Determining The Pathobiology Of Human Sarcomeric Myopathies Using Zebrafish
Funder
National Health and Medical Research Council
Funding Amount
$509,541.00
Summary
Laing muscular dystrophy and ACTA1 congenital muscular dystrophy are severe muscle diseases with high morbidity. We will create zebrafish strains that carry these diseases and use these to understand the causes of muscle failure and investigate possible areas of treatment for these conditions.
The Role Of Scube Genes In Hedgehog Signal Transduction
Funder
National Health and Medical Research Council
Funding Amount
$496,446.00
Summary
Cancer often results form the miss-regulation and-or mutation of genes that control tissue formation in the developing embryo. Particular sets of genes combine to form a signal transduction pathway that coordinates the cell's response to its environment during the course of normal fetal growth. One such pathway is called the Hedgehog signal transduction pathway which has been shown to coordinated cell division and patterning within malignant and normal tissues. Genes encoding components of this ....Cancer often results form the miss-regulation and-or mutation of genes that control tissue formation in the developing embryo. Particular sets of genes combine to form a signal transduction pathway that coordinates the cell's response to its environment during the course of normal fetal growth. One such pathway is called the Hedgehog signal transduction pathway which has been shown to coordinated cell division and patterning within malignant and normal tissues. Genes encoding components of this pathway are mutated in the most common forms of human cancers. Understanding how this pathway is regulated is critical to designing strategies to treat the onset and progression of these cancers. The studies outlined in this grant plan to study a new component of this pathway that we have identified in our laboratory, in an easy to study vertebrate model, the zebrafish embryo. We plan to study how this class of proteins, termed scube proteins, acts to control activation of the pathway. We hope this will lead to a fuller understanding of this process, and at the same time help understand the nature of the end result of the patterning process within the muscle cells that we are studyingRead moreRead less
The Regulation And Function Of Cadherin-mediated Adhesion Within The Zebrafish Myotome.
Funder
National Health and Medical Research Council
Funding Amount
$436,773.00
Summary
Co-ordinating how cells interact with their neighbours and where different cells are positioned within an organ is the role of proteins termed cell adhesion molecules. They delineate and sort cells into different groups depending on which cell adhesion molecules are expressed on their surface. Cell adhesion molecules are also important during the onset of disease, in particular cancer, where the levels and type of cell adhesion molecules expressed on the surface of a cancer cell can determine ho ....Co-ordinating how cells interact with their neighbours and where different cells are positioned within an organ is the role of proteins termed cell adhesion molecules. They delineate and sort cells into different groups depending on which cell adhesion molecules are expressed on their surface. Cell adhesion molecules are also important during the onset of disease, in particular cancer, where the levels and type of cell adhesion molecules expressed on the surface of a cancer cell can determine how invasive or aggressive the cancer cell will become. However, despite the fundamental importance that cell adhesion plays in sorting out cells in every tissue, the exact basis of cell migratory behaviours that occur within the intact organism remain poorly defined. We have examined the ability of specific members of a particular class of cell adhesion molecules, the classical Cadherins, to control formation of muscle. To do this we have examined muscle formation within embryos of the zebrafish, a small embryologically accessible fresh water fish. We have determined how different cadherin molecules co-ordinate the final pattern of the myotome, the structure that gives rise to the majority of muscle in the early embryo. We have determined that differential cell adhesion drives cell sorting of specific muscle cell types via differential use of members of the classical cadherin family of proteins. This study aims to look further at the way that these proteins are regulated in different muscle cells of the forming body. By understanding how these molecules regulate cell sorting and adhesion within the zebrafish myotome we hope to be able to apply this knowledge to how these molecules control the formation of more complex tissues. Furthermore, we believe the implication of specific signalling pathways in the control of cadherin gene expression has particular implications for the role these proteins play in the progression of metastatic cancer.Read moreRead less
Analysis Of The Function Of The Presenilin Genes During Embryogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$197,317.00
Summary
The presenilin genes are essential for normal human mental health. Deleterious changes in presenilin genes are the root cause of 60% of Alzheimers Disease that is inherited within families (ie. Oearly onsetO Alzheimers disease) and of 10% of all Alzheimers disease. Normal presenilin genes are also necessary for correct embryo development. There is evidence that the proteins produced by the presenilin genes interact with other proteins such as those produced by the Notch genes. Changes in Notch g ....The presenilin genes are essential for normal human mental health. Deleterious changes in presenilin genes are the root cause of 60% of Alzheimers Disease that is inherited within families (ie. Oearly onsetO Alzheimers disease) and of 10% of all Alzheimers disease. Normal presenilin genes are also necessary for correct embryo development. There is evidence that the proteins produced by the presenilin genes interact with other proteins such as those produced by the Notch genes. Changes in Notch genes can also produce dementia and developmental defects. However, despite their obvious importance, we know little about how presenilin and Notch genes function and interact! We want to understand how presenilin genes interact with Notch genes and any other genes that are important for normal embryo development. To investigate this we are using the eggs of a small, freshwater fish, the zebrafish. These eggs are easily available (hundreds are produced by a female zebrafish every week), accessible and, being transparent, every cell in a developing zebrafish egg can be observed! They also develop about one hundred times faster that a human! In our experiments we will produce antibodies to the protein products of the presenilin and Notch genes of zebrafish and then use these to observe interactions between the presenilin and Notch proteins. We will observe how changes in the levels of presenilin protein in an embryo affect the function of the Notch genes and we will attempt to discover other genes that are affected by such changes. This work will be important for understanding how genes interact to create our bodies during embryo development. Also, since genes typically interact in similar ways during embryo development and in adults, the discoveries that we make will help us to understand what goes wrong when changes in the presenilin genes cause Alzheimers disease.Read moreRead less
The Role Of Crim1, A Novel TGFb Superfamily Modulator, In Early Vertebrate Patterning, Vascular And Renal Development.
