This work will analyse how cells, the building blocks of tissues, are organized together to form functioning organs. It focuses on the adhesion molecules that allow cells to recognize one another, which cooperate with the internal skeleton of cells to link them together. We aim to understand how these cellular systems work normally and how they are targeted to disrupt tissue integrity in diseases like cancer and inflammation.
The Role Of The Mammalian Grainyhead-like Gene Family In Neural Tube Closure
Funder
National Health and Medical Research Council
Funding Amount
$569,541.00
Summary
Failure of the skin to close over the brain and spinal cord during human development results in the devastating congenital birth defects anencephaly and spina bifida, known collectively as the neural tube defects. These are the second most common congenital birth defects affecting 1:1000 pregnancies. Anencephaly is not compatible with life and affected babies die at birth. In contrast children with spina bifida survive, but suffer from limb paralysis, bowel and bladder dysfunction, learning diff ....Failure of the skin to close over the brain and spinal cord during human development results in the devastating congenital birth defects anencephaly and spina bifida, known collectively as the neural tube defects. These are the second most common congenital birth defects affecting 1:1000 pregnancies. Anencephaly is not compatible with life and affected babies die at birth. In contrast children with spina bifida survive, but suffer from limb paralysis, bowel and bladder dysfunction, learning difficulties and psycho-social disturbances. Our laboratories have identified a family of genes essential for the colsure of the neural tube in mammals. The aim of this proposal is to understand the mechanisms of action with a view to developing new therapeutics that mey be used preventatively in these conditions. We also hope that these studies may facilitate the development of a genetic test to screen couples at risk.Read moreRead less
Biological, Functional And Radiographic Evaluation Of Autologous Chondrocyte Implantation
Funder
National Health and Medical Research Council
Funding Amount
$307,400.00
Summary
We will test the hypothesis that autologous chondrocyte implantation (ACI) and extensor realignment produces superior clinical, biological and radiographic results when compared with conventional treatment of realignment and debridement. We will specifically address the following aims: 1. Quantify the clinical outcome of ACI compared to the traditionally used treatment of debridement through the use of functional evaluation in a blinded randomised controlled clinical trial; 2. Evaluate the radio ....We will test the hypothesis that autologous chondrocyte implantation (ACI) and extensor realignment produces superior clinical, biological and radiographic results when compared with conventional treatment of realignment and debridement. We will specifically address the following aims: 1. Quantify the clinical outcome of ACI compared to the traditionally used treatment of debridement through the use of functional evaluation in a blinded randomised controlled clinical trial; 2. Evaluate the radiographic changes in the patellofemoral joint that occur as a result of ACI, using high resolution magnetic resonance imaging (MRI) to quantify the regeneration of hyaline articular cartilage; 3. Using the new technique of confocal arthroscopy, we will compare the histologic appearances of the ACI graft and its interface with adjacent articular cartilage; 4. Evaluate patient, surgical and explant chondrocyte characteristics in relation to functional, radiographic and biological outcomes. With respect to the matrix-induced autologous chondrocyte implantation (MACI) technique, we wish to clarify the clinical practice as a definitive treatment for articular cartilage defects. This will be the first randomised, controlled clinical trial of the MACI technique compared to that used by other groups. A positive clinical outcome from this trial will help promote the three cornerstones of this procedure – successful cell culture, efficient surgical procedures, and complimentary postoperative rehabilitation. Furthermore, this research will: a) Enhance the expansion of the MACI technique; b) Encourage development of endoscopic techniques of implantation using a combination of – • Preoperative defect registration with MRI • pre-cut custom patches, implanted with • Computer-assisted navigation techniques: c) Increase the potential to cater for a larger number of patients requiring articular cartilage repair; d) Confirm the long-term durability of regenerated cartilage in the 4th year and beyond; e) Add further commercial value by demonstrating MACI may prevent the onset of osteoarthritis.Read moreRead less
Identification And Characterisation Of Genes Required For Cardiac Morphogenesis
Funder
National Health and Medical Research Council
Funding Amount
$434,706.00
Summary
The heart is the first organ to become functional as an embryo forms, reflecting its critical role in sustaining life. Mistakes that occur as the heart develops have devastating consequences for an individualÍs survival and health. We have identified two zebrafish mutants with heart defects and, using sophisticated imaging and genetic studies, will investigate these defects and identify the genes responsible. This research will improve our understanding of correct and diseased heart formation.
Cortactin: Molecular Regulation Of Cadherin Activity And Epithelial Morphogenesis.
Funder
National Health and Medical Research Council
Funding Amount
$239,250.00
Summary
Interactions between cells and their neighbouring cells control many important processes in the body. The adhesion molecule E-cadherin is a major protein that controls how cells interact with one another in many epithelial tissues (e.g. breast, lung, gut). These tissues are the source of many common diseases, particular cancer and inflammation. E-cadherin is essential for these tissues to form normally, and loss of E-cadherin function contributes to disease in these tissues (especially common ca ....Interactions between cells and their neighbouring cells control many important processes in the body. The adhesion molecule E-cadherin is a major protein that controls how cells interact with one another in many epithelial tissues (e.g. breast, lung, gut). These tissues are the source of many common diseases, particular cancer and inflammation. E-cadherin is essential for these tissues to form normally, and loss of E-cadherin function contributes to disease in these tissues (especially common cancers, such as breast and lung). Understanding how E-cadherin controls normal cell function in these tissues will therefore provide key insights into how disease arises. In this study we will investigate how a protein which binds to E-cadherin, cortactin, contributes to the biological effect of E-cadherin in supporting tissue architecture. Understanding the fundamental elements of how cortactin works with E-cadherin will provide invaluable information into how cells recognize one another in health, and fail to adequately recognize each other in common diseases.Read moreRead less
MicroRNAs are small molecules that modulate the expression of most genes and so affect nearly every biological process and pathology although, they were only discovered in humans less than 10 years ago. The bottleneck in discovering the functions of miRNAs is in identifying their molecular targets, the majority of which remain unknown. We aim to comprehensively identify direct target genes of epithelial-specific microRNAs and to confirm a number of them by gene target validation approaches.
Identifying The Critical Pathways Which Regulate Vertebrate Craniofacial Development
Funder
National Health and Medical Research Council
Funding Amount
$552,131.00
Summary
Understanding the genes which underlie human birth defects is of immense clinical importance. Our laboratory is a world-leader investigating a gene responsible for facial skeleton development, Grhl2. With our wide range of models, we will discover how Grhl2 works to ensure the face and skull develop properly during birth.
Investigating The Genetic Cause Of Genital Abnormalities In Males
Funder
National Health and Medical Research Council
Funding Amount
$299,564.00
Summary
This project investigates the genetic cause of a relatively common defect in male genitalia, hypospadias, in which the penis opening is aberrantly located. Hypospadias affects 1 in ~250 males, usually requires surgery and can cause problems with intercourse and urination. Using new technologies to study patient DNA, we will identify mutations causing hypospadias and new genes involved in development of the male genitalia. This will lead to improved clinical diagnosis and management of patients.
Role Of The MiR-200 Target Quaking In Alternative Splicing During EMT And Cancer Progression
Funder
National Health and Medical Research Council
Funding Amount
$443,160.00
Summary
The spread of cancer to other organs involves cancer cells changing to a more aggressive state and is a major cause of cancer related death. MicroRNAs are a class of genes that control whether cancer cells become more aggressive by regulating other genes. In this project we will examine the function of a new microRNA target which controls the cancer cell aggression. The outcome will be a better understanding of how cancers spread and the identification of new therapeutic targets.