Tyrosine Kinases And Phosphatases In Cell Cycle Checkpoint Responses
Funder
National Health and Medical Research Council
Funding Amount
$513,946.00
Summary
In order for an organism to grow and develop, the cells that make up the tissues and organs need to undergo a process of cellular division, wherein individual cells grow and then divide into two cells. During this process of cellular growth and division the entire genome needs to be duplicated (this occurs during S-phase) and then divided equally into the two daughter cells. In S-phase several so-called 'checkpoint' mechanisms exist which ensure that this occurs in an orderly and precise manner. ....In order for an organism to grow and develop, the cells that make up the tissues and organs need to undergo a process of cellular division, wherein individual cells grow and then divide into two cells. During this process of cellular growth and division the entire genome needs to be duplicated (this occurs during S-phase) and then divided equally into the two daughter cells. In S-phase several so-called 'checkpoint' mechanisms exist which ensure that this occurs in an orderly and precise manner. The so-called 'DNA replication checkpoint' delays S-phase progression in response to 'replication stresses' that may otherwise cause DNA damage. Protein tyrosine kinases (PTKs) are hyperactivated in many human solid tumours and blood malignancies contributing to varied aspects of tumour progression. Our preliminary studies indicate that the inactivation of PTKs by protein tyrosine phosphatases may be essential for the suppression of S-phase progression in response to replication stress. Our goal is to understand the molecular mechanisms by which PTKs and tyrosine phosphatases contribute to S-phase checkpoints. Our studies will provide important insights into DNA replication stress-induced checkpoint responses in mammals and identify unprecedented mechanisms by which hyperactivated PTKs may contribute to tumour development.Read moreRead less
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.
Biomathematical Analysis Of Cell Invasion: Migration Of Neural Crest Cells To Form The Enteric Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$449,484.00
Summary
Extending scientific studies to a mathematical level is the way to produce deep understanding and control. Mathematics has been applied less to biology, particularly the biology of development, than to other branches of science, no doubt due to the innate complexity and technical difficulties of seeing and measuring what is actually going on. Labelling, imaging and computational tools to visualise biological processes are only now becoming available. To build our bodies during embryonic developm ....Extending scientific studies to a mathematical level is the way to produce deep understanding and control. Mathematics has been applied less to biology, particularly the biology of development, than to other branches of science, no doubt due to the innate complexity and technical difficulties of seeing and measuring what is actually going on. Labelling, imaging and computational tools to visualise biological processes are only now becoming available. To build our bodies during embryonic development, cells must move; this is called cell migration. The same process occurs throughout life in wound repair. Uncontrolled migration is the hallmark of malignant cancers, where it is called invasion. The molecular mechanisms in cells that allow them to move are just beginning to be understood. However, the big questions determining the general rules of migration are more difficult to approach. Here are some examples of such questions. When to migrate? Where to migrate to? Which pathways? How many cells to migrate? How far? How fast? How to stop? Such simple questions are still unanswered. We are pioneering a novel and unique approach combining imaging of real cells migrating in real tissues (digital time-lapse movies) with mathematical modelling to understand the driving forces of cell migration-invasion. This technology is here applied to a particular example of cell migration where precursor nerve cells migrate all the way along the length of the gastro-intestinal tract in early development. This process gives rise to fatal birth defects associated with migration failure. The development of the nervous system in the gut has features in common with all other migrations and invasions, normal and pathological. A much more profound knowledge of the big picture of the developmentally and clinically crucial process of cell migration-invasion will emerge from this marriage of biological experimentation and mathematical modelling.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
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
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.
Re-purposing shelved 'antibiotics' in the search for new herbicides. This project aims to identify target-specific herbicidal compounds that inhibit amino acid biosynthesis pathways to tackle herbicide resistance. This project expects to validate a novel herbicide discovery strategy by exploiting the similarity between bacterial and plant enzymes in these pathways to re-purpose failed 'antibiotics'. Expected outcomes include advances in our knowledge of the structure, function and inhibition of ....Re-purposing shelved 'antibiotics' in the search for new herbicides. This project aims to identify target-specific herbicidal compounds that inhibit amino acid biosynthesis pathways to tackle herbicide resistance. This project expects to validate a novel herbicide discovery strategy by exploiting the similarity between bacterial and plant enzymes in these pathways to re-purpose failed 'antibiotics'. Expected outcomes include advances in our knowledge of the structure, function and inhibition of novel herbicide targets, and the identification of compounds with herbicidal activity. This should lay the foundations for long-term benefits related to improving the quantity and quality of Australia’s crops to ensure our food security.Read moreRead less
Molecular basis of the interaction between plant disease resistance proteins and pathogen avirulence proteins. Management of crop diseases involves the integrated use of resistant cultivars and the application of chemical pesticides. Many diseases, however, including rust, continue to pose an economically significant threat to agricultural productivity in Australia. The research outlined in this proposal aims to understand the mechanisms, at a molecular and structural level, that enable resistan ....Molecular basis of the interaction between plant disease resistance proteins and pathogen avirulence proteins. Management of crop diseases involves the integrated use of resistant cultivars and the application of chemical pesticides. Many diseases, however, including rust, continue to pose an economically significant threat to agricultural productivity in Australia. The research outlined in this proposal aims to understand the mechanisms, at a molecular and structural level, that enable resistant plants to detect and respond to pathogen attack. The outcomes of this currently unavailable fundamental understanding will enable new, durable and more effective resistance genes to be engineered. Therefore, the work has significant economic and environmental implications for agricultural crop plant productivity in this country.Read moreRead less