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Proteolysis of binding protein complexes regulates bioavailability of insulin-like growth factor (IGF). We aim to determine how growth factors kept inactive in complexes in the blood can become free and active. The fundamental knowledge gained will help us understand the regulation of growth factors' availability to tissues and develop novel or more effective delivery systems for therapeutic growth factors that could impact on several conditions including diabetes, growth disorders and critical ....Proteolysis of binding protein complexes regulates bioavailability of insulin-like growth factor (IGF). We aim to determine how growth factors kept inactive in complexes in the blood can become free and active. The fundamental knowledge gained will help us understand the regulation of growth factors' availability to tissues and develop novel or more effective delivery systems for therapeutic growth factors that could impact on several conditions including diabetes, growth disorders and critical illness. This project therefore benefits Australia at two levels: by maintaining our international leadership in the study of these important growth-regulatory molecules, and by providing a better understanding of physiological mechanisms that might benefit the health of Australians and provide opportunities to develop novel therapeutics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454170
Funder
Australian Research Council
Funding Amount
$187,341.00
Summary
Biacore3000-Expansion of Proteomics Facility. The sequencing of the human genome has led to redirection of effort towards the rapid characterisation of the products of genes, proteins. This project will establish state of the art facilities for protein identification and characterisation in the Hunter Region. The investigators are representative of several major research programs and are unified by their specific expertise in the fundamental molecular mechanisms underlying the control of cellula ....Biacore3000-Expansion of Proteomics Facility. The sequencing of the human genome has led to redirection of effort towards the rapid characterisation of the products of genes, proteins. This project will establish state of the art facilities for protein identification and characterisation in the Hunter Region. The investigators are representative of several major research programs and are unified by their specific expertise in the fundamental molecular mechanisms underlying the control of cellular processes in plants, animals and humans. Understanding these mechanisms will provide the basis for improved management of the environment and pathological conditions through identifying molecular targets for diagnosis, genetic manipulation or drug design.Read moreRead less
Determination of the mechanisms of immune system regulation of inflammation by the human protein, chaperonin 10. The aim of this project is to determine the mechanisms by which a human protein, chaperonin 10 (Cpn10), regulates the immune system and suppresses inflammation. When cells of the human immune system are challenged with lipopolysaccharide (LPS) (a product of bacterial infection), the pro-inflammatory cytokine TNF is released. Cpn10 has been shown to suppress production of TNF on chall ....Determination of the mechanisms of immune system regulation of inflammation by the human protein, chaperonin 10. The aim of this project is to determine the mechanisms by which a human protein, chaperonin 10 (Cpn10), regulates the immune system and suppresses inflammation. When cells of the human immune system are challenged with lipopolysaccharide (LPS) (a product of bacterial infection), the pro-inflammatory cytokine TNF is released. Cpn10 has been shown to suppress production of TNF on challenge of cells with LPS, while increasing the levels of the anti-inflammatory cytokine IL-10. Investigating the role of Cpn10 in modulating inflammation will contribute to the understanding and treatment of diseases associated with inflammation, including multiple sclerosis and rheumatoid arthritis.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561173
Funder
Australian Research Council
Funding Amount
$207,189.00
Summary
High throughput proteomics - Thermo Finnigan ProteomeX LCQ Integrated Proteomics Workstation. As research in the biological sciences moves into post-genomics era, so attention has focused on the development of technologies capable of characterizing the molecular complexity inherent in the proteome. Recent technical innovations in this field have resulted in the advancement of mass spectrometers that are capable of exemplifying unknown proteins with great efficiency. These new technologies are ....High throughput proteomics - Thermo Finnigan ProteomeX LCQ Integrated Proteomics Workstation. As research in the biological sciences moves into post-genomics era, so attention has focused on the development of technologies capable of characterizing the molecular complexity inherent in the proteome. Recent technical innovations in this field have resulted in the advancement of mass spectrometers that are capable of exemplifying unknown proteins with great efficiency. These new technologies are central to any institution committed to the development of a competitive research nexus in biological sciences. The purpose of this application is to upgrade the mass spectrometry facility at the University of Newcastle such that it is able to provide cutting edge support to the extensive scientific community within the Hunter region.Read moreRead less
Characterisation of p14ARF intracellular trafficking pathways. Over 3500 new cases of melanoma are diagnosed in NSW each year, and one of the most important proteins involved in suppressing melanoma initiation or growth is p14ARF. This project will characterise the movement and functions of this protein with the aim of identifying novel targets for more effective drug therapies.
