Defining The Role Of IGF-1 As A Novel Angiocrine Factor In The Development And Treament Of Common Craniofacial Disorders
Funder
National Health and Medical Research Council
Funding Amount
$573,848.00
Summary
1 in 1000 children are born with a small jaw, which requires invasive surgery for treatment. We identified that defects in blood vessel development in the jaw underlie some cases of these craniofacial defects. We found that factors secreted from the major artery in the jaw can promote jaw growth, and our research proposal aims to identify what exactly these factors are. These factors have the potential to be used to therapeutically treat children with a small jaw to help it grow correctly.
Novel Roles For Neural Crest Cells In Cardiac Morphogenesis
Funder
National Health and Medical Research Council
Funding Amount
$553,848.00
Summary
Abnormal formation of the cardiac outflow tract leads to common malformations affecting over 1% of all births. Taking advantage of novel mouse models this grant aims to identify the molecular mechanisms by which neural crest cells control formation of the cardiac outflow tract. New information generated from this study stands to identify new targets which may be used for predictive testing and regenerative therapies.
Functional Screening Of Novel Genes In Craniofacial Development
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
Our faces are central to our ability to communicate, feed, breath and interact with each other. Birth defects that impact on the normal development of the face are common and affect not only the child but have a dramatic impact on the child's family as well. The genetic causes of most facial birth defects are unknown. This project will develop a method for determining how development of the face is controlled and will help identify genes that are responsible for facial birth defects.
Globally, zebrafish are making a very significant impact on biomedical research. Zebrafish have a number of attributes that make them ideal models for the study of development and disease, including: - adults are relatively small, so housing is cheap - eggs are transparent, so early developmental processes can be visualized easily - development is rapid - organs are made in 1-7 days - zebrafish are vertebrates and thus have a gene complement very similar to humans - large numbers of eggs are pro ....Globally, zebrafish are making a very significant impact on biomedical research. Zebrafish have a number of attributes that make them ideal models for the study of development and disease, including: - adults are relatively small, so housing is cheap - eggs are transparent, so early developmental processes can be visualized easily - development is rapid - organs are made in 1-7 days - zebrafish are vertebrates and thus have a gene complement very similar to humans - large numbers of eggs are produced each week from a single mother, aiding experimentation - ENU mutagenesis screens have generated thousands of useful mutants, including an increasing number that accurately model human genetic diseases - high-resolution imaging of RNA and protein expression in whole embryos is easy - drugs and chemicals can be easily tested for activities in zebrafish by adding them to the water Becuase of these attributes, zebrafish are becoming the model organism of choice for the study to human development and disease - indeed, the zebrafish field is growing at three times the rate of the mouse field. The international biomedical community has invested very heavily in infrastructure to aid the zebrafish community in realising the potential of this model. In Australia we have very strong basic research teams whom have embraced zebrafish mdoels. However, we lag behind other parts of the world in that, as yet, we have not had much specific funding allocated to animal model infrastructure. This Enabling Grant will build unique infrastructure by bringing together the zebrafish community with two areas in which Australia is very strong - genomics and biodiversity. This will result in a greatly enhanced ability to determine how genes work, and a pipeline for screening Australia's rich source of natural products and chemical libraries for activites against common human diseases such as cancer, dementia, and muscle diseases using zebrafish models.Read moreRead less
Head Development: Genetic Determinants And Tissue Potency
Funder
National Health and Medical Research Council
Funding Amount
$947,116.00
Summary
Congenital malformations involving major defects of brain (anencephalus and related anomalies) and facial structures (ear, face and neck) are encountered in 3.4 and 1.4 per 10000 births respectively (Congenital Malformations Australia 1981-1996, National Perinatal Statistics Unit) and they constitute a substantial clinical burden. It is believed that these major structural defects usually result from abnormal development in the first trimester, which coincides with the time frame for the formati ....Congenital malformations involving major defects of brain (anencephalus and related anomalies) and facial structures (ear, face and neck) are encountered in 3.4 and 1.4 per 10000 births respectively (Congenital Malformations Australia 1981-1996, National Perinatal Statistics Unit) and they constitute a substantial clinical burden. It is believed that these major structural defects usually result from abnormal development in the first trimester, which coincides with the time frame for the formation of the basic components of the embryonic head in the mouse. Knowledge of the formation of the head in the mouse model is therefore relevant to the understanding of related developmental processes in early human development. This project which involves the application of sophisticated embryological and molecular analyses on mouse embryos generated by transgenesis and genetic manipulation provides a detailed studies of craniofacial morphogenesis in a mammalian model for early human development. The micro-manipulation procedures, embryo culture, fluorescence microscopy and the in situ hybridization are routinely performed in our laboratory, and most of the mouse lines are well established in my laboratory. Experiments proposed for this project that focus on the embryological and molecular analysis of normal and mutant embryos should discover new information on the cellular and molecular mechanisms that regulate head development. The knowledge will also offer insight into the pathogenesis of similar craniofacial malformations in other mutant embryos.Read moreRead less
Coronary artery disease is the largest single cause of death in Australia, and commonly manifests as heart attack and angina. Congenital heart disease is the most common birth defect. We have identified a gene, Crim1, that is important for heart and coronary artery development. Investigating how this gene functions will lead to a greater understanding of congenital heart disease and may lay the foundation for therapeutics to regenerate damaged hear tissue.
In Australia, chronic kidney disease costs >$1 billion per annum and can only be treated by dialysis or transplantation. Your kidney function depends upon what happened during your development as all the functional units of the kidney are made prior to birth from a stem cell population that then disappears. We have found a way to recreate these stem cells from adult cells. In this project, we will optimise this process and investigate whether regenerated stem cells can repair an adult kidney.
Aberrant Mesenchymal-epithelial Transition: A Pathogenic Mechanism In Tissue Maintenance And Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$522,299.00
Summary
The causative genetic factors associated with aberrant changes of cellular properties are identified by analysing the profile and the control mechanism of gene expression. Specifically,this project will reveal how the transition of different patterns of tissue organization may be manifested in birth defects and malignant diseases.
One of the most critical steps in embryonic development is the assembly of the different tissue components into a three-dimensional structure in order to build a major body part of the foetus. In the development of the head, this form-shaping process undertaken by different cell populations is coordinated by genetic activity that is triggered by signals received by cells. The objective of our research is to understand how one of the many signalling mechanisms, WNT signalling, works in making the ....One of the most critical steps in embryonic development is the assembly of the different tissue components into a three-dimensional structure in order to build a major body part of the foetus. In the development of the head, this form-shaping process undertaken by different cell populations is coordinated by genetic activity that is triggered by signals received by cells. The objective of our research is to understand how one of the many signalling mechanisms, WNT signalling, works in making the head and face of the embryo. We will study the development of embryos of mice in which mutations have been introduced experimentally in genes that code for factors of the WNT signalling pathway. Understanding the complexity of tissue interactions and the interplay of molecular mechanisms of head formation in the embryo is a major challenge. However, knowledge of the processes in animal models will contribute to a better delineation of the role of signalling in normal head development. It will also help to direct the focus of future clinical investigations to the most relevant genetic determinants of birth defects of the head and face, which is present in about 8 per 10,000 births in Australia.Read moreRead less