Defining A Role For The STONED Proteins In The Synaptic Vesicle Cycle
Funder
National Health and Medical Research Council
Funding Amount
$301,527.00
Summary
Nerve cells communicate with each other by means of chemical neurotransmitters. The level of communication is strictly controlled, and changes in the level, either up or down, is known as synaptic plasticity. This plasticity is thought to underly changes in the brain that account for both long and short term memory. Uncontrolled alterations in plasticity can also induce abnormal brain function, resulting in neurological disorders. Changes in the release of neurotransmitter are regulated at the m ....Nerve cells communicate with each other by means of chemical neurotransmitters. The level of communication is strictly controlled, and changes in the level, either up or down, is known as synaptic plasticity. This plasticity is thought to underly changes in the brain that account for both long and short term memory. Uncontrolled alterations in plasticity can also induce abnormal brain function, resulting in neurological disorders. Changes in the release of neurotransmitter are regulated at the molecular level by unknown mechanisms, however the chemical neurotransmitters are enclosed in small vesicles and it is believed that the control of the release of these vesicles, and their recycling, are important components of this mechanism. We have identified a gene that encodes two novel proteins of neurotransmission. Mutations that alter these genes can result in either increased or decreased synaptic activity. By using a combination of genetic and molecular techniques we propose to investigate how one of these two proteins operate to alter synaptic activity, as well as attempting to show how it interacts with other components of the synaptic machinery.Read moreRead less
THE ROLE OF NOVEL TUMOUR SUPPRESSORS DURING DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$200,880.00
Summary
Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are intereste ....Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell proliferation, and have been studying this in the genetically amenable animal model system, Drosophila. Central to the control of cell proliferation in all organisms are the Cyclin dependent protein kinases. Cyclin E-dependent protein kinase is required to drive cells from the G1 (resting state) into S phase (where DNA replication occurs). Correct control of Cyclin E is important in limiting cell proliferation and many cancer causing mutations result in up-regulation of this critical cell cycle regulator and premature entry into the cell cycle. We have used a genetic approach using a weak mutation in Drosophila Cyclin E to isolate mutations in other important regulators of the G1 to S phase transition. We have identified a number of genes that act to negatively regulate the cell cycle, 2 of which have characteristics typical of tumour suppressors. We have identified candidate genes for 3 of these mutations, all of which encode novel proteins related to mammalian proteins involved in negative regulation of cell proliferation or tumour suppressors. In this proposal we seek to determine the way in which these proteins function to control cell proliferation in Drosophila. Due to the remarkable conservation of genes involved in cell proliferation control through evolution, this study is likely to be highly relevant to the control of cell proliferation and the development of cancer in humans.Read moreRead less
Fibroblast Growth Factors In The Development Of Forebrain Commissures
Funder
National Health and Medical Research Council
Funding Amount
$497,796.00
Summary
In order to function correctly the two hemispheres of the brain must communicate information. This communication occurs across large fibre tracts called commissures. There are three commissural projections in the forebrain; the corpus callosum, the hippocampal commissure and the anterior commissure. Here we investigate the development of these commissures and provide a comprehensive analysis of the role of several secreted, fibroblast growth factor proteins, in their development.
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.
The Primary Cilium In Hedgehog Signalling And Disease
Funder
National Health and Medical Research Council
Funding Amount
$583,312.00
Summary
Every mammalian cell has a single protrusion called the primary cilium. Recent studies in mice and humans have highlighted the importance of the primary cilium in disease states affecting the limb, kidney, skeleton, brain, eyes, ears and lungs, as well as obesity and diabetes. We have isolated a novel mouse with a defect in the machinery required for correct functioning of the primary cilium. This mouse has widespread abnormalities and will be used to elucidate the role of cilia in disease.
