Mechanism of glutamate transport from experimental and simulation studies. Glutamate transporters play key roles in shaping the electrical signaling in the brain. Under conditions of stress or after a stroke, glutamate transporter function is impaired, which can lead to excessive levels of glutamate, cell death and impaired brain function. The project will help to decipher the operation of glutamate transporters at a molecular level and provide greater understanding of how glutamate levels are c ....Mechanism of glutamate transport from experimental and simulation studies. Glutamate transporters play key roles in shaping the electrical signaling in the brain. Under conditions of stress or after a stroke, glutamate transporter function is impaired, which can lead to excessive levels of glutamate, cell death and impaired brain function. The project will help to decipher the operation of glutamate transporters at a molecular level and provide greater understanding of how glutamate levels are controlled, which is vital for developing better treatments for neurological disorders such as stroke. The project will also provide research training in experimental/computational molecular biology, which is a rapidly growing field underpinning the biotechnological and pharmaceutical industries. Read moreRead less
Redefining the metallothionein's role in the injured brain: extracellular metallothioneins play an important role in astrocyte-neuron responses to injury. This project is being performed by an Australian team of researchers who are leaders in this field of research, and has significant national benefits in supporting this team reveal fundamental information on the cellular interactions that occur between astrocytes and neurons within the injured brain. In national terms, it will contribute to th ....Redefining the metallothionein's role in the injured brain: extracellular metallothioneins play an important role in astrocyte-neuron responses to injury. This project is being performed by an Australian team of researchers who are leaders in this field of research, and has significant national benefits in supporting this team reveal fundamental information on the cellular interactions that occur between astrocytes and neurons within the injured brain. In national terms, it will contribute to the concerted effort by Australian scientists to understand how and why neurons die following brain injury or neurodegenerative disease. Furthermore, this research contributes directly to the Designated National Research Priorities by identifying some of the earliest biochemical and cellular processes associated with aging or disease of the brain.Read moreRead less
Function and regulation of the Na+,K+-ATPase. The Na+,K+-ATPase is the major energy-consuming enzyme of animal cells. Its ion pumping is essential for numerous physiological functions (e.g. heart, kidney, brain). Molecular detail of its pumping mechanism is, however, lacking and its regulation is still unclear. We will use rapid reaction methods on purified enzyme in vitro to locate the rate-determining step of the enzyme cycle, determine its mechanism, investigate its regulation by sodium conce ....Function and regulation of the Na+,K+-ATPase. The Na+,K+-ATPase is the major energy-consuming enzyme of animal cells. Its ion pumping is essential for numerous physiological functions (e.g. heart, kidney, brain). Molecular detail of its pumping mechanism is, however, lacking and its regulation is still unclear. We will use rapid reaction methods on purified enzyme in vitro to locate the rate-determining step of the enzyme cycle, determine its mechanism, investigate its regulation by sodium concentration, phosphorylation and membrane composition, and isolate its charge-transporting steps. The results will have immediate impact on the understanding of the enzyme's mechanism, its metabolic control and its role in disease.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
LIM-homeodomain interactions in neuronal development. The loss of central nervous system function, through accident or disease, is devastating for affected individuals and their families. Our current inability to stimulate the regeneration of nervous tissue is a result of the lack of detailed knowledge of the complex processes that must take place, at the molecular and cellular levels, during neuronal development. We are determining how a group of cellular proteins that have key roles in motor n ....LIM-homeodomain interactions in neuronal development. The loss of central nervous system function, through accident or disease, is devastating for affected individuals and their families. Our current inability to stimulate the regeneration of nervous tissue is a result of the lack of detailed knowledge of the complex processes that must take place, at the molecular and cellular levels, during neuronal development. We are determining how a group of cellular proteins that have key roles in motor neuron development interact with each other and with DNA. With this information we are developing reagents that can be used to further probe central nervous system function and may ultimately be used to regenerate damaged nerves.Read moreRead less
