Pre-clinical evaluation of snake venom proteins with therapeutic potential. Australia harbors some of the most toxic snakes in the world. Their venoms contain a range of substances that are designed to rapidly immobilize and kill their prey. These include agents that lead to enhanced blood clotting; excess bleeding. We have isolated and characterized a large number of the components involved over the last several years. The aim here is to carry out pre-clinical trials in animal models to test th ....Pre-clinical evaluation of snake venom proteins with therapeutic potential. Australia harbors some of the most toxic snakes in the world. Their venoms contain a range of substances that are designed to rapidly immobilize and kill their prey. These include agents that lead to enhanced blood clotting; excess bleeding. We have isolated and characterized a large number of the components involved over the last several years. The aim here is to carry out pre-clinical trials in animal models to test the efficacy of three proteins as anti-bleeding agents and investigate several other novel components. The ultimate outcome will be the development of novel drugs that will have application in the treatment of human disorders. Read moreRead less
Fish venom as a model system for the molecular evolution of defensive toxins. The key aim of this study is to undertake a thorough investigation of venoms found in distinct fish lineages, including enigmatic species such as venomous and medically important species such as the stonefish. By characterising the biodiversity of toxins found in the venoms of different fish, the evolutionary history of venom in this major vertebrate lineage can be revealed. The investigations proposed here will also d ....Fish venom as a model system for the molecular evolution of defensive toxins. The key aim of this study is to undertake a thorough investigation of venoms found in distinct fish lineages, including enigmatic species such as venomous and medically important species such as the stonefish. By characterising the biodiversity of toxins found in the venoms of different fish, the evolutionary history of venom in this major vertebrate lineage can be revealed. The investigations proposed here will also determine the functional activities of different venoms and their components. This will not only help the understanding of the medical consequences of the annual thousands of fish envenomings but also explore a largely unstudied resource for the discovery of new pharmacological diagnostics and therapeutics.Read moreRead less
Evolutionary venomics: Venom system diversification in the animal kingdom. This proposal represents a tremendous opportunity for biodiscovery from the Australian toxic fauna. This will be achieved through the researcher's unique approach of investigating previously unmapped venom systems for divergent, bioactive proteins. An understanding of venomous animal protein evolution has practical implications for the treatment of envenomations - an enormous problem in Australia - as well as great pot ....Evolutionary venomics: Venom system diversification in the animal kingdom. This proposal represents a tremendous opportunity for biodiscovery from the Australian toxic fauna. This will be achieved through the researcher's unique approach of investigating previously unmapped venom systems for divergent, bioactive proteins. An understanding of venomous animal protein evolution has practical implications for the treatment of envenomations - an enormous problem in Australia - as well as great potential in drug discovery and other commercial applications. This project will provide Australian graduate and post-graduate students with finely tuned skills in cutting edge methodological techniques and a fluent understanding of molecular evolution, preparing them to be internationally competitive scientists.Read moreRead less
Molecular evolution and toxinology of colubrid snake venom toxins. This project proposes to examine the origin and evolution of venom systems in advanced snakes (Caenophidia) focusing on the colubrid radiation comprising the rear-fanged species. Demonstration by us of the presence of a potent postsynaptic neurotoxin in the Durvenoy's secretions of the Asian ratsnake Elaphe radiata, an archetypal non-venomous colubrid species, forced a fundamental rethink of venom evolution. The toxin is homologo ....Molecular evolution and toxinology of colubrid snake venom toxins. This project proposes to examine the origin and evolution of venom systems in advanced snakes (Caenophidia) focusing on the colubrid radiation comprising the rear-fanged species. Demonstration by us of the presence of a potent postsynaptic neurotoxin in the Durvenoy's secretions of the Asian ratsnake Elaphe radiata, an archetypal non-venomous colubrid species, forced a fundamental rethink of venom evolution. The toxin is homologous with the three finger toxins, previously thought unique to elapids, and supports the role of venom as a key evolutionary innovation in the diversification of advanced snakes. This project extends this work to other species and toxin families.Read moreRead less
Genetics of Postmenopausal Bone Loss. The major consequence of bone loss in our ageing society is fracture. At 50 years for women, the lifetime risk of sustaining an osteoporotic fracture is 50%. The consequences of these fractures, which can include reduced life expectancy, prolonged medical care, and loss of independence, have a profound socioeconomic impact in an ageing population. The proposed study offers a unique opportunity to examine the contribution of genetic factors to postmenopausal ....Genetics of Postmenopausal Bone Loss. The major consequence of bone loss in our ageing society is fracture. At 50 years for women, the lifetime risk of sustaining an osteoporotic fracture is 50%. The consequences of these fractures, which can include reduced life expectancy, prolonged medical care, and loss of independence, have a profound socioeconomic impact in an ageing population. The proposed study offers a unique opportunity to examine the contribution of genetic factors to postmenopausal osteoporosis.Read moreRead less
Left-right patterning of the heart. This project aims to investigate how the heart responds to left-right (LR) signals, which tissue is dominant in this response; determine tissue intrinsic factors at play, and determine whether we can manipulate this. Expected outcomes include fundamental information about how organs are patterned.