YrdC translational control: physical and functional interactions, identification and influence of amino acid phosphorylation. This project will expand our basic understanding of the mechanisms with which a newly identified and highly conserved protein, YrdC203 regulates the process of protein synthesis from mRNA. This work will lead to basic insights into how gene expression is regulated at the level of translation, and generate valuable research tools, such as YrdC203 knockdown tools, peptide m ....YrdC translational control: physical and functional interactions, identification and influence of amino acid phosphorylation. This project will expand our basic understanding of the mechanisms with which a newly identified and highly conserved protein, YrdC203 regulates the process of protein synthesis from mRNA. This work will lead to basic insights into how gene expression is regulated at the level of translation, and generate valuable research tools, such as YrdC203 knockdown tools, peptide mimetics and decoys, phospho-specific and phospho-non specific antibodies. Exploitation of this breakthrough science will open up new avenues for therapeutic intervention in the future, while commercial exploitation of such reagents that recognise or interfere with YrdC203 will generate economic returns to Australia.Read moreRead less
Understanding the potency and role of individual stem cells in the skin using Rainbow technology. To renew itself, the skin and its components rely on the activity of stem cells. This project will define more precisely the role of each individual stem cell by labelling them with a unique colour and following its fate. This project has the potential to change our current view on how the skin maintains and repairs itself.
A unified model of amino acid homeostasis. This project aims to develop a unified model of amino acid homeostasis in mammalian cells and apply it to brain cells. The model will be underpinned by a mathematical algorithm that allows predicting amino acid levels in the cytosol based on fundamental parameters such as transport and metabolism. This project should provide the significant benefit of enabling the prediction of essential functions such as cell growth and survival.
Control of developmental switches by importin 5. Aims: This project will study a key molecular switch called IPO5, a protein that is required for cells and organs to form and function normally, and it will reveal how it works.
Significance: These experiments will provide the first complete description of how this molecular switch controls the behaviour of a cell across its lifespan. IPO5 is highly conserved, so these studies will be relevant to a wide range of animals.
Expected Outcomes: This k ....Control of developmental switches by importin 5. Aims: This project will study a key molecular switch called IPO5, a protein that is required for cells and organs to form and function normally, and it will reveal how it works.
Significance: These experiments will provide the first complete description of how this molecular switch controls the behaviour of a cell across its lifespan. IPO5 is highly conserved, so these studies will be relevant to a wide range of animals.
Expected Outcomes: This knowledge will reveal how IPO5 controls formation of sperm by revealing what other proteins it binds to and how this affects cell signaling and responses to the environment.
Benefits: This will provide information about potential interventions to control fertility or to repair abnormal cells.
Read moreRead less
How IGFBP-3 improves cancer cell responsiveness to DNA-damaging therapies. A protein called IGFBP-3 can modulate the way cancer cells respond to treatments such as radiotherapy and certain chemotherapy drugs. These therapies, which act by damaging cells' DNA, play an important role in the treatment of many cancers, but their effectiveness is limited by the ability of cells to oppose the treatment by repairing damaged DNA. This project aims to discover how IGFBP-3 acts to change cancer cells' res ....How IGFBP-3 improves cancer cell responsiveness to DNA-damaging therapies. A protein called IGFBP-3 can modulate the way cancer cells respond to treatments such as radiotherapy and certain chemotherapy drugs. These therapies, which act by damaging cells' DNA, play an important role in the treatment of many cancers, but their effectiveness is limited by the ability of cells to oppose the treatment by repairing damaged DNA. This project aims to discover how IGFBP-3 acts to change cancer cells' response to treatment, using breast cancer cells growing in culture as a model system. This work has the potential to lead to improvements in the treatment of cancer patients by increasing our understanding of what happens when cancer cells are exposed to radio- or chemotherapy.Read moreRead less