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Mechanisms Underlying Growth, Lineage Commitment And Differentiation Of Liver Progenitor Cells
Funder
National Health and Medical Research Council
Funding Amount
$535,333.00
Summary
Liver disease is a serious health problem. Viral hepatitis, obesity and alcohol can result in end-stage liver disease. Organ transplant is the only treatment available. A widening gap between organ donations and recipients mandates alternative treatments are developed. Cell transplantation and artificial liver devices are alternatives which can use liver progenitor cells. We will investigate how factors grow and convert them into liver cells for treating liver disease patients.
When Prometheus Needs A Hand – How Human Amnion Epithelial Cells Resolve Fibrosis And Regenerate The Liver
Funder
National Health and Medical Research Council
Funding Amount
$530,653.00
Summary
Cirrhosis can progress to end stage disease for which transplantation provides the only hope for survival. Liver donors in Australia are scarce; the need for donor organs is increasing. Using stem cells to repair and regenerate damaged liver may provide an alternative to organ transplantation. We are studying placental stem cells that can decrease inflammation and increase progenitor cells to repair and regenerate liver. Our goal is to use these stem cells as treatment for human liver disease
Understanding And Applying Macrophage-mediated Effects On Liver Progenitor Cells To Treat Liver Disease.
Funder
National Health and Medical Research Council
Funding Amount
$628,109.00
Summary
As liver cancer risk correlates with increased liver stem/progenitor cell numbers, therapies that reduce their numbers will reduce cancer development. On the contrary, therapies to increase progenitor cell numbers will assist their use in cell therapy-based approaches or artificial liver devices to treat chronic liver disease. This project will determine how to use inflammatory cells to manipulate progenitor cell numbers.
Leveraging Genomics Strategies To Generate Adult Neurons From IPSCs And Somatic Cells
Funder
National Health and Medical Research Council
Funding Amount
$1,593,336.00
Summary
Recent advances have made it possible to derive myriad specialized human cells from stem cells or by directly reprogramming cell identity. However, these derived cells are generally arrested at a fetal developmental stage, and do not mature to function like adult cells. We will use new genomic, epigenetic, cell reprogramming, and manipulation methods to discover how to derive mature cells, aiming to generate mature neurons for use in neurobiology research, disease modeling, and drug screening.
Most eye diseases have a genetic contribution, whether rare disorders affecting children such as retinoblastoma or congenital cataracts through to common disorders of older people such as myopia, age-related macular degeneration or glaucoma. We will continue our successful research to find genes that cause these diseases and use this to improve patient care and prevent blindness. We will work out how families can use this genetic information to participate in trials to develop new treatments.
Magnetically controlled drug release from tissue scaffolds for the treatment of acute burns. Severe skin burns are frequently associated with functionally disabling scarring and the risk of death. New magnetically activated wound seals for the treatment of acute burns will be developed that reduce the need for frequent painful dressing changes and hence facilitate rapid healing with a significantly reduced chance of scarring.
Rapid mapping of genes for complex traits. This project will develop a new resource that will allow rapid identification of genes controlling complex traits. This world-leading resource will improve knowledge of diseases like diabetes and neurological diseases.
From causative genes to establishing therapies for patients with neuromuscular diseases. A major focus of this project will be pursuing multiple therapeutic approaches for a class of skeletal muscle diseases, which are most often severe and lethal within the first year of life. It will also hunt down the defective genes in human patients with other neuromuscular diseases and explore how these cause disease.
The development of tools to study carbohydrate-processing enzymes implicated in human disease. Diseases caused by improper function of carbohydrate-processing enzymes are a major health burden. This research aims to find ways to restore the function of these enzymes bringing a better quality of life to people suffering from these diseases.
Kruppel-like factors and the methylome. This project aims to test the hypothesis that the KLF/SP family of transcription factors work in part via dynamic interactions with methylated cytosine nucleotides in DNA. This is fundamental to their function as pioneer factors in reprograming and their ability to co-ordinate differentiation and organogenesis. Conversely, dynamic changes in methylation status engage or disengage new regulatory elements in the genome via recruitment of KLF/SP family protei ....Kruppel-like factors and the methylome. This project aims to test the hypothesis that the KLF/SP family of transcription factors work in part via dynamic interactions with methylated cytosine nucleotides in DNA. This is fundamental to their function as pioneer factors in reprograming and their ability to co-ordinate differentiation and organogenesis. Conversely, dynamic changes in methylation status engage or disengage new regulatory elements in the genome via recruitment of KLF/SP family proteins as specific effectors. This project will address a new paradigm in genetics that is likely to underpin development.Read moreRead less