Gene regulatory networks in heart development. In humans, structural and functional malformations of the heart are very common and are associated with a high economic and emotional burden. In this project, we will study how genetic networks initiate and control heart development at a molecular level. We will establish and employ state-of-the-art technologies and bioinformatics tools to explore the function of cardiac regulatory genes in detail. Our work will contribute both to discover new cardi ....Gene regulatory networks in heart development. In humans, structural and functional malformations of the heart are very common and are associated with a high economic and emotional burden. In this project, we will study how genetic networks initiate and control heart development at a molecular level. We will establish and employ state-of-the-art technologies and bioinformatics tools to explore the function of cardiac regulatory genes in detail. Our work will contribute both to discover new cardiac pathways for a better understanding of heart formation and disease, and to develop advanced techniques that will contribute to strengthen Australian basic and strategic research.Read moreRead less
Genetic analysis of lymphatic vascular development. This project investigates the fundamental molecular components that regulate lymphatic vascular system development in the zebrafish embryo. Lymphatic vessels play critical roles in vascular diseases and cancer metastasis. This study will identify and examine key new molecules that will further our basic understanding of lymphatic development.
The molecular control of lymphatic vascular differentiation. This project aims to improve our understanding of how a new vascular system forms and the molecules that control this process. Lymphatic vasculature plays roles in fluid drainage, inflammation, obesity, metastasis and tissue repair, yet we cannot readily promote or inhibit lymphatic vessel formation. This project aims to build new knowledge that is expected to improve our ability to generate lymphatic vessels for stem cell application ....The molecular control of lymphatic vascular differentiation. This project aims to improve our understanding of how a new vascular system forms and the molecules that control this process. Lymphatic vasculature plays roles in fluid drainage, inflammation, obesity, metastasis and tissue repair, yet we cannot readily promote or inhibit lymphatic vessel formation. This project aims to build new knowledge that is expected to improve our ability to generate lymphatic vessels for stem cell applications, tissue engineering, tissue repair and regeneration. This project will use zebrafish embryos, new genomic datasets and novel tools to uncover the genetic control of this process, and should have implications in stem cell biology, tissue engineering, repair and regeneration.Read moreRead less
Neurovascular pericytes in development and brain regeneration. The brain is responsible for a quarter of the body’s metabolism and is thus perfused by an extensive network of blood vessels. Pericytes surround these vessels and interact with neurons, glia, immune cells and neural stem cells of the neurovascular unit. Pericytes influence brain development, function and regeneration but remain enigmatic. This project investigates molecular control of pericyte development, functional coupling of per ....Neurovascular pericytes in development and brain regeneration. The brain is responsible for a quarter of the body’s metabolism and is thus perfused by an extensive network of blood vessels. Pericytes surround these vessels and interact with neurons, glia, immune cells and neural stem cells of the neurovascular unit. Pericytes influence brain development, function and regeneration but remain enigmatic. This project investigates molecular control of pericyte development, functional coupling of pericytes with adjacent cells and pericyte function in tissue regeneration. We aim to produce new fundamental knowledge in brain development, structure, function and evolution. New knowledge generated here may lead to future approaches in stem cell biology, tissue engineering, regeneration and ageing of the brain. Read moreRead less