Funder
National Health and Medical Research Council
Funding Amount
$501,300.00
Summary
The transforming growth factor (TGF) beta superfamily is a large group of secreted growth factors who play many different roles in normal development of tissues such as the brain, skeleton, heart, kidney, eyes, teeth and limbs. One of the groups within the superfamily, the bone morphogenetic proteins (BMPs), are being used in clinical trials to assist in regrowing bones after fracture. These molecules are also of interest for clinical reasons as growth factors within this family can also be dele ....The transforming growth factor (TGF) beta superfamily is a large group of secreted growth factors who play many different roles in normal development of tissues such as the brain, skeleton, heart, kidney, eyes, teeth and limbs. One of the groups within the superfamily, the bone morphogenetic proteins (BMPs), are being used in clinical trials to assist in regrowing bones after fracture. These molecules are also of interest for clinical reasons as growth factors within this family can also be deleterious, with their overexpression leading to conditions such as renal fibrosis and cataract. The activity of these growth factors is regulated by many other proteins, including protein antagonists which bind and inactivate them. It is therefore possible that by understanding these antagonists, we can find new ways of altering TGF beta superfamily activity. We have previously identified a novel protein, Crim1, which we have now shown can bind to TGF superfamily members and can reduce their secretion. We believe that Crim1 plays a role in the patterning of the central nervous system, the development of the blood vessels and the kidneys by regulating the TGFbeta superfamily. In this grant we will be investigating what the effect of disruption to Crim1 is on these organ systems and working out which members of the TGFbeta superfamily it is affecting to cause these effects. To do this, we will knock out the gene in zebrafish and characterise the defects found in a mouse line in which the gene has been disrupted. This may be important in developing new ways of activating or inactiviating these growth factors in a number of clinical conditions.Read moreRead less
Characterisation Of Conserved Sox18-dependent Genes In Lymphatic Vascular Development
Funder
National Health and Medical Research Council
Funding Amount
$401,355.00
Summary
Lymphatic vessels are important in a number of diseases including lymphoedema and cancer. There is a significant gap in our basic understanding of how lymphatic vessels form. We have identified a series of genes that are regulated downstream of the lymphatic master gene Sox18 in mouse lymphatic vessels. This study aims to characterise these genes using complementary model systems. The genes and pathways identified will represent potential therapeutic targets in a number of disease contexts.
The Mechanism Of Ccbe1 Function During Lymphangiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$502,437.00
Summary
Tumours induce the regional growth of lymphatic vessels (in a process termed lymphangiogenesis) and then spread (a process termed metastasis) via lymphatic vessels and lymph nodes. Inhibiting lymphangiogenesis can inhibit metastasis. We have identified a gene called ccbe1 that is essential for lymphangiogenesis during development. We aim to understand how this potential therapeutic target functions at the molecular level during lymphangiogenesis.
A New BTB-ZF Family Transcription Factor Required In Development And Dysregulated In Malignant Disease
Funder
National Health and Medical Research Council
Funding Amount
$439,813.00
Summary
We are studying the function and biology of a novel gene that looks like a generegulator. We generated a zebrafish mutant with defective myeloid development, and we found this gene causes the defect. This mutant fish provides a handle on the biological function of the gene in development. This gene has the hallmarks of a transcription factor and we will study how it regulates other genes, and how it may be a target for treatment of several cancers in which expression of this gene is activated.
Molecular And Cellular Basis For Muscle Regeneration In Zebrafish.
Funder
National Health and Medical Research Council
Funding Amount
$541,104.00
Summary
Muscle repair occurs via the use of muscle stem cells, which provide skeletal muscle with its regenerative capacity. Muscle stem cells are particularly important in muscle diseases such as muscular dystrophies where muscle regeneration is an important factor in disease progression. We will identify the processes controlling muscle regeneration utilising zebrafish as a model organism. We hope this research will lead to an understanding of how muscle stem cells are generated.
Role Of Laminin-mediated Adhesion In Regulating Muscle Cell Attachment In Development And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$490,202.00
Summary
Muscular dystrophies and myopathies are amongst the largest group of inherited disorders to afflict the human condition. It is our hope that the results of this research will lead to a better understanding of how treatments could be employed to correct such disorders. Our development of zebrafish models of common muscular dystrophies allows us to study these disorders utilising the advantages of the zebrafish system.