Dendritic cells are essential components of our immune systems. They are located throughout our body and provide the first line of defence against invading microbes. Dendritic cells sense the invader and send out signals to recruit our immune cells to the site of infection. Our research aims to understand how our dendritic cell network is set up and how it functions to promote our immune health.
Understanding The Role Of The Essential Regulator WalKR In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$555,239.00
Summary
Staphylococcus aureus is one of the most common human bacterial pathogens. This project aims to characterise an important global control system in S. aureus, and determine if chemical inhibitors of this control system could be used to treat S. aureus disease in the future.
Identification Of Factors Critical For Maintenance Of The Epidermal Barrier
Funder
National Health and Medical Research Council
Funding Amount
$616,950.00
Summary
The human skin plays a crucial role in the body’s defence against our hostile environment. The outer most layer of the skin, the epidermis is the key structural component of the skin barrier and is essential for its integrity. We have identified a family of genes that are pivotal for epidermal barrier formation, maintenance and repair. This project examines the mechanisms that underpin the function of this family, and has broad ramifications in a host of dermatological conditions.
Genetic Programs Orchestrated By AP-1 Transcription Factors In Colorectal Cancer Progression
Funder
National Health and Medical Research Council
Funding Amount
$599,941.00
Summary
Colorectal cancer (CRC) is the third most common cancer worldwide. About half of all patients diagnosed with the disease die as a result of its spread in the body. This project will investigate the role that a specific DNA-binding protein plays in orchestrating gene expression programs required for CRCs to spread. The research will provide new insights into underlying mechanisms of CRC progression as well as identify new therapeutic targets for aggressive forms of the disease.
Reprogramming is the conversion of any cell into induced pluripotent stem cells (iPSC). iPSC carry immense clinical potential as they are pluripotent and can hence form any cell of the human body, however, they can also form tumours. We have identified a cell type during reprogramming which is pluripotent but cannot form tumours. It is the aim of this project to determine the molecular differences between iPSC and this cell type in order to facilitate the delivery of cell replacement therapies.
Regulation Of TNF Expression In Inflammation And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$728,447.00
Summary
By studying a spontaneous mutation in mice, we have found an error in the TNF gene (a major factor in many inflammatory diseases) that causes severe arthritis, heart valve disease and gut inflammation. We have also identified new regulators of TNF expression, which might be useful therapeutic targets to limit inflammation. We intend to study the role of these regulators in controlling the expression of TNF, and the link between chronic inflammation and the development of cancer.
MicroRNA Networks That Safeguard The Functional Program Of Regulatory T Cells
Funder
National Health and Medical Research Council
Funding Amount
$457,941.00
Summary
A newly discovered group of molecules termed microRNAs are thought to function as rheostats for the activity of genes. We have shown that these molecules are critical for the function of an immune cell type termed regulatory T cells. Without these cells, the immune system is unable to prevent uncontrolled and destructive inflammation. This proposal aims to utilize diverse technologies to uncover the precise molecular mechanisms by which microRNAs safeguard the function of regulatory T cells.
Endocrine And Molecular Regulation Of Placental CRH Expression
Funder
National Health and Medical Research Council
Funding Amount
$466,980.00
Summary
Approximately 70% of infant death is associated with premature birth. Preterm birth occurs in 6-10% of pregnancies, and there has been no reduction in the rates of premature birth in the last 30 years. This is largely because we remain ignorant of how normal and abnormal birth is controlled. Understanding the physiology of human pregnancy is a critical step in the development of ways to detect and prevent preterm birth. Our group has demonstrated a link between production of a hormone (corticotr ....Approximately 70% of infant death is associated with premature birth. Preterm birth occurs in 6-10% of pregnancies, and there has been no reduction in the rates of premature birth in the last 30 years. This is largely because we remain ignorant of how normal and abnormal birth is controlled. Understanding the physiology of human pregnancy is a critical step in the development of ways to detect and prevent preterm birth. Our group has demonstrated a link between production of a hormone (corticotrophin releasing hormone, CRH) in the placenta and the length of time the baby is carried in the mother. In women who will deliver prematurely a rise in CRH occurs earlier in the pregnancy and more rapidly, while in women who deliver late the rise occurs more slowly. This work has given rise to the concept of a biological clock that determines the length of time the fetus will be carried by the mother before birth, and in which production of CRH in the placenta plays a central role. We have been studying how the CRH gene is controlled in placental cells. We have discovered some regions in the DNA of the CRH gene which have important roles in controlling how much CRH is made by the placenta. The experiments described in this research project will determine the molecular mechanisms that control the production of CRH in the human placenta. This will be done in two ways: (1) by examining the DNA sequences involved in controlling expression of the CRH gene and (2) by identifying the proteins that actually perform the regulating functions that result in either increased or decreased amounts of CRH being produced by the placenta. This important information will help us better understand how normal and abnormal birth is controlled, and from that knowledge new ways to detect and prevent premature birth can be invented.Read moreRead less