The biological and pathological functions of TDP-43. The social and economic burden of neurodegenerative such as MND is enormous. A key histopathological hallmark of this and many other related diseases are deposits of the protein TDP-43. Our research aims at understanding its largely unknown functions, for example by generating transgenic animal models. These will form the base for the development for a TDP-43-directed drug treatment. The national benefit of this research is manifold: by deciph ....The biological and pathological functions of TDP-43. The social and economic burden of neurodegenerative such as MND is enormous. A key histopathological hallmark of this and many other related diseases are deposits of the protein TDP-43. Our research aims at understanding its largely unknown functions, for example by generating transgenic animal models. These will form the base for the development for a TDP-43-directed drug treatment. The national benefit of this research is manifold: by deciphering basic biological mechanisms, patenting new data, developing treatment strategies for un-curable and fatal disorders, and expanding links to Australian biotech and international pharmaceutical companies.Read moreRead less
Neuronal functions of the microtubule-associated protein tau in development and ageing. The project uses a combination of transgenic mouse strains characterised by neurodegeneration and senescence-accelerated (SAM) mice, to determine the first steps of the aggregation of the protein tau in degenerating neurons, how absence of tau protects from brain atrophy, and in which physiological processes tau is involved. This project provides the biological foundation for a tau-based therapy of senescence ....Neuronal functions of the microtubule-associated protein tau in development and ageing. The project uses a combination of transgenic mouse strains characterised by neurodegeneration and senescence-accelerated (SAM) mice, to determine the first steps of the aggregation of the protein tau in degenerating neurons, how absence of tau protects from brain atrophy, and in which physiological processes tau is involved. This project provides the biological foundation for a tau-based therapy of senescence-associated conditions. It provides the biological foundation for developing effective therapies for human neurodegenerative conditions, by preventing tau aggregation and phosphorylation. We will patent new data and expand our existing links to Australian biotech and international pharmaceutical companies.Read moreRead less
Novel human tryptases: their potential role in inflammatory diseases of the young and old. We have discovered a number of novel human tryptases, and while other members of this enzyme family have been implicated in the development of inflammatory diseases (including rheumatoid arthritis), little is known about these new molecules. We aim to characterise these new enzymes by determining what part of the body they are produced in, whether they are associated with specific inflammatory diseases, an ....Novel human tryptases: their potential role in inflammatory diseases of the young and old. We have discovered a number of novel human tryptases, and while other members of this enzyme family have been implicated in the development of inflammatory diseases (including rheumatoid arthritis), little is known about these new molecules. We aim to characterise these new enzymes by determining what part of the body they are produced in, whether they are associated with specific inflammatory diseases, and what target molecules they act on. A better understanding of these factors will increase the chances of finding cures and developing better treatments for important inflammatory diseases of the ageing population.Read moreRead less
Biological probes for understanding mammalian cellular transport mechanisms. Cellular components are moved around within cells by molecular motors. This fundamental transport mechanism depends on a network of tracks. Blocks in this cellular transport can result in a number of mammalian diseases, particularly within nerve cells. This project will increase our understanding of the mechanisms of cellular transport and, in particular, how molecular motors engage their cargo. This is essential ground ....Biological probes for understanding mammalian cellular transport mechanisms. Cellular components are moved around within cells by molecular motors. This fundamental transport mechanism depends on a network of tracks. Blocks in this cellular transport can result in a number of mammalian diseases, particularly within nerve cells. This project will increase our understanding of the mechanisms of cellular transport and, in particular, how molecular motors engage their cargo. This is essential groundwork for the development of drugs that target this transport mechanism.Read moreRead less
Visualising neuron-glia interactions in the injured central nervous system. The adult brain and spinal cord recovery poorly from injury. Attempts to overcome this problem include methods to promote the intrinsic regenerative capacity of injured neurons, and modulating the inhibitory extracellular environment to become permissive to regeneration. The goal of this project is to investigate an endogenous regenerative mechanism in the injured brain. This project will use the latest, cutting-edge mic ....Visualising neuron-glia interactions in the injured central nervous system. The adult brain and spinal cord recovery poorly from injury. Attempts to overcome this problem include methods to promote the intrinsic regenerative capacity of injured neurons, and modulating the inhibitory extracellular environment to become permissive to regeneration. The goal of this project is to investigate an endogenous regenerative mechanism in the injured brain. This project will use the latest, cutting-edge microscopy techniques to visualise whether the endogenous astrocyte protein metallothionein can promote regeneration in the injured nervous system of living zebrafish. The successful outcomes of this project will provide significant insight into understanding how the brain responds to injury.Read moreRead less