Biochemistry of tropoelastin and elastin. Elastin is the main protein responsible for the elasticity of vertebrate tissues. The Weiss Lab makes large quantities of full-length tropoelastin, which is crosslinked to make elastin. We want to examine the biochemistry of tropoelastin, learn how its domains participate in elastin structure and assembly, and explore cellular responses to our synthetic elastin biomaterial. Remarkably little is known of this biochemistry because elastin is a highly cross ....Biochemistry of tropoelastin and elastin. Elastin is the main protein responsible for the elasticity of vertebrate tissues. The Weiss Lab makes large quantities of full-length tropoelastin, which is crosslinked to make elastin. We want to examine the biochemistry of tropoelastin, learn how its domains participate in elastin structure and assembly, and explore cellular responses to our synthetic elastin biomaterial. Remarkably little is known of this biochemistry because elastin is a highly cross-linked and substantially insoluble macroscopic network of tropoelastin multimers. Our availability of tropoelastin and synthetic elastin now makes these studies possible.Read moreRead less
Biochemistry of tropoelastin and elastin: the molecular architecture of elastic fibre assembly. Elastin destruction drives the progression of emphysema, a major component of chronic obstructive pulmonary disease which is a major cause of death. Loss of elastin leads to profound blockage of arteries. If we are to treat these problems we need to know how to make and repair elastin. This research will enable us to discover how elastin is constructed and define its interacting partners. We will lear ....Biochemistry of tropoelastin and elastin: the molecular architecture of elastic fibre assembly. Elastin destruction drives the progression of emphysema, a major component of chronic obstructive pulmonary disease which is a major cause of death. Loss of elastin leads to profound blockage of arteries. If we are to treat these problems we need to know how to make and repair elastin. This research will enable us to discover how elastin is constructed and define its interacting partners. We will learn how to make tissue components found in parts of the body that expand and contract such as the arteries, lung and skin. We will learn about the molecular mechanisms of elastin assembly and cell interactions, which gives us the core molecular toolkit to repair elastin tissue.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883032
Funder
Australian Research Council
Funding Amount
$1,300,000.00
Summary
800 MHz NMR spectrometer for biomolecular structure-function analysis. An understanding of how organisms function at the molecular level is central to developing the ability to fight many diseases in a rational way. This equipment will provide the capability for many different laboratories around NSW and the ACT to advance our knowledge at this fundamental level, primarily by examining the structures and functions of biomolecules such as proteins.
Identification of functionally important autophosphorylation site(s) on ataxia telangiectasia and Rad 3 - related (ATR) protein kinase. The integrity of our genetic material must be maintained so that it can be passed on from one generation to the next and also to minimize the risk of cancer and other pathologies in an individual. There are multiple proteins involved in protecting our DNA including several enzymes that detect and signal DNA damage to a series of pathways involved in halting the ....Identification of functionally important autophosphorylation site(s) on ataxia telangiectasia and Rad 3 - related (ATR) protein kinase. The integrity of our genetic material must be maintained so that it can be passed on from one generation to the next and also to minimize the risk of cancer and other pathologies in an individual. There are multiple proteins involved in protecting our DNA including several enzymes that detect and signal DNA damage to a series of pathways involved in halting the passage of cells through the cell cycle so that repair can occur. This project studies the mechanism of action of one of these enzymes which will be of benefit in designing new compounds to fight disease. Read moreRead less
The effects of alpha-2-macroglobulin on amyloid formation and toxicity. The expected outcomes will provide major advances in understanding how the abundant human blood protein alpha-2-macroglobulin influences the formation of protein aggregates that underpin a number of serious diseases (e.g. Alzheimer's disease). The linkages involved are of the highest calibre and will give the Fellowship holder a unique opportunity for training in environments that are truly internationally leading-edge. Fur ....The effects of alpha-2-macroglobulin on amyloid formation and toxicity. The expected outcomes will provide major advances in understanding how the abundant human blood protein alpha-2-macroglobulin influences the formation of protein aggregates that underpin a number of serious diseases (e.g. Alzheimer's disease). The linkages involved are of the highest calibre and will give the Fellowship holder a unique opportunity for training in environments that are truly internationally leading-edge. Furthermore, the very high novelty and broad significance of this work indicate that it will produce high-impact publications which will tangibly assist Australia being recognized as a major contributor to international research outcomes of the highest quality.Read moreRead less
