Inhibitory control of retinal sensitivity. We will determine how the nerve cells that carry information from the eye to the brain are always able to provide signals despite very different environments; daylight, fog and night. Knowledge of how nerve cells achieve this rapid learning is important for any understanding of brain function; it is fundamental if we are to develop machines that see or that help restore vision in humans. The project will provide the world's first look at the synaptic ph ....Inhibitory control of retinal sensitivity. We will determine how the nerve cells that carry information from the eye to the brain are always able to provide signals despite very different environments; daylight, fog and night. Knowledge of how nerve cells achieve this rapid learning is important for any understanding of brain function; it is fundamental if we are to develop machines that see or that help restore vision in humans. The project will provide the world's first look at the synaptic physiology that underpins all visual perception, helping to bring Australia back to the forefront of research in this field. This new collaboration between two successful researchers will attract top quality students and researchers from Australia and abroad and be published in major journals.Read moreRead less
Cross-bridge cycling-dependent activation of force production in the absence of Ca2+ in fast- and slow-twitch skeletal muscle fibre types. The project will contribute new knowledge about how skeletal muscle works, which will be published in top international journals in biological sciences. This will increase the reputation of Australian science in muscle research and will have the potential to benefit Australian people and Australian athletes. The project will also provide several Australian re ....Cross-bridge cycling-dependent activation of force production in the absence of Ca2+ in fast- and slow-twitch skeletal muscle fibre types. The project will contribute new knowledge about how skeletal muscle works, which will be published in top international journals in biological sciences. This will increase the reputation of Australian science in muscle research and will have the potential to benefit Australian people and Australian athletes. The project will also provide several Australian research students the opportunity to develop sophisticated laboratory and reasoning skills.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989782
Funder
Australian Research Council
Funding Amount
$524,000.00
Summary
A Core Western Australian Cell Sorting Facility - Ultra-Small Objects and Rare Cell Populations. This new generic capacity to rapidly isolate structures smaller than the cell has extraordinarily wide application in the biological sciences. Making this capacity widely accessible through a core facility to the Western Australian research community will generate research outcomes of national and community benefit. Sorting chromosomes to better understand genetic abnormalities and sorting bacteria t ....A Core Western Australian Cell Sorting Facility - Ultra-Small Objects and Rare Cell Populations. This new generic capacity to rapidly isolate structures smaller than the cell has extraordinarily wide application in the biological sciences. Making this capacity widely accessible through a core facility to the Western Australian research community will generate research outcomes of national and community benefit. Sorting chromosomes to better understand genetic abnormalities and sorting bacteria to better understand and reduce bacterial infection will result in improvements in human health. Sorting parasites, bacteria and immune cells will lead to new animal vaccines for parasites and diseases such as bird flu. Sorting marine plankton will lead to more sustainable marine ecosystems and fisheries.Read moreRead less
Matching of gas exchanger structure and function with activity and environment in air-breathing fishes. This project will investigate the physiology and structure of Australian fishes that use gills and breathe air. It will measure the partitioning of oxygen and carbon dioxide exchange between the aquatic (gills) and aerial (lung, swim-bladder or mouth) respiratory organs, in relation to dissolved oxygen in the water and metabolic energy demands by the fish. Rates of gas exchange, biochemical ....Matching of gas exchanger structure and function with activity and environment in air-breathing fishes. This project will investigate the physiology and structure of Australian fishes that use gills and breathe air. It will measure the partitioning of oxygen and carbon dioxide exchange between the aquatic (gills) and aerial (lung, swim-bladder or mouth) respiratory organs, in relation to dissolved oxygen in the water and metabolic energy demands by the fish. Rates of gas exchange, biochemical characteristics of the blood, anatomy and physiology of the exchange organs, and respiratory/locomotory coupling will be measured in three selected species during graded exercise. The results will help us understand the factors influencing the evolution of air-breathing.Read moreRead less
