Funding Amount
$509,017.00
Summary
Now that the human genome has been sequenced, we can see that a human being is defined bye approximately 30000 genes. One of the biggest surprises to come from this work was that the number of genes was significantly smaller than many predicted. Similar surprise was registered at the discovery that the genome of the fruit fly actually contained fewer genes than that of the model worm, Caenorhabditis elegans. Part of the explanation for these apparent discrepencies lies in the phenomenon known as ....Now that the human genome has been sequenced, we can see that a human being is defined bye approximately 30000 genes. One of the biggest surprises to come from this work was that the number of genes was significantly smaller than many predicted. Similar surprise was registered at the discovery that the genome of the fruit fly actually contained fewer genes than that of the model worm, Caenorhabditis elegans. Part of the explanation for these apparent discrepencies lies in the phenomenon known as gene splicing, whereby one gene can actually give rise to many different isoforms of the same protein. These different isoforms can have different structures and-or functions, and dramatically increase the complexity that it is possible for an organism to achieve with a given number of genes. The process of splicing is very intricate, requiring precise control to allow an organism to develop normally. Many human genetic diseases are known to arise from problems with splicing. However, our understanding of the mechanisms of splicing is rather incomplete. This proposal aims to improve our understanding of the splicing process through a range of biophysical and molecular biological approaches. This information should prove useful in understanding human development and disease.Read moreRead less
Arterial stiffness: mechanistic role of interaction of cellular processes and the extracellular matrix. Arterial stiffness causes high blood pressure with age, so with more people living longer it is important to understand why arteries become stiff. This investigation uses genetically engineered mice to study how changes in nitric oxide in the cells of the artery wall can lead to changes in the wall material and so affect arterial stiffness.