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
How tissues generate the peptide hormone angiotensin II. This project aims to investigate how local tissue renin-angiotensin systems operate. A blood-borne renin–angiotensin system (RAS) produces a peptide (AngII) to control blood pressure, and fluid/salt balance. Many tissues, such as the brain and heart, also possess an independent, tissue RAS, but how these function is not well understood. The project will use a model whereby infiltrating macrophages (following damage to the heart) drive the ....How tissues generate the peptide hormone angiotensin II. This project aims to investigate how local tissue renin-angiotensin systems operate. A blood-borne renin–angiotensin system (RAS) produces a peptide (AngII) to control blood pressure, and fluid/salt balance. Many tissues, such as the brain and heart, also possess an independent, tissue RAS, but how these function is not well understood. The project will use a model whereby infiltrating macrophages (following damage to the heart) drive the activation of this system to trigger the local generation of AngII. This project addresses the question of where exactly in the heart the RAS components are turned on, how they interact to generate AngII and whether the activation of the local RAS is beneficial or not to cardiac function. The findings should provide critical insights into an important hormonal system.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.
Novel ways of regulating epithelial transport. This project is intended to discover novel intracellular mechanisms that regulate the rate of ion transport by the lung, the gut and the kidney. It will not only provide new insights into how the body controls a process that is critical to animal life, but also provide new targets for the development of pharmaceuticals.
Structural Determinants of an Intracellular Calcium Store. Understanding the molecular interactions between key proteins in calcium signalling in muscle and the heart will allow calcium signalling to be used as a platform for a variety of purposes. These include reducing the debilitating effects of changes in calcium signalling and muscle performance in aging and in genetically- or drug-induced disorders. The project will have benefits for Australian biotechnology since it will facilitate the de ....Structural Determinants of an Intracellular Calcium Store. Understanding the molecular interactions between key proteins in calcium signalling in muscle and the heart will allow calcium signalling to be used as a platform for a variety of purposes. These include reducing the debilitating effects of changes in calcium signalling and muscle performance in aging and in genetically- or drug-induced disorders. The project will have benefits for Australian biotechnology since it will facilitate the design of novel compounds for treating muscle disorders in animals and humans, for improving meat quality and for use as insecticides. The project will facilitate graduate and undergraduate training in basic science with exposure to biotechnology, through our commercial partner Biotron.Read moreRead less
The sulfate anion transporter gene, Sat1: physiology, regulation and developmental expression. Sulfate is an essential nutrient for cell growth and survival. The kidneys and liver help regulate sulfate levels in the body, by yet unknown mechanisms. Recently, we cloned a gene, Sat1, expressed in mouse liver and kidneys, which may be responsible for body sulfate maintenance. In this study, we will determine the physiological importance of Sat1 in cell growth/survival and in controlling body sulfa ....The sulfate anion transporter gene, Sat1: physiology, regulation and developmental expression. Sulfate is an essential nutrient for cell growth and survival. The kidneys and liver help regulate sulfate levels in the body, by yet unknown mechanisms. Recently, we cloned a gene, Sat1, expressed in mouse liver and kidneys, which may be responsible for body sulfate maintenance. In this study, we will determine the physiological importance of Sat1 in cell growth/survival and in controlling body sulfate levels. We will generate and characterise a Sat1 lacking mouse, study its expression during development and its effects on other genes. We will elucidate how body sulfate levels are maintained and its importance in cell growth/development.Read moreRead less
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
SKELETAL MUSCLE: REVERSIBLE TEMEPERATURE-INDUCED UNCOUPLING OF CONTRACTION FROM THE ACTIVATOR Ca2+ AND TUBULAR SYSTEM ROLES IN MUSCLE FUNCTION REGULATION. Skeletal muscles represent the largest organ in the body of vertebrates and are responsible for major functions including maintaining posture and locomotion. Skeletal muscles are also a major source of heat production. The project focuses on temperature-induced effects on the ability of the skeletal muscle to contract in warm blooded animals, ....SKELETAL MUSCLE: REVERSIBLE TEMEPERATURE-INDUCED UNCOUPLING OF CONTRACTION FROM THE ACTIVATOR Ca2+ AND TUBULAR SYSTEM ROLES IN MUSCLE FUNCTION REGULATION. Skeletal muscles represent the largest organ in the body of vertebrates and are responsible for major functions including maintaining posture and locomotion. Skeletal muscles are also a major source of heat production. The project focuses on temperature-induced effects on the ability of the skeletal muscle to contract in warm blooded animals, including marsupials, and on the complex roles played by a cellular structure unique to the muscle fibre, the tubular system, with respect to regulation of muscle function at physiological temperatures. The project will test hypotheses that will have far-reaching implications for muscle physiology, cell biology and evolutionary biology.Read moreRead less
Deciphering novel control mechanisms in the skin. The overall aim of this project is to understand the cellular mechanisms that maintain skin integrity, and in particular, the role of a novel population of regulatory cells in mediating this process. This is important for our understanding of fundamental physiological interactions in the skin. The proposed research aims to uncover essential new information regarding a recently discovered population of regulatory cells, with particular respect to ....Deciphering novel control mechanisms in the skin. The overall aim of this project is to understand the cellular mechanisms that maintain skin integrity, and in particular, the role of a novel population of regulatory cells in mediating this process. This is important for our understanding of fundamental physiological interactions in the skin. The proposed research aims to uncover essential new information regarding a recently discovered population of regulatory cells, with particular respect to understanding their mechanisms of action. The outcomes of this work should provide fundamental new knowledge of skin physiology and lead to novel insights regarding how skin integrity may be maintained following the disruption of homeostasis mechanisms.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