Transcription factor nuclear residency as a driver of gene expression. Persistently active proteins can stay in the nucleus to drive cell growth and prevent cell death. This project will define how one specific active protein can remain in the nucleus and regulate gene expression through the action of unique ribonucleic acid (RNA) molecules. The results will enable persistent gene activation to be manipulated in cancer.
Physiology and genetics of barley grain germination in the malting and brewing industries. An international research team will provide new scientific information on barley grain germination. This detailed basic knowledge will be immediately applied in breeding programs that are aimed at improving malting and brewing quality in a commercial context. At the same time, the industry's carbon footprint will be significantly reduced.
Regulatory mechanisms for calcium release-activated calcium channels. Store-operated calcium channels play a central role in the functions of all animal cells. They participate in generating the cellular responses to hormones, growth factors and other physiological stimuli. The aims of this project are to elucidate the mechanisms that regulate the activity of store-operated channels and how their properties can be modulated by different pharmacological agents. Using chiefly the techniques of ele ....Regulatory mechanisms for calcium release-activated calcium channels. Store-operated calcium channels play a central role in the functions of all animal cells. They participate in generating the cellular responses to hormones, growth factors and other physiological stimuli. The aims of this project are to elucidate the mechanisms that regulate the activity of store-operated channels and how their properties can be modulated by different pharmacological agents. Using chiefly the techniques of electrophysiology and molecular biology we expect to learn the fundamental mechanisms that modulate the opening and closing of store-operated calcium channels and to gain an important information that can be used for determining the molecular structure of these channelsRead moreRead less
Second messenger-activated calcium channels in liver cells. This project concerns second messenger-activated calcium channels, part of the family of hormone-activated calcium channels which are essential to the functions of all animal cells. The aims are to elucidate the properties of a novel "large conductance" Ca2+ channel (using maitotoxin as an artificial activator), an inositol 1,4,5-trisphosphate-activated calcium channel, and the calcium channel formed by the transient receptor potential ....Second messenger-activated calcium channels in liver cells. This project concerns second messenger-activated calcium channels, part of the family of hormone-activated calcium channels which are essential to the functions of all animal cells. The aims are to elucidate the properties of a novel "large conductance" Ca2+ channel (using maitotoxin as an artificial activator), an inositol 1,4,5-trisphosphate-activated calcium channel, and the calcium channel formed by the transient receptor potential-1 (TRP-1) protein in hepatocytes. The electrophysiological properties, mechanisms of activation and intracellular trafficking of the channels will be investigated. It is anticipated the results will provide basic information on the physiological functions of second messenger-activated calcium channels. This will benefit the understanding of liver function, hepatotoxicity in animals, animal production and the development of pharmaceuticals in animal husbandary.Read moreRead less
The bHLH.PAS transcription factors: Determinants of dimerization specificity and high affinity DNA binding. This program of fundamental research will advance our knowledge of the way essential proteins act to correctly regulate critical biological processes. A detailed understanding of these processes at the molecular level has the potential to contribute to the design of pharmaceutical compounds to assist in the treatment of diseases such as ischaemia, myocardial infarction and tumour progress ....The bHLH.PAS transcription factors: Determinants of dimerization specificity and high affinity DNA binding. This program of fundamental research will advance our knowledge of the way essential proteins act to correctly regulate critical biological processes. A detailed understanding of these processes at the molecular level has the potential to contribute to the design of pharmaceutical compounds to assist in the treatment of diseases such as ischaemia, myocardial infarction and tumour progression. The work will contribute to the training of one or more graduate students in a technologically advancing and internationally competitive field.Read moreRead less
Molecular dynamics of steroid receptor crosstalk. This project uses state-of-the-art technology to show how steroids (for example, testosterone) affect many aspects of human life, and how these can be disrupted by chemicals and synthetic hormones. The results can be used to interpret disease, predict safety of new drugs, and to monitor risk to humans and wildlife of environmental chemicals.
Investigation of the fundamental roles of class Ib MHC (major histocompatibility complex) molecules in immunity. The proposed research program, using laboratory-based and synchrotron-based radiation, will provide insight into the roles of a poorly understood class of immune molecules. This will improve our understanding of the regulation of immunity, and the knowledge gained will increase Australia's international research profile.
Defining the spatial and temporal regulation of neurite branching. This project aims to identify mechanisms via which the cytoskeleton regulates the branching of nerve cell extensions. The formation of branched cell extensions is essential for establishing a complex network of connecting and communicating nerve cells in all higher organisms. This project expects that by combining advanced light microscopy technology and recently developed tools for the study of the cell architecture in vitro and ....Defining the spatial and temporal regulation of neurite branching. This project aims to identify mechanisms via which the cytoskeleton regulates the branching of nerve cell extensions. The formation of branched cell extensions is essential for establishing a complex network of connecting and communicating nerve cells in all higher organisms. This project expects that by combining advanced light microscopy technology and recently developed tools for the study of the cell architecture in vitro and in vivo, we will be able to define the molecular changes in neurites that control neurite branching. This should provide significant benefits, such as gaining crucial insights into the mechanisms of forming complex neuronal networks.Read moreRead less
Structural studies of the interactions of actinin-4 and intracellular signalling proteins. The intracellular signalling cascade plays important roles in cellular processes such as growth and differentiation by exerting changes in gene expression or remodelling of the intracellular protein framework. The actin-based cytoskeleton is one such network of proteins responsible for a number of processes including cell division, migration and adhesion to other cells and tissues. This proposal aims to un ....Structural studies of the interactions of actinin-4 and intracellular signalling proteins. The intracellular signalling cascade plays important roles in cellular processes such as growth and differentiation by exerting changes in gene expression or remodelling of the intracellular protein framework. The actin-based cytoskeleton is one such network of proteins responsible for a number of processes including cell division, migration and adhesion to other cells and tissues. This proposal aims to understand how actinin-4, a component of the actin cytoskeleton in non-muscle tissues, interacts with and is stimulated by proteins of the intracellular signalling cascade.Read moreRead less
Non-classical steroid signalling through SF-1 responsive genes: a key mechanism in environmental endocrine disruption, cancer, and aging. Endocrine disruption by pervasive manmade chemicals, which mimic natural hormones, and are found in plastics, cosmetics, and fire retardants, is known to cause developmental defects in model organisms and wildlife, with substantial risk also to human health. This risk increases with increasing population density and dependence on water recycling. Current tests ....Non-classical steroid signalling through SF-1 responsive genes: a key mechanism in environmental endocrine disruption, cancer, and aging. Endocrine disruption by pervasive manmade chemicals, which mimic natural hormones, and are found in plastics, cosmetics, and fire retardants, is known to cause developmental defects in model organisms and wildlife, with substantial risk also to human health. This risk increases with increasing population density and dependence on water recycling. Current tests to assess such substances use oversimplified modes of hormone action and grossly underestimate the risk of endocrine disruption. This proposal will yield new knowledge about how such substances act in the body, or on wildlife, and form the basis for new more sensitive methods of environmental monitoring.Read moreRead less