Investigation of Macrophage Function in an Immunologically Privileged Site. The unique phenotype of the testicular macrophage demands understanding, and this project has the potential to open up an entirely new direction of research. The basic information so generated could facilitate development of strategies to alter either host or donor tissue macrophage functions in order to prevent rejection responses in humans, and be used in the development of new anti-inflammatory drugs. Such technologie ....Investigation of Macrophage Function in an Immunologically Privileged Site. The unique phenotype of the testicular macrophage demands understanding, and this project has the potential to open up an entirely new direction of research. The basic information so generated could facilitate development of strategies to alter either host or donor tissue macrophage functions in order to prevent rejection responses in humans, and be used in the development of new anti-inflammatory drugs. Such technologies will have application in development of novel therapeutics for transplantation and the treatment of chronic inflammatory diseases. Read moreRead less
Amino acids as nutrients - the molecular basis of amino acid absorption in kidney and intestine. Nutrition is a critical factor for well being and health. This is highlighted by the increase in frequency of type II diabetes and the obesity problem that all societies with a western diet face. Most studies in nutrition focus on fat and carbohydrates because of their direct involvement in obesity and diabetes. Proteins and the resulting peptides and amino acids, however, form 10-15% of our nutritio ....Amino acids as nutrients - the molecular basis of amino acid absorption in kidney and intestine. Nutrition is a critical factor for well being and health. This is highlighted by the increase in frequency of type II diabetes and the obesity problem that all societies with a western diet face. Most studies in nutrition focus on fat and carbohydrates because of their direct involvement in obesity and diabetes. Proteins and the resulting peptides and amino acids, however, form 10-15% of our nutrition. At a time where protein-rich diets are recommended to fight obesity and diabetes, it is important to understand the basis of protein absorption and metabolism. This project investigates the mechanism and mediators of amino acid absorption in kidney and intestine. Read moreRead less
Environmental Control of Developmental Plasticity of Vertebrate Cardio-Pulmonary Systems. Our research will generate the first comprehensive picture of how environmental conditions are transduced to control the development of the vertebrate respiratory and cardiovascular systems over the perinatal period. The research will demonstrate how physiological systems are modified and hence evolve. Moreover, understanding the developmental pathology in embryos induced by changing environmental condition ....Environmental Control of Developmental Plasticity of Vertebrate Cardio-Pulmonary Systems. Our research will generate the first comprehensive picture of how environmental conditions are transduced to control the development of the vertebrate respiratory and cardiovascular systems over the perinatal period. The research will demonstrate how physiological systems are modified and hence evolve. Moreover, understanding the developmental pathology in embryos induced by changing environmental conditions (especially exposure to steroid-like pollutants) is crucial to support breeding programs of endangered species and may improve veterinary and medicinal treatment of premature animals and humans. This multi-disciplinary, international collaboration provides an international training ground and two-way exchange of students and postdocs.Read moreRead less
Regulation of local lymphocyte trafficking and its role during infection. The study of early immune responses will contribute to the development of better vaccination strategies. In particular it will contribute by helping to understand the essential differences between reactogenicity and immunogenicity and how this relates to adjuvants. Using this understanding it will be possible to develop novel adjuvants that induce appropriate immunity with minimal side effects.
Relaxin: molecular mechanisms of action in the reversal of fibrosis. Defects in relaxin and relaxin receptors are increasingly implicated as a cause of fibrosis which is associated with many disease processes. This study will examine the molecular mechanisms linking relaxin and fibrosis and will determine whether relaxin can be used to reverse the condition.
A molecular structure-function investigation of major membrane channels involved in olfactory transduction. Olfactory receptor neurons are extraordinarily-sensitive sensors for detecting minute concentrations of odorant molecules. This project aims to extend our previous studies of these specialised mammalian olfactory cells by using state-of-the art technologies: electrophysiology (patch-clamp) and molecular biology (site-directed-mutagenesis), to investigate how the molecular structure of the ....A molecular structure-function investigation of major membrane channels involved in olfactory transduction. Olfactory receptor neurons are extraordinarily-sensitive sensors for detecting minute concentrations of odorant molecules. This project aims to extend our previous studies of these specialised mammalian olfactory cells by using state-of-the art technologies: electrophysiology (patch-clamp) and molecular biology (site-directed-mutagenesis), to investigate how the molecular structure of their ion channels (selective protein pores) and receptors contribute to the odorant-induced generation of electrical activity, which mediates our sense of smell (olfaction). The project has specific relevance for understanding olfaction, as well as relevance for other sensory systems and other ion channels.Read moreRead less