The intestinal lining is continuously renewed by specialised cells called intestinal stem cells. Stem cells throughout the body are regulated by nearby connective tissues. But, the identity of these supportive cells in the gut are unknown. We test whether a discrete population of connective tissue cells in the gut support intestinal stem cells. This project will identify new cellular therapies and targets to promote intestinal repair and manage intestinal cancer.
Stem And Progenitor Cell Contribution To Skin Wounds And Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$408,388.00
Summary
Skin wounds represent a major health and economic burden. Although skin stem cells have been used routinely for the treatment of wounds, they cannot reconstitute a fully functional skin given the complexity and the many cell types usually involved in wound healing. In this project, we intend to evaluate the role of different cell populations on modulating skin wound healing to produce more regeneration and less scaring.
Dental diseases affecting the gums (periodontal diseases) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised chewing function. If left untreated, the associated loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characterize these cell ....Dental diseases affecting the gums (periodontal diseases) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised chewing function. If left untreated, the associated loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characterize these cells and explore whether they can be used to restore periodontal tissues damaged by periodontal disease.Read moreRead less
The Role Of Angiopoietin-1 In The Self-renewal And Metastasis Of Prostate Cancer Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$558,742.00
Summary
Bone metastasis occurs in more than 80% of cases of advanced prostate cancer (PCa), and is the major cause of morbidity and mortality in PCa patients. Understanding why PCa cells preferentially metastasize to bone may lead to the the development of novel therapy for inhibiting PCa metastasis. This project will study how the bone cell-secreted protein angiopoietin-1 promotes the metastasis of PCa cells to bone and whether inactivation of this protein can inhibit PCa bone metastasis.
Role Of Lamin A-C In Osteoblastogenesis And Age-related Bone Loss
Funder
National Health and Medical Research Council
Funding Amount
$475,515.00
Summary
Osteoporosis prevalence in Australia has increased, especially in the older population. Patients with accelerated aging (Hutchinson Gilford) suffer from severe osteoporosis. A mutation in lamin A-C was identified as the cause of this disease. Therefore it could be the link between aging and bone loss. We will identify the role of lamin in bone biology. We will generate a new understanding of the connection between aging and bone loss and a new potential therapeutic target for senile osteoporosis
GENERATION OF VASCULARISED, BIOENGINEERED SOFT TISSUES
Funder
National Health and Medical Research Council
Funding Amount
$445,045.00
Summary
One of the most exciting areas in reconstructive surgery today is the tissue engineering of body parts, the process by which blood vessels are implanted into skin, muscle, bone, cartilage or even synthetic materials, to build composite living structures. Once a circulation becomes established, the engineered part can be transferred by joining the implanted blood vessels to corresponding ones at the recipient site. We have discovered that new tissue will grow out of a surgically created blood ves ....One of the most exciting areas in reconstructive surgery today is the tissue engineering of body parts, the process by which blood vessels are implanted into skin, muscle, bone, cartilage or even synthetic materials, to build composite living structures. Once a circulation becomes established, the engineered part can be transferred by joining the implanted blood vessels to corresponding ones at the recipient site. We have discovered that new tissue will grow out of a surgically created blood vessel loop placed in a cylindrical plastic chamber filled with a scaffold made of naturally occurring structural molecules. In Part 1 of this project, it is planned to optimise the rate of new vascularised tissue growth through the addition to the growth chamber of various biodegradable scaffolds. In Part 2, we aim to produce fat by 3 possible methods using: (a) cells from the rat scrotum, (b) skeletal muscle separated from its blood supply for 24 hours, or (c) bone marrow-derived stem cells, as well as bone from stem cells of the same source. In Part 3, vascularised bone, fat and connective tissue, as produced in Part 2, will be microsurgically transferred to another site in the body to study the short-term (4 weeks) and long-term (12 weeks) survival and changes (if any) in these tissues. These unique methods are currently being patented. This technology introduces the possibility of producing tailor-made tissues of specific composition to suit the repair of a particular tissue type, for example, (1) myocutaneous flaps to replace tissue loss following traumatic injury, (2) bone for nose, digit or joint repair, and (3) fat to provide a bulky flap as required in contour defects of the face and neck. The development of new growth chambers of appropriate body shapes (eg. ears, noses, etc) has significant commercial implications.Read moreRead less
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.
Haematopoietic Stem Cells From Human Pluripotent Stem Cells: The Future Of Bone Marrow Transplantation
Funder
National Health and Medical Research Council
Funding Amount
$763,845.00
Summary
Blood stem cell transplantation is a vital therapy for patients with leukaemia following chemotherapy or for patients with bone marrow failure. Because many patients lack a donor, there is a need for an alternate source of stem cells. My laboratory will make blood stem cells from human pluripotent stem cells that will treat patients needing a transplant and will be a useful research tool to help us to understand what goes wrong in the blood system in a range of illnesses.
Adult and embryonic stem cells have enormous therapeutic potential. Haemopoietic stem cells have been the most intensely studied and widely used in a therapeutic setting, yet we have only a patchy knowledge of the genes required for their proliferation and survival. I will use classical genetic screens in the mouse to identify genes that regulate stem cell behaviour. I will analyse two existing mutant mouse strains with reduced numbers of haemopoietic stem cells, and execute a novel genetic scre ....Adult and embryonic stem cells have enormous therapeutic potential. Haemopoietic stem cells have been the most intensely studied and widely used in a therapeutic setting, yet we have only a patchy knowledge of the genes required for their proliferation and survival. I will use classical genetic screens in the mouse to identify genes that regulate stem cell behaviour. I will analyse two existing mutant mouse strains with reduced numbers of haemopoietic stem cells, and execute a novel genetic screen utilising mice with a defect in the self-renewal of adult haemopoietic and neural stem cells, to find mice with a recovered stem cell compartment.Read moreRead less