Novel Probiotics And Naturally-sourced Extracts As Treatment Strategies For Chemotherapy-induced
Funder
National Health and Medical Research Council
Funding Amount
$322,183.00
Summary
Intestinal mucositis is a serious disorder associated with chemotherapy treatment in cancer patients. Recently, a new strain of probiotic bacteria has been described with the potential to decrease the severity of intestinal mucositis. However, it is not known whether the live probiotic is necessary for this effect. We will compare the live probiotic, dead probiotic and factors sourced from this probiotic for the potential to decrease the severity of intestinal mucositis. Similarly, there have be ....Intestinal mucositis is a serious disorder associated with chemotherapy treatment in cancer patients. Recently, a new strain of probiotic bacteria has been described with the potential to decrease the severity of intestinal mucositis. However, it is not known whether the live probiotic is necessary for this effect. We will compare the live probiotic, dead probiotic and factors sourced from this probiotic for the potential to decrease the severity of intestinal mucositis. Similarly, there have been anecdotal claims of medicinal application for so-called ‘bioactive’ extracts and formulations derived from a range of mammalian, marine and plant sources. Specifically, Lyprinol (an extract derived from the New Zealand Green-Lipped Mussel), Emu Oil (derived from Emu meat) and the herbal extract Iberogast, have been reported to possess antiinflammatory properties. Indeed, these agents are used widely for the adjunctive relief of symptoms associated with arthritis and joint pain. However, these agents have yet to be tested for their potential to treat or prevent intestinal mucositis. For the first time, utilizing proven, controlled animal model systems, the current submission will explore the therapeutic potential of these agents, alone and in combination with indicated probiotics, for their capacity to treat or prevent mucositis. Should efficacy be demonstrated, a potential mechanism of action will be sought by investigating effects on intestinal stem cells.Read moreRead less
Role Of LncRNA IDH1-AS1 In Regulating C-Myc Driven-glycolysis And Tumorigenesis
Funder
National Health and Medical Research Council
Funding Amount
$685,043.00
Summary
It is thought that understanding cancer metabolism will reveal vulnerabilities that can be exploited in the clinic. Indeed, compared to most normal cells, cancer cells utilise different fuels to sustain proliferation and to adapt to their environment. Herein we have discovered a molecular switch that regulates the key metabolic enzyme IDH1 and show this controls tumour growth. Given this switch may be active in 50% of cancers we anticipate our work will have significance to many cancer types.
Discovering The Function And Structure Of RIO Kinases – Toward New Nematocides
Funder
National Health and Medical Research Council
Funding Amount
$545,477.00
Summary
This project is focused on: high quality fundamental molecular science, contributing to national objectives, including the development of novel and innovative scientific concepts and international collaborations; consolidating links between basic and applied research; enhancing the skills-base in molecular biology and global visibility of Australian science.
Myosin VI: A Novel Molecular Apparatus For Epithelial Cohesion
Funder
National Health and Medical Research Council
Funding Amount
$605,096.00
Summary
Adhesion between cells holds the human body together and affects many aspects of our health including normal tissue and organ function. Conversely, loss of normal cell-cell adhesion contributes to major diseases, including cancer and inflammation. One key molecule, E-cadherin, is necessary for many epithelial organs and its function is perturbed in disease. This research project addresses how E-cadherin works with a cellular motor, Myosin VI, to maintain the integrity of epithelial tissues.
Mechanisms Of Hedgehog Signaling In Small Cell Lung Cancer
Funder
National Health and Medical Research Council
Funding Amount
$439,564.00
Summary
Some types of lung are very sensitive to chemotherapy, however they frequently relapse, at which time they become resistant to this form of treatment. This project investigates how embryonic signaling pathways, that normally function to regulate organ formation in development, are activated and promote tumor regrowth following chemotherapy for lung cancer.
Development Of Improved Vaccine Strategies For Measles Using Plant-derived Edible Vaccines
Funder
National Health and Medical Research Council
Funding Amount
$331,980.00
Summary
Measles is a highly contagious viral disease that is contracted via the respiratory tract. Severe infection may lead to complications such as otitis media, pneumonia, encephalitis. Despite our current vaccination strategy outbreaks still occur in Australia and measles is a major problem in developing countries. In developing nations the case fatality rate of measles is several hundred times that of developed nations. Over 800,000 children still die each year due to measles. Problems with the cur ....Measles is a highly contagious viral disease that is contracted via the respiratory tract. Severe infection may lead to complications such as otitis media, pneumonia, encephalitis. Despite our current vaccination strategy outbreaks still occur in Australia and measles is a major problem in developing countries. In developing nations the case fatality rate of measles is several hundred times that of developed nations. Over 800,000 children still die each year due to measles. Problems with the current vaccination strategy are: a) doesn't work in children less than 1 year of age, b) must be kept cold c) must be given by injection. We believe that a plant derived edible vaccine for measles will address the limitations of currently available vaccine i.e. we can give it children under the age of 1 year, it can be eaten and doesn't have to be kept cold.Read moreRead less
Molecular Characterisation Of Telomere Trimming And Its Role In Cell Proliferative Capacity
Funder
National Health and Medical Research Council
Funding Amount
$403,439.00
Summary
Telomeres are protective structures at the ends of chromosomes. Telomere length is a major determinant of how many times a cell can proliferate. We have recently discovered a rapid telomere shortening process that we have called telomere trimming. We will analyse the molecular details of this process to determine whether it could be used to shorten telomeres and stop cancer cell proliferation, and whether blocking it could increase cell proliferation in patients with short telomere syndromes.
Adhesion between cells is important during health and disease. Cell-cell interactions are necessary both as the embryo forms and to preserve tissues and organs in later life. Important disease states arise when cell-cell adhesion is broken. Only by understanding the molecular mechanisms that hold cells together can we analyse how they are perturbed to cause diseases such as cancer and inflammation.
Regulation Of Dynamic Cell-cell Adhesions By Coordinated Action Of Lipid Kinases And Phosphatases
Funder
National Health and Medical Research Council
Funding Amount
$529,565.00
Summary
This research project studies the molecular mechanisms that allow cells to attach to, and recognize, one another. Such cell-to-cell adhesion is mediated by the cadherin family of molecules, which reside on the surfaces of cells. Cadherins allow cells to recognize one another and, upon recognition, to adhere to each other. By this means, populations of individual cells can be linked together into cohesive populations - i.e. the tissues and organs of the body. The importance of cadherin adhesion i ....This research project studies the molecular mechanisms that allow cells to attach to, and recognize, one another. Such cell-to-cell adhesion is mediated by the cadherin family of molecules, which reside on the surfaces of cells. Cadherins allow cells to recognize one another and, upon recognition, to adhere to each other. By this means, populations of individual cells can be linked together into cohesive populations - i.e. the tissues and organs of the body. The importance of cadherin adhesion is exemplified by the fact that disruption of cadherin adhesion contributes to many important diseases, especially inflammation and cancer. Thus understanding how cadherins hold cells together is necessary for us to understand the molecular basis of common diseases. In this project we study how cadherins signal to regulate cellular behaviour. We build on our recent discovery that E-cadherin can activate a lipid in the cell membrane, PIP3, that is known to be a key regulator of many cellular activities. We aim to understand how this signal is generated in response to E-cadherin adhesion and how it elicits normal cellular responses to cadherin adhesion.Read moreRead less