Plant Transfer Cells - Discovering the Mechanisms of Wall Ingrowth Formation. This project seeks fundamental molecular understanding of how specialized plant cells that are designed for optimum transport of nutrients develop. So-called "transfer cells" are important for efficient nutrient transport and distribution in many crop species of significance to agriculture. Discovering the mechanisms that coordinate development of these specialized cells will maintain Australia's international reputat ....Plant Transfer Cells - Discovering the Mechanisms of Wall Ingrowth Formation. This project seeks fundamental molecular understanding of how specialized plant cells that are designed for optimum transport of nutrients develop. So-called "transfer cells" are important for efficient nutrient transport and distribution in many crop species of significance to agriculture. Discovering the mechanisms that coordinate development of these specialized cells will maintain Australia's international reputation in this field of research, as well as provide technological opportunities to enhance crop yields by manipulating the efficiency of nutrient distribution in crop species. Read moreRead less
Induction of Plant Transfer Cells - Discovering Regulatory Networks. This project seeks molecular understanding of regulatory mechanisms responsible for inducing formation of specialized plant cells that are of central importance in controlling nutrient transport. These so-called "transfer cells" play pivotal roles in determining crop nutrition and hence yield under normal and stressful environments such as soil nutrient deficiencies and salinity. Discovering regulatory mechanisms that control f ....Induction of Plant Transfer Cells - Discovering Regulatory Networks. This project seeks molecular understanding of regulatory mechanisms responsible for inducing formation of specialized plant cells that are of central importance in controlling nutrient transport. These so-called "transfer cells" play pivotal roles in determining crop nutrition and hence yield under normal and stressful environments such as soil nutrient deficiencies and salinity. Discovering regulatory mechanisms that control formation of these specialized cells will maintain Australia's international reputation in this field of research. In addition, the information platform generated may provide technological opportunities to optimise nutrient flows in healthy plants, combat certain environmental stresses and control pathogen attack.
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Investigating the activator function of the Bim protein. Apoptosis is a research area where Australia has had long standing success. The first observations of this important process were made by Prof John Kerr in the 60's and 70's. A molecular renaissance developed in the late 80's and has led to the current explosion in this area of research. Many of these recent studies have been conducted at the Walter and Eliza Hall Institute. Our scientific endeavour is aimed at broadening the understanding ....Investigating the activator function of the Bim protein. Apoptosis is a research area where Australia has had long standing success. The first observations of this important process were made by Prof John Kerr in the 60's and 70's. A molecular renaissance developed in the late 80's and has led to the current explosion in this area of research. Many of these recent studies have been conducted at the Walter and Eliza Hall Institute. Our scientific endeavour is aimed at broadening the understanding of the mechanisms of cell death using genetically modified mouse models. Insights gained through this project will have far reaching implications for the design of new drugs to combat cancer and degenerative diseases.Read moreRead less
Neurotrophic factors for pelvic autonomic neurons: the role of neurturin. This project is about pelvic parasympathetic neurons, which are responsible for involuntary activities such as bladder voiding and penile erection. We are interested in the neurotrophic factors that determine survival of these neurons during early mammalian development and keep them healthy in adults. Little is known about ?parasympathetic neurotrophic factors? in general. However we have recently discovered that the prote ....Neurotrophic factors for pelvic autonomic neurons: the role of neurturin. This project is about pelvic parasympathetic neurons, which are responsible for involuntary activities such as bladder voiding and penile erection. We are interested in the neurotrophic factors that determine survival of these neurons during early mammalian development and keep them healthy in adults. Little is known about ?parasympathetic neurotrophic factors? in general. However we have recently discovered that the protein neurturin is very important in the pelvic parasympathetic system. We will determine exactly how neurturin affects pelvic neurons and how it interacts with other neurotrophic factors. Our results will fill a major gap in our knowledge of fundamental neurobiology.Read moreRead less
Development of sympathetic nerve pathways. The mature nervous system contains many types of neurons connected in precise ways. Developing neurons must make many decisions about what type of neuron to become and what connections to make. This study looks at the mechanisms that guide the developing neurons in these important decisions.
