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
Studies of the pi3-kinase enzyme family using selective inhibitors. The objective of this project is to study the function of the PI3-kinase enzyme family in blood platelets. To do this, inhibitors which block the action of specific family members, will be evaluated for their effects in assays of platelet function. The results will enhance our understanding of the way in which platelets and other cells respond to stimuli, and lead new approaches to designing novel drugs that block these response ....Studies of the pi3-kinase enzyme family using selective inhibitors. The objective of this project is to study the function of the PI3-kinase enzyme family in blood platelets. To do this, inhibitors which block the action of specific family members, will be evaluated for their effects in assays of platelet function. The results will enhance our understanding of the way in which platelets and other cells respond to stimuli, and lead new approaches to designing novel drugs that block these responses.Read moreRead less
Defining in molecular terms cis-inhibition as a means to inhibit Notch signaling. Normal development of a baby and our health after birth is dependent on how our cells behave. Signals move between cells and within them to tell them what to do. Proteins interacting with other proteins mostly transmit these signals. This research focuses on a protein named Notch and the signals that it transmits. Notch functions in normal processes, such as blood vessel formation; but abnormal signaling causes and ....Defining in molecular terms cis-inhibition as a means to inhibit Notch signaling. Normal development of a baby and our health after birth is dependent on how our cells behave. Signals move between cells and within them to tell them what to do. Proteins interacting with other proteins mostly transmit these signals. This research focuses on a protein named Notch and the signals that it transmits. Notch functions in normal processes, such as blood vessel formation; but abnormal signaling causes and/or contributes to pathological situations such as degenerative disease and cancer. We are working to understand how the Notch signal is made and how to control it when it is abnormal. This will allow new medications to be developed to help people who have cancer and other Notch-related illnessesRead moreRead less
Structural and functional characterisation of PI3Kgamma, uniquely activated by p101. The movement of cells is involved in all aspects of life including development, growth and maintenance of organisms. In spite of this, our understanding of the mechanism involved in cell migration is limited. There are a number of conditions in which the ability to control cell movement would be of significant benefit. Examples include autoimmune conditions, asthma and cancer, the social and economic burdens ....Structural and functional characterisation of PI3Kgamma, uniquely activated by p101. The movement of cells is involved in all aspects of life including development, growth and maintenance of organisms. In spite of this, our understanding of the mechanism involved in cell migration is limited. There are a number of conditions in which the ability to control cell movement would be of significant benefit. Examples include autoimmune conditions, asthma and cancer, the social and economic burdens of which account for billions of dollars and millions of Australians. This project aims to understand one of the major mechanisms that controls cell migration, which is expected to produce significant economic and social outcomes in the areas of basic science knowledge, human health, and biotechnology. Read moreRead less
Function and modulation of the protein quality control network in mammalian mitochondria. This project has potential technological benefit in the areas of biotechnology and molecular medicine especially in relation to age-related cellular degeneration. As a result of our research outputs, strategies could be developed to either delay the onset or reduce the severity of diseases related to mitochondrial dysfunction. Training research scientists of the future, forms an integral part of our researc ....Function and modulation of the protein quality control network in mammalian mitochondria. This project has potential technological benefit in the areas of biotechnology and molecular medicine especially in relation to age-related cellular degeneration. As a result of our research outputs, strategies could be developed to either delay the onset or reduce the severity of diseases related to mitochondrial dysfunction. Training research scientists of the future, forms an integral part of our research program and our association with world leaders in the field provide excellent opportunity for exchange of personnel, ideas and emerging methodologies. This project will lead the way in this field and consequently will expand Australia's reputation at the forefront of scientific advancement. Read moreRead less
A proteomic approach to identifying the signaling pathway(s) by which acute oxidative stress causes cell death by apoptosis. Oxidative stress following traumatic injury (heart attack or stroke) is known to activate signaling pathways leading to programmed cell death (apoptosis). The aim of this project is to develop methods to identify the signaling proteins involved. Identifying proteins involved in causing cell death will be useful in developing diagnostic tools as well as providing potential ....A proteomic approach to identifying the signaling pathway(s) by which acute oxidative stress causes cell death by apoptosis. Oxidative stress following traumatic injury (heart attack or stroke) is known to activate signaling pathways leading to programmed cell death (apoptosis). The aim of this project is to develop methods to identify the signaling proteins involved. Identifying proteins involved in causing cell death will be useful in developing diagnostic tools as well as providing potential therapeutic possibilities.Read moreRead less