Defining The Genetic Causes Of The Abnormal Vertebral Segmentation Syndrome, Spondylocostal Dysostosis
Funder
National Health and Medical Research Council
Funding Amount
$476,523.00
Summary
There are many birth defects that cause vertebral malformations along the spinal column. These occur as the embryo develops in utero, during the formation of structures known as somites. Somites also form the ribs, muscle, tendons and dermis. We are studying an example of this type of birth defect called spondylocostal dysostosis (SCD). We have shown that mutations in three different genes cause some cases of this inherited disease in humans. These genes are called DLL3, MESP2 and LFNG. However, ....There are many birth defects that cause vertebral malformations along the spinal column. These occur as the embryo develops in utero, during the formation of structures known as somites. Somites also form the ribs, muscle, tendons and dermis. We are studying an example of this type of birth defect called spondylocostal dysostosis (SCD). We have shown that mutations in three different genes cause some cases of this inherited disease in humans. These genes are called DLL3, MESP2 and LFNG. However, 80% of SCD patients do not have a mutation in any of these genes. Thus we need to discover how these other cases occur. This project uses two strategies in parallel. Firstly, we will analyse large families that have a history of SCD, and use this information to find causative gene mutations. However, a significant proportion of cases occur without family history. To find out what genes are involved in these cases is more difficult. We have created a mutant mouse by specifically deleting the DLL3 gene. This mouse has very similar vertebral malformations to SCD. We will compare embryos from normal and mutant mice to find genes that do not operate normally in the mutant. These genes are candidates for causing SCD, and thus we will screen these genes in human patients for mutations. However, simply finding a change in a candidate gene does not necessarily mean that this is the cause of SCD. To prove this, we have developed several tests to determine if the mutation alters the normal function of the protein encoded by the mutated gene. This work will greatly benefit the future genetic assessment of SCD patients. In addition, by studying our mouse model of SCD, we will gain a greater understanding of how DLL3 functions. This knowledge may be useful in developing stem cell-based therapies that involve the production of specific cell types.Read moreRead less
THE ROLE OF A NOVEL NEGATIVE CELL CYCLE REGULATORY PATHWAY DURING ANIMAL DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$406,980.00
Summary
Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are intereste ....Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell proliferation, and have been studying this in the genetically amenable animal model system, Drosophila. Central to the control of cell proliferation in all organisms are the Cyclin dependent protein kinases. Cyclin E-dependent protein kinase is required to drive cells from the G1 (resting state) into S phase (where DNA replication occurs). Correct control of Cyclin E is important in limiting cell proliferation and many cancer causing mutations result in up-regulation of this critical cell cycle regulator and premature entry into the cell cycle. We have used a genetic approach using a weak mutation in Drosophila Cyclin E to isolate mutations in other important regulators of the G1 to S phase transition. This proposal focuses on one of these regulators, Phyl, and the proteins that function with it, Sina and Ebi, which act to target and lead to the degradation of key proteins that negatively regulate differentiation and that promote cell proliferation. In this proposal we seek to understand how the Ebi-Phyl-SIna protein complex functions to control cell proliferation in Drosophila. In addition, we will examine whether the Sina complex also acts to inhibit cell proliferation in the mouse. Due to the remarkable conservation of genes involved in cell proliferation control through evolution, this study is directly relevant to the control of cell proliferation and the development of cancer in humans.Read moreRead less
Defining The Genetic And Environmental Factors That Cause Abnormal Vertebral Segmentation During Embryogenesis
Funder
National Health and Medical Research Council
Funding Amount
$724,147.00
Summary
Many birth defects cause vertebral malformations along the spinal column. They originate as the fetus forms, and may be caused by gene mutation or environmental factors. Whilst studying one type of vertebral malformation we have found a genetic cause for 30% of cases. We will investigate the genetic and environmental cause of the remainder. We will look for new genes causing this disease, and use a mouse model to learn how low oxygen levels during pregnancy causes such malformations
Dissecting The Role Of Hedgehog Signalling In Chondrogenesis And Skeletal Disease
Funder
National Health and Medical Research Council
Funding Amount
$408,739.00
Summary
There are close to 400 inherited disorders that affect how the skeleton develops, as well as a range of injury and age-related skeletal defects. There is much interest in treating such abnormalities with artificial bone grown outside the body. In order to achieve this aim we must understand all of the processes involved in producing and maintaining bone within the body. We are using both mouse and cell culture models of skeletal development to increase our understanding of these processes.