Genes to phenotype: Exploiting the marsupial model. This research will exploit one of Australia's finest natural resources, its marsupial fauna. The features of marsupial reproduction and development provide a unique opportunity to answer fundamental biological questions. This research will show how the minor differences in key developmental genes that have arisen in their 100 million year isolation give rise to the characteristic differences in developmental timing and reproduction between mar ....Genes to phenotype: Exploiting the marsupial model. This research will exploit one of Australia's finest natural resources, its marsupial fauna. The features of marsupial reproduction and development provide a unique opportunity to answer fundamental biological questions. This research will show how the minor differences in key developmental genes that have arisen in their 100 million year isolation give rise to the characteristic differences in developmental timing and reproduction between marsupials and other mammals. The focus on reproduction and development will also provide invaluable knowledge to underpin efforts to conserve our endangered species and to control those that are overabundant.Read moreRead less
Re-uniting marsupials and eutherians by embryonic micromanipulation. The unique responsibility for transmitting life from generation to generation normally depends on the gametes. This project will use new reproductive technologies to investigate the properties of the oocyte in reprogramming somatic cell nuclei, and will use the nuclei of both marsupial and eutherian somatic cells to test this. We will also use both marsupial and eutherian genes to insert into the oocyte to create the first tra ....Re-uniting marsupials and eutherians by embryonic micromanipulation. The unique responsibility for transmitting life from generation to generation normally depends on the gametes. This project will use new reproductive technologies to investigate the properties of the oocyte in reprogramming somatic cell nuclei, and will use the nuclei of both marsupial and eutherian somatic cells to test this. We will also use both marsupial and eutherian genes to insert into the oocyte to create the first transgenic marsupials. We will also investigate the ability of spermatozoa from species of increasing genetic distance to ferttilise marsupial eggs using intracytoplasmic sperm injection (ICSI).Read moreRead less
The role of turgor in hyphal extension of the Ascomycete Neurospora crassa. Cellular expansion is an absolute necessity during the growth and development of plants and fungi. This process relies heavily upon the accumulation of inorganic ions. Osmotically driven water influx then creates the hydrostatic pressure that underlies the increase in cell volume. Cellular expansion is normally asymmetric and localised in one small region, such as hyphal tip. How does the cell maintain the turgor that dr ....The role of turgor in hyphal extension of the Ascomycete Neurospora crassa. Cellular expansion is an absolute necessity during the growth and development of plants and fungi. This process relies heavily upon the accumulation of inorganic ions. Osmotically driven water influx then creates the hydrostatic pressure that underlies the increase in cell volume. Cellular expansion is normally asymmetric and localised in one small region, such as hyphal tip. How does the cell maintain the turgor that drives expansion? How is expansion controlled spatially? These questions will be addressed in this project by comprehensive study of ion transport processes in a model organism, Neurospora crassa, using osmotic sensitive and transport mutants.Read moreRead less
Quantifying the adaptive immune response. The aim of this project is to develop mathematical models and computer software capable of predicting immune responses in infection and disease. The ability to predict immune responses should allow better vaccine design and better understanding of what causes the immune system to attack its own body, causing autoimmune disease, or fail to respond, causing immunodeficiency. The models and software will also be applicable to other areas of cell biology, ....Quantifying the adaptive immune response. The aim of this project is to develop mathematical models and computer software capable of predicting immune responses in infection and disease. The ability to predict immune responses should allow better vaccine design and better understanding of what causes the immune system to attack its own body, causing autoimmune disease, or fail to respond, causing immunodeficiency. The models and software will also be applicable to other areas of cell biology, such as describing growth and development. Thus, this project will lead to advances in understanding of fundamental biology, as well as potential improvements in treatments for a range of diseases.Read moreRead less
Marsupial germ cells and genes. Germ cells are the most fascinating cells in the body, since theirs is the unique responsibility for transmitting life from generation to generation. Studies in mice have suggested that position in the embryo determines their origin, but the early embryology of the mouse is so different from that of other mammals that the events need confirming and extending in another species. The simplified embryology of the tammar wallaby makes it ideal for studying one of the ....Marsupial germ cells and genes. Germ cells are the most fascinating cells in the body, since theirs is the unique responsibility for transmitting life from generation to generation. Studies in mice have suggested that position in the embryo determines their origin, but the early embryology of the mouse is so different from that of other mammals that the events need confirming and extending in another species. The simplified embryology of the tammar wallaby makes it ideal for studying one of the most fundamental questions in the whole of biology: what is the basis for the primal distinction between sex and soma?Read moreRead less