Identifying The Pathological Mechanism Of PCDH19-Girls Clustering Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$523,988.00
Summary
Changes in the PCDH19 gene are a relatively common cause of epilepsy. To better understand the basis of this disorder, we have developed unique mouse models that mimic the genetic changes and symptoms of this condition. We will perform careful analysis of brain development in these models to determine the primary cause of this condition. These experiments will create greater understanding of how changes in PCDH19 cause epilepsy in girls and facilitate the development of new treatments.
The genetic basis of leaf lamina establishment and growth. This study will help reveal how the development of leaves is coordinated by tissue patterning genes and the plant growth hormone auxin. All plants grow in this way, and the findings, made using a model laboratory plant, will be applicable to crop species as well.
Understanding the evolution of the alternation of generations in the land plant life cycle. This project will investigate the genetic basis and evolution of the land plant life cycle, in which both haploid and diploid phases consist of complex multicellular bodies. The project's findings, which will be made using two model laboratory plants, will be applicable to all plants and will help understand important processes such as pollen and seed production.
Molecular mechanisms that generate muscle cell type diversity. The general aim of this project is to exploit the advantages of the zebrafish system and our access to the embryology of Australian shark species to generate an understanding of the basis for muscle fibre diversity and evolution. While there is some understanding of the fundamental genetic basis of how to make an individual muscle cell from a nascent myoblast there is far less knowledge on how individual muscle cells generate mature ....Molecular mechanisms that generate muscle cell type diversity. The general aim of this project is to exploit the advantages of the zebrafish system and our access to the embryology of Australian shark species to generate an understanding of the basis for muscle fibre diversity and evolution. While there is some understanding of the fundamental genetic basis of how to make an individual muscle cell from a nascent myoblast there is far less knowledge on how individual muscle cells generate mature muscle types and patterns. The intended outcome of this research is to generate understanding of the complex molecular basis of muscle patterning in the simple paradigm of the zebrafish myotome that could be applied across the vertebrate phylogeny.Read moreRead less
Development and evolution of land plant shoots. How do plants grow and develop their wonderful diversity of forms, from cereal crops to eucalypt forests? The project aims to understand basic mechanisms of plant development via comparative studies using the model angiosperm, Arabidopsis, and the liverwort, Marchantia, which possesses a simplified genome. Comparative studies of the genetic basis of the body plan, branching, and hormonal action could unlock their evolutionary elaboration from the s ....Development and evolution of land plant shoots. How do plants grow and develop their wonderful diversity of forms, from cereal crops to eucalypt forests? The project aims to understand basic mechanisms of plant development via comparative studies using the model angiosperm, Arabidopsis, and the liverwort, Marchantia, which possesses a simplified genome. Comparative studies of the genetic basis of the body plan, branching, and hormonal action could unlock their evolutionary elaboration from the simpler liverworts to more complex flowering plants. The project may generate new understanding of the principles of how genes and hormones control the architecture of plant shoot systems, and support the targeted selection of new agricultural plants.Read moreRead less
The integration of physical and genetic signals in cardiac development. The patterning of the heart is a highly complicated process. This project will investigate how blood flow through the heart, as a result of heart function, is important in stimulating the formation of structures within the heart and changes in the shape of the heart as it grows.
Understanding gonadal development and disease using a unique model system, the avian embryo. This project will provide information on normal and abnormal gonadal development during embryonic life. The study will aid in the diagnosis and management of humans born with disorders of sexual development and will be useful for sex ratio manipulation in the poultry industry.
Genetic regulation of testis development in the chicken embryo. This project aims to shed light on the genetic control of testis development during embryonic life, using the chicken embryo as a model. The results will have implications for sex ratio manipulation in poultry and for our understanding of sexual disorders in humans.
Determining The Impact Of Inherited Epigenetic Information On Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$511,691.00
Summary
Recent observations show that the environment in which you live can alter disease susceptibility in your children, without altering the sequence of your genes. This is due to epigenetic mechanisms which control the way the DNA is interpreted. In this study we will study the potential for epigenetic mechanisms to affect sperm production and impact characteristics and disease in the next generation.
Old genes learning new tricks: characterising regulatory changes driving increased heart complexity during vertebrate evolution. The heart has dramatically increased in morphological complexity during vertebrate evolution but the molecular basis driving these major changes remains unknown. Using comparative genomics approaches, this project will explore changes in the regulation of genes involved in heart formation that lead to changes in cardiac structure. It will elucidate for the first time t ....Old genes learning new tricks: characterising regulatory changes driving increased heart complexity during vertebrate evolution. The heart has dramatically increased in morphological complexity during vertebrate evolution but the molecular basis driving these major changes remains unknown. Using comparative genomics approaches, this project will explore changes in the regulation of genes involved in heart formation that lead to changes in cardiac structure. It will elucidate for the first time the cardiac regulatory repertoire in zebrafish and will compare it with that of fly and mouse using cutting-edge bioinformatics pipelines. This work will unravel cardiac-specific regulatory modifications that give rise to evolutionary changes. On a broader scale, it will shed new light on the role of regulatory innovations over gene innovations in the emergence of new traits.Read moreRead less