Establishing the role of alpha-2-macroglobulin in quality control of extracellular protein folding. The expected outcomes will provide important advances in understanding the role of alpha-2-macroglobulin (A2M) in maintaining the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad si ....Establishing the role of alpha-2-macroglobulin in quality control of extracellular protein folding. The expected outcomes will provide important advances in understanding the role of alpha-2-macroglobulin (A2M) in maintaining the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad significance of this work indicate that it will produce high-impact publications which will tangibly assist Australia being recognized as a major contributor to world research outcomes. This project will also provide a direct social benefit by training research students with the skills necessary to further the development of biological research in Australia.Read moreRead less
Discovering Mechanisms for Quality Control of Extracellular Protein Folding. The expected outcomes will provide important advances in understanding of how the mammalian body maintains the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad significance of this work indicate that it w ....Discovering Mechanisms for Quality Control of Extracellular Protein Folding. The expected outcomes will provide important advances in understanding of how the mammalian body maintains the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad significance of this work indicate that it will produce high-impact publications which will tangibly assist Australia being recognized as a major contributor to world research outcomes. This project will also provide a direct social benefit by training research students with the skills necessary to further the development of biological research in Australia. Read moreRead less
Proteomic analysis of subcellular changes during apoptosis. This project aims to use a novel proteomic approach to examine mechanisms of apoptosis at the level of the plasma membrane, mitochondrion, nucleus and cytosol, screening protein extracts of cell organelles by the new technique of SELDI-TOF mass spectrometry in which proteins are adsorbed onto activated chips. This will provide protein mass profiles characteristic of various stages of apoptosis, and will allow identification of proteins ....Proteomic analysis of subcellular changes during apoptosis. This project aims to use a novel proteomic approach to examine mechanisms of apoptosis at the level of the plasma membrane, mitochondrion, nucleus and cytosol, screening protein extracts of cell organelles by the new technique of SELDI-TOF mass spectrometry in which proteins are adsorbed onto activated chips. This will provide protein mass profiles characteristic of various stages of apoptosis, and will allow identification of proteins of interest by conventional proteomic methods. The establishment of SELDI-MS as a viable tool for cell proteomics would open new opportunities to understand a broad range of cellular functions at the level of protein expression.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668241
Funder
Australian Research Council
Funding Amount
$824,610.00
Summary
A Facility for High-Throughput, Functional Gene Discovery Using Arrayed Retroviral Expression Cloning. The proposed facility will represent world-leading technology in functional genomics and provide Australian scientists with unique opportunities to identify genes involved in a broad range of biological processes. This will contribute to fundamental knowledge in mammalian biology, and equally importantly, is likely to identify genes involved in important health problems such as cancer, inflamma ....A Facility for High-Throughput, Functional Gene Discovery Using Arrayed Retroviral Expression Cloning. The proposed facility will represent world-leading technology in functional genomics and provide Australian scientists with unique opportunities to identify genes involved in a broad range of biological processes. This will contribute to fundamental knowledge in mammalian biology, and equally importantly, is likely to identify genes involved in important health problems such as cancer, inflammatory disease, brain damage and diabetes. Such genes may in turn constitute targets against which new therapies may be developed. This endeavour will contribute to national research priorities in both the health and scientific/technological development arenas.Read moreRead less
Structure and function of a new class of multi-zinc finger (MZF) transcriptional regulators. An understanding of how genes are switched on and off during the development and lifetime of an organism is central to developing the ability to fight many diseases in a rational way. This project will advance our knowledge in this area at a fundamental molecular level by examining the mechanisms through which a specific set of proteins controls gene expression.