AAA+ proteases: substrate binding, translocation and modulation by novel adaptor proteins. Protein quality control is essential for the proper maintenance of the cell. It ensures the correct folding of newly synthesised proteins, the refolding or degradation of misfolded and aggregated proteins, and the controlled degradation of regulatory proteins. These functions are collectively performed by molecular chaperones and proteases. This project will define the molecular basis of substrate selectiv ....AAA+ proteases: substrate binding, translocation and modulation by novel adaptor proteins. Protein quality control is essential for the proper maintenance of the cell. It ensures the correct folding of newly synthesised proteins, the refolding or degradation of misfolded and aggregated proteins, and the controlled degradation of regulatory proteins. These functions are collectively performed by molecular chaperones and proteases. This project will define the molecular basis of substrate selectivity for ATP-dependent proteases and determine the relationship between chaperones and proteases. A major focus will be directed towards the mechanistic analysis of novel AAA+ cofactors such as ClpS, which we recently discovered. A detailed analysis of such proteins is central to understanding how chaperones and protease (a) recognize their substrates and (b) compete for different substrates in vivo.Read moreRead less
Molecular signals that regulate the regenerative properties of intestinal epithelial cells. Most cancer deaths are due to the cancer spreading to other organs. Cancer is much more difficult to treat once it has spread to other organs in the body where the cancer cells can exist in a dormant state. Dormant cancer cells evade conventional anticancer treatment and can remain dormant for a very long time before they change back to a 'tumour-growing' state. An understanding of how the cancer initiati ....Molecular signals that regulate the regenerative properties of intestinal epithelial cells. Most cancer deaths are due to the cancer spreading to other organs. Cancer is much more difficult to treat once it has spread to other organs in the body where the cancer cells can exist in a dormant state. Dormant cancer cells evade conventional anticancer treatment and can remain dormant for a very long time before they change back to a 'tumour-growing' state. An understanding of how the cancer initiating (stem cell) property of tumour cells is maintained offers potential novel avenues to eliminate persistent cancer cells. This knowledge will ultimately lead to better management and treatment of cancer, and increase survival. An understanding of stem cell behaviour is also central to the control of degenerative conditions.Read moreRead less
Post-genomic investigation of the relict plastid and mitochondrion of malaria parasites. Malaria is a major global health problem. The malaria parasite has two substructures, a relict chloroplast and a mitochondrion, that are excellent targets for new and existing drugs. However, we do not know the key functions of these two compartments. The entire genetic blueprint (genome) is now available for the malaria parasite and I propose to determine exactly which parts of the genome service the rel ....Post-genomic investigation of the relict plastid and mitochondrion of malaria parasites. Malaria is a major global health problem. The malaria parasite has two substructures, a relict chloroplast and a mitochondrion, that are excellent targets for new and existing drugs. However, we do not know the key functions of these two compartments. The entire genetic blueprint (genome) is now available for the malaria parasite and I propose to determine exactly which parts of the genome service the relict chloroplast and mitochondria. This will sketch out a picture of their inner workings. Armed with this information we can take a rational approach to seeking an Achilles? Heel of malaria against which parasite-specific drugs can be developed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989105
Funder
Australian Research Council
Funding Amount
$495,000.00
Summary
An Advanced Mass Spectrometry Facility for Applications in Proteomics and Organic Chemistry. Biomolecular research and research training, in which proteomics is core, has become a critical component of post-industrial development in the Hunter region. Development of a cutting edge proteomics facility will benefit a research community comprising over 50 researchers and 150 undergraduate students significantly enhancing their research productivity and translation of outcomes in areas of national i ....An Advanced Mass Spectrometry Facility for Applications in Proteomics and Organic Chemistry. Biomolecular research and research training, in which proteomics is core, has become a critical component of post-industrial development in the Hunter region. Development of a cutting edge proteomics facility will benefit a research community comprising over 50 researchers and 150 undergraduate students significantly enhancing their research productivity and translation of outcomes in areas of national importance. These include understanding the impact of the environment on plant and animal development, pest animal control, development of new biotechnology tools, new drugs and new methods for the detection of narcotics and explosives.Read moreRead less