A bird's eye view of sex: the chicken embryo as a model for gonadal development. The development of an embryo as either male or female (sex determination) is a fundamental biological process that fascinates both scientific and lay communities alike. This project will use the chicken embryo as a unique model organism to study how genes control sex determination. We will bring a novel method to our field of study; the use of avian viruses to deliver genes into embryos. This project will enhance ou ....A bird's eye view of sex: the chicken embryo as a model for gonadal development. The development of an embryo as either male or female (sex determination) is a fundamental biological process that fascinates both scientific and lay communities alike. This project will use the chicken embryo as a unique model organism to study how genes control sex determination. We will bring a novel method to our field of study; the use of avian viruses to deliver genes into embryos. This project will enhance our understanding of a basic biological process. It will have application to the poultry industry, in terms of sex ratio manipulation. It will also aid in the diagnosis of humans born with sexual abnormalities. The project will consolidate Australia's standing as a world leader in the area of reproduction and development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561030
Funder
Australian Research Council
Funding Amount
$441,100.00
Summary
Developmental Imaging Facility. This application seeks to establish a facility to undertake expression profiling in vertebrate tissues on a genomic scale and at the highest resolution. Undertaking large scale projects of this nature requires specialised robotics and dedicated infrastructure for microscopy and tissue preparation. This facility will be the first of its type in Australia will permit researchers to perform genomic scale in situ screens, many as part of large international initiative ....Developmental Imaging Facility. This application seeks to establish a facility to undertake expression profiling in vertebrate tissues on a genomic scale and at the highest resolution. Undertaking large scale projects of this nature requires specialised robotics and dedicated infrastructure for microscopy and tissue preparation. This facility will be the first of its type in Australia will permit researchers to perform genomic scale in situ screens, many as part of large international initiatives in developmental and cellular biology. This large-scale, high-resolution expression profiling infrastructure is required to maintain international competitiveness and will dramatically improve our gene discovery, functional assessment and understanding of vertebrate development.Read moreRead less
A knockout approach to identifying genes involved in epidermal development and homeostasis. These studies will identify new genes which play a role in the development or maintenance of the skin, some of which may subsequently be shown to play a role in disease. The project capitalises on an investment of tens of millions of dollars by the Wellcome Trust in generating a significant cohort of knockout mice. Our involvement in this international initiative will ensure Australia's participation in ....A knockout approach to identifying genes involved in epidermal development and homeostasis. These studies will identify new genes which play a role in the development or maintenance of the skin, some of which may subsequently be shown to play a role in disease. The project capitalises on an investment of tens of millions of dollars by the Wellcome Trust in generating a significant cohort of knockout mice. Our involvement in this international initiative will ensure Australia's participation in a project at the forefront of mouse genetics, using cutting edge infrastructure and technologies to provide insights into the complement of genes involved in skin biology. Models of interest will be repatriated to Australia for further study capitalising on existing infrastructure provided through the NCRIS funding program. Read moreRead less
How do interactions between axon guidance molecules bring about directed axon growth? This project deals with a fundamental, yet poorly understood biological problem at the cutting edge of international science - how axons navigate to their targets. A better understanding of this basic biological process will greatly assist the development of therapies to treat a wide range of clinical conditions in which axonal connections between neurons are disrupted by trauma or disease.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668266
Funder
Australian Research Council
Funding Amount
$264,000.00
Summary
High Resolution Cellular and Molecular Imaging System. Understanding where molecules are within cells, and how they interact with each other, is fundamental to significant advances being made in biology. Our research will use advanced imaging techniques to localize proteins within a variety of cells including neurons and germ cells. We will be able to determine how the different molecules within a single cell interact with each other. This information is relevant to many biological mechanisms ....High Resolution Cellular and Molecular Imaging System. Understanding where molecules are within cells, and how they interact with each other, is fundamental to significant advances being made in biology. Our research will use advanced imaging techniques to localize proteins within a variety of cells including neurons and germ cells. We will be able to determine how the different molecules within a single cell interact with each other. This information is relevant to many biological mechanisms and to many human diseases. Furthermore, our research will help maintain Australia's strong international reputation in the fields of neuroscience, protein trafficking and stem cells. Read moreRead less
Adaptive Evolution of BRCA1 in Ancestral Mammals. This project investigates adaptive evolution of BRCA1 in the early radiation of mammals. We will test the hypothesis that the evolution of mammary glands and X chromosome inactivation has resulted in modification of the BRCA1 protein sequence as it aquired new roles in these processes. We will also investigate the importance of these changes inducing compensatory changes in other parts of the protein.
Molecular genetic analyses of trinucleotide repeat expansions. Several neuronal diseases like Huntington's disease, Frederick's ataxia and fragile X syndrome are caused by expansion of trinucleotide repeat sequences in the deoxyribonucleic acid (DNA). These diseases show progressive severity in subsequent generations. Here we use a simple plant model with a very similar DNA mutation to study the genetic basis of repeat expansions over several generations across populations. This proposal will im ....Molecular genetic analyses of trinucleotide repeat expansions. Several neuronal diseases like Huntington's disease, Frederick's ataxia and fragile X syndrome are caused by expansion of trinucleotide repeat sequences in the deoxyribonucleic acid (DNA). These diseases show progressive severity in subsequent generations. Here we use a simple plant model with a very similar DNA mutation to study the genetic basis of repeat expansions over several generations across populations. This proposal will improve our mechanistic understanding of genetic diseases in populations. In addition, this proposal is expected to lead to identification of potential targets and technologies that would be of interest to Australian industry.Read moreRead less
An RNA interference based genetic screen for novel epigenetic modifiers involved in mammalian X inactivation. All the information required to form an adult human is contained in the DNA of the fertilized egg. Development is achieved by a complex orchestration of genes being switched on and off, controlled by proteins called epigenetic modifiers. Sometimes this goes awry, leading to disease. Despite their vital role, only around ten percent of the potential epigenetic modifiers have been characte ....An RNA interference based genetic screen for novel epigenetic modifiers involved in mammalian X inactivation. All the information required to form an adult human is contained in the DNA of the fertilized egg. Development is achieved by a complex orchestration of genes being switched on and off, controlled by proteins called epigenetic modifiers. Sometimes this goes awry, leading to disease. Despite their vital role, only around ten percent of the potential epigenetic modifiers have been characterized in humans, making it impossible to interpret how they work together, or when they fail. We will develop a novel screen-based technology to find hundreds more true epigenetic modifiers. This technology will aid us and other Australian scientists to understand the role of epigenetics in normal development and disease, ultimately leading to better public health.Read moreRead less
Socs proteins in development and disease. Socs proteins are a component of a pathway that is central to a range of developmental processes, including embryonic development. In addition, there is evidence that these proteins are perturbed in several disorders. This Project will enhance our understanding of the Socs proteins and their role in disease, and ultimately provide an opportunity to identify new therapeutic strategies.
Unravelling the sub-nuclear complexity of the brain. Understanding the function of the brain is a major frontier of scientific research. The ability to increase knowledge of brain function is reliant upon the development of novel methods. This application will develop a novel approach for understanding the function of particular nerve cells. One outcome will be demonstration of the applicability of a novel method of benefit to all brain researchers. Another outcome will be increased understandin ....Unravelling the sub-nuclear complexity of the brain. Understanding the function of the brain is a major frontier of scientific research. The ability to increase knowledge of brain function is reliant upon the development of novel methods. This application will develop a novel approach for understanding the function of particular nerve cells. One outcome will be demonstration of the applicability of a novel method of benefit to all brain researchers. Another outcome will be increased understanding of one brain region that is known to contribute to the development of cardiovascular disease. It is expected that increased knowledge of brain function will lead to novel theories of brain disease and therapeutic strategies.